Loss of dihydroceramide desaturase drives neurodegeneration by disrupting endoplasmic reticulum and lipid droplet homeostasis in glial cells

Yuqing Zhu; Kevin Cho; Haluk Lacin; Yi Zhu; Jose T DiPaola; Beth A Wilson; Gary J Patti; James B Skeath

doi:10.7554/eLife.99344.1

Abstract

Dihydroceramide desaturases convert dihydroceramides to ceramides, the precursors of all complex sphingolipids. Reduction of DEGS1 dihydroceramide desaturase function causes pediatric neurodegenerative disorder hypomyelinating leukodystrophy-18 (HLD-18). We discovered that infertile crescent (ifc), the Drosophila DEGS1 homolog, is expressed primarily in glial cells to promote CNS development by guarding against neurodegeneration. Loss of ifc causes massive dihydroceramide accumulation and severe morphological defects in cortex glia, including endoplasmic reticulum (ER) expansion, failure of neuronal ensheathment, and lipid droplet depletion. RNAi knockdown of the upstream ceramide synthase schlank in glia of ifc mutants rescues ER expansion, suggesting dihydroceramide accumulation in the ER drives this phenotype. RNAi knockdown of ifc in glia but not neurons drives neuronal cell death, suggesting that ifc function in glia promotes neuronal survival. Our work identifies glia as the primary site of disease progression in HLD-18 and may inform on juvenile forms of ALS, which also feature elevated dihydroceramide levels.

eLife assessment

Zhu, et al. present convincing data that details the function of the infertile crescent gene (ifc) in fly development with implications on human neurodegenerative disease. The authors unveil interesting and novel phenotypes of ifc loss-of-function in glia. The experiments are well planned and executed, and the data support the conclusions. These important findings have theoretical and practical implications beyond a single subfield and the methods are in line with current state-of-the-art.

https://doi.org/10.7554/eLife.99344.1.sa4

Introduction

Sphingolipids are key structural and functional components of the cell membrane in all eukaryotic cells and are enriched in glial cells, such as oligodendrocytes, where they comprise up to 30% of all membrane lipids.¹ All complex sphingolipids, like glycosylsphingolipids and sphingomyelin, derive from ceramide.^2,3,4 In the de novo ceramide biosynthesis pathway, dihydroceramide desaturases, such as DEGS1, produce ceramide from dihydroceramide by catalyzing the formation of a trans double bond between carbons 4 and 5 of the sphingoid backbone, which enhances conformational plasticity.^5,6 In humans, bi-allelic mutations in DEGS1 cause hypomyelinating leukodystrophy-18 (HLD-18), a progressive, often fatal pediatric neurodegenerative disease marked by cerebral atrophy, white matter reduction, and hypomyelination.^7,8,9 The primary neural cell type impacted by loss of DEGS1 function and the cell biology of how disruption of ceramide synthesis leads to neurodegeneration remain unknown.

The de novo ceramide biosynthetic pathway is well conserved among higher metazoans.^{4,10,11,12,13} De novo ceramide synthesis occurs in the endoplasmic reticulum (ER) and starts with the rate-limiting activity of the serine palmitoyltransferase (SPT) complex, which condenses serine and palmitoyl-CoA (lauoryl-CoA in flies) to form 3-Ketosphinganine, which is converted to sphinganine by 3-Ketosphinganine reductase. Ceramide synthases condense sphinganine with acyl-CoA to generate dihydroceramide, which is converted to ceramide by dihydroceramide desaturases. Ceramide is then efficiently transported by the specific ceramide transporter CERT from the ER to the Golgi,¹⁴ where it undergoes headgroup modifications to produce complex sphingolipids that eventually translocate to the plasma membrane.¹⁵ Mutations in most members of the SPT complex, ceramide synthases, and DEGS1 lead to neurodegeneration,^4,12,13 identifying the de novo ceramide biosynthesis pathway as a hotspot for neurodegenerative disease mutations.

Consistent with its central role in ceramide biogenesis, reduction or loss of DEGS1 function in human patients or cell lines, mice, zebrafish, and flies drive dihydroceramide accumulation and ceramide depletion.^8,9,16,17 HLD-18 patients display reduced myelin sheath thickness in peripheral nerves, and knockdown of DEGS1 function in zebrafish reduces the number of myelin basic protein-positive oligodendrocytes,^8,9 suggesting DEGS1 regulates Schwann cell and oligodendrocyte development. In Drosophila, genetic ablation of infertile crescent (ifc), the fly DEGS1 ortholog, drives activity-dependent photoreceptor degeneration,¹⁷ suggesting that ifc function is crucial for neuronal homeostasis. In addition, forced expression of a wildtype ifc transgene in neurons, glia, or muscles was shown to rescue the ifc mutant phenotype.¹⁷ Whether ifc/DEGS1 acts primarily in glia, neurons, or other cells to regulate nervous system development then remains to be determined.

Research on DEGS1 points to dihydroceramide accumulation as the driver of nervous system defects caused by DEGS1 deficiency. Pharmacological or genetic inhibition of ceramide synthase function, which should reduce dihydroceramide levels, suppresses the observed reduction of MBP-positive oligodendrocytes in zebrafish and the activity-dependent photoreceptor degeneration in flies triggered by reduction of DEGS1/ifc function.^9,17 Dihydroceramide accumulation may also contribute to other neurodegenerative diseases, as gain of function mutations in components of the SPT complex cause juvenile amyotrophic lateral sclerosis due to elevated sphingolipid biosynthesis, with dihydroceramides showing the greatest relative increase of all sphingolipids.^18,19,20,21 How dihydroceramide accumulation alters the cell biology of neurons, glia, or both to trigger myelination defects and neurodegeneration is unclear.

With its vast genetic toolkit, Drosophila is a powerful system in which to dissect the genes and pathways that regulate glial development and function.^22,23 In flies, six morphologically and functionally distinct glial subtypes regulate nervous system development and homeostasis.^24,25 The surface perineurial and subperineural glia act as physiochemical barriers to protect the nervous system and control metabolite exchange with the hemolymph, carrying out a similar function as the human blood-brain-barrier.^26,27 Residing between the surface glia and the neuropil, cortex glia ensheath the cell bodies of neuroblasts and neurons in the CNS in protective, nutritive, honeycomb-like membrane sheaths. Ensheathing glia define the boundary of the neuropil and insulate axons, dendrites, and synapses from neuronal cell bodies in the CNS.²⁸ Astrocyte-like glia extend fine membrane protrusions that infiltrate the neuropil and form a meshwork of cellular processes that ensheath synapses and regulate synaptic homeostasis in the CNS.²⁸ In the PNS, wrapping glia reside internally to the surface glia and insulate axons in the PNS to enhance neuronal signaling and provide energy support.

Using the Drosophila model, we found that ifc acts primarily in glia to regulate CNS development with its loss disrupting glial morphology. Our work supports a model in which inappropriate accumulation and retention of dihydroceramide in the ER drives ER expansion, glial swelling, and the failure of glia to enwrap neurons, ultimately leading to neuronal degeneration as a secondary consequence of glial dysfunction. Given the conserved nature of de novo ceramide biosynthesis, our findings likely illuminate the exact mechanism through which elevated dihydroceramide levels drive neuronal degeneration and cell death in flies and humans.

Results

ifc contributes to the regulation developmental timing and CNS structure

In an EMS-based genetic screen, we uncovered three non-complementing mutations that when homozygous or trans-heterozygous to each other resulted in identical phenotypes, including a 3-day or greater delay in reaching the late-third larval instar stage, reduced brain size, progressive ventral nerve cord elongation, axonal swelling, and lethality at the late larval or early pupal stage (Figure 1A; data not shown). Whole genome sequencing revealed that ifc was independently mutated in each line: ifc^js¹ and ifc^js² encode V276D and G257S missense mutations, respectively, and ifc^js³ encodes a W162* nonsense mutation (Figures 1A and 1B). Sanger sequencing also uncovered a missense mutation, E241K, in the molecularly uncharacterized ifc¹ allele (Figure 1B). All four mutations reside in the fatty acid desaturase domain, the hotspot for mutations in human DEGS1 that cause HLD-18 (Figures 1B-B’).

*ifc* regulates CNS and glial morphology. A) Ventral views of late-third instar larvae of indicated genotype showing 3xP3 RFP labeling of CNS and nerves. Arrowheads indicate nerve bulges; scale bar is 200μm. B-B’) Schematic of Ifc (B) and human DEGS1 (B’) proteins indicating location and nature of *ifc* mutations and 15 HLD-18-causing *DEGS1* mutations.^7,8,9 C) Schematic of *de novo* ceramide biosynthesis pathway indicating the subcellular location of ceramide synthesis and ceramide modifications. D) Chemical structure of dihydroceramide and ceramide; arrow indicates *trans* carbon-carbon double bond between C4 and C5 in the sphingoid backbone created by the enzymatic action of Ifc/DEGS1. E) Normalized quantification of the relative levels of dihydroceramide, ceramide, and six related sphingolipid species in the dissected CNS of wild-type and *ifc^-/-* late-third instar larvae. F) Ventral views of *Drosophila* CNS and peripheral nerves in wild-type and *ifc^-/-* mutant late-third instar larvae labeled for NCAD to mark the neuropil, HRP to label axons, RFP to label glia, Dpn to label neuroblasts, ELAV to label neurons, and FABP to label cortex glia. Anterior is up; scale bar is 100μm for whole CNS images and 20μm for peripheral nerve image. Statistics: * denotes p < 0.05, ** denotes p < 0.01, *** denotes p < 0.001, **** *denotes p* < 0.0001.

As a prior study reported that a CRISPR-generated, gene-specific deletion of ifc, ifc-KO, resulted in early larval lethality¹⁷, we first confirmed the genetic nature of our ifc alleles because they caused late larval-early pupal lethality. Complementation crosses of each ifc allele against a deficiency of the region (Df(2L)BSC184) and ifc-KO revealed that all combinations, including larvae trans-heterozygous for ifc-KO over Df(2L)BSC184, survived to the late larval-early pupal stage and yielded phenotypes identical to those detailed above for the newly uncovered ifc alleles. Flies homozygous for ifc-KO, however, died as early larvae. Further analysis uncovered second site mutation(s) in the 21E2 chromosomal region responsible for the early lethal phenotype of the ifc-KO chromosome (see Methods). When uncoupled from these mutation(s), larvae homozygous for the “clean” ifc-KO chromosome developed to the late larval-early pupal stage and manifested phenotypes identical to the other ifc alleles. This analysis defined the correct lethal phase for ifc and identified our ifc alleles as strong loss of function mutations.

Loss of ifc function drives ceramide depletion and dihydroceramide accumulation

As ifc/DEGS1 converts dihydroceramide to ceramide, we used untargeted lipidomics on whole larvae and the isolated CNS from wild-type and ifc-KO/ifc^JS³ larvae (hereafter termed ifc^-/- larvae) to assess the effect of loss of ifc function on metabolites in the ceramide pathway (Figure 1C). Loss of ifc function resulted in a near complete loss of ceramides and a commensurate increase in dihydroceramides in the CNS and whole larvae (Figures 1E, S1). Sphinganine, the metabolite directly upstream of dihydroceramide, also exhibited a significant increase in its levels in the absence of ifc function, while metabolites further upstream were unchanged in abundance or undetectable (Figures 1E, S1). Ceramide derivatives like sphingosine, CPE, and Glucosyl-Ceramide (Glc-Cer), were reduced in levels and replaced by their cognate dihydroceramide forms (e.g., Glc-DiCer) (Figures 1E, S1). Loss of the enzymatic function of Ifc then drives dihydroceramide accumulation and ceramide loss.

ifc governs glial morphology and survival

To connect this metabolic profile to a cellular phenotype, we assayed ifc function in the CNS. We leveraged the expression of fatty acid binding protein (FABP) as a marker of cortex glia²⁹ and that of the M{3xP3-RFP.attP} phi-C31 “landing pad” transgene, which resided in the isogenic target chromosome of our screen, as a general glial marker (Figure S2). In addition, we labeled neuroblasts with Deadpan (Dpn), neurons with ELAV, and axons with N-Cadherin (NCad). In ifc^-/- larvae, we observed a clear reduction in Dpn-positive neuroblasts in the optic lobe, swelling of glia in peripheral nerves, enhanced RFP expression in the CNS, and the presence of large swollen, cortex glia identified by RFP labeling and fatty acid binding protein (FABP) expression (Figure 1F). In wild-type larvae, cortex glia display compact cell bodies and fully enwrap individual neuronal cell bodies with their membrane sheaths (Figures 1F and S3).²⁹ In ifc^-/- larvae, cortex glia display swollen cell bodies, fail to fully enwrap neuronal cell bodies, displace neurons from their regular arrangement, and appear to contain brightly fluorescent RFP-positive aggregates (Figure 1F, S4-S5). ifc is then necessary for glial development and function in the larval nervous system.

To track the impact of ifc on glial morphology, we combined GAL4 lines specific for each glial subtype with a UAS-linked membrane-tagged GFP transgene (Myr-GFP) and the MultiColor FlpOut system.^30,31,32 Using this approach, we determined that loss of ifc function affects all CNS glial subtypes except perineurial glia (Figures 2E-E’ and 2J-J’). Cortex glia appeared swollen, failed to enwrap neurons, and accumulated large amounts of Myr-GFP⁺ internal membranes (Figures 2A-A’ and 2F-F’). Ensheathing glia (Figures 2B-B’ and 2G-G’) and subperineurial glia (Figures 2D-D’ and 2I-I’) also displayed swollen, disorganized cell bodies and accumulated Myr-GFP⁺ internal membranes. Astrocyte-like glia displayed smaller cell bodies, reduced membrane extensions, and disrupted organization along the dorsal ventral nerve cord (Figures 2C-C’). We conclude that ifc regulates the morphology of most glial subtypes in the larval CNS.

Loss of *ifc* disrupts glial morphology. A-E’) High magnification ventral views and X-Z and Y-Z projections of the nerve cord of wildtype and *ifc^-/-* late third instar larvae labeled for ELAV (magenta) for neurons and Myr-GFP (green) for cell membranes of indicated glial subtype. Anterior is up; scale bar is 40μm. F-J’) High magnification views of individual glial cells of indicated glial subtype in the nerve cord of wildtype and *ifc^-/-* larvae created by the MultiColor-FlpOut method.³² Anterior is up; scale bar is 20μm. K-N) Quantification of total number of indicated glial subtype in the nerve cord of wildtype and *ifc^-/-* late third instar larvae (n = 7 for K, L, N; n = 6 for M). Statistics: * denotes p < 0.05, **** denotes p < 0.0001, and ns, not significant.

Next, we asked if loss of ifc function alters the number of each glial subtype. Using the same glial subtype-specific GAL4 lines to drive a nuclear-localized GFP transgene, we counted the total number of all CNS glial subtypes, except perineurial glia, in wild type and ifc^-/- larvae. To remove the small size of the brain in ifc^-/- larvae as a confounding factor, we focused our analysis on the ventral nerve cord. The number of subperineurial glia was unchanged between the two genotypes, but we observed a 12%, 40%, and 72% reduction in the number of astrocyte-like, ensheathing, and cortex glia, respectively, in ifc^-/- larvae relative to wild-type (Figures 2K-N). Our data reveal a broad role for ifc in regulating glial cell morphology and number in the Drosophila larval CNS.

ifc acts in glia to regulate glial and CNS development

Prior work in zebrafish showed that DEGS1 knockdown reduced the number of myelin basic protein-positive oligodendrocytes;⁹ in flies, loss of ifc function in the eye drove photoreceptor degeneration.¹⁷ Neither study uncovered the cell type in which ifc/DEGS1 acts to regulate neural development. To address this question, we used the GAL4/UAS system, RNAi-mediated gene depletion, and gene rescue approaches to see if ifc acts in neurons or glia to control glial development and CNS morphology. First, we used a UAS-linked ifc-RNAi transgene to deplete ifc function in all neurons (elav-GAL4; repo-GAL80) or all glia (repo-GAL4). Focusing on FABP-positive cortex glia due to their easily scorable phenotype, we found that pan-glial, but not pan-neuronal, knockdown of ifc recapitulated the swollen cortex glia phenotype observed in ifc mutant larvae (Figures 3C-D and 3J).

*ifc* acts in glia to regulate CNS structure and glial morphology. A-I) Ventral views of photomontages of the CNS of late third instar larvae labeled for FABP (greyscale) to mark cortex glia in late third instar larvae of indicated genotype. Neuronal-specific transgene expression was achieved by using *elav-GAL4* combined with *repo-GAL80*; glial-specific transgene expression was achieved by using *repo-GAL4*. J-K) Quantification of the number of swollen cortex glia in the abdominal segments of the CNS of late-third instar larvae of the indicated genotype for the RNAi (J) and gene rescue assays (K). Statistics: * denotes p < 0.05, ** denotes p < 0.01, *** denotes p < 0.001, **** denotes p < 0.0001, and ns, not significant.

To complement our RNAi approach, we asked if GAL4-driven expression of a wild-type Drosophila ifc or human DEGS1 transgene rescued the ifc^-/- CNS phenotype. In the absence of a GAL4 driver, the ifc transgene drove weak rescue of the cortex glia phenotype (Figures 3E and 3K), consistent with modest GAL4-independent transgene expression reported for UAS-linked transgenes.³³ Pan-neuronal expression of ifc drove modest rescue of the ifc CNS phenotype beyond that observed for the ifc transgene alone (Figures 3F and 3K), but pan-glial expression of ifc fully rescued the ifc mutant cortex glia phenotype and other CNS phenotypes (Figures 3H, 3K, and S6). Identical experiments using the human DEGS1 transgene revealed that only pan-glial DEGS1 expression provided rescuing activity (Figures 3G, 3I, and 3K). We infer that ifc acts primarily in glia to govern CNS development and that human DEGS1 can partially substitute for ifc function in flies despite a difference in the preferred length of the sphingoid backbone in flies versus mammals.¹⁰

ifc is predominately expressed in glia and localizes to the ER

Next, we tracked ifc expression in the CNS via RNA in-situ hybridization and an ifc-T2A-GAL4 transcriptional reporter. RNA in-situ hybridization revealed that ifc is widely expressed in the CNS (Figure 4A), most obviously in the distinctive star-shaped astrocyte-like glia (Figure 4B), which are marked by Ebony expression.³⁴ RNA in-situ hybridization was not ideal for tracing ifc expression in other cells, likely due to signal diffusion. Thus, we paired ifc-T2A-GAL4 with a nuclear RFP (nRFP) transgene³⁵ and confirmed authenticity of the ifc-T2A-GAL4 line by its strong expression in astrocyte-like glia (Figure 4C). Using this approach, we found that ifc is strongly expressed in all glial cells (Figures 4D and S7A) and more weakly neurons in the larval CNS (Figures 4E and S7B).

Loss of ifc drives ER expansion in cortex glia. A-E) Dorsal (A, B-B’’, and C-C’’) and ventral (D-D’’ and E-E’’) views of the CNS of late-third instar wild-type larvae labeled for *ifc* RNA (grey in A; magenta in B’), *ifc-GAL4>nRFP* (magenta; C’-E’), EBONY to mark astrocytes (green; B and C), REPO to mark glia (green; D), and ELAV to mark neurons (green; E). Panels D-D’’ and E-E’’ show surface and interior views, respectively, along the Z-axis on the ventral side of the nerve cord. Arrowheads in E-E’’ identify neurons with low level *ifc-GAL4* expression. F-G) High magnification ventral views of thoracic segments in the CNS of wild-type late third instar larvae labeled for GFP (green; F and G), CNX99A (magenta; F’), ESYT (magenta; G’). H-M) Late third instar larvae of indicated genotype labeled for 3xP3-RFP (green; H’-M’), CNX99A (magenta; H and K), GOLGIN84 (magenta; I and L), and LAMP (magenta; J and M). Anterior is up; scale bar is 100μm for panel A and 30μm for panels B-M.

Using a fosmid transgene that harbors a GFP-tagged version of ifc flanked by ∼36-kb of its endogenous genomic region and molecular markers for ER, cis-Golgi, and trans-Golgi,^36,37,38,39 we found that the Ifc-GFP colocalized strongly with the ER markers Calnexin 99A (CNX99A) and ESYT (Figures 4F-F’ and 4G-G’) and weakly with the cis-Golgi marker GOLGIN84 (Figure S7C) and the trans-Golgi marker GOLGIN245 (Figure S7D). Our results indicate that Ifc localizes primarily to the ER, aligning with the presumed site of de novo ceramide biosynthesis and prior work on DEGS1 localization in cell lines.^8,40

Loss of ifc drives ER expansion and lipid droplet loss in cortex glia

We next asked if loss of ifc function altered ER, Golgi, or lysosome morphology. Focusing on cortex glia, we observed a clear expansion of the ER marker CNX99A (Figures 4H-H’ and K-K’), a mild enrichment of the Golgi markers, GOLGIN84 and GOLGIN245, in diffuse “clouds” (Figures 4I-I’, 4L-L’, S7E-F), and a reduction in expression of the lysosome marker LAMP (Figures 4J-J’ and M-M’) in ifc^-/- larvae. The expansion of ER markers in ifc mutant larvae compelled us to obtain high-resolution views of organelle structure in cortex glia via transmission electron microscopy (TEM). In wild-type, cortex glia display a compact cytoplasm that surrounds a large nucleus (Figures 5A-B) and extend glial sheaths that fully enwrap adjacent neuronal cell bodies (black arrows; Figures 5C-D). In ifc^-/- larvae, cortex glia display enlarged cell bodies with a maze-like pattern of internal membranes (solid white arrows; Figures 5A’-B’ and 5E-E’) and fail enwrap neurons (hollow white arrows; Figures 5C’-D’). The internal membrane structures appear to assume an ER-like identity, as we observed significant overlap between the ER marker CNX99A and the membrane marker Myr-GFP when Myr-GFP was driven by a cortex glia-specific GAL4 line (Figure 5F). We observed similar yet milder effects on cell swelling and internal membrane accumulation in subperineurial and wrapping glia in abdominal nerves (purple and pink shading, respectively; Figures 5G-G’ and 5H-H’), indicating that loss of ifc drives internal membrane accumulation in and swelling of multiple glial subtypes.

Loss of *ifc* leads to internal membrane accumulation and lipid droplet loss in cortex glia. A-E’) TEM images of cortex glia cell body (A-A’ and B-B’) and neuronal cell bodies (C-C’ and D-D’) at low (A-A’) and high (B-B’, C-C’, and D-D’) magnification in the nerve cord of wildtype (A-D) and *ifc^-/-* (A’-D’ and E-E’) late third instar larvae. (A-A’) Dotted lines demarcate cell boundary of cortex glia; yellow squares highlight regions magnified in B, B’, and E’. Scale bar is 3μm for A and A’ and 1μm for B-B’. (B-B’) Cy denotes cytoplasm; Nu denotes nucleus. Solid white arrows highlight the layered internal membranes that occupy the cytoplasm of *ifc^-/-* cortex glia. (C-C’ and D-D’) Black arrows highlight cortex glia membrane extensions that enwrap neuronal cell bodies; hollow white arrows denote the absence of cortex glia membrane extensions; white asterisk denotes lipid droplets. Scale bar is 2μm. E-E’) An additional example of membrane-filled cortex glia cell body in *ifc^-/-* larvae. Scale bar is 2μm for E and 1μm for E’. F) Cortex glia in *ifc* mutant larvae labeled for Myr-GFP (green) to label membranes and CNX99A to label ER membranes. Scale bar is 30μm. G-H) Black and white and colored TEM cross-sections of peripheral nerves in wild type and *ifc^-/-* late-third instar larvae. Blue marks perineurial glia; purple marks subperineurial glia; pink marks wrapping glia. Scale bar: 2μm. I-I’) High magnification ventral views of abdominal segments in the ventral nerve cord of wild-type (I) and *ifc* mutant (I’) third instar larvae labeled for BODIPY (green) to mark lipid droplets and FABP (magenta) to label cortex glia. Anterior is up; scale bar is 30μm. J) Graph of log-fold change of transcription of five genes that promote membrane lipid synthesis in *ifc^-/-* larvae relative to wildtype. K-M) Quantification of the number (G) and area of lipid droplets (H and I) in the dissected CNS of wildtype and *ifc^-/-*larvae. Statistics: * denotes p < 0.05, ** denotes p < 0.01, *** denotes p < 0.001, **** denotes p < 0.0001, and ns, not significant.

TEM analysis also revealed a near complete depletion of lipid droplets in the CNS of ifc^-/- larvae (compare Figures 5A, 5C, and 5D to 5A’, 5C’ and 5D’; lipid droplets marked by asterisk; Figure 5M), which we confirmed using BODIPY to mark neutral lipids in FABP-positive cortex glia (Figure 5I-L). In the CNS, lipid droplets form primarily in cortex glia²⁹ and are thought to act as building blocks of membrane lipids versus an energy source in the brain.⁴¹ Consistent with lipid droplet depletion indicating increased membrane lipid biogenesis, RNA-seq assays of dissected nerve cords revealed that loss of ifc drove transcriptional upregulation of genes that promote membrane lipid biogenesis, such as SREBP, the conserved master regulator of lipid biosynthesis, SCAP, an activator of SREBP, and Pcyt1/Pcyt2, which promote phosphatidylcholine and phosphatidylethanolamine synthesis.^42,43,44 The spliced form of Xbp-1 mRNA (Xbp-1s) (Figure 5J), which promotes membrane lipid synthesis required for ER biogenesis and is activated by the unfolded protein response (UPR),⁴⁵ is also upregulated in the CNS of ifc mutant larvae. Most ER chaperones, which are typically transcriptionally upregulated upon UPR activation,⁴⁶ were however downregulated (Figure S8A), suggesting that in this case misfolded protein is not the factor that triggers UPR activation and increased ER membrane biogenesis upon loss of ifc.

Loss of ifc increases the saturation levels of triacylglycerols and membrane phospholipids

Lipid droplets are composed largely of triacylglycerols (TGs),⁴⁴ and we observed a 5-fold and 3-fold drop in TG levels in the CNS and whole larvae of ifc mutant larvae relative to wild-type (Figure 6A). Our lipidomics analysis also revealed a shift of TGs toward higher saturation levels in the absence of ifc function (Figures 6A-C). Consistent with this, we observed transcriptional upregulation of most genes in the Lands cycle, which remodels phospholipids by replacing existing fatty acyl groups with new fatty acyl groups (Figures S8B-C).^47,48,49,50 As TGs function as building blocks of membrane phospholipids, we asked if changes in TG levels and saturation were reflected in the levels or saturation of the membrane phospholipids phosphatidylcholine (PC), phosphatidylethanolamine (PE), and phosphatidylserine (PS). In the absence of ifc function, PC and PE exhibited little change in quantity (Figures 6D, 6G), but the levels of the less abundant PS were increased three-fold increase in the CNS of ifc mutant larvae relative to wild-type (compare Figure 6J to Figures 6D and 6G). All three phospholipids, however, displayed increased saturation levels: The relative levels of all PC, PE, and PS species were reduced, except for the most saturated form of each phospholipid – 18:1/18:1 – which is increased (Figures 6E-F and 6H-L). This increase was more pronounced in the CNS than whole larvae (Figures 6F, 6I, and 6L), implying that loss of ifc function creates greater demand for lipid remodeling in the CNS.

PC, PE, PS, and TG exhibit higher saturation levels in a CNS-specific manner in *ifc* mutant late third instar larvae. A-C) Quantification of total (A) and species-specific (B and C) TGs in whole larvae (A and C) and dissected CNS (A, B, and C) of wildtype and *ifc^-/-*larvae. D-F). Quantification of total (D) and species-specific (E and F) PCs in whole larvae (D and F) and dissected CNS (D, E, and F) of wildtype and *ifc^-/-*larvae. G-I) Quantification of total (G) and species-specific (H and I) PEs in whole larvae (G and H) and dissected CNS (G, H, and I) of wild-type and *ifc^-/-* larvae. J-L) Quantification of total (J) and species-specific (K and L) PSs in the whole larvae (J and L) and dissected CNS (J, K, and L) of wild-type and *ifc^-/-* larvae. Statistics: * denotes p < 0.05, ** denotes p < 0.01, *** denotes p < 0.001, **** denotes p < 0.0001, and ns, not significant.

Reduction of dihydroceramide synthesis suppresses the ifc CNS phenotype

Following its synthesis, CERT transports ceramide from the ER to the Golgi, but CERT is less efficient at transporting dihydroceramide than ceramide.¹³ The expanded nature of the ER in ifc mutant larvae supports a model in which loss of ifc triggers excessive accumulation and retention of dihydroceramide in the ER, driving ER expansion and glial swelling. If this model is correct, reduction of dihydroceramide levels should suppress the ifc CNS phenotype. In agreement with this model, we found that the schlank^G⁰³⁶⁵ loss of function allele dominantly suppressed the enhanced RFP expression (Figure 7M) and CNS elongation phenotypes of ifc (Figure 7N). We also found that glial-specific depletion of schlank suppressed the internal membrane accumulation (Figures 7A-B), reduced lipid droplet size (Figures 7C-D, and 7O), glial swelling (Figures 7E-F, and S10), enhanced RFP expression (Figure 7M), CNS elongation (Figure 7N), and reduced optic lobe (Figure S4) phenotypes observed in otherwise ifc mutant larvae. Our data support the model that inappropriate retention of dihydroceramide in the ER drives ER expansion and glial swelling and dysfunction.

Glial-specific knockdown of *ifc* triggers neuronal cell death. A-D) TEM images of cortex glia cell body (A and B) and neuronal cell bodies (C and D) at low (A) and high (B, C, and D) magnifications in the nerve cord of *ifc^-/-*; *repo>schlank RNAi* late third instar larvae. Dotted lines demarcate cell boundary of cortex glia; yellow squares highlight regions magnified in A. Scale bar: 3μm for A, 1μm for B, and 2μm for C and D. (B) Cy denotes cytoplasm; Nu denotes nucleus. (C-D) Black asterisk denotes lipid droplets. E-F) Ventral views of abdominal sections of CNS of *ifc^-/-*; *UAS-schlank RNAi/+* larvae (E) and *ifc^-/-*; repoGAL4/*UAS-schlank RNAi* larvae (F) labeled for neurons (ELAV, Green) and cortex glia (FABP, magenta/grey). Scale bar is 30μm for E-F. G-L) Low (G-L) and high (G’-L’ and G’’-L’’) magnification views of the brain (G-I) and nerve cord (J-L) of late-third instar larvae of the indicated genotypes labeled for ELAV (magenta or greyscale) and Caspase-3 (green). Arrows indicate regions of high Caspase-3 signal and/or apparent neuronal cell death identified by perforations in the neuronal cell layer. Scale bar is 50μm for panels G-L and 10μm for panels G’-L’’. M-N) Quantification of CNS elongation (M) and 3xP3 RFP intensity (N) in *ifc* mutants alone, *ifc* mutants with one copy of *schlank[G0365]* loss-of-function allele, or *ifc* mutants in which *schlank* function is reduced via RNAi in glial cells. O) Quantification of the area of lipid droplets in dissected CNS of *ifc* mutants and *ifc* mutants in which *schlank* function is reduced via RNAi in glial cells. Anterior is up in all panels. P-Q) Quantification of Cleaved Caspase-3 neurons for panels G-I (P) and J-L (Q). Statistics: * denotes p < 0.05, ** denotes p < 0.01, *** denotes p < 0.001, **** denotes p < 0.0001, and ns, not significant.

Glial-specific depletion of ifc function triggers neuronal cell death

Loss of DEGS1/ifc in human and flies has been shown to promote neurodegeneration and neuronal cell death,^8,9,17 but whether neuronal death results from an intrinsic defect in neurons or is induced by glial dysfunction remains unclear. To see if loss of ifc causes neuronal cell death, we used Cleaved Caspase-3, a marker of cell death,^51,52 and ELAV to track neuronal cell death in the brain and ventral nerve cord of wild-type and ifc^-/- mutant late-third instar larvae. In wildtype, little to no cell death was evident in the brain or nerve cord and neurons appear smoothly packed next to each other; in contrast, in ifc^-/-larvae, significant cell death was apparent in the brain and to a lesser degree in the nerve cord, with Caspase-3 staining often highlighting small perforations in the neuronal cell layer (Figures 7G-H, and 7P). This perforated pattern was associated with and more expansive than Caspase-3 staining, indicating the perforations mark Caspase-positive dying neurons and Caspase-negative dead neurons. Glial-specific depletion of schlank function in otherwise ifc^-/- larvae suppressed the neuronal cell death phenotype (Figures 7I and 7P), supporting the model that loss of ifc function specifically in glia, rather than a specific requirement for ifc function in neurons, drives neuronal cell death. To directly test whether ifc function in glia is required to guard against neuronal cell death, we used the GAL4-UAS system and RNAi mediated gene interference to deplete ifc function specifically in glia (repo-GAL4) or in neurons (elav-GAL4; repo-GAL80) and found that glial-specific, but not neuronal-specific, depletion of ifc function drove significant neuronal cell death in the brain and to a greater extent the nerve cord, a phenotype that was enhanced upon removal of one copy of ifc (Figures 7J-L, 7Q, and S11). Loss of ifc function then triggers glial dysfunction, whin in turn drives neuronal cell death.

Discussion

Our work on ifc supports a model in which loss of ifc/DEGS1 function drives glial dysfunction through the accumulation and inappropriate retention of dihydroceramide in the ER of glia with this proximal defect driving ER expansion, glial swelling, and subsequent neuronal cell death and neurodegeneration. A large increase in dihydroceramide would also impact ER membrane structure: ER membranes are typically loosely packed, thin, semi-fluid structures, with sphingolipids comprising just 3% of ER phospholipids.⁴⁴ Sphingolipids in general and dihydroceramide in specific are highly saturated lipids, promote lipid order, tighter lipid packing, membrane rigidity, and thicker membranes.^53,54 Our observation of thick ER membranes in cortex glia in ifc^-/- larvae (Figure 5) aligns with increased dihydroceramide levels in the ER. In this context, we note that of many clinical observations made on an HLD-18 patient, one was widening of the ER in Schwann cells,⁸ a finding that when combined with our work suggests that dihydroceramide accumulation in the ER is the proximal cause of HLD-18.

Although we think ER expansion represents the most proximal effect of loss of ifc/DEGS1 function and dihydroceramide accumulation on cortex glia, other organelles and their functions are likely also disrupted, minimally as a consequence of ER disruption. For example, the apparent reduction of the lysosome marker, LAMP, in cortex glia of ifc mutant larvae correlates with increased RFP levels and the presence of bright RFP puncta or aggregates in this cell type, suggesting impaired lysosome function contributes to increased RFP perdurance and aggregation. Defects in the activity of multiple organelles may collaborate to elicit the full phenotype manifested by loss of ifc/DEGS1 function, resulting in glial dysfunction and subsequent neuronal cell death.

Increased dihydroceramide levels may contribute to a broader spectrum of neurodegenerative diseases than simply HLD-18. Recent work reveals that gain of function mutations in SPTLC1 and SPTLC2, which encode components of the SPT complex that catalyzes the initial, rate limiting step of de novo ceramide and sphingolipid biosynthesis,⁵⁵ cause juvenile ALS via increased sphingolipid biosynthesis.^18,19,20,21 Of all sphingolipids, the relative levels of dihydroceramide were increased the most in patient plasma samples, suggesting that DEGS1 activity becomes limiting in the presence of enhanced SPT activity and that dihydroceramide accumulation contributes to juvenile ALS. Any mutations that increase metabolite flux through the ceramide pathway upstream of DEGS1 may then increase dihydroceramide levels, drive ER expansion and cell swelling, and lead to neurodegeneration, with disease severity predicated on the extent of excessive dihydroceramide accumulation. Model systems, like flies, can harness the power of genetic modifier screens to identify genes and pathways (potential therapeutic targets), that can be tweaked to ameliorate the effect of elevated dihydroceramide levels on neurodegeneration.

Our work appears to pinpoint the cell type impacted by loss of ifc/DEGS1 function: Glia, specifically glia that exhibit great demand for membrane biogenesis like cortex glia in the fly and oligodendrocytes or Schwann cells in mammals. In larvae, ifc is expressed at higher levels in glial cells than in neurons, and its genetic function is required at a greater level in glia than neurons to govern CNS development. Our unpublished work on other genes in the ceramide metabolic pathway reveals similar glial-centric expression patterns in the larval CNS to that observed for ifc, suggesting they too function primarily in glia rather than neurons at this stage. In support of this idea, a study on CPES, which converts ceramide into CPE, the fly analog of sphingomyelin, revealed that CPES is required in cortex glia to promote their morphology and homeostasis and to protect flies from photosensitive epilepsy.⁵⁶ Similarly, ORMDL, a dedicated negative regulator of the SPT complex, is required in oligodendrocytes to maintain proper myelination in mice.⁵⁷ Given that many glial cell types, are enriched in sphingolipids and exhibit a great demand for new membrane biogenesis during phases of rapid neurogenesis and axonogenesis, we speculate that glial cells, such as cortex glia, oligodendrocytes, and Schwann cells, rather than neurons manifest a greater need for ifc/DEGS1 function and ceramide synthesis during developmental stages marked by significant nervous system growth.

Will this glial-centric model for ifc/DEGS1 function, and more generally ceramide synthesis, hold true in the adult when neurogenesis is largely complete and the demand for new membrane synthesis in glia dissipates? Recent work in the adult fly eye suggests it may not. Wang et al.⁵⁸ argued that the GlcT enzyme, which converts ceramide to glucosylceramide, is expressed at much higher levels in neurons than glia, and that glucosylceramide is then transported from neurons to glial cells for its degradation, suggesting cell-type specific compartmentalization of sphingolipid synthesis in neurons and its degradation in glia in the adult. In the future, it will be exciting to uncover whether genes of the sphingolipid metabolic pathway alter their cell-type specific requirements as a function of developmental stage.

Altered glial function may derive not just from dihydroceramide buildup in the ER, but also from altered cell membrane structure due to the replacement of ceramide and its derivates, such as GlcCer and CPE, with the cognate forms of dihydroceramide. Relative to dihydroceramide species, the 4-5 trans carbon-carbon double bond in the sphingoid backbone of ceramide-containing sphingolipids enables them to form more stable hydrogen bonds with water molecules and facilitates their ability to associate with lipids of different saturation levels.⁵ A high dihydroceramide to ceramide ratio has been shown to form rigid gel-like domains within model membranes and to destabilize biological membranes by promoting their permeabilization.^59,60 As even minor alterations to membrane properties can disrupt glial morphology,⁶¹ such alterations in membrane rigidity and stability may underlie the failure of cortex glia to enwrap adjacent neurons. The observed increase in saturation of PE, PC, and PS in the CNS of ifc mutant larvae may reflect a compensatory response employed by cells to stabilize cell membranes when challenged with elevated levels of dihydroceramide.

The observed loss of lipid droplets in cortex glia may also contribute to their inability to fully enwrap neuronal cell bodies. Under wild-type conditions, many lipid droplets are present in cortex glia during the rapid phase of neurogenesis that occurs in larvae. During this phase, lipid droplets likely support the ability of cortex glia to generate large quantities of membrane lipids to drive membrane growth needed to ensheath newly born neurons. Supporting this idea, lipid droplets disappear in the adult Drosophila CNS when neurogenesis is complete and cortex glia remodeling stops.²⁹ We speculate that lipid droplet loss in ifc mutant larvae contributes to the inability of cortex glia to enwrap neuronal cell bodies. Prior work on lipid droplets in flies has focused on stress-induced lipid droplets generated in glia and their protective or deleterious roles in the nervous system.^62,63,64 Work in mice and humans has found that more lipid droplets are often associated with the pathogenesis of neurodegenerative diseases,^65,66,67 but our work correlates lipid droplet loss with CNS defects. In the future, it will be important to determine how lipid droplets impact nervous system development and disease.

Acknowledgements

We thank the Iowa Developmental Studies Hybridoma Bank for antibodies, and the Bloomington Stock Center, Vienna Drosophila Research Center, FlyORF, and the National Institutes of Genetics stock center in Japan for countless fly lines. We thank Drs. Christian Klambt, Chih-Chiang Chan, Dion Dickman for reagents. We thank Dr. Tristan Qingyuan Li for comments on the manuscript. We thank the Genome Technology Access Center at Washington University for next-generation sequencing and analysis of RNA-seq samples. We thank Dr. Sanja Sviben, Gregory Strout, and John Wulf II for assistance in TEM studies conducted at the Washington University Center for Cellular Imaging, which is supported in part by Washington University School of Medicine, The Children’s Discovery Institute of Washington University and St. Louis Children’s Hospital (CDI-CORE-2015-505 and CDI-CORE-2019-813), the Foundation for Barnes-Jewish Hospital (3770) and the Washington University Diabetes Research Center (NIH P30 DK020579).

Author Contributions

BAW, HL, Yi Zhu, and JBS completed the genetic screen that identified the ifc alleles and completed the initial genetic characterization of these alleles. Yuqing Zhu, JD, and JBS completed all other experiments except for the lipidomics analyses, which were completed by KC and GJP. Yuqing Zhu and JBS wrote the manuscript and compiled figures with help from JD with figures. All authors read, commented on, and edited the manuscript.

Funding

This work was supported by grants from the National Institutes of Health (NS036570) to J.B.S., (NS122903) to H.L., and (R35 ES2028365) to G.J.P.

Declaration of interests

G.J.P. has collaborative research agreements with Agilent Technologies and Thermo Scientific. G.J.P. is the chief scientific officer of Panome Bio. The remaining authors declare no competing interests.

Methods

Key resources table

Fly stocks used

Antibodies and lipid marker used

Deposited data

Software used

Method details

Fly husbandry

Flies were raised on standard molasses-based food at 25°C. Unless otherwise noted, wild type is an otherwise wild-type stock harboring the M{3xP3-RFP.attP}ZH-51D insert in an isogenic second chromosome.

Mutagenesis

A standard autosomal recessive forward genetic screen was carried out using 25-30 μm EMS to mutagenize a M{3xP3-RFP.attP}ZH-51D isogenic second chromosome. Homozygous mutant third instar larvae were visually screened under a standard fluorescent microscope for defects in CNS morphology. A detailed description of the screen and all other identified genes will be described elsewhere.

Creation of recombinant lines and identification of second site mutations in ifc-KO chromosome

Standard genetic methods were used to generate fly strains that contained specific combinations of GAL4 and UAS-linked transgenes in the ifc^js³ or ifc-KO background. During this process, we uncovered that the ifc-KO deletion could be unlinked from at least one second chromosomal mutation that caused early larval lethality, resulting in homozygous ifc-KO flies that survived to late L3 to early pupa. A subsequent EMS-based F2 lethal non-complementation screen using the M{3xP3-RFP.attP}ZH-51D isogenic second chromosome as target chromosome and screening against the ifc-KO chromosome identified multiple mutations in four complementation groups that led to an early larval lethal phenotype. Whole genome sequencing identified these genes as Med15, lwr, Nle, and Sf3b1; all four genes reside within ∼90 Kb of each other in chromosomal bands 21D1-21E2 near the telomere in chromosome 2L, identifying the site of the associated lethal mutations and suggesting the actual lesion may be a small deletion that removes these genes. The following alleles of these genes are available at Bloomington Stock Center: Med15^js¹ (Q175*), Med15^js² (Q398*), Med15^js³ (C655Y), lwr^js¹ (I4N), lwr^js²(E12K), Nle^js¹ (W146R), Nle^js² (L125P), Nle^js³ (Q242*), Sf3b1^js¹ (R1160*), Sf3b1^js² (Q1264*), Sf3b1^js³ (570 bp deletion at the following coordinates chr2L571720-572290; this deletion removes amino acids 1031 through 1222 and introduces a frameshift into the reading frame).

Gene rescue and in vivo RNAi phenocopy assays

To restrict UAS-linked transgene expression specifically to glia, we used the repoGAL4 driver line. To restrict UAS-linked transgene expression specifically to neurons, we paired the elavGAL4 driver lines, which activates transgene expression strongly in all neurons and moderately in glia, with repoGAL80, which blocks GAL4-dependent activation in glia. We used P{VSH330794} (VDRC 330794) for the RNAi experiments and UAS-ifc⁶⁸ and UAS-DEGS1 (BDSC 79200) for the gene rescue assays. All gene rescue experiments were performed in the ifc^js³/ifc-KO background with the UAS-transgene placed into the ifc^js³ background and the GAL4 drivers into the ifc-KO background.

The GAL4-UAS method was also used to assess the phenotype of each glial subtype. In combination with the UAS-Myr-GFP transgene, which labels cell membranes, we used the following GAL4 lines to trace the morphology of each glial subtype in wild type and ifc^-/- larvae: GMR85G01-GAL4 (perineurial glia; BDSC 40436), GMR54C07-GAL4 (subperineurial glia; BDSC 50472), GMR54H02-GAL4 (cortex glia; BDSC 45784), GMR56F03-GAL4 (ensheathing glia; BDSC 77469 and 39157), and GMR86E01-GAL4 (astrocyte-like glia; BDSC45914). The UAS-Myr-GFP transgene was placed into the ifc^js³ background; each glial GAL4 line was placed into the ifc-KO background.

DNA sequencing

Genomic DNA was obtained from wild type larvae or larvae homozygous for each relevant mutant line and provided to GTAC (Washington University) or GENEWIZ for next-generation or Sanger sequencing.

RNA in-situ hybridization

ifc RNA probes for in-situ hybridization chain reaction (HCR) were designed and made by Molecular Instruments (HCR™ RNA-FISH v3.0).⁶⁹ Wild type CNS was harvested and fixed in 2% paraformaldehyde at late L3. The fixed CNS underwent gradual dehydration and rehydration, followed by standard hybridization and amplification steps of the HCR protocol.⁶⁹ For double labeling with antibody, the post-HCR labeled CNS was briefly fixed for 30 minutes prior to standard antibody labeling protocol to identify specific CNS cell type(s) with highly localized ifc _RNAs.70,71

MultiColor FlpOut labeling of glial subtypes

For glial labeling in the control background, the MCFO1 line was crossed to GMR-GAL4 driver lines for each glial subtype (Supplemental Table 1).³² For glial labeling in ifc^-/- background, the MCFO1 line was placed in the ifc^JS³ background, each of the five glial-specific GMR-GAL4 lines were placed individually into the ifc-KO background, and then the MCFO, ifc^JS³ line was crossed to each glial specific GAL4, ifc-KO line. Flies were allowed to lay eggs for 24 hr at 25°C, and progeny were raised at 25°C for 4 days prior to heat-activated labeling. On day 4 after egg-laying, F1 larvae were incubated in a 37°C water bath for 5-minutes. When wild-type or ifc^-/- mutant larvae reached late L3, which was day 5-6 for control and day 9-10 for ifc^-/- mutants, the CNS was dissected, fixed, stained, and then analyzed under a Zeiss LSM 700 Confocal Microscope for the presence of clones, using Zen software.

Antibody generation

YenZym (CA, USA) was used as a commercial source to generate affinity purified antibodies against a synthetic peptide that corresponded to amino acids 85-100 (TLDGNKLTQEQKGDKP) of FABP isoform B. Briefly, the peptide was conjugated to KLH, used as an immunogen in rabbits to generate a peptide-specific antibody response, and antibodies specific to the peptide were affinity purified. The affinity-purified antibodies were confirmed to label cortex glia specifically based on comparison of antibody staining relative to Myr-GFP when a UAS-Myr-GFP was driven under control of the cortex specific glial GAL4 driver GMR-54H02 (Figure S3). The FABP antibodies are used at 1:500-1:1000.

Immunofluorescence and lipid droplet staining

Gene expression analysis was performed essentially as described in Patel.⁷² Briefly, the larval CNS was dissected in PBS, fixed in 2.5% paraformaldehyde for 55 minutes, and washed in PTx (1xPBS, 0.1% TritonX-100. The fixed CNS was incubated in primary antibody with gentle rocking overnight at 4°C. Secondary antibody staining was conducted for at least two hours to overnight at room temperature. All samples were washed in PTx at least five times and rocked for an hour before and after secondary antibody staining. A detailed list of the primary and secondary antibodies is available in Supplemental Table 2. Dissected CNS were mounted either in PTx or dehydrated through an ethanol series and cleared in xylenes prior to mounting in DPX mountant.⁷³ All imaging was performed on a Zeiss LSM-700 Confocal Microscope, using Zen software.

For lipid droplet staining, the fixed CNS was incubated for 30 minutes at room temperature at 1:200 dilution of 1mg/mL BODIPY™ 493/503 (Invitrogen: D3922). It was then rinsed thoroughly in PBS and immediately mounted for imaging on a Zeiss LSM-700 Confocal Microscope, using Zen software.

Transmission electron microscopy (TEM) imaging

For transmission electron microscopy (TEM), samples were immersion fixed overnight at 4°C in a solution containing 2% paraformaldehyde and 2.5% glutaraldehyde in 0.15 M cacodylate buffer with 2 mM CaCl2, pH 7.4. Samples were then rinsed in cacodylate buffer 3 times for 10 minutes each and subjected to a secondary fixation for one hour in 2% osmium tetroxide/1.5% potassium ferrocyanide in cacodylate buffer. Following this, samples were rinsed in ultrapure water 3 times for 10 minutes each and stained overnight in an aqueous solution of 1% uranyl acetate at 4°C. After staining was complete, samples were washed in ultrapure water 3 times for 10 minutes each, dehydrated in a graded acetone series (50%, 70%, 90%, 100% x4) for 15 minutes in each step, and infiltrated with microwave assistance (Pelco BioWave Pro, Redding, CA) into Spurr’s resin. Samples were then cured in an oven at 60°C for 72 hours and post-curing, 70 nm thin sections were cut from the resin block, post-stained with uranyl acetate and Sato’s lead and imaged on a Transmission Electron Microscope (JEOL JEM-1400 Plus, Tokyo, Japan) operating at 120 KeV.

Lipidomics

Untargeted lipidomics analysis was conducted on whole larva and dissected CNS of wild type and ifc^-/- mutants at the late-third instar stage. Five replicates were prepared for each set of experiments. For whole larvae, at least 15 larvae of each genotype were used for each replicate. For the dissected CNS, at least 50 wild type and 60 ifc^-/- CNS were used per replicate. Immediately following collection or dissection, larvae and the dissected CNS were flash frozen in liquid nitrogen and placed at -80°C.

Lipids were extracted from frozen whole larvae and dissected larval CNS samples by using an Omni Bead Ruptor Elite Homogenizer using acetonitrile:methanol:water (2:2:1; 40 μL/mg tissue). Two Ultrahigh performance LC-(UHPLC)/MS systems were used in this work: a Thermo Vanquish Flex UHPLC system with a Thermo Scientific Orbitrap ID-X and an Agilent 1290 Infinity II UPLC system with an Agilent 6545 QTOF as described previously.⁷⁴ Lipids were separated on a Waters Acquity HSS T3 column (150 x 2.1 mm, 1.8 mm). The mobile-phase solvents were composed of A: 0.1% formic acid, 10 mM ammonium formate, 2.5 μM medronic acid in 60:40 acetonitrile:water; and B = 0.1% formic acid, 10 mM ammonium formate in 90:10 2-propanol:acetonitrile. The column compartment was maintained at 60 °C. The following linear gradient was applied at a flow rate of 0.25 mL min-1: 0 – 2 min, 30% B; 17 min, 75% B; 20 min, 85% B; 23 – 26 min, 100% B. The injection volume 4 μL for all lipids analysis. Data was acquired in positive ion.

LC/MS data were processed and analyzed with the open-source Skyline software.⁷⁵ Lipid MS/MS data were annotated with Agilent Lipid Annotator software.

RNA sequencing and analysis

To determine the CNS-specific transcriptional changes upon loss of ifc, RNA-seq was conducted on five replicates of dissected CNS tissue derived from wild type and ifc^-/- mutant late-third instar larvae. For each replicate, roughly 30-35 dissected CNS of wild type or ifc-/- larvae were used. Invitrogen™ RNAqueous™-Micro Total RNA Isolation Kit (AM1931) was used to extract RNA. Agilent 4200 TapeStation system was used for RNA quality control.

Samples were prepared according to library kit manufacturer’s protocol, indexed, pooled, and sequenced on an Illumina NovoSeq. Basecalls and demultiplexing were performed with Illumina’s bcl2fastq software and a custom python demultiplexing program with a maximum of one mismatch in the indexing read. RNA-seq reads were then aligned to the Ensembl release 76 primary assembly with STAR version 2.5.1a.⁷⁶ Gene counts were derived from the number of uniquely aligned unambiguous reads by Subread:featureCount version 1.4.6-p5.⁷⁷ Isoform expression of known Ensembl transcripts were estimated with Salmon version 0.8.2.⁷⁸ To find the most critical genes, the raw counts were variance stabilized with the R/Bioconductor package DESeq2⁷⁹ and was then analyzed via weighted gene correlation network analysis with the R/Bioconductor package WGCNA.⁸⁰

Statistics

All data are presented as mean ± SEM. Statistical significance between groups was determined using Student’s t-test or one-way ANOVA with multiple comparisons, and with varying levels of significance assessed as * P < 0.05, ** P < 0.01, *** P < 0.001, **** P < 0.0001, and ns, not significant.

References

1.
1. Jackman N.
2. Ishii A.
3. Bansal R.
2009Oligodendrocyte development and myelin biogenesis: parsing out the roles of glycosphingolipidsPhysiology 24:290–297
2.
1. Ghosh A.
2. Kling T.
3. Snaidero N.
4. Sampaio J. L.
5. Shevchenko A.
6. Gras H.
7. Simons M.
2013A global in vivo Drosophila RNAi screen identifies a key role of ceramide phosphoethanolamine for glial ensheathment of axonsPLoS genetics 9
3.
1. Vacaru A. M.
2. van den Dikkenberg J.
3. Ternes P.
4. Holthuis J. C.
2013Ceramide Phosphoethanolamine Biosynthesis in Drosophila Is Mediated by a Unique Ethanolamine Phosphotransferase in the Golgi LumenJournal of Biological Chemistry 288:11520–11530
4.
1. Hannun Y. A.
2. Obeid L. M.
2018Sphingolipids and their metabolism in physiology and diseaseNature reviews Molecular cell biology 19:175–191
5.
1. Li L.
2. Tang X.
3. Taylor K. G.
4. DuPré D. B.
5. Yappert M. C.
2002Conformational characterization of ceramides by nuclear magnetic resonance spectroscopyBiophysical journal 82:2067–2080
6.
1. Yasuda T.
2. Al Sazzad M. A.
3. Jäntti N. Z.
4. Pentikäinen O. T.
5. Slotte J. P.
2016The influence of hydrogen bonding on sphingomyelin/colipid interactions in bilayer membranesBiophysical Journal 110:431–440
7.
1. Dolgin V.
2. Straussberg R.
3. Xu R.
4. Mileva I.
5. Yogev Y.
6. Khoury R.
7. Konen O.
8. Barhum Y.
9. Zvulunov A.
10. Mao C.
11. Birk O. S.
2019DEGS1 variant causes neurological disorderEuropean Journal of Human Genetics 27:1668–1676
8.
1. Karsai G.
2. Kraft F.
3. Haag N.
4. Korenke G. C.
5. Hänisch B.
6. Othman A.
7. Kurth I.
2019DEGS1-associated aberrant sphingolipid metabolism impairs nervous system function in humansThe Journal of clinical investigation 129:1229–1239
9.
1. Pant D. C.
2. Dorboz I.
3. Schluter A.
4. Fourcade S.
5. Launay N.
6. Joya J.
7. Pujol A.
2019Loss of the sphingolipid desaturase DEGS1 causes hypomyelinating leukodystrophyThe Journal of clinical investigation 129:1240–1256
10.
1. Fyrst H.
2. Herr D. R.
3. Harris G. L.
4. Saba J. D.
2004Characterization of free endogenous C14 and C16 sphingoid bases from Drosophila melanogasterJournal of lipid research 45:54–62
11.
1. Acharya U.
2. Acharya J. K.
2005Enzymes of sphingolipid metabolism in Drosophila melanogasterCellular and Molecular Life Sciences CMLS 62:128–142
12.
1. Dunn T. M.
2. Tifft C. J.
3. Proia R. L.
2019A perilous path: the inborn errors of sphingolipid metabolismJournal of lipid research 60:475–483
13.
1. Pan X.
2. Dutta D.
3. Lu S.
4. Bellen H. J.
2023Sphingolipids in neurodegenerative diseasesFrontiers in Neuroscience 17
14.
1. Kumagai K.
2. Yasuda S.
3. Okemoto K.
4. Nishijima M.
5. Kobayashi S.
6. Hanada K.
2005CERT mediates intermembrane transfer of various molecular species of ceramidesJournal of Biological Chemistry 280:6488–6495
15.
1. Kobayashi T.
2. Menon A. K.
2018Transbilayer lipid asymmetryCurrent Biology 28:R386–R391
16.
1. Holland W. L.
2. Brozinick J. T.
3. Wang L. P.
4. Hawkins E. D.
5. Sargent K. M.
6. Liu Y.
7. Summers S. A.
2007Inhibition of ceramide synthesis ameliorates glucocorticoid-, saturated-fat-, and obesity-induced insulin resistanceCell metabolism 5:167–179
17.
1. Jung W. H.
2. Liu C. C.
3. Yu Y. L.
4. Chang Y. C.
5. Lien W. Y.
6. Chao H. C.
7. Huang S.Y.
8. Kuo C.H.
9. Ho H.C.
10. Chan C. C.
2017Lipophagy prevents activity-dependent neurodegeneration due to dihydroceramide accumulation in vivoEMBO reports 18:1150–1165
18.
1. Lone M. A.
2. Aaltonen M. J.
3. Zidell A.
4. Pedro H. F.
5. Saute J. A. M.
6. Mathew S.
7. Hornemann T.
2022SPTLC1 variants associated with ALS produce distinct sphingolipid signatures through impaired interaction with ORMDL proteinsThe Journal of Clinical Investigation 132
19.
1. Lone M. A.
2. Zeng S.
3. Bourquin F.
4. Wang M.
5. Huang S.
6. Lin Z.
7. Hornemann T.
2023SPTLC1 p. Leu38Arg, a novel mutation associated with childhood ALSBiochimica et Biophysica Acta (BBA)-Molecular and Cell Biology of Lipids 159359
20.
1. Syeda S. B.
2. Lone M. A.
3. Mohassel P.
4. Donkervoort S.
5. Munot P.
6. França M. C.
7. Bönnemann C. G.
2023Recurrent de novo SPTLC2 variant causes childhood-onset amyotrophic lateral sclerosis (ALS) by excess sphingolipid synthesisJournal of Neurology, Neurosurgery & Psychiatry
21.
1. Dohrn M. F.
2. Beijer D.
3. Lone M. A.
4. Bayraktar E.
5. Oflazer P.
6. Orbach R.
7. Zuchner S.
2023Recurrent de-novo gain-of-function mutation in SPTLC2 confirms dysregulated sphingolipid production to cause juvenile amyotrophic lateral sclerosisJournal of Neurology, Neurosurgery & Psychiatry
22.
1. Freeman M. R.
2. Doherty J.
2006Glial cell biology in Drosophila and vertebratesTrends in neurosciences 29:82–90
23.
1. Coutinho-Budd J.
2. Freeman M. R.
2013Probing the enigma: unraveling glial cell biology in invertebratesCurrent opinion in neurobiology 23:1073–1079
24.
1. Yildirim K.
2. Petri J.
3. Kottmeier R.
4. Klämbt C.
2019Drosophila glia: Few cell types and many conserved functionsGlia 67:5–26
25.
1. Corty M. M.
2. Coutinho-Budd J.
2023Drosophila glia take shape to sculpt the nervous systemCurrent Opinion in Neurobiology 79
26.
1. Stork T.
2. Engelen D.
3. Krudewig A.
4. Silies M.
5. Bainton R. J.
6. Klämbt C.
2008Organization and function of the blood–brain barrier in DrosophilaJournal of Neuroscience 28:587–597
27.
1. Volkenhoff A.
2. Weiler A.
3. Letzel M.
4. Stehling M.
5. Klämbt C.
6. Schirmeier S.
2015Glial glycolysis is essential for neuronal survival in DrosophilaCell metabolism 22:437–447
28.
1. Freeman M. R.
2015Drosophila central nervous system gliaCold Spring Harbor perspectives in biology 7
29.
1. Kis V.
2. Barti B.
3. Lippai M.
4. Sass M.
2015Specialized cortex glial cells accumulate lipid droplets in Drosophila melanogasterPLoS One 10
30.
1. Kremer M. C.
2. Jung C.
3. Batelli S.
4. Rubin G. M.
5. Gaul U.
2017The glia of the adult Drosophila nervous systemGlia 65:606–638
31.
1. Pfeiffer B. D.
2. Ngo T. T. B.
3. Hibbard K. L.
4. Murphy C.
5. Jenett A.
6. Truman J. W.
7. Rubin G. M.
2010Refinement of tools for targeted gene expression in DrosophilaGenetics 186:735–755
32.
1. Nern A.
2. Pfeiffer B. D.
3. Rubin G. M.
2015Optimized tools for multicolor stochastic labeling reveal diverse stereotyped cell arrangements in the fly visual systemProceedings of the National Academy of Sciences 112:E2967–E2976
33.
1. Southall T. D.
2. Gold K. S.
3. Egger B.
4. Davidson C. M.
5. Caygill E. E.
6. Marshall O. J.
7. Brand A. H.
2013Cell-type-specific profiling of gene expression and chromatin binding without cell isolation: assaying RNA Pol II occupancy in neural stem cellsDevelopmental cell 26:101–112
34.
1. Ziegler A. B.
2. Brüsselbach F.
3. Hovemann B. T.
2013Activity and coexpression of Drosophila black with ebony in fly optic lobes reveals putative cooperative tasks in vision that evade electroretinographic detectionJournal of Comparative Neurology 521:1207–1224
35.
1. He L.
2. Binari R.
3. Huang J.
4. Falo-Sanjuan J.
5. Perrimon N.
2019In vivo study of gene expression with an enhanced dual-color fluorescent transcriptional timerElife 8
36.
1. Sarov M.
2. Barz C.
3. Jambor H.
4. Hein M. Y.
5. Schmied C.
6. Suchold D.
7. Schnorrer F.
2016A genome-wide resource for the analysis of protein localisation in Drosophilaelife 5
37.
1. Bergeron J. J.
2. Brenner M. B.
3. Thomas D. Y.
4. Williams D. B.
1994Calnexin: a membrane-bound chaperone of the endoplasmic reticulumTrends in biochemical sciences 19:124–128
38.
1. Kikuma K.
2. Li X.
3. Kim D.
4. Sutter D.
5. Dickman D. K.
2017Extended synaptotagmin localizes to presynaptic ER and promotes neurotransmission and synaptic growth in DrosophilaGenetics 207:993–1006
39.
1. Park S. Y.
2. Muschalik N.
3. Chadwick J.
4. Munro S.
2022In vivo characterization of Drosophila golgins reveals redundancy and plasticity of vesicle capture at the Golgi apparatusCurrent Biology 32:4549–4564
40.
1. Kawano M.
2. Kumagai K.
3. Nishijima M.
4. Hanada K.
2006Efficient trafficking of ceramide from the endoplasmic reticulum to the Golgi apparatus requires a VAMP-associated protein-interacting FFAT motif of CERTJournal of Biological Chemistry 281:30279–30288
41.
1. Grabner G. F.
2. Xie H.
3. Schweiger M.
4. Zechner R.
2021Lipolysis: cellular mechanisms for lipid mobilization from fat storesNature metabolism 3:1445–1465
42.
1. Eberlé D.
2. Hegarty B.
3. Bossard P.
4. Ferré P.
5. Foufelle F.
2004SREBP transcription factors: master regulators of lipid homeostasisBiochimie 86:839–848
43.
1. Osborne T. F.
2. Espenshade P. J.
2009Evolutionary conservation and adaptation in the mechanism that regulates SREBP action: what a long, strange tRIP it’s beenGenes & development 23:2578–2591
44.
1. Jacquemyn J.
2. Cascalho A.
3. Goodchild R. E.
2017The ins and outs of endoplasmic reticulum-controlled lipid biosynthesisEMBO reports 18:1905–1921
45.
1. Sriburi R.
2. Bommiasamy H.
3. Buldak G. L.
4. Robbins G. R.
5. Frank M.
6. Jackowski S.
7. Brewer J. W.
2007Coordinate regulation of phospholipid biosynthesis and secretory pathway gene expression in XBP-1 (S)-induced endoplasmic reticulum biogenesisJournal of Biological Chemistry 282:7024–7034
46.
1. Bernales S.
2. Papa F. R.
3. Walter P.
2006Intracellular signaling by the unfolded protein responseAnnu. Rev. Cell Dev. Biol 22:487–508
47.
1. Moessinger C.
2. Klizaite K.
3. Steinhagen A.
4. Philippou-Massier J.
5. Shevchenko A.
6. Hoch M.
7. Thiele C.
2014Two different pathways of phosphatidylcholine synthesis, the Kennedy Pathway and the Lands Cycle, differentially regulate cellular triacylglycerol storageBMC cell biology 15:1–17
48.
1. Moessinger C.
2. Kuerschner L.
3. Spandl J.
4. Shevchenko A.
5. Thiele C.
2011Human lysophosphatidylcholine acyltransferases 1 and 2 are located in lipid droplets where they catalyze the formation of phosphatidylcholineJournal of Biological Chemistry 286:21330–21339
49.
1. Harayama T.
2. Eto M.
3. Shindou H.
4. Kita Y.
5. Otsubo E.
6. Hishikawa D.
7. Shimizu T.
2014Lysophospholipid acyltransferases mediate phosphatidylcholine diversification to achieve the physical properties required in vivoCell metabolism 20:295–305
50.
1. O’Donnell V. B.
2022New appreciation for an old pathway: the Lands Cycle moves into new arenas in health and diseaseBiochemical Society Transactions 50:1–11
51.
1. Yu S. Y.
2. Yoo S. J.
3. Yang L.
4. Zapata C.
5. Srinivasan A.
6. Hay B. A.
7. Baker N. E.
2002A pathway of signals regulating effector and initiator caspases in the developing Drosophila eyeDevelopment 129:3269–3278
52.
1. Fan Y.
2. Bergmann A.
2010The cleaved-Caspase-3 antibody is a marker of Caspase-9-like DRONC activity in DrosophilaCell Death & Differentiation 17:534–539
53.
1. O’Brien J. S.
1965Stability of the Myelin Membrane: Lipid molecules may impart stability to the myelin membrane through intermolecular cohesionScience 147:1099–1107
54.
1. Marcus J.
2. Popko B.
2002Galactolipids are molecular determinants of myelin development and axo–glial organizationBiochimica et Biophysica Acta (BBA)-General Subjects 1573:406–413
55.
1. Harrison P. J.
2. Dunn T. M.
3. Campopiano D. J.
2018Sphingolipid biosynthesis in man and microbesNatural product reports 35:921–954
56.
1. Kunduri G.
2. Turner-Evans D.
3. Konya Y.
4. Izumi Y.
5. Nagashima K.
6. Lockett S.
7. Acharya J. K.
2018Defective cortex glia plasma membrane structure underlies light-induced epilepsy in cpes mutantsProceedings of the National Academy of Sciences 115:E8919–E8928
57.
1. Clarke B. A.
2. Majumder S.
3. Zhu H.
4. Lee Y. T.
5. Kono M.
6. Li C.
7. Khanna C.
8. Blain H.
9. Schwartz R.
10. Proia R. L.
2019The Ormdl genes regulate the sphingolipid synthesis pathway to ensure proper myelination and neurologic function in miceelife 8
58.
1. Wang L.
2. Lin G.
3. Zuo Z.
4. Li Y.
5. Byeon S. K.
6. Pandey A.
7. Bellen H. J.
2022Neuronal activity induces glucosylceramide that is secreted via exosomes for lysosomal degradation in gliaScience Advances 8
59.
1. Vieira C. R.
2. Munoz-Olaya J. M.
3. Sot J.
4. Jiménez-Baranda S.
5. Izquierdo-Useros N.
6. Abad J. L.
7. Goñi F. M.
2010Dihydrosphingomyelin impairs HIV-1 infection by rigidifying liquid-ordered membrane domainsChemistry & biology 17:766–775
60.
1. Hernández-Tiedra S.
2. Fabrias G.
3. Dávila D.
4. Salanueva I. J.
5. Casas J.
6. Montes L. R.
7. Velasco G.
2016Dihydroceramide accumulation mediates cytotoxic autophagy of cancer cells via autolysosome destabilizationAutophagy 12:2213–2229
61.
1. Aggarwal S.
2. Yurlova L.
3. Simons M.
2011Central nervous system myelin: structure, synthesis and assemblyTrends in cell biology 21:585–593
62.
1. Bailey A. P.
2. Koster G.
3. Guillermier C.
4. Hirst E. M.
5. MacRae J. I.
6. Lechene C. P.
7. Gould A. P.
2015Antioxidant role for lipid droplets in a stem cell niche of DrosophilaCell 163:340–353
63.
1. Liu L.
2. Zhang K.
3. Sandoval H.
4. Yamamoto S.
5. Jaiswal M.
6. Sanz E.
7. Bellen H. J.
2015Glial lipid droplets and ROS induced by mitochondrial defects promote neurodegenerationCell 160:177–190
64.
1. Liu L.
2. MacKenzie K. R.
3. Putluri N.
4. Maletić-Savatić M.
5. Bellen H. J.
2017The glia-neuron lactate shuttle and elevated ROS promote lipid synthesis in neurons and lipid droplet accumulation in glia via APOE/DCell metabolism 26:719–737
65.
1. Marshall L. L.
2. Stimpson S. E.
3. Hyland R.
4. Coorssen J. R.
5. Myers S. J.
2014Increased lipid droplet accumulation associated with a peripheral sensory neuropathyJournal of chemical biology 7:67–76
66.
1. Farmer B. C.
2. Walsh A. E.
3. Kluemper J. C.
4. Johnson L. A.
2020Lipid droplets in neurodegenerative disordersFrontiers in neuroscience 14
67.
1. Marschallinger J.
2. Iram T.
3. Zardeneta M.
4. Lee S. E.
5. Lehallier B.
6. Haney M. S.
7. Wyss-Coray T.
2020Lipid-droplet-accumulating microglia represent a dysfunctional and proinflammatory state in the aging brainNature neuroscience 23:194–208
68.
1. Bischof J.
2. Björklund M.
3. Furger E.
4. Schertel C.
5. Taipale J.
6. Basler K.
2013A versatile platform for creating a comprehensive UAS-ORFeome library in DrosophilaDevelopment 140:2434–2442
69.
1. Choi H. M.
2. Schwarzkopf M.
3. Fornace M. E.
4. Acharya A.
5. Artavanis G.
6. Stegmaier J.
7. Cunha A.
8. Pierce N. A.
2018Third-generation in situ hybridization chain reaction: multiplexed, quantitative, sensitive, versatile, robustDevelopment 145
70.
1. Lacin H.
2. Chen H. M.
3. Long X.
4. Singer R. H.
5. Lee T.
6. Truman J. W.
2019Neurotransmitter identity is acquired in a lineage-restricted manner in the Drosophila CNSelife 8
71.
1. Duckhorn J. C.
2. Junker I. P.
3. Ding Y.
4. Shirangi T. R.
2022Combined in situ hybridization chain reaction and immunostaining to visualize gene expression in whole-mount Drosophila central nervous systemsBehavioral Neurogenetics :1–14
72.
1. Patel N. H.
1994Imaging neuronal subsets and other cell types in whole-mount Drosophila embryos and larvae using antibody probesMethods in cell biology 44:445–487
73.
1. Truman J. W.
2. Schuppe H.
3. Shepherd D.
4. Williams D. W.
2004Developmental architecture of adult-specific lineages in the ventral CNS of DrosophilaGenetics
74.
1. Cho K.
2. Schwaiger-Haber M.
3. Naser F. J.
4. Stancliffe E.
5. Sindelar M.
6. Patti G. J.
2021Targeting unique biological signals on the fly to improve MS/MS coverage and identification efficiency in metabolomicsAnalytica chimica acta 1149
75.
1. Adams K. J.
2. Pratt B.
3. Bose N.
4. Dubois L. G.
5. St. John-Williams L.
6. Perrott K. M.
7. Alzheimer’s Disease Metabolomics Consortium
2020Skyline for small molecules: a unifying software package for quantitative metabolomicsJournal of proteome research 19:1447–1458
76.
1. Dobin A.
2. Davis C. A.
3. Schlesinger F.
4. Drenkow J.
5. Zaleski C.
6. Jha S.
7. Batut P.
8. Chaisson M.
9. Gingeras T. R.
2013STAR: ultrafast universal RNA-seq alignerBioinformatics 29:15–21
77.
1. Liao Y.
2. Smyth G. K.
3. Shi W.
2014featureCounts: an efficient general purpose program for assigning sequence reads to genomic featuresBioinformatics 30:923–930
78.
1. Patro R.
2. Duggal G.
3. Love M. I.
4. Irizarry R. A.
5. Kingsford C.
2017Salmon provides fast and bias-aware quantification of transcript expressionNature methods 14:417–419
79.
1. Love M. I.
2. Huber W.
3. Anders S.
2014Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2Genome biology 15:1–21
80.
1. Langfelder P.
2. Horvath S.
2008WGCNA: an R package for weighted correlation network analysisBMC bioinformatics 9:1–13

Article and author information

Yuqing Zhu
Department of Genetics, Washington University School of Medicine, 4523 Clayton Avenue, St. Louis, MO 63110, USA
Kevin Cho
Department of Chemistry, Washington University in St. Louis, One Brookings Drive, St. Louis, MO 63130, USA, Department of Medicine, Washington University School of Medicine, St. Louis, MO 63110, USA, Center for Mass Spectrometry and Metabolic Tracing, Washington University in St. Louis, One Brookings Drive, St. Louis, MO 63130, USA
Haluk Lacin
Division of Biological and Biomedical Systems, University of Missouri-Kansas City, Kansas City, MO 64110, USA
Yi Zhu
Department of Genetics, Washington University School of Medicine, 4523 Clayton Avenue, St. Louis, MO 63110, USA
Jose T DiPaola
Department of Genetics, Washington University School of Medicine, 4523 Clayton Avenue, St. Louis, MO 63110, USA
Beth A Wilson
Department of Genetics, Washington University School of Medicine, 4523 Clayton Avenue, St. Louis, MO 63110, USA
Gary J Patti
Department of Chemistry, Washington University in St. Louis, One Brookings Drive, St. Louis, MO 63130, USA, Department of Medicine, Washington University School of Medicine, St. Louis, MO 63110, USA, Center for Mass Spectrometry and Metabolic Tracing, Washington University in St. Louis, One Brookings Drive, St. Louis, MO 63130, USA
James B Skeath
Department of Genetics, Washington University School of Medicine, 4523 Clayton Avenue, St. Louis, MO 63110, USA
For correspondence:
jskeath@wustl.edu

Version history

Preprint posted: May 21, 2024
Sent for peer review: May 21, 2024
Reviewed Preprint version 1: July 31, 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: 190
downloads: 5
citations: 0

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