Mitochondrial stress in GABAergic neurons non-cell autonomously regulates organismal health and aging

Laxmi Rathor; Shayla Curry; Youngyong Park; Taylor McElroy; Briana Robles; Yi Sheng; Wei-Wen Chen; Kisuk Min; Rui Xiao; Myon Hee Lee; Sung Min Han

doi:10.7554/eLife.97767.1

eLife assessment

This study interrogates cell non-autonomous signaling between GABAergic neurons and somatic tissues in the nematode C. elegans. The authors report that mitochondrial stress in only GABAergic neurons extends lifespan and improves healthspan, phenotypes that are dependent on the transcription factor daf-16/FOXO3a. However, while the findings may be valuable to furthering our understanding of neuronal control of aging and health, the current evidence is incomplete and additional experiments are needed to support their claims.

https://doi.org/10.7554/eLife.97767.1.sa3

Significance of findings

valuable: Findings that have theoretical or practical implications for a subfield

landmark
fundamental
important
valuable
useful

Strength of evidence

incomplete: Main claims are only partially supported

exceptional
compelling
convincing
solid
incomplete
inadequate

During the peer-review process the editor and reviewers write an eLife assessment that summarises the significance of the findings reported in the article (on a scale ranging from landmark to useful) and the strength of the evidence (on a scale ranging from exceptional to inadequate). Learn more about eLife assessments

Abstract

Mitochondrial stress within the nervous system can trigger non-cell autonomous responses in peripheral tissues. However, the specific neurons involved and their impact on organismal aging and health have remained incompletely understood. Here, we demonstrate that mitochondrial stress in γ-aminobutyric acid-producing (GABAergic) neurons in Caenorhabditis elegans (C. elegans) is sufficient to significantly alter organismal lifespan, stress tolerance, and reproductive capabilities. This mitochondrial stress also leads to significant changes in mitochondrial mass, energy production, and levels of reactive oxygen species (ROS). DAF-16/FoxO activity is enhanced by GABAergic neuronal mitochondrial stress and mediates the induction of these non-cell-autonomous effects. Moreover, our findings indicate that GABA signaling operates within the same pathway as mitochondrial stress in GABAergic neurons, resulting in non-cell-autonomous alterations in organismal stress tolerance and longevity. In summary, these data suggest the crucial role of GABAergic neurons in detecting mitochondrial stress and orchestrating non-cell-autonomous changes throughout the organism.

Introduction

Mitochondria are essential organelles involved in various cellular functions, including energy production, calcium regulation, cell signaling, and apoptosis. Their reciprocal relationship with aging is widely acknowledged, wherein mitochondrial dysfunction impacts organismal longevity and health, and aging affects mitochondrial homeostasis across variable model animals ^{1, 2}. The degree of mitochondrial dysfunction determines the effect on an organismal lifespan. Mild mitochondrial disruption has been shown to increase lifespan in model animals such as C. elegans, flies, and mice ^3–10. For instance, the lifespan of C. elegans is extended by inhibiting mitochondria-related genes through genetic and RNA interference (RNAi) knockdown, including isp-1 (an iron-sulfur subunit of complex III of the mitochondrial electron transport chain (ETC)) ⁶, spg-7 (a mitochondrial quality control m-AAA protease) ^11–13, and clk-1 (a hydroxylase involved in the biosynthesis of ubiquinone) ^{5, 14}. Like C. elegans clk-1 mutant, mice with the mclk1 mutation, which exhibits normal growth and fertility, also exhibits an increase in lifespan ¹⁵.

The mechanisms underlying longevity enhancements through mitochondrial perturbations bring forth the mitohormesis theory that enhanced stress response pathways contribute to longer lifespans ^{4, 16–21}. It has been demonstrated that some mitochondrial stress requires the mitochondrial unfolded protein response (mitoUPR) pathway to trigger lifespan extension ^{4, 16–19}. The forkhead transcription factor DAF-16/FoxO has also been reported as an additional mediator responsible for extending the lifespan of C. elegans ETC mutants ^{20, 21}. However, certain mitochondrial perturbations and mutations in ETC genes can independently extend lifespan without involving atfs-1, a key regulator of mitoUPR ^{17, 22}. Similarly, it has been documented that DAF-16/FoxO is not indispensable in mediating the lifespan extension in some ETC mutants ⁶, suggesting a complex regulation of organismal aging in response to mitochondrial dysfunction through multiple pathways.

Aging is also accompanied by various changes in mitochondria, including the decreased activity of mitochondrial enzymes, reduced mitochondrial oxygen consumption, increased ROS production, decreased mitochondrial biogenesis, and increased mutations in mitochondrial DNA ^23–27. Interestingly, different types and levels of mitochondrial DNA mutations accumulate in various tissues during aging in humans and model animals ^{28, 29}. Even within a single tissue, such as the brain and muscle, variations in mitochondrial DNA mutations have been reported ^30–32. As a result, there is growing interest in understanding how organisms respond to mitochondrial stress in specific tissues and cells.

Recent studies have elucidated the phenomenon wherein perturbations in mitochondrial function within a specific tissue can elicit lifespan extension and health improvement ^{16, 33, 34}. Remarkably, the nervous system exhibits a particular role in detecting its intrinsic mitochondrial stress and extending organismal lifespan ^{16, 33–36}. However, it remains unclear which neuronal subtype is responsible for extending organismal longevity in response to their mitochondrial stress and what mechanisms underlie the non-cell-autonomous changes in this regard.

γ-aminobutyric acid (GABA) is a widely utilized neurotransmitter found in both vertebrate and invertebrate nervous systems. In vertebrates, a substantial proportion, estimated to be between 30% and 40%, of central nervous system synapses rely on GABA transmission ³⁷. GABA levels tend to gradually decrease as organisms age, and disruptions in GABA neurotransmission have been associated with various neurological disorders and age-related cognitive decline ^{38, 39}. In C. elegans, 26 neurons have been anatomically and functionally characterized as GABAergic neurons ^{40, 41}. Interestingly, recent studies in C. elegans indicate that the GABA signaling pathway plays an important role in regulating the lifespan and overall health of the organism, mitochondrial unfolded protein response, and proteostasis in the post-synaptic muscle tissue ^42–45.

In this study, we utilized C. elegans as a model organism to explore the role of GABAergic neurons in regulating organismal health and aging in response to mitochondrial perturbations, as well as the mechanisms underlying these effects. Our findings indicate that mitochondrial stress in GABAergic neurons can influence the activity of DAF-16/FoxO in peripheral tissues through GABA signaling. This, in turn, leads to non-cell-autonomous alterations in the mitochondria activity and organismal healthspan, reproductive capacity, and lifespan.

Results

Mitochondrial perturbations in GABAergic neurons are sufficient to prolong the organismal lifespan

To explore the influence of mitochondrial dysfunction in GABAergic neurons on lifespan and healthspan, we inhibited the functions of isp-1 and spg-7, well-documented genes that extend organismal lifespan when their normal functions are disrupted ^{11–13, 33, 46, 47}. In line with previous studies, systemic RNA interference (hereinafter referred to as sRNAi) targeting isp-1 and spg-7 significantly extended the lifespan of wild-type N2 animals when compared to control animals subjected to empty vector (EV) control RNAi (Figures 1A and 1B; Table S1). Tissue-specific RNAi in GABAergic neurons (hereinafter referred to as gRNAi) was accomplished by employing a previously well-established transgenic animal ^48–50. In this model, the function of rde-1, a member of the PIWI/STING/Argonaute protein family, was specifically restored in GABAergic neurons by introducing a transgene that expresses RDE-1 under the control of the GABAergic neuron-specific promoter derived from the unc-47 gene (Pgaba) (Figure 1C) ^{48, 51–53}. Additionally, they expressed sid-1, a gene responsible for dsRNA transport. When gRNAi against isp-1 was induced from the L1 stage, it resulted in a median lifespan extension of 55.5% compared to the control (Figures 1D and Table S1). spg-7(gRNAi) animals also showed an extended median lifespan of 33.3% (Figure 1E and Table S1).

Mitochondrial stress in GABAergic neurons is sufficient to prolong the organismal lifespan.
(A and B) Lifespan analysis of systemic *isp-1(sRNAi)* and *spg-7(sRNAi)* animals. (C) GABA-neuron-specific RNAi system. The gRNAi system is based on the *rde-1* mosaic mutant background, which carries a loss-of-function mutation in *rde-1*, thereby preventing RNAi ^{48, 50, 51, 53, 56, 131}. This system also involves *eri-1* and *lin-15* loss-of-function mutant backgrounds, resulting in hyperactivated RNAi sensitivity in all neurons ^{48, 132}. Restricted feeding RNAi to GABAergic neurons is achieved by exclusive RDE-1 expression in GABAergic neurons, along with the SID-1 dsRNA channel protein ⁴⁸. (D and E) Lifespan analysis of *isp-1(gRNAi)* and *spg-7(gRNAi)* animals. (F) GABAergic neuron-*specific isp-1* RNAi through *in vivo* transcription of sense and antisense RNAs in GABAergic neurons under the *sid-1(eq9)* null mutant background. (G) Lifespan analysis of *sid-1(qt9)* and *sid-1(qt9)*+Pgaba::isp-1 dsRNA animals. The significance of the lifespan curves (A, B, D, E, and G) was assessed using a Log-rank (Mantel-Cox) test. (H and I) The levels of lipofuscin in *isp-1(gRNAi)* and *spg-7(gRNAi)* animals at the 9-day-old adult stage were compared to those in control animals. (H) Representative images of lipofuscin fluorescence in the whole body of animals under the indicated conditions. Bar, 50 µm. (I) Quantification of lipofuscin fluorescence intensity. Each dot represents a single animal. ****P < 0.0001; one-way ANOVA test. Data are expressed as means ± SEM. Created with https://www.biorender.com/.
© 2024, BioRender Inc. Any parts of this image created with BioRender are not made available under the same license as the Reviewed Preprint, and are © 2024, BioRender Inc.

To exclude the possibility of any remaining systemic RNAi effects in the rde-1 mutant background, we carried out another tissue-specific RNAi strategy ⁵⁴. We expressed isp-1 double-stranded RNAs (dsRNAs) in GABAergic neurons using the Pgaba promoter (hereinafter referred to as Pgaba::isp-1 dsRNA) in the sid-1(qt9) null mutant background, which lacks intercellular dsRNA transport, preventing sRNAi (Figure 1F) ^{55, 56}. The expression of isp-1 dsRNAs in GABAergic neurons within the wild-type N2 animal background proved effective in upregulating the expression of Phsp-6::GFP, which serves as a fluorescent reporter for mitoUPR activity, specifically in the intestine, suggesting that this isp-1 dsRNA expression effectively induced mitochondrial defects (Figure S1A and S1B) ^{4, 34, 57}. Notably, we observed that Pgaba::isp-1 dsRNA expression in sid-1 null mutants also significantly extended organismal lifespan (Figures 1G and Table S1) ^58–60. Additionally, in 9-day-old adult isp-1(gRNAi) and spg-7(gRNAi) animals, we observed reduced lipofuscin fluorescence in the intestine, an aging hallmark that typically increases progressively over time (Figures 1H and 1I) ⁶¹. These findings collectively suggest that mitochondrial perturbation within GABAergic neurons is sufficient to prolong the organismal lifespan and attenuate the aging process.

Mitochondrial stress in GABAergic neurons increases the stress tolerance of the organism

Next, we sought to determine whether mitochondrial stress in GABAergic neurons could also alter the parameters of a healthspan. We tested thermal and oxidative stresses during aging, which are healthspan parameters closely linked to longevity across species ^62–66 (Figure 2A). In mid-age adults (3-day-old adult) groups, gRNAi against isp-1 and spg-7 increased survivability against paraquat exposure compared to controls (Figure 2B). This improvement was also observed in older adult groups (Figures 2C and 2D). Moreover, isp-1(gRNAi) and spg-7(gRNAi) animals displayed a significant increase in survival when exposed to thermal stress at 35 °C (Figures 2E-2G). To validate the efficacy of RNAi, we maximized the RNAi effect by culturing animals under the feeding RNAi condition against spg-7 for three generations (Figure S2A) and observed consistently improved survival rates in response to both oxidative stress (Figures S2B and S2C) and thermal stress (Figures S3D and S3E). In addition, sid-1 null mutants expressing Pgaba::isp-1 dsRNA expression also exhibited enhanced tolerance to thermal and paraquat stresses (Figures 2H and 2I). These findings suggest that mitochondrial stress in GABAergic neurons can enhance healthspan parameters.

Mitochondrial stress in GABAergic neurons enhances stress resistance
(A) A diagram illustrating the paraquat and thermal stress experimental procedures is provided. (B-D) The survival rate of animals cultured in indicated concentrations of paraquat for 24 hours was measured at 3, 6, and 9-day-old adult stages. (E-G) The survival rate after incubation at 35°C for 5 hours was measured in animals at 3, 6, and 9-day-old adult stages. At least 30 animals were tested for each set. Statistical significance is indicated as follows: (H-I) Survival rates of animals at the 3-day-old adult stage after 100 mM paraquat treatment for 24 hours (H) and 24 hours after incubation at 35°C for 5 hours (I) were measured. *P < 0.05, **P < 0.005, ***P < 0.0005, ****P < 0.0001; one-way ANOVA test. Data are expressed as means ± SEM.

GABAergic neuronal mitochondrial stress alters reproduction

While depletion of some mitochondrial ETC in the entire nervous system of C. elegans and flies increases lifespan in a non-cell-autonomous manner, it does not consistently affect fertility ^{8, 16}. Therefore, we sought to determine if mitochondrial dysfunction in GABAergic neurons similarly has no impact on reproduction. C. elegans exists as a hermaphrodite and produces a limited number of sperm in the L4 stage. In the adult stage, it undergoes oocyte development and self-fertilizes to produce embryos (Figure 3A) ^{67, 68}. While isp-1 mutant has a prolonged lifespan, it has been shown to have a reduced brood size ⁶⁹. Interestingly, isp-1 gRNAi was sufficient to reduce the number of fertile animals (Figure 3B). The total number of embryos produced by fertile isp-1(gRNAi) animals was also significantly decreased (P < 0.0001) (Figure 3C). When we assessed reproductive activity daily, fertile isp-1(gRNAi) animals displayed a reproductive period similar to that of the control group. However, brood sizes from the 2-day-old stage to the 4-day-old stage were significantly reduced (P<0.005 for the 2 and 3-day-old stages and P<0.0001 for the 4-day-old stage) (Figure 3D). Intrigued by these results, we evaluated the impact of isp-1(gRNAi) on the three critical stages of germline development including mitotic germ cell proliferation, meiotic germ cell apoptosis, and oogenesis (Figure 3A). Although the length of the mitotic area was not significantly affected by isp-1(gRNAi) (Figures 3E and S3A), the total number of mitotic germ cells was decreased during the early reproductive periods (1 to 3 days after the L4 stage) (Figure 3F). The number of apoptotic germ cells in the meiotic gonadal loop region, undergoing germline apoptosis, was not different from that in control animals at the 2-day-old adult stage, but it was substantially decreased at the 3-day-old stage (Figure 3G) ⁷⁰. Thus, an increased loss of meiotic germ cells was not likely the primary cause of the reduced brood size. Interestingly, 2-day-old adult isp-1(gRNAi) animals displayed large DNA aggregates in the proximal gonad, a characteristic feature of an endomitotic oocyte phenotype (Figures 3H and 3I)⁷¹. Once embryos were produced, most of them were hatched in isp-1(gRNAi) animals (Figure S3B). Our results indicated that disruption of the mitochondrial ETC in GABAergic neurons negatively affected germline development and reproductive ability.

Reproductive effects of mitochondrial perturbation in GABAergic neurons.
(A) A diagram of the *C. elegans* hermaphrodite reproductive system was presented, showing the distal gonad with the mitotic area for germ cell proliferation, the meiotic germ area for meiosis, and an area undergoing germ cell apoptosis, the proximal area with oogenesis, the spermatheca for sperm storage, and the uterus for fertilized egg storage. (B) Sterility in *isp-1(gRNAi)* animals compared to control animals. (C) The total number of embryos in fertile *isp-1(gRNAi)* and *spg-7(gRNAi)* animals. (D) The daily brood size in fertile *isp-1(gRNAi)* and *spg-7(gRNAi)* animals. (E) Representative images of dissected distal gonad arms stained with DAPI from 2-day-old *isp-1(gRNAi)* and control animals. The dashed lines indicate the endpoint of the mitotic area. (F) Quantitative analysis of germ cell numbers in the mitotic regions of *isp-1(gRNAi)* and control animals. (G) A violin plot is presented, displaying the median (solid line) and quartiles (dashed lines), illustrating the apoptotic germ cells in the loop regions of *isp-1(gRNAi)* and control animals. (H) Representative images of dissected proximal gonad stained with DAPI from 2-day-old *isp-1(gRNAi)* and control animals. The arrowheads indicate stained oocyte chromosomes. (I) Quantitative analysis of endomitotic nuclei in diakinesis oocytes in the proximal gonad of *isp-1(gRNAi)* and control animals. Statistical significance is indicated as follows: *P < 0.05, ***P < 0.0005, ****P < 0.0001; two-tailed Mann–Whitney test. Each dot represents an individual worm (C and D) and gonad arm (F, G, and I). Additionally, each dot indicates an individual group (B and I), animal (C and D), and gonad (F and G). Data are expressed as means ± SEM except (G). Created with https://www.biorender.com/.
© 2024, BioRender Inc. Any parts of this image created with BioRender are not made available under the same license as the Reviewed Preprint, and are © 2024, BioRender Inc.

Mitochondrial stress in GABAergic neurons enhances mitochondrial function in the peripheral tissues

Accumulated evidence indicates that aging is linked to a decline in mitochondrial function and biogenesis ^72–75. Additionally, experimentally increasing mitochondrial membrane potential and biogenesis is associated with lifespan extension ^{75, 76}. Therefore, we hypothesized that the mitochondrial stress specific to GABAergic neurons could impact the function and homeostasis of mitochondria in other peripheral tissues. At the 2-day-old stage, staining animals with the mitochondrial membrane potential-dependent MitoTracker Red CMXRos dye revealed a higher mitochondrial membrane potential in both the whole body (Figures 4A and 4B) and the intestine (Figure 4C) of isp-1(gRNAi) and spg-7(gRNAi) animals compared to that in the control group ^77,78. Additionally, whole-body extracts from isp-1(gRNAi) animals showed a marked increase in ATP levels (Figure 4D). spg-7(gRNAi) animals showed somewhat higher ATP levels compared to the control group, but it was not significant (Figure 4D). Next, we stained isp-1(gRNAi) and spg-7(gRNAi) animals using the MitoTracker FM Green dye that accumulates in mitochondria in a membrane potential-independent manner, indicating the mass of mitochondria ⁷⁹. We observed that both isp-1(gRNAi) and spg-7(gRNAi) animals exhibited higher MitoTracker FM Green fluorescence in the whole body than the control animals, suggesting an increase in mitochondrial mass (Figures 4E and 4F). In agreement with these results, the copy number of mitochondrial DNA was increased in isp-1(gRNAi) and spg-7(gRNAi) animals compared to control animals (Figure 4G). The expression of mitochondrial DNA polymerase gamma polg-1 was also significantly upregulated in isp-1(gRNAi) animals (Figure 4H) ^{35, 80, 81}. Notably, staining isp-1(gRNAi) and spg-7(gRNAi) animals with the ROS indicator DCF-DA showed lower ROS levels compared to the control animals (Figures 4I-4K) ⁸². Altogether, these results suggest that disturbances in mitochondrial homeostasis within GABAergic neurons could systemically increase overall mitochondrial membrane potential, ATP levels, and mitochondrial mass while decreasing ROS levels.

GABAergic neuronal mitochondrial stress alters the mitochondrial homeostasis in peripheral tissues of animals.
(A) Representative images of mitochondrial membrane potential in *isp-1(gRNAi)* and *spg-7(gRNAi)* animals after MitoTracker CMXRos dye staining at 3-day-old adults. (B and C) Quantitative analysis of MitoTracker CMXRos fluorescent intensity measured by microscopy with a 100x magnification in the indicated animals at 3-day-old adult stage (B) and in the anterior intestine region assessed by microscopy with a 400x magnification (C). (D) The ATP bioluminescence assay measured ATP levels in the whole-body extracts of *isp-1(gRNAi)* and *spg-7(gRNAi)* animals. (E) Representative image of MitoTracker FM Green fluorescence in animals at 3-day-old adults to visualize mitochondrial mass. (F) Quantitative MitoTracker FM Green fluorescence intensity in *isp-1(gRNAi)* and *spg-7(gRNAi)* animals (G) Relative mtDNA copy number analyzed by the qPCR method in *isp-1(gRNAi)* and *spg-7(gRNAi)* animals. (H) Relative transcript levels of mitochondrial DNA polymerase gamma *polg-1* gene expression measured by qPCR in *isp-1(gRNAi)* animals at the 2-day-old adult stage. (I) Representative images of *isp-1(gRNAi)* and *spg-7(gRNAi)* animals stained with H2DCF-DA dye to measure ROS levels in the whole body. (J) Quantitative analysis of H2DCF fluorescent intensity monitored by a spectrophotometer in *isp-1(gRNAi)* and *spg-7(gRNAi)* animals at 3-day-old adults. (K) Quantitative fluorescence intensity in the anterior intestine of animals after H2DCF-DA staining with a 400x magnification. Statistical significance is indicated as follows: *P < 0.05, **P < 0.005, ***P < 0.0005, ****P < 0.0001; one-way ANOVA test for (B, C, D, F, G, J, and K) and two-tailed student’s t-test for (H). Each dot indicates an individual worm (B, C, F, J, and K). Data are expressed as means ± SEM. Bars, 50 µm.

GABAergic neuronal Mitochondrial Stress Enhances the DAF-16/FoxO Pathway

Despite the increased total mitochondrial mass and activity, the decreased ROS levels in isp-1(gRNAi) and spg-7(gRNAi) animals suggest the possibility that their ability to mitigate oxidative stress has improved. Therefore, we analyzed changes in stress response regulators associated with mitochondria and ROS, including DAF-16/FoxO, mitoUPR, and SKN-1/Nrf ^{21, 57, 83–85}. It has been demonstrated that mutations in isp-1 and RNAi targeting isp-1 (isp-1 sRNAi) result in enhanced expression of reporter genes associated with the mitoUPR pathway, such as hsp-6 or hsp-60 ^{4, 34, 57}. In line with this, when the expression of Pgaba::isp-1 dsRNA was induced in N2 wild-type worms, leading to systemic isp-1 RNAi, a significant increase in Phsp-6::GFP expression was observed (Figures S1A and S1B). Additionally, we observed that sRNAi against isp-1 effectively triggered the expression of Phsp-6::GFP, and this induction was dependent on atfs-1, a crucial mediator of the mitoUPR pathway ⁸⁶ (Figure S4A). These findings indicate the efficiency of our RNAi feeding conditions. However, isp-1 gRNAi did not significantly elevate the mRNA levels of hsp-60 and hsp-6, as evaluated by quantitative reverse transcription PCR (RT-qPCR) analysis (Figure 5A). The mRNA level of gst-4, a downstream target of the SKN-1/Nrf pathway, was also not significantly increased by isp-1(gRNAi) (Figure 5A) ^{87, 88}. In contrast, the mRNA levels of three DAF-16/FoxO downstream genes, including sod-3, hsp-16.2, and dlk-1, were substantially increased by isp-1(gRNAi) (Figure 5A) ^89–91. Additionally, sid-1(eq9) null mutants expressing isp-1 dsRNA in GABAergic neurons also showed increased expression of DAF-16/FoxO target genes (Figure 5B). The intensity of a fluorescent reporter for the DAF-16/FoxO pathway (muIs84 [Psod-3::gfp]) was also enhanced in this condition (Figures 5C and 5D). The elevated expression of sod-3 and dlk-1 induced by isp-1(gRNAi) was suppressed by the loss of DAF-16, suggesting that their expression is mediated by the DAF-16/FoxO pathway (Figure 5E).

GABAergic neuronal mitochondria stress elevated the DAF-16/FoxO pathway.
(A) RT-qPCR analysis to assess the relative transcript levels of mitoUPR, SKN-1/Nrf, and DAF-16/FoxO signaling target genes in *isp-1(gRNAi)* animals compared to control EV(gRNAi) animals. The expression levels of each gene were normalized to the reference gene *act-2* which encodes actin. (B) RT-qPCR analysis was conducted to assess the relative transcript levels of *sod-3* in *sid-1(qt9)* null mutants expressing *isp-1* dsRNA in GABAergic neurons. (C and D) Representative images and the quantification of Psod-3::GFP expression, a reporter for DAF-16/FoxO activity, in *sid-1(qt9)* control animals and *sid-1(qt9)+* Pgaba::isp-1 dsRNA animals. Each dot indicates an individual worm. (E) RT-qPCR analysis was performed to assess the relative transcript levels of *sod-3* and *dlk-1* in *daf-16(mgDf47)* null mutants, both with and without *isp-1* gRNAi treatment. Statistical significance is indicated as follows: **P < 0.005, ***P < 0.0005, ****P < 0.0001; two-tailed student’s t-test (B); two-tailed Mann–Whitney test (D); two-way ANOVA (A and E). Data are expressed as means ± SEM.

The non-cell-autonomous effects of GABAergic neuronal mitochondrial defects require DAF-16/FoxO

Further investigations were conducted to evaluate the functional involvement of DAF-16/FoxO in the non-cell-autonomous effects of mitochondrial stress in GABAergic neurons. It was found that sRNAi against isp-1 required DAF-16/FoxO function to extend lifespan, as previously reported (Figure S4B and Table S1) ^{20, 21}. DAF-16/FoxO was also necessary for the enhanced tolerance against paraquat in isp-1(sRNAi) worms (Figure S4C). Notably, the lifespan extension by isp-1 gRNAi was suppressed in daf-16(mgDf47) null mutants (Figure 6A). Additionally, DAF-16/FoxO was required for the increased stress tolerance against thermal (Figure 6B) and paraquat (Figure 6C) stresses in isp-1(gRNAi) animals. DAF-16 loss also suppressed the upregulation of mitochondrial membrane potential (Figures 6D and 6E) and mitochondrial mass (Figures 6F and 6G) induced by isp-1 gRNAi. Moreover, gRNAi against isp-1 in the daf-16(mgDf47) null mutant background failed to increase mitochondrial DNA copy number (Figure 6H) and polg-1 mRNA levels (Figure 6I). Finally, the daf-16 null mutation suppressed the abnormalities in daily reproductive ability (Figure 6J) and total brood size (Figure 6K) caused by isp-1 gRNAi. Interestingly, the double RNAi knockdown of isp-1 and daf-16 in GABAergic neurons (isp-1+daf-16 gRNAi) also resulted in a normal lifespan, to a level similar to that displayed in EV(gRNAi) and daf-16(gRNAi) conditions, suggesting that DAF-16 function in GABAergic neurons is required to mediate the lifespan extension (Figure S4D and Table S1). These findings collectively suggest that DAF-16/FoxO plays a critical role in mediating non-cell autonomous changes resulting from GABAergic neuronal mitochondrial stress, influencing organismal lifespan, stress tolerance, mitochondrial homeostasis, and reproductive capacity.

GABAergic neuronal mitochondria stress requires DAF-16/FoxO to trigger the non-cell-autonomous effects.
(A) Lifespan analysis to evaluate the role of *daf-16* in the extended lifespan induced by Pgaba::isp-1 dsRNA. The significance of the lifespan curves was assessed using a Log-rank (Mantel-Cox) test. (B and C) Stress tolerance assays. In a *daf-16(mgDf47)* mutant background, Pgaba::isp-1 dsRNA expression failed to increase resistance to heat stress (B) or paraquat stress (C) compared to control EV gRNAi. (D and E) Representative images (D) and quantification (E) of mitochondrial membrane potential assessed by MitoTracker Red CMXRos dye staining at 3-day-old adults. (F and G) Representative images (F) and quantification (G) of MitoTracker FM Green fluorescent staining at 3-day-old adults to monitor mitochondria mass. (H and I) Relative mtDNA copy number (H) and *polg-1* gene expression level (I) were analyzed by qPCR in EV(gRNAi) and *isp-1(gRNAi)* under *daf-16(mgDf47)* null mutant background. (J) Comparison of the mean number of eggs laid each day between *daf-16(mgDf47)*+*isp-1(gRNAi)* and control *daf-16(mgDf47)*; EV(gRNAi) animals. (K) The total number of embryos in fertile *daf-16(mgDf47)*+*isp-1(gRNAi)* and control *daf-16(mgDf47)*; EV(gRNAi) animals. Each dot represents an individual animal (E, G, J, and K). Statistical significance is indicated as follows: *P < 0.05, **P < 0.005, ***P < 0.0005, ****P < 0.0001; a one-way ANOVA test for B and C, and a two-tailed Mann–Whitney test for E, G, H, I, J, and K. Data are expressed as means ± SEM. Bars, 50 µm.

Mitochondrial stress in GABAergic neurons causes non-cell-autonomous changes by acting on the same mechanisms as GABA signaling

Recent studies in C. elegans have revealed that GABA signaling plays a role not only in the regulation of GABAergic neuronal function but also in governing organismal longevity. Specifically, loss of unc-25, which encodes glutamic acid decarboxylase, has been shown to prolong lifespan and enhance stress tolerance ^{42, 43}. Hence, we conducted epistatic tests to investigate the possible interaction between the loss of GABA signaling and isp-1 knockdown conditions in GABAergic neurons and their impact on organismal health and longevity. We found that targeting isp-1 specifically in GABAergic neurons by expressing Pgaba::isp-1 dsRNAs in sid-1(qt9) mutants did not lead to a further extension of lifespan in unc-25 null mutants (Figures 7A and S5A; Table S1). Additionally, GABAergic neuronal mitochondrial stress did not lead to an additive increase in stress tolerance beyond the levels observed in unc-25(e156); sid-1(qt9) mutants (Figures 7B and 7C). The enhanced GFP expression driven by the sod-3 promoter due to isp-1 dsRNA expression in GABAergic neurons was not further increased in the unc-25 null mutant condition (Figure 7D).

Non-cell autonomous effects of GABAergic neuronal mitochondrial stress were not additively enhanced by the loss of GABA signaling.
(A) Lifespan analysis was conducted on animals with indicated genetic backgrounds to investigate the relationship between GABA signaling and mitochondrial stress in GABAergic neurons. (B and C) Paraquat and thermal stress assays were performed on *unc-25* null mutants with and without GABAergic neuronal mitochondrial stress induced by Pgaba::isp-1 dsRNA expression to elucidate their relationship. (D) Assessment of the fluorescence intensity of the Psod-3::GFP reporter, indicative of DAF-16/FoxO activity, in the specified mutants. (E) Evaluation of aldicarb sensitivity in response to the expression of *isp-1* dsRNAs in GABAergic neurons. Each dot represents an individual group in B, D, and E and individual animal in D. *P < 0.05, **P < 0.005, ***P < 0.005, ****P < 0.001; Log-rank (Mantel-Cox) test for A; one-way ANOVA test for B, C, D, and E. Data were expressed as means ± SEM.

Next, we assess if GABAergic neuronal mitochondrial stress affects GABA function by testing the sensitivity of animals to aldicarb, an acetylcholinesterase inhibitor that can cause post-synaptic receptor hyperstimulation and paralysis due to reduced acetylcholine breakdown ⁹². As previously reported, depletion of GABA in unc-25 mutants increased the sensitivity to aldicarb ^92–94 (Figures 7E). GABAergic neuronal expression of isp-1 dsRNA also significantly elevated the sensitivity to aldicarb, particularly when animals were exposed to it for a prolonged period (120 min). The expression of Pgaba::isp-1 dsRNA did not further increase the hypersensitivity to aldicarb in unc-25 mutants, indicating that they function in the same pathway. Together, these findings suggest that diminished GABA signaling and mitochondrial stress within GABAergic neurons trigger alterations in organismal lifespan and healthspan through a common pathway.

Neuropeptide signaling in GABAergic neurons regulates organismal aging and health without additive effects with mitochondrial stress in GABAergic neurons

Next, we tested the potential roles of neuropeptide signaling in the non-cell autonomous effects of GABA neuronal mitochondrial stress ³³. We measured the lifespan of mutants with mutations in unc-31, required for dense-core vesicle exocytosis ⁹⁵. In agreement with the previous report, unc-31(e928) mutants exhibited prolonged lifespan (Figure 8A and Table S1). There is no additive lifespan increase by Pgaba::isp-1 dsRNA expression in the unc-31 mutant background, suggesting the potential involvement of neuropeptide signaling in regulating lifespan (Figure 8A and Table S1). GABAergic neurons have been suggested to express several neuropeptides, including flp-10, flp-11, flp-13, and flp-22 ^{96, 97}. In line with previous studies, flp-13 was expressed in a subset of C. elegans GABAergic motor neurons (Figure S6A) ^{97, 98}. We found that flp-13+EV gRNAi extended the lifespan of animals compared to control animals, indicating its non-cell autonomous function in GABAergic neurons in regulating organismal lifespan (Figure 8B); Table S1). Double gRNAi against flp-13 and isp-1 did not further increase lifespan compared to flp-13+EV gRNAi alone, suggesting that depletion of FLP-13 and mitochondrial disruption in GABA neurons could extend lifespan through a common mechanism (Figure 8B and Table S1). While gRNAi against flp-13+EV did not affect the tolerance of animals against heat stress, it improved stress tolerance against paraquat to a level comparable to that observed in animals treated with flp-13+isp-1 double gRNAi (Figures 8C and 8D). Maximal treatment of flp-13 gRNAi, without mixing with EV bacteria, did not significantly increase the heat tolerance compared to the control group, suggesting that the lack of impact of flp-13+EV gRNAi on heat stress is unlikely to be attributed to a diluted RNAi efficiency due to the double RNAi method (Figure S6B). Additionally, maximal treatment of flp-13 gRNAi still showed enhanced paraquat tolerance and lifespan (Figures S6C and S6D; Table S1). Collectively, these findings indicate a novel role for the neuropeptide FLP-13 in regulating organismal aging and health. This regulation appears to be mediated by a common mechanism associated with non-cell autonomous effects resulting from GABA neuronal mitochondrial dysfunction. The selective response of flp-13 mutants to specific stressors implies the existence of additional mechanisms that respond to mitochondrial stress within GABAergic neurons.

FLP-13 neuropeptides modulate organismal lifespan and stress tolerance, without expanding the non-cell autonomous effects of GABAergic neuronal mitochondrial stress.
(A and B) Lifespan assays were conducted to evaluate the role of *unc-31* (A) and *flp-13* in regulating organismal longevity. (C and D) Quantitative analysis of the thermal (C) and paraquat (D) stress resistance assays was performed after double gRNAi, induced by feeding worms a 50:50 mixture of two bacterial strains expressing either EV, *flp-13*, or *isp-1* dsRNAs. *P < 0.05, **P < 0.005, ***P < 0.005, ****P < 0.001; Log-rank (Mantel-Cox) test for A and B; one-way ANOVA test for H and I. Data were expressed as means ± SEM.

Discussion

Our findings suggest that GABAergic neurons play a critical role in sensing mitochondrial stress and regulating longevity. Additionally, disrupting the mitochondria in GABAergic neurons alone was sufficient to induce alterations in organismal health and reproduction. Enhanced DAF-16/FoxO activity is necessary for mediating the non-cell autonomous changes observed in animals. Furthermore, we identified GABA signaling and one neuropeptide signaling as a factor associated with the non-cell autonomous effects caused by mitochondrial stress in GABAergic neurons.

Previous studies have demonstrated that mitochondrial stress in all neurons is sufficient to extend organismal lifespan. However, it remains incompletely understood which neurons respond to their mitochondrial stress to mediate this non-cell autonomous effects on organismal lifespan. Sha and colleagues have tested 18 neurons out of the total 302 in C. elegans regarding their potential to activate non-cell-autonomous effects and demonstrated that a specific subset, consisting of ASK, AWA, AWC, and AIA neurons, exhibits the capacity to induce non-cell-autonomous activation of the mitoUPR pathway in response to mitochondrial stress their mitochondria perturbation ³³. Interestingly, these conditions do not alter organismal lifespan, suggesting an unlink between mitoUPR and lifespan in certain conditions ³³.

The specific role of GABAergic neurons in non-cell autonomous regulation of aging and health in response to mitochondrial dysfunction has not been reported. This could be because these GABAergic neurons have not been tested or that previous studies primarily focused on neurons that non-cell autonomously affect the mitoUPR pathway in the peripheral tissues ^{16, 33–36}. However, a recent study reveals that induced ROS production in GABAergic neurons can trigger mitoUPR induction in other peripheral tissues through activating UNC-49/GABA_A receptor signaling, suggesting a central role of GABAergic neurons in regulating organismal stress response ⁴⁵. In our study, we prioritized monitoring changes in the lifespan rather than detecting mitoUPR reporter activity and found that inducing mitochondrial stress, specifically in GABAergic neurons, was sufficient to extend the lifespan of the animal. We employed two independent RNAi strategies to knock down two genes related to mitochondria. The tissue-specific RNAi approach, utilizing the rde-1(ne219) null mutant background and exclusively restoring rde-1 in target tissues, has been successfully utilized in multiple studies ^{48, 50, 51, 53}. To eliminate the possibility of incomplete gRNAi, we also conducted isp-1 knockdown in GABAergic neurons by expressing isp-1 dsRNAs in sid-1 null mutant backgrounds, and we consistently observed an extension in lifespan in both RNAi strategies. isp-1 mutants and Pgaba::isp-1 dsRNA expression in wildtype animals robustly increase mitoUPR. In contrast, our qPCR results showed that there was no increase in mitoUPR reporter expression in isp-1(gRNAi) animals ⁴. Additionally, the isp-1(gRNAi) animals did not fully recapitulate the phenotypes of isp-1 mutants, including normal ATP level, increased ROS level, and decreased mitochondrial membrane potential ^99–102, supporting that our two isp-1 knockdown conditions did not occur systemically other than in GABAergic neurons.

Longevity is associated with healthspan, but not in all cases ¹⁰³. Our results show that mitochondrial stress in GABAergic neurons not only prolonged lifespan but also improved stress tolerance, a typical healthspan parameter. Notably, we also found enhancements in mitochondria activity and ATP levels. These improvements in mitochondria could be, in part, a result of an increase in mitochondria population evidenced by increases in mitochondrial DNA copy number and mass. Consistently this notion, we also found increased mRNA levels of polg-1, encoding the mitochondrial DNA polymerase that is responsible for the replication of the mitochondrial genome, suggesting a potential increase in mitochondria biogenesis by GABAergic neuronal mitochondrial stress ^{35, 104}. The concept of aging in model organisms has long been linked to a decrease in mitochondrial function and biogenesis ¹. Similarly, in humans, mitochondrial function declines with age ^{2, 105}. Enhancing mitochondrial function has been proposed as an intervention strategy against aging. In mice, the brain-specific overexpression of Sirt1, a pivotal regulator of mitochondrial biogenesis through PGC-1a, not only extended lifespan but also induced non-cell-autonomous effects in skeletal muscle including improved mitochondria homeostasis ⁷⁵. A recent study indicates that experimentally rejuvenated mitochondrial membrane potential is sufficient to extend C. elegans lifespan ⁷⁶. Additionally, while isp-1 mutants have been shown to have elevated levels of ROS, a central factor in aging, our findings suggest that knockdown of isp-1 in GABAergic neurons leads to a reduction in ROS levels, despite an increased mitochondrial population and heightened activity ^{6, 102, 106}. Therefore, both enhanced mitochondrial homeostasis and reduced ROS levels could contribute to the non-cell-autonomous enhancement in aging and health.

The reduced ROS also proposed the potential involvement of the stress response pathway against ROS. Strikingly, our qPCR results showed no evidence supporting the activation of mitoUPR by GABAergic-neuronal mitochondrial stress ^{16, 33–36}. It has been shown that afts-1 acts cell-autonomously in certain neurons to mediate non-cell autonomous effects of mitochondrial stress in specific neurons ³³. Thus, it is still possible that mitoUPR activation in GABAergic neurons plays a role in mediating lifespan extension and improving stress resistance. Recent studies have demonstrated that experimentally enhanced ROS production in GABAergic neurons activates the mitoUPR and this requires UNC-49 GABA_A receptor ⁴⁵. However, unc-49 mutants exhibit a normal lifespan ^{42, 43}. Therefore, the extended lifespan resulting from mitochondrial defects in GABAergic neurons is not primarily mediated by increased ROS production and non-cell-autonomous activation of mitoUPR.

Our results suggested that GABAergic neuronal mitochondrial stress requires DAF-16/FoxO. We found that GABA-neuronal mitochondrial stress promoted the expression of sod-3, hsp-16.2, and dlk-1, which are regulated by DAF-16 ^89–91. A recent study also reveals that ROS induction in GABAergic neurons results in non-cell autonomously increased expression of sod-3 along with hsp-6 ⁴⁵. DAF-16 is another pathway suggested to be activated by mitochondrial dysfunction, contributing to the extended lifespan observed in C. elegans with whole-body mitochondrial dysfunction ²¹. However, another study reports that while DAF-16 is required for the longevity of mitochondrial mutants in certain conditions, it was not sufficient to fully account for the observed lifespan extension ⁶. We found that depletion of DAF-16 suppressed a series of non-cell-autonomous changes in lifespan, stress resistance, mitochondrial DNA (mtDNA) copy number, and polg-1 expression. These results indicate the functional importance of DAF-16 in mediating the non-cell autonomous effects of mitochondrial disruption in GABAergic neurons.

Recent studies on C. elegans have reported that GABA signaling regulates lifespan and health ^{42, 43}. Notably, GABA loss increases DAF-16/FoxO activity in the intestine, thereby increasing organismal longevity and health span ^{42, 43}. Additionally, GABA signaling modulates protein homeostasis in C. elegans post-synaptic muscle cells ⁴⁴. In contrast to the role of GABA signaling in C. elegans lifespan, knockdown of the Drosophila GABA_B receptor shorts lifespan ¹⁰⁷. Nevertheless, these results indicate that GABA signals could have a conserved role in regulating organismal health and aging. Our aldicarb assay results suggest that GABAergic neuronal mitochondrial stress could interfere with GABAergic neuronal activity. It has been revealed that mitochondria abundantly accumulate at the presynapse and affect synaptic activity by regulating the supply of ATP and calcium homeostasis, which are required for proper neurotransmitter release and recycling ^108–113. Our previous studies have demonstrated that over 75% of mitochondria localize at the presynapse in GABAergic motor neurons in C. elegans ¹¹⁴. A screen for essential genes required for GABAergic neuronal function, utilizing a GABAergic neuron-specific feeding RNAi in C. elegans, has identified several mitochondrial-related genes. Knockdown of these genes in GABAergic neurons triggers hypersensitivity against aldicarb ⁴⁸. Therefore, GABAergic neuronal mitochondrial perturbation could mimic effects induced by a reduction in GABA signaling. This hypothesis is supported by our epistatic analysis results, suggesting that GABAergic neuronal mitochondrial stress and the loss of GABA signaling in unc-25 mutants may share a common mechanism influencing longevity, stress tolerance, and sod-3 expression. Understanding how mitochondrial stress can modulate downstream mediators such as DAF-16 through altering GABA singling and ultimately affecting longevity and health can be complex. Mitochondrial stress in GABAergic neurons may partially reduce GABA signaling to varying degrees rather than completely turning it off ^{112, 115}. Moreover, GABA signaling differentially regulates lifespan and each healthspan parameter through three receptors and a combination of four downstream pathways ⁴³. Thus, reduced GABA signaling caused by GABA mitochondrial stress could affect each downstream receptor pathway to varying degrees, depending on the ability of each receptor to respond to GABA ligands.

It has been well-documented that cell-autonomous responses to mitochondrial defects can vary depending on the stressor conditions, including disruptions in each ETC component and disruption modes, pathological conditions, and environmental stressors ^{101, 116}. These variations highlight the complex responses to mitochondrial disturbances. Interestingly, the non-cell autonomous longevity changes also differ depending on the type of mitochondrial perturbation. It has been reported that inhibition of spg-7 and cco-1, encoding a cytochrome c oxidase-1, in the entire nervous system prolongs lifespan ^{16, 33}, but it was not suppressed by mitoUPR loss. Mitochondrial stress induced by pan-neuronal expression of polyglutamine repeats (polyQ40) and mutation in ucp-4, encoding a mitochondrial uncoupling protein-4, do not further prolong the lifespan than wild-type animals, but mitoUPR function is required to preserve normal lifespan ³³. Also, the deletion of spg-7 in AIY neurons is sufficient to induce mitoUPR in distal tissues but does not prolong lifespan ^7,32,35. Additionally, pan-neuronal expression of KillerRed, which induces oxidative stress, resulted in a reduced lifespan, despite an enhanced mitoUPR pathway in remote tissues ³³. In this study, we targeted to inhibition of isp-1 and spg-7 in GABAergic neurons and observed consistent changes in lifespan and stress resistance. Notably, isp-1 gRNAi resulted in decreased reproductive ability. Previous studies report that depletion of CCO-1, a component of mitochondria ETC, in the nervous system results in mitoUPR activation in the peripheral tissues and prolongs lifespan without affecting brood size ^{16, 33}. Similarly, in Drosophila, ETC reduction in the nervous system increases longevity but maintains normal fertility ⁸. However, it remains unclear whether other mitochondrial stressors in GABAergic neurons can produce similar non-cell-autonomous effects as seen with isp-1 and spg-7 knockdown, which could be one reason the role of GABAergic neurons in regulating the non-cell-autonomous effects of mitochondrial disturbance has not been elucidated previously.

Finally, studies have demonstrated that neuropeptide signaling mediates the non-cell autonomous regulation of mitoUPR and organismal aging in response to mitochondrial stress in specific neurons ^{42, 117–122}. For instance, mitochondrial stress in ASK, AWA, AWC, and AIA neurons utilizes the FLP-2 neuropeptide to induce mitoUPR in peripheral tissues ³³. These results suggest that there could be additional signaling molecules mediating the non-cell autonomous effects of GABAergic neuronal mitochondrial stress. GABAergic neurons have been found to express several neuropeptides, including flp-10, flp-11, flp-13, and flp-22 ^{96, 97}. Our finding indicates that gRNAi against unc-31 increased lifespan resulting from depletion of dense core vesicle exocytosis was not further increased by GABA-neuronal mitochondrial stress, suggesting that neuropeptide signaling could be involved in non-autonomous changes caused by GABA-neuronal mitochondrial damage ⁹⁵. FLP-13 loss increased lifespan and stress resistance, which is similar to the phenotype of animals with mitochondrial perturbations in GABAergic neurons. Animals with both conditions did show significant changes in stress resistance and lifespan compared to animals with either single condition, indicating that they work through the same mechanism to mediate non-cell autonomous effects. Therefore, it is possible that GABAergic neuronal mitochondrial stress reduces FLP-13 function, which inhibits lifespan and healthspan. Future studies are needed to elucidate the specific role of FLP-13 and other neuropeptides in the non-cell-autonomous effects of GABA-neuronal mitochondrial stress.

Acknowledgements

We thank Drs. Shinichi Someya, Christiaan Leeuwenburgh, Stephanie Wohlgemuth, and Sejin Lee for their valuable discussions. Some strains were provided by the CGC, funded by the NIH Office of Research Infrastructure Programs (P40 OD010440). This research was conducted while SMH was a Hevolution/AFAR New Investigator Awardee in Aging Biology and Geroscience Research (AWD16056). SMH was also supported by the National Institute on Aging (NIA) of the National Institutes of Health (NIH) under award numbers R56AG066654 and R01AG081270, as well as the Glenn Foundation for Medical Research and the American Federation for Aging Research under award numbers AWD06577 and AWD11009 to SMH. Additionally, support was provided by NIA/NIH under award number AG060373-01 and the National Science Foundation under award number IOS (2132286) to MHL.

Author Contributions

S.M.H. supervised the study. M.H.L. and S.M.H. conceived the study. L.R. and S.M.H. wrote the manuscript with input from all authors. L.R. and S.C. designed and performed experiments and analyzed and interpreted data. Y. P. and M.H.L designed germline experiments and interpreted data. B.R. and T.M. assisted with planning and performing the stress response and lifespan assays. Y.S. and R.X generated reagents and assisted with planning and interpreting data. K.M., W.C., and R.X. provided expertise and resources and reviewed the manuscript.

Declaration of Interests

The authors declare no competing interests.

Inclusion and diversity

We support inclusive, diverse, and equitable conduct of research.

Data availability

All numerical data supporting the findings of this study are available in the supplemental information and from the corresponding author upon reasonable request.

Material and Methods

C. elegans strains

All C. elegans strains were maintained at 20 °C on nematode growth medium (NGM) plates seeded with the OP50 strain of Escherichia coli (E. coli) as described before ¹²³. A list of strains used in this study is the following: N2 (Wild type), XE1375 (wpIs36 I; wpSi1 II; eri-1(mg366) IV; rde-1(ne219) V; lin-15B(n744) X), SJ4100 (zcIs13 [hsp-6p::gfp]), CB156 (unc-25(e156) III), HC196 (sid-1(qt9) V), GR1352 (daf-16(mgDf47)I), TJ356 (zIs356 IV [daf-16p::daf-16a/b::gfp; rol-6(su1006)]), CF1553 (muIs84 [(pAD76) sod-3p::gfp + rol-6(su1006)]), CL2166 (dvIs19 III [(pAF15)gst-4p::gfp::NLS]). HAN260 (daf-16(mgDf47) I; wpIs36 I; wpSi1 II; eri-1(mg366) IV; rde-1(ne219) V; lin-15B(n744) X), HAN186 (unc-25(e156); sid-1(qt9)), HAN356 (unc-25(e156); sid-1(qt9)+ sbsEx27 [unc-47p::isp-1 sense+ unc-47p::isp-1 antisense]), HAN357 (sid-1(qt9)+sbsEx27 [unc-47p::isp-1 sense+ unc-47p::isp-1 antisense]).

RNAi assay

RNAi was performed by the feeding method ^{124, 125}. Briefly, freshly streaked single colonies of HT115(DE3) bacteria containing either empty L4440 vector (control) or isp-1 and spg-7 RNAi plasmid were grown overnight at 37°C in Luria broth (LB) medium supplemented with carbenicillin (25 μg/ml). HT115(DE3) bacterial feeding strains were obtained from the genome-wide library ¹²⁵. PCR and sequencing were used to confirm that strains contained the correct clones. RNAi bacteria were seeded on NGM plates containing IPTG (1 mM) and cultured overnight before transferring animals. To prevent undesired non-specific effects, we did not use 5-fluoro-2′-deoxyuridine (FUdR) in seeded RNAi plates. Duplex RNAi was performed by mixing two HT115(DE3) bacterial strains, each containing the desired RNAi plasmid or empty vector in a 1:1 volume ratio. The efficiency of double RNAi, which involves feeding a 1:1 volume ratio mixture of bacteria strains targeting two different genes, was compared to that of single gene RNAi, which involves feeding a 1:1 volume ratio mixture of bacteria strains targeting one gene and an empty vector.

Lifespan assay

Age-synchronized animals were prepared by egg prep from adult animals cultured on each RNAi or regular NGM plate at 20°C ¹²⁶. The isolated embryos were transferred and allowed to hatch on RNAi NGM plates for the desired gene or regular NGM plates. Then, approximately 50 animals at the L4 stage were transferred to fresh RNAi plates. Every day, animals that failed to respond to gentle prodding with platinum wire were scored as dead. Lifespan data were statistically analyzed for significance by the log-rank test, comparing survival curves using GraphPad Prism software. Lifespan assays were performed at least in triplicate. To prevent undesired non-specific effects, we did not use 5-fluoro-2′-deoxyuridine (FUdR) in the seeded RNAi plates.

Aldicarb sensitivity assay

Aldicarb sensitivity assay was performed as described previously ⁹². Briefly, approximately 40-50 mutant animals were grown on OP50-seeded NGM plates at 20 °C for 72 hours. Approximately 40 L4 stage mutant animals were then picked and placed on 35 mm OP50-seeded NGM plates containing 0.5 mM aldicarb (Sigma Aldrich, 33386: prepared aldicarb NGM plates 1 day before the assay) and scored for paralysis every 30 minutes over a 120-minute period. Animals were considered paralyzed when they failed to show any movements in response to touching at a fixed time. This assay was carried out in triplicate for each experimental condition.

Reproductive assay

After pre-exposure to spg-7 and isp-1 RNAi from the L1 stage, age-synchronized XE1375 animals at the L4 stage (n=∼20-30) were individually transferred to fresh spg-7 and isp-1 RNAi NGM plates. Every day, we moved mother animals to new spg-7 and isp-1 RNAi NGM plates until egg-laying stopped. The embryos produced daily were counted, and the total number of produced embryos was used to calculate the brood size. The egg production period was used to calculate the reproductive span, and the number of embryos produced each day was used to analyze reproductive trends. The hatching rate was scored 24 hours after egg-laying. The brood size, reproductive span, hatching rate, and reproductive trend data were generated from independent experiments. At least three replicate experiments were performed for each assay.

Stress assays

For the paraquat assay, 30-50 age-synchronized animals were pretreated to RNAi for each gene from the L1 stage. Then, 2-day-old adult animals were transferred to 96-well plates containing M9 with paraquat, a reactive oxygen species generator (Sigma-Aldrich, 36541-100MG), at a concentration of 0 mM, 50 mM, 100 mM, and 150 mM in a total volume of 100 µl per well. The survival of animals was evaluated after 24 hours, and animals that failed to respond to platinum wire touch were scored as dead. In the heat stress resistance assay, age-synchronized adult animals pretreated with isp-1 or spg-7 RNAi were exposed to thermal stress at 37°C for 5 hours. The survival after heat shock was recorded every hour for 5 hours by gently prodding with a platinum loop. Animals that failed to respond were scored as dead. All experiment was independently repeated at least three times.

Staining assays for ROS level and mitochondrial homeostasis

We used the fluorescent probe H₂DCF-DA dye (Invitrogen, D399) to detect ROS levels in vivo, as previously described ⁸². 2-day-old adult stage mutants or XE1375 animals pretreated with spg-7, isp-1, or control EV RNAi from the L1 stage were washed with M9 buffer to remove the bacteria. After washing 3 times, animals were collected in 300 µl of PTw buffer (1xPBS with 0.1% tween20). Then, around 30-35 animals were transferred to 96-well plates containing 10 mM H₂DCF-DA. The fluorescence was recorded using Spectra Max M2 multimode microplate reader (Molecular Devices) at 485 nm excitation and 530 nm emission. The change in fluorescence was recorded for 120 min at 20 min intervals at 37 °C. The experiment was performed 3 times independently. To perform the H₂DCF-DA assay using an image, we transferred 30-40 pretreated spg-7 and isp-1 RNAi animals in 500 µl M9 buffer and washed 3 times. Afterward, animals were incubated in 500 µl M9 buffer containing 10 mM H₂DCF-DA for 1 hour. Animals were washed with M9 buffer at least 3 times, transferred to 2% agarose pads on glass slides, and visualized using a GFP filter and imaged using a 40x objective (Andor, DSD2 spinning disk confocal, Andor, Zyra4.2 camera). To evaluate mitochondrial membrane potential and mass, we used MitoTracker CMXRos (Invitrogen, M7512) and FM green dye (Invitrogen, M7514), respectively, as described in previous studies ^{127, 128}. The lyophilized dyes were dissolved in DMSO and made to the final concentration of 100 μM. Animals were pretreated from the L1 stage to spg-7 and isp-1 gRNAi. L4 stage animals (n=30-40) were transferred to spg-7 and isp-1 RNAi plates with MitoTracker CMXRos or MitoTracker FM green dye and incubated for 48 hours at room temperature under dark conditions. Next, stained animals were transferred to fresh NGM plates (without the dye) for 1 hour to remove the bacterial fluorescent background inside the gut. The animals were observed using a 10x magnification to visualize the whole-body staining and a 40x objective to observe the anterior body, including the intestine.

ATP assay

We used previously reported protocols with a minor modification ⁵². Approximately 150 age-synchronized animals treated with spg-7 and isp-1 RNAi from the L1 stage were prepared.1-day-old adult animals were washed 5 times with M9 buffer to remove the intestinal bacteria and washed with TE buffer. The animals were frozen at −80 °C. The sample was sonicated for 15 seconds with a 15-second interval, followed by boiling for 10 minutes to release ATP and block ATPase activity. Debris was removed by centrifuging at 4 °C for 10 minutes. The supernatant was collected, and the ATP levels were measured using the bioluminescence detection kit (Promega ENLITEN ATP Assay System, FF2000) and Spectra Max M2 multimode microplate reader (Molecular Devices). Luminescence was normalized to protein content measured with a Pierce BCA protein determination kit (Thermo Scientific, 23227).

mtDNA quantification

mtDNA quantification was performed using a quantitative PCR (qPCR) based method ¹²⁹. About 30 age-synchronized L4 staged spg-7(gRNAi) and isp-1(gRNAi) animals were collected in 30 µl of lysis buffer (freshly added proteinase K) and frozen immediately at −80 °C for 10 minutes before lysis at 65 °C for 1 hour, followed by 95°C for 15 minutes, and then maintained at 4 °C. Relative quantification was used for determining the fold changes in mtDNA. 2 µl of lysate sample was used as template DNA in each triplicate reaction. qPCR was performed using the SYBR green mixture in a CFX96 Touch Real-Time PCR System (Bio-Rad). Primers (mtDNA target-specific primer) for cox-4 and nd-1 were used to determine the mtDNA copy number. The cox-4 forward primer 5’GCCGACTGGAAGAACTTGTC-3’ and reverse primer 5’-GCGGAGATCACCTTCCAGTA-3’. The nd-1 forward primer 5’-AGCGTCATTTATTGGGAAGAAGAC-3’ and reverse primer 5’-AAGCTTGTGCTAATCCCATAAATGT-3’. All qPCR results were performed in triplicates.

Quantitative reverse transcriptase PCR

RNA isolation and quantitative reverse transcriptase PCR (qRT-PCR) analysis were performed as previously described ¹³⁰. Animals raised on spg-7 or isp-1 gRNAi plates were synchronized by egg prep. Then, total RNA was extracted using the TRIzol (Invitrogen, 15596026) method from age-synchronized animals (approximately 1,500 animals at the 3-day-old adult stage). RNA was purified using a Qiagen Rneasy kit, and 2 µg RNA was used for cDNA synthesis (Thermo Scientific, Verso cDNA synthesis kit, AB1453A). qPCR was performed using SYBR Green master mix (Bio-Rad Laboratories). qPCR primers are listed below. Act-1 Forward 5’-GCTGGACGTGATCTTACTGATTACC-3’, act-1 Reverse 5’-GTAGCAGAGCTTCTCCTTGATGTC-3’, daf-16 Forward 5’-CCAACACATTCATCCCAGTG-3’, daf-16 Reverse 5’-GATGGGATAGAGGTAGCATT-3’, sod-3 Forward 5’-CTGATGGACACTATTAAGCG-3’, sod-3 Reverse 5’-AAGTGGGACCATTCCTTCCAA-3’, gst-4 Forward 5’-GCTGAGCCAATCCGTAT-3’, gst-4 Reverse 5’-GTAAAATGGGAAGCTGGC-3’, dlk-1 Forward 5’-TCGACGCTATCTCCGAACTT-3’, dlk-1 Reverse 5’-TGCTTGATCTCGGTCTCCTT-3’, hsp-6 Forward 5’-CGAAAGCTATTTGGGAACCA-3’, hsp-6 Reverse 5’-GCTCGTTGATGACACGAAGA-3’, hsp-60 Forward 5’-CCGTCTCTGTCACTATGGGC-3’, hsp-60 Reverse 5’-CTCGAATCCCTCTTTGGCGA-3’, polg-1 Forward 5’-GTTACGGCCGACGAGATACG-3’, polg-1 Reverse 5’-CGTAGCTTCCGGACTCCAAA-3’. All qPCR results were performed at least in triplicates.

Statistics

Statistics were performed using GraphPad PRISM (version 9 and 10). No statistical method was used to pre-determine sample size. For Figures 5D and 7D, outliers were identified using the ROUT method at Q = 1% and excluded from further analysis. Within experimental groups, animals were randomized for each experimental replicate. The qPCR experiments were analyzed using the delta-delta Ct method ¹²¹. All experiments were reliably reproduced at least 3 times independently. For the qPCR assays, in cases where the control and subjects were not paired, the average control delta Ct value was utilized to calculate delta-delta Ct values. However, if the control and experimental groups were paired, individual control delta Ct values were used to calculate delta-delta Ct values for each paired experimental group.

(Related to Figure 1). Global induction of mitoUPR reporter upon *isp-1* dsRNAs expression in GABAergic neurons of wild-type animals.
(A) Representative image showing the increased expression of Phsp-6::gfp transgene in the animals with transcription of *isp-1* sense and antisense RNAs *in vivo* under the GABAergic neuron-specific promoter. Note that the N2 wild-type background allowed the systemic RNAi effects on peripheral tissues. (B) Quantitation of the Phsp-6::GFP fluorescence intensity in the intestine showing the non-cell-autonomous effects of *in vivo* transcription of *isp-1* dsRNAs in GABAergic neurons. Each dot represents an individual animal. Data were expressed as means ± SEM. A two-tailed Mann–Whitney test.

(Related to Figure 2). Continuous gRNAi against *spg-7* over three generations led to altered organismal stress resistance.
(A) A diagram showing the experimental procedure of paraquat and thermal stress response assays in *spg-7(gRNAi)* animals after continuous RNAi for three generations. (B and C) Quantification of paraquat stress assays in *spg-7(gRNAi)* animals at 1-day or 9-day-old adult stages. (D and E) Quantification of thermal stress assays in *spg-7(gRNAi)* animals at the L4 and 9-day-old adult stages. Animals were exposed to 35 °C for 5 hours. Data were expressed as means ± SEM. *P.<0.05, **P.<0.005, ***P.<0.005, ****P.<0.001; two-tailed student’s t-test. Created with https://www.biorender.com/.
© 2024, BioRender Inc. Any parts of this image created with BioRender are not made available under the same license as the Reviewed Preprint, and are © 2024, BioRender Inc.

(Related to Figure 3). Non-cell autonomous effects of GABA neuronal mitochondrial stress on the reproductive system.
(A) Diameter of the mitotic area in the distal gonad in *isp-1(gRNAi)* animals. (B) Hatching rates of embryos in *isp-1(GABA-RNAi)* and *spg-7(GABA-RNAi)* animals. *P.<0.05, **P.<0.005; a two-tailed Mann–Whitney test for A; ne-way ANOVA test for B. Data were expressed as means ± SEM.

(Related to Figure 6). The role of DAF-16 in the non-cell autonomous effects of GABA neuronal mitochondrial stress.
(A) Quantification of the Phsp-6::GFP intensity in the indicated sRNAi strains. (B and C) Lifespan
(B) and paraquat tolerance (C) assays of isp-1 sRNAi under the *daf-16(mgDf47)* null mutant background. (D) Lifespan was tested after gRNAi induction by feeding GABAergic neuronal-specific RNAi strain (XE1375) worms with a 50:50 mixture of bacteria producing either EV, *isp-1*, or *daf-16* dsRNAs.*P.<0.05, **P.<0.005, ***P.<0.005, ****P.<0.001; a two-tailed Mann–Whitney test was used for A; Log-rank (Mantel-Cox) test for B and D; one-way ANOVA test for C. Data were expressed as means ± SEM.

(Related to Figure 7): Assessing the impact of mitochondrial stress in GABAergic neurons on lifespan in *unc-25* null mutants.
(A) Repeated lifespan analysis of *unc-25(qt9)* mutants with and without *isp-1(sRNAi)*. The significance was analyzed by a Log-rank (Mantel-Cox) test.

(Related to Figure 8). The effects of single GABA-RNAi inhibition against *flp-13* **and *isp-1* on lifespan and stress response.**
(A) Representative images of Pflp-13::GFP expression. GABA neurons are visualized by mCherry derived by *unc-47* promoter. Arrowheads indicate the cell body of GABA neurons on the ventral nerve cord with GFP expression. Arrows indicate the cell bodies only with mCherry signals. The dashed boxes are magnified below. (A, B, and C) Lifespan and stress tolerance were tested after gRNAi induction by feeding GABAergic neuronal-specific RNAi strain (XE1375) worms with bacteria producing either *isp-1* or *flp-13* dsRNAs alone for each condition. (B) The survival rate after incubation at 35°C for 5 hours was measured in animals at the 3-day-old adult stage. At least 30 animals were tested for each set. (C) The survival rate of animals cultured in indicated concentrations of paraquat for 24 hours was measured at the 3-day-old adult stage. (D) Lifespan assay of *isp-1(gRNAi)* and *flp-13(gRNAi)* animals. **P < 0.005, ****P < 0.001; one-way ANOVA test for B and C; a Log-rank (Mantel-Cox) test for D. Data were expressed as means ± SEM.

Related to Figs. 1, 6, 7, S4, and S5. Lifespan summary. For P values, stars in the ‘Genotype’ column are provided to denote the genotype (within the group delimited by color) against which the comparison was performed. Actual P values are provided in the ‘significance’ column. The results indicate the total lifespan summary of triplicates.

References

1.
1. Rockstein M.
2. Brandt K.F
1963Enzyme changes in flight muscle correlated with aging and flight ability in the male houseflyScience 139:1049–1051
2.
1. Petersen K.F.
2. et al.
2003Mitochondrial dysfunction in the elderly: possible role in insulin resistanceScience 300:1140–1142
3.
1. Dillin A.
2. et al.
2002Rates of behavior and aging specified by mitochondrial function during developmentScience 298:2398–2401
4.
1. Wu Z.
2. et al.
2018Mitochondrial unfolded protein response transcription factor ATFS-1 promotes longevity in a long-lived mitochondrial mutant through activation of stress response pathwaysBMC Biol 16
5.
1. Felkai S.
2. et al.
1999CLK-1 controls respiration, behavior and aging in the nematode Caenorhabditis elegansEmbo j 18:1783–1792
6.
1. Feng J.
2. Bussière F.
3. Hekimi S
2001Mitochondrial electron transport is a key determinant of life span in Caenorhabditis elegansDev Cell 1:633–644
7.
1. Lee S.S.
2. et al.
2003A systematic RNAi screen identifies a critical role for mitochondria in C. elegans longevityNat Genet 33:40–48
8.
1. Copeland J.M.
2. et al.
2009Extension of Drosophila life span by RNAi of the mitochondrial respiratory chainCurr Biol 19:1591–1598
9.
1. Owusu-Ansah E.
2. Song W.
3. Perrimon N
2013Muscle mitohormesis promotes longevity via systemic repression of insulin signalingCell 155:699–712
10.
1. Huang X.
2. Cheng H.J.
3. Tessier-Lavigne M.
4. Jin Y
2002MAX-1, a novel PH/MyTH4/FERM domain cytoplasmic protein implicated in netrin-mediated axon repulsionNeuron 34:563–576
11.
1. Chaudhari S.N.
2. Kipreos E.T
2017Increased mitochondrial fusion allows the survival of older animals in diverse C. elegans longevity pathwaysNature communications 8
12.
1. Maglioni S.
2. Mello D.F.
3. Schiavi A.
4. Meyer J.N.
5. Ventura N
2019Mitochondrial bioenergetic changes during development as an indicator of C. elegans health-spanAging (Albany NY 11:6535–6554
13.
1. Chen D.
2. Pan K.Z.
3. Palter J.E.
4. Kapahi P
2007Longevity determined by developmental arrest genes in Caenorhabditis elegansAging Cell 6:525–533
14.
1. Ewbank J.J.
2. et al.
1997Structural and functional conservation of the Caenorhabditis elegans timing gene clk-1Science 275:980–983
15.
1. Liu X.
2. et al.
2005Evolutionary conservation of the clk-1-dependent mechanism of longevity: loss of mclk1 increases cellular fitness and lifespan in miceGenes Dev 19:2424–2434
16.
1. Durieux J.
2. Wolff S.
3. Dillin A
2011The cell-non-autonomous nature of electron transport chain-mediated longevityCell 144:79–91
17.
1. Bennett C.F.
2. et al.
2014Activation of the mitochondrial unfolded protein response does not predict longevity in Caenorhabditis elegansNature communications 5
18.
1. Tian Y.
2. et al.
2016Mitochondrial Stress Induces Chromatin Reorganization to Promote Longevity and UPR(mt)Cell 165:1197–1208
19.
1. Gao K.
2. Li Y.
3. Hu S.
4. Liu Y
2019SUMO peptidase ULP-4 regulates mitochondrial UPR-mediated innate immunity and lifespan extensioneLife 8
20.
1. Wolff S.
2. et al.
2006SMK-1, an essential regulator of DAF-16-mediated longevityCell 124:1039–1053
21.
1. Senchuk M.M.
2. et al.
2018Activation of DAF-16/FOXO by reactive oxygen species contributes to longevity in long-lived mitochondrial mutants in Caenorhabditis elegansPLoS Genet 14
22.
1. Bennett C.F.
2. et al.
2017Transaldolase inhibition impairs mitochondrial respiration and induces a starvation-like longevity response in Caenorhabditis elegansPLoS Genet 13
23.
1. Cortopassi G.A.
2. Arnheim N
1990Detection of a specific mitochondrial DNA deletion in tissues of older humansNucleic Acids Res 18:6927–6933
24.
1. Pikó L.
2. Hougham A.J.
3. Bulpitt K.J
1988Studies of sequence heterogeneity of mitochondrial DNA from rat and mouse tissues: evidence for an increased frequency of deletions/additions with agingMech Ageing Dev 43:279–293
25.
1. Hughes A.L.
2. Gottschling D.E
2012An early age increase in vacuolar pH limits mitochondrial function and lifespan in yeastNature 492:261–265
26.
1. Hughes C.E.
2. et al.
2020Cysteine Toxicity Drives Age-Related Mitochondrial Decline by Altering Iron HomeostasisCell 180:296–310
27.
1. Mansell E.
2. et al.
2021Mitochondrial Potentiation Ameliorates Age-Related Heterogeneity in Hematopoietic Stem Cell FunctionCell Stem Cell 28:241–256
28.
1. Li M.
2. Schröder R.
3. Ni S.
4. Madea B.
5. Stoneking M
2015Extensive tissue-related and allele-related mtDNA heteroplasmy suggests positive selection for somatic mutationsProc Natl Acad Sci U S A 112:2491–2496
29.
1. Brandt T.
2. et al.
2017Changes of mitochondrial ultrastructure and function during ageing in mice and DrosophilaElife 6
30.
1. Soong N.W.
2. Hinton D.R.
3. Cortopassi G.
4. Arnheim N
1992Mosaicism for a specific somatic mitochondrial DNA mutation in adult human brainNat Genet 2:318–323
31.
1. Warren C.
2. et al.
2020Decoding mitochondrial heterogeneity in single muscle fibres by imaging mass cytometrySci Rep 10
32.
1. Gredilla R.
2. Garm C.
3. Holm R.
4. Bohr V.A.
5. Stevnsner T
2010Differential age-related changes in mitochondrial DNA repair activities in mouse brain regionsNeurobiol Aging 31:993–1002
33.
1. Shao L.W.
2. Niu R.
3. Liu Y
2016Neuropeptide signals cell non-autonomous mitochondrial unfolded protein responseCell Res 26:1182–1196
34.
1. Zhang Q.
2. et al.
2018The Mitochondrial Unfolded Protein Response Is Mediated Cell-Non-autonomously by Retromer-Dependent Wnt SignalingCell 174:870–883
35.
1. Zhang Q.
2. et al.
2021The memory of neuronal mitochondrial stress is inherited transgenerationally via elevated mitochondrial DNA levelsNat Cell Biol 23:870–880
36.
1. Berendzen K.M.
2. et al.
2016Neuroendocrine Coordination of Mitochondrial Stress Signaling and ProteostasisCell 166:1553–1563
37.
1. Docherty M.
2. Bradford H.F.
3. Wu J.Y.
4. Joh T.H.
5. Reis D.J
1985Evidence for specific immunolysis of nerve terminals using antisera against choline acetyltransferase, glutamate decarboxylase and tyrosine hydroxylaseBrain Res 339:105–113
38.
1. McQuail J.A.
2. Frazier C.J.
3. Bizon J.L
2015Molecular aspects of age-related cognitive decline: the role of GABA signalingTrends Mol Med 21:450–460
39.
1. Porges E.C.
2. Jensen G.
3. Foster B.
4. Edden R.A.
5. Puts N.A
2021The trajectory of cortical GABA across the lifespan, an individual participant data meta-analysis of edited MRS studiesElife 10
40.
1. Schuske K.
2. Beg A.A.
3. Jorgensen E.M
2004The GABA nervous system in C. elegansTrends Neurosci 27:407–414
41.
1. McIntire S.L.
2. Jorgensen E.
3. Kaplan J.
4. Horvitz H.R
1993The GABAergic nervous system of Caenorhabditis elegansNature 364:337–341
42.
1. Chun L.
2. et al.
2015Metabotropic GABA signalling modulates longevity in C. elegansNature communications 6
43.
1. Yuan F.
2. et al.
2019GABA receptors differentially regulate life span and health span in C. elegans through distinct downstream mechanismsAm J Physiol Cell Physiol 317:C953–c963
44.
1. Garcia S.M.
2. Casanueva M.O.
3. Silva M.C.
4. Amaral M.D.
5. Morimoto R.I
2007Neuronal signaling modulates protein homeostasis in Caenorhabditis elegans post-synaptic muscle cellsGenes Dev 21:3006–3016
45.
1. Pohl F.
2. et al.
2023UNC-49 is a redox-sensitive GABA(A) receptor that regulates the mitochondrial unfolded protein response cell nonautonomouslySci Adv 9
46.
1. Van Raamsdonk J.M.
2. Hekimi S
2009Deletion of the mitochondrial superoxide dismutase sod-2 extends lifespan in Caenorhabditis elegansPLoS Genet 5
47.
1. Feng J.
2. Bussière F.
3. Hekimi S
2001Mitochondrial electron transport is a key determinant of life span in Caenorhabditis elegansDevelopmental cell 1:633–644
48.
1. Firnhaber C.
2. Hammarlund M
2013Neuron-specific feeding RNAi in C. elegans and its use in a screen for essential genes required for GABA neuron functionPLoS Genet 9
49.
1. Han S.M.
2. Baig H.S.
3. Hammarlund M
2016Mitochondria Localize to Injured Axons to Support RegenerationNeuron 92:1308–1323
50.
1. Qadota H.
2. et al.
2007Establishment of a tissue-specific RNAi system in C. elegansGene 400:166–173
51.
1. Timmons L.
2. Fire A
1998Specific interference by ingested dsRNANature 395
52.
1. Han S.M.
2. et al.
2013VAPB/ALS8 MSP ligands regulate striated muscle energy metabolism critical for adult survival in caenorhabditis elegansPLoS Genet 9
53.
1. Zou L.
2. et al.
2019Construction of a germline-specific RNAi tool in C. elegansSci Rep 9
54.
1. Calixto A.
2. Chelur D.
3. Topalidou I.
4. Chen X.
5. Chalfie M
2010Enhanced neuronal RNAi in C. elegans using SID-1Nat Methods 7:554–559
55.
1. Tavernarakis N.
2. Driscoll M
2000Caenorhabditis elegans degenerins and vertebrate ENaC ion channels contain an extracellular domain related to venom neurotoxinsJ Neurogenet 13:257–264
56.
1. Tabara H.
2. et al.
1999The rde-1 gene RNA interference, and transposon silencing in C. elegansCell 99:123–132
57.
1. Yoneda T.
2. et al.
2004Compartment-specific perturbation of protein handling activates genes encoding mitochondrial chaperonesJ Cell Sci 117:4055–4066
58.
1. Shih J.D.
2. Hunter C.P
2011SID-1 is a dsRNA-selective dsRNA-gated channelRna 17:1057–1065
59.
1. Feinberg E.H.
2. Hunter C.P
2003Transport of dsRNA into cells by the transmembrane protein SID-1Science 301:1545–1547
60.
1. Winston W.M.
2. Molodowitch C.
3. Hunter C.P
2002Systemic RNAi in C. elegans requires the putative transmembrane protein SID-1Science 295:2456–2459
61.
1. Garigan D.
2. et al.
2002Genetic analysis of tissue aging in Caenorhabditis elegans: a role for heat-shock factor and bacterial proliferationGenetics 161:1101–1112
62.
1. Lithgow G.J.
2. White T.M.
3. Melov S.
4. Johnson T.E
1995Thermotolerance and extended life-span conferred by single-gene mutations and induced by thermal stressProc Natl Acad Sci U S A 92:7540–7544
63.
1. Harshman L.G.
2. Haberer B.A
2000Oxidative stress resistance: a robust correlated response to selection in extended longevity lines of Drosophila melanogaster?J Gerontol A Biol Sci Med Sci 55:B415–417
64.
1. Fabrizio P.
2. Pozza F.
3. Pletcher S.D.
4. Gendron C.M.
5. Longo V.D
2001Regulation of longevity and stress resistance by Sch9 in yeastScience 292:288–290
65.
1. Johnson T.E.
2. et al.
2002Longevity genes in the nematode Caenorhabditis elegans also mediate increased resistance to stress and prevent diseaseJ Inherit Metab Dis 25:197–206
66.
1. Murakami S.
2. Salmon A.
3. Miller R.A
2003Multiplex stress resistance in cells from long-lived dwarf miceFASEB J 17:1565–1566
68.
1. Hubbard E.J.
2. Greenstein D
2005Introduction to the germ lineWormBook :1–4
69.
1. Dues D.J.
2. et al.
2017Uncoupling of oxidative stress resistance and lifespan in long-lived isp-1 mitochondrial mutants in Caenorhabditis elegansFree Radic Biol Med 108:362–373
70.
1. Gumienny T.L.
2. Lambie E.
3. Hartwieg E.
4. Horvitz H.R.
5. Hengartner M.O
1999Genetic control of programmed cell death in the Caenorhabditis elegans hermaphrodite germlineDevelopment 126:1011–1022
71.
1. Clandinin T.R.
2. DeModena J.A.
3. Sternberg P.W
1998Inositol trisphosphate mediates a RAS-independent response to LET-23 receptor tyrosine kinase activation in C. elegansCell 92:523–533
72.
1. Marcus D.L.
2. Ibrahim N.G.
3. Freedman M.L
1982Age-related decline in the biosynthesis of mitochondrial inner membrane proteinsExp Gerontol 17:333–341
73.
1. Bailey P.J.
2. Webster G.C
1984Lowered rates of protein synthesis by mitochondria isolated from organisms of increasing ageMech Ageing Dev 24:233–241
74.
1. Rooyackers O.E.
2. Adey D.B.
3. Ades P.A.
4. Nair K.S
1996Effect of age on in vivo rates of mitochondrial protein synthesis in human skeletal muscleProc Natl Acad Sci U S A 93:15364–15369
75.
1. Satoh A.
2. et al.
2013Sirt1 Extends Life Span and Delays Aging in Mice through the Regulation of Nk2 Homeobox 1 in the DMH and LHCell Metabolism 18:416–430
76.
1. Berry B.J.
2. et al.
2023Optogenetic rejuvenation of mitochondrial membrane potential extends C. elegans lifespanNature Aging 3:157–161
77.
1. Pendergrass W.
2. Wolf N.
3. Poot M
2004Efficacy of MitoTracker Green and CMXrosamine to measure changes in mitochondrial membrane potentials in living cells and tissuesCytometry A 61:162–169
78.
1. Han S.M.
2. et al.
2012Secreted VAPB/ALS8 major sperm protein domains modulate mitochondrial localization and morphology via growth cone guidance receptorsDev Cell 22:348–362
79.
1. Monteiro L.B.
2. Davanzo G.G.
3. de Aguiar C.F.
4. Moraes-Vieira P.M.M
2020Using flow cytometry for mitochondrial assaysMethodsX 7
80.
1. Bratic I.
2. et al.
2009Mitochondrial DNA level, but not active replicase, is essential for Caenorhabditis elegans developmentNucleic Acids Res 37:1817–1828
81.
1. Gui Y.X.
2. Xu Z.P.
3. Lv W.
4. Zhao J.J.
5. Hu X.Y
2015Evidence for polymerase gamma, POLG1 variation in reduced mitochondrial DNA copy number in Parkinson’s diseaseParkinsonism Relat Disord 21:282–286
82.
1. Yoon D.S.
2. Lee M.H.
3. Cha D.S
2018Measurement of Intracellular ROS in Caenorhabditis elegans Using 2’,7’-Dichlorodihydrofluorescein DiacetateBio Protoc 8
83.
1. Blackwell T.K.
2. Steinbaugh M.J.
3. Hourihan J.M.
4. Ewald C.Y.
5. Isik M
2015SKN-1/Nrf, stress responses, and aging in Caenorhabditis elegansFree Radic Biol Med 88:290–301
84.
1. Haynes C.M.
2. Petrova K.
3. Benedetti C.
4. Yang Y.
5. Ron D
2007ClpP mediates activation of a mitochondrial unfolded protein response in C. elegansDev Cell 13:467–480
85.
1. Haynes C.M.
2. Fiorese C.J.
3. Lin Y.F
2013Evaluating and responding to mitochondrial dysfunction: the mitochondrial unfolded-protein response and beyondTrends Cell Biol 23:311–318
86.
1. Nargund A.M.
2. Pellegrino M.W.
3. Fiorese C.J.
4. Baker B.M.
5. Haynes C.M
2012Mitochondrial import efficiency of ATFS-1 regulates mitochondrial UPR activationScience 337:587–590
87.
1. Leiers B.
2. et al.
2003A stress-responsive glutathione S-transferase confers resistance to oxidative stress in Caenorhabditis elegansFree Radic Biol Med 34:1405–1415
88.
1. Wang J.
2. et al.
2010RNAi screening implicates a SKN-1-dependent transcriptional response in stress resistance and longevity deriving from translation inhibitionPLoS Genet 6
89.
1. Byrne A.B.
2. et al.
2014Insulin/IGF1 signaling inhibits age-dependent axon regenerationNeuron 81:561–573
90.
1. Honda Y.
2. Honda S
1999The daf-2 gene network for longevity regulates oxidative stress resistance and Mn-superoxide dismutase gene expression in Caenorhabditis elegansFaseb j 13:1385–1393
91.
1. Libina N.
2. Berman J.R.
3. Kenyon C
2003Tissue-specific activities of C. elegans DAF-16 in the regulation of lifespanCell 115:489–502
92.
1. Mahoney T.R.
2. Luo S.
3. Nonet M.L
2006Analysis of synaptic transmission in Caenorhabditis elegans using an aldicarb-sensitivity assayNat Protoc 1:1772–1777
93.
1. Jin Y.
2. Jorgensen E.
3. Hartwieg E.
4. Horvitz H.R
1999The Caenorhabditis elegans gene unc-25 encodes glutamic acid decarboxylase and is required for synaptic transmission but not synaptic developmentJ Neurosci 19:539–548
94.
1. Vashlishan A.B.
2. et al.
2008An RNAi screen identifies genes that regulate GABA synapsesNeuron 58:346–361
95.
1. Speese S.
2. et al.
2007UNC-31 (CAPS) is required for dense-core vesicle but not synaptic vesicle exocytosis in Caenorhabditis elegansJ Neurosci 27:6150–6162
96.
1. Li C.
2. Kim K.
2008NeuropeptidesWormBook :1–36
97.
1. Melkman T.
2. Sengupta P
2005Regulation of chemosensory and GABAergic motor neuron development by the C. elegans Aristaless/Arx homolog alr-1Development 132:1935–1949
98.
1. Shan G.
2. Kim K.
3. Li C.
4. Walthall W.W
2005Convergent genetic programs regulate similarities and differences between related motor neuron classes in Caenorhabditis elegansDevelopmental Biology 280:494–503
99.
1. Jafari G.
2. et al.
2015Tether mutations that restore function and suppress pleiotropic phenotypes of the C. elegans isp-1(qm150) Rieske iron-sulfur proteinProc Natl Acad Sci U S A 112:E6148–6157
100.
1. Lemire B.D.
2. Behrendt M.
3. DeCorby A.
4. Gášková D
2009C. elegans longevity pathways converge to decrease mitochondrial membrane potentialMechanisms of Ageing and Development 130:461–465
101.
1. Yang W.
2. Hekimi S
2010Two modes of mitochondrial dysfunction lead independently to lifespan extension in Caenorhabditis elegansAging Cell 9:433–447
102.
1. Lee S.J.
2. Hwang A.B.
3. Kenyon C
2010Inhibition of respiration extends C. elegans life span via reactive oxygen species that increase HIF-1 activityCurr Biol 20:2131–2136
103.
1. Bansal A.
2. Zhu L.J.
3. Yen K.
4. Tissenbaum H.A
2015Uncoupling lifespan and healthspan in Caenorhabditis elegans longevity mutantsProc Natl Acad Sci U S A 112:E277–286
104.
1. Rahman S.
2. Copeland W.C
2019POLG-related disorders and their neurological manifestationsNat Rev Neurol 15:40–52
105.
1. Short K.R.
2. et al.
2005Decline in skeletal muscle mitochondrial function with aging in humansProc Natl Acad Sci U S A 102:5618–5623
106.
1. Back P.
2. Braeckman B.P.
3. Matthijssens F
2012ROS in aging Caenorhabditis elegans: damage or signaling?Oxid Med Cell Longev 2012
107.
1. Enell L.E.
2. Kapan N.
3. Söderberg J.A.
4. Kahsai L.
5. Nässel D.R
2010Insulin signaling, lifespan and stress resistance are modulated by metabotropic GABA receptors on insulin producing cells in the brain of DrosophilaPLoS One 5
108.
1. Ly C.V.
2. Verstreken P
2006Mitochondria at the synapseNeuroscientist 12:291–299
109.
1. Kwon S.K.
2. et al.
2016LKB1 Regulates Mitochondria-Dependent Presynaptic Calcium Clearance and Neurotransmitter Release Properties at Excitatory Synapses along Cortical AxonsPLoS Biol 14
110.
1. Sun T.
2. Qiao H.
3. Pan P.Y.
4. Chen Y.
5. Sheng Z.H
2013Motile axonal mitochondria contribute to the variability of presynaptic strengthCell reports 4:413–419
111.
1. Ivannikov M.V.
2. Sugimori M.
3. Llinas R.R
2013Synaptic vesicle exocytosis in hippocampal synaptosomes correlates directly with total mitochondrial volumeJ Mol Neurosci 49:223–230
112.
1. Verstreken P.
2. et al.
2005Synaptic mitochondria are critical for mobilization of reserve pool vesicles at Drosophila neuromuscular junctionsNeuron 47:365–378
113.
1. Smith H.L.
2. et al.
2016Mitochondrial support of persistent presynaptic vesicle mobilization with age-dependent synaptic growth after LTPElife 5
114.
1. Schultz J.
2. et al.
2017The secreted MSP domain of C. elegans VAPB homolog VPR-1 patterns the adult striated muscle mitochondrial reticulum via SMN-1Development 144:2175–2186
115.
1. Sun T.
2. Qiao H.
3. Pan P.Y.
4. Chen Y.
5. Sheng Z.H
2013Motile axonal mitochondria contribute to the variability of presynaptic strengthCell Rep 4:413–419
116.
1. Gorman G.S.
2. et al.
2016Mitochondrial diseasesNat Rev Dis Primers 2
117.
1. Jeong D.E.
2. Artan M.
3. Seo K.
4. Lee S.J
2012Regulation of lifespan by chemosensory and thermosensory systems: findings in invertebrates and their implications in mammalian agingFront Genet 3
118.
1. Wolkow C.A.
2. Kimura K.D.
3. Lee M.S.
4. Ruvkun G
2000Regulation of C. elegans life-span by insulinlike signaling in the nervous systemScience 290:147–150
119.
1. Taguchi A.
2. Wartschow L.M.
3. White M.F
2007Brain IRS2 signaling coordinates life span and nutrient homeostasisScience 317:369–372
120.
1. Apfeld J.
2. Kenyon C
1999Regulation of lifespan by sensory perception in Caenorhabditis elegansNature 402:804–809
121.
1. Alcedo J.
2. Kenyon C
2004Regulation of C. elegans longevity by specific gustatory and olfactory neuronsNeuron 41:45–55
122.
1. Chen Y.C.
2. et al.
2016A C. elegans Thermosensory Circuit Regulates Longevity through crh-1/CREB-Dependent flp-6 Neuropeptide SignalingDev Cell 39:209–223
123.
1. Brenner S
1974The genetics of Caenorhabditis elegansGenetics 77:71–94
124.
1. Kamath R.S.
2. Martinez-Campos M.
3. Zipperlen P.
4. Fraser A.G.
5. Ahringer J
2001Effectiveness of specific RNA-mediated interference through ingested double-stranded RNA in Caenorhabditis elegansGenome Biol 2
125.
1. Kamath R.S.
2. Ahringer J
2003Genome-wide RNAi screening in Caenorhabditis elegansMethods 30:313–321
126.
1. Stiernagle T
2006Maintenance of C. elegansWormBook :1–11
127.
1. Han S.M.
2. et al.
2006Deleted in cancer 1 (DICE1) is an essential protein controlling the topology of the inner mitochondrial membrane in C. elegansDevelopment 133:3597–3606
128.
1. Dingley S.
2. et al.
2010Mitochondrial respiratory chain dysfunction variably increases oxidant stress in Caenorhabditis elegansMitochondrion 10:125–136
129.
1. Rooney J.P.
2. et al.
2015PCR based determination of mitochondrial DNA copy number in multiple speciesMethods Mol Biol 1241:23–38
130.
1. Sheng Y.
2. Yang G.
3. Markovich Z.
4. Han S.M.
5. Xiao R
2021Distinct temporal actions of different types of unfolded protein responses during agingJ Cell Physiol 236:5069–5079
131.
1. Grishok A.
2. Tabara H.
3. Mello C.C
2000Genetic requirements for inheritance of RNAi in C. elegansScience 287:2494–2497
132.
1. Wang D.
2. et al.
2005Somatic misexpression of germline P granules and enhanced RNA interference in retinoblastoma pathway mutantsNature 436:593–597

Article and author information

Author information

Laxmi Rathor
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Shayla Curry
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Youngyong Park
Division of Hematology/Oncology, Department of Internal Medicine, Brody School of Medicine at East Carolina University, Greenville, NC 27834, USA, Department of Biology, Johns Hopkins University, Baltimore, MD, 21218, USA
Taylor McElroy
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Briana Robles
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Yi Sheng
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Wei-Wen Chen
School of Chemistry & Biochemistry, College of Sciences, Georgia Institute of Technology, Atlanta, GA 30332, USA
Kisuk Min
Department of Kinesiology, University of Texas at El Paso, El Paso, TX 79968, USA
Rui Xiao
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
Myon Hee Lee
Department of Biology, Johns Hopkins University, Baltimore, MD, 21218, USA, Department of Biology, East Carolina University, Greenville, NC 27858, USA
Sung Min Han
Department of Physiology and Aging, College of Medicine, University of Florida, Gainesville, FL 32610, USA
ORCID iD: 0000-0001-7442-754X
- Corresponding author: Sung Min Han, Ph.D. Department of Physiology and Aging, Institute on Aging, College of Medicine, University of Florida, Gainesville, Florida 32610, USA. Tel.: 352-273-5682, Fax: 352-273-5737, Email: han.s@ufl.edu.

Version history

Sent for peer review: March 20, 2024
Preprint posted: March 25, 2024
Reviewed Preprint version 1: May 14, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Metrics

views: 511
downloads: 18
citations: 0

Views, downloads and citations are aggregated across all versions of this paper published by eLife.

Significance of findings

Strength of evidence

Abstract

Introduction

Results

Mitochondrial perturbations in GABAergic neurons are sufficient to prolong the organismal lifespan

Mitochondrial stress in GABAergic neurons is sufficient to prolong the organismal lifespan.

Mitochondrial stress in GABAergic neurons increases the stress tolerance of the organism

Mitochondrial stress in GABAergic neurons enhances stress resistance

GABAergic neuronal mitochondrial stress alters reproduction

Reproductive effects of mitochondrial perturbation in GABAergic neurons.

Mitochondrial stress in GABAergic neurons enhances mitochondrial function in the peripheral tissues

GABAergic neuronal mitochondrial stress alters the mitochondrial homeostasis in peripheral tissues of animals.

GABAergic neuronal Mitochondrial Stress Enhances the DAF-16/FoxO Pathway

GABAergic neuronal mitochondria stress elevated the DAF-16/FoxO pathway.

The non-cell-autonomous effects of GABAergic neuronal mitochondrial defects require DAF-16/FoxO

GABAergic neuronal mitochondria stress requires DAF-16/FoxO to trigger the non-cell-autonomous effects.

Mitochondrial stress in GABAergic neurons causes non-cell-autonomous changes by acting on the same mechanisms as GABA signaling

Non-cell autonomous effects of GABAergic neuronal mitochondrial stress were not additively enhanced by the loss of GABA signaling.

Neuropeptide signaling in GABAergic neurons regulates organismal aging and health without additive effects with mitochondrial stress in GABAergic neurons

FLP-13 neuropeptides modulate organismal lifespan and stress tolerance, without expanding the non-cell autonomous effects of GABAergic neuronal mitochondrial stress.

Discussion

Acknowledgements

Author Contributions

Declaration of Interests

Inclusion and diversity

Data availability

Material and Methods

C. elegans strains

RNAi assay

Lifespan assay

Aldicarb sensitivity assay

Reproductive assay

Stress assays

Staining assays for ROS level and mitochondrial homeostasis

ATP assay

mtDNA quantification

Quantitative reverse transcriptase PCR

Statistics

(Related to Figure 1). Global induction of mitoUPR reporter upon isp-1 dsRNAs expression in GABAergic neurons of wild-type animals.

(Related to Figure 2). Continuous gRNAi against spg-7 over three generations led to altered organismal stress resistance.

(Related to Figure 3). Non-cell autonomous effects of GABA neuronal mitochondrial stress on the reproductive system.

(Related to Figure 6). The role of DAF-16 in the non-cell autonomous effects of GABA neuronal mitochondrial stress.

(Related to Figure 7): Assessing the impact of mitochondrial stress in GABAergic neurons on lifespan in unc-25 null mutants.

(Related to Figure 8). The effects of single GABA-RNAi inhibition against flp-13 and isp-1 on lifespan and stress response.

References

Article and author information

Author information

Laxmi Rathor

Shayla Curry

Youngyong Park

Taylor McElroy

Briana Robles

Yi Sheng

Wei-Wen Chen

Kisuk Min

Rui Xiao

Myon Hee Lee

Sung Min Han

Version history

Copyright

Metrics

(Related to Figure 8). The effects of single GABA-RNAi inhibition against flp-13 **and isp-1 on lifespan and stress response.**