DNL343 is CNS penetrant and suitable for acute and chronic in vivo dosing.

(A) Chemical structure of DNL343. (B) Schematic of DNL343 dosing studies in wild-type mice. Left: DNL343 (62.5 mg/kg) was administered via oral gavage and mice were taken down 7 hours after. Right: DNL343 was formulated in food at a concentration of 0, 50, 150, or 500 mg/kg chow. Plasma was sampled on days 2 and 29 of dosing at 1h after lights on (zeitgeber, ZT1) and animals were taken down on day 37 at ZT6. (C) DNL343 unbound concentration in the plasma and brain at 7 hours after a single administration of DNL343 at 62.5 mg/kg. (D) DNL343 unbound concentration in the plasma after 2 and 29 days of in-food dosing. (E) DNL343 unbound concentration in the plasma and brain after 37 days of in-food dosing. (F) Body weight of mice maintained on DNL343-formulated diet. Data are presented as mean ± SEM of N=8/group (C) or N=5/group (D-F).

DNL343 engages the ISR and is neuroprotective in an acute ISR-driven neurodegeneration model, the optic nerve crush (ONC).

(A) Schematic of the DNL343 dosing study in the ONC model. Wild-type mice underwent ONC procedure and received once daily DNL343 administrations via oral gavage 3 hours later. Animals were taken down at 2 or 14 days after the ONC procedure and retinas, ipsi- and contra-lateral to the crushed site, were collected. (B) DNL343 unbound concentration in the plasma and brain. (C) Heatmap showing expression level of ISR mRNA markers in the retina, ipsilateral to the crush at 2 and 14 days after ONC, relative to control retinas from the uncrushed side. (D-E) DNL343 reduced axonal degeneration score and retinal ganglion cell loss. (F) Representative immunofluorescent images of retinal ganglion cells as identified by TUJ1 (green) and γ-synuclein (red) immunoreactivity. Data are presented as mean ± SEM of N=8-12/group. Statistical significance for DNL343 effect was set at P <0.05 as determined by a one-way ANOVA followed by multiple comparison tests against crushed retina from vehicle-treated animals (*, P <0.05. **, P <0.01, ***, P <0.001, ****, P <0.0001).

Bulk brain and CSF proteomics reveal distinct signatures of CNS ISR activation and neurodegeneration in the eIF2B HOM mice.

(A) Volcano plot showing protein expression changes in the brain of 11-15-week-old eIF2B HOM mice relative to wild-type control with absolute log2 fold change (FC) >0.5 and P <0.00005. Blue and red circles denote either down- or up-regulated proteins, respectively. Larger symbols denote proteins with absolute log2 FC >1. In this analysis, 7,939 proteins were detected. (B) Fast pre-ranked protein set enrichment (FPSEA) analysis of dysregulated proteins matched to mouse reactome pathways. Detected proteins corresponded to 657 pathways defined in the mouse reactome pathways and significantly (adjusted P <0.05) up or down-regulated protein/gene sets are shown. The x-axis in the barcode plot shows ranked lists of proteins and the vertical bar shows protein normalized enrichment scores (NES). Proteins were ranked based on differential expression significance and fold change with most significantly up- or down-regulated genes are shown in the top or the bottom of list, respectively. NES scores indicate overall normalized enrichment scores of the whole set. Significance of enrichments are listed in the adjusted p-value column. (C) Unsupervised principal component analysis results from the brain are shown. Top 10 variables contributing Dim1 and Dim2 are shown in bar plots. Results show a clear separation of eIF2B HOM from wild-type mice along the y axis showing PC2 (Dim2) scores. Top 10 proteins contributing to Dim2 scores were metabolic enzymes involved in lipid, 1-carbon, aldehyde and serine metabolism. (D) Volcano plot showing protein expression changes in the CSF of 11-15-week-old eIF2B HOM mice relative to wild-type. Blue and red circles denote either down- or up-regulated proteins, respectively. Significantly dysregulated proteins with absolute log2 FC >0.25 and P <0.05 are labelled. 572 proteins were detected in this analysis. (E) Top 3 up- or down-regulated reactome pathways from CSF proteomic analysis identified from FPSEA analysis are shown. A higher abundance of proteins involved in mitochondria, lipid, and carbohydrate metabolism were observed in the eIF2B HOM relative to wild-type mice. Significant downregulations of proteins involved in cell cycle regulation were observed in the CSF compartment. (F) Visualization of unsupervised PCA analysis from CSF proteome data. As compared to the brain proteome, less discrimination between the two genotypes were observed. Between group variances were mostly along the PC1 (Dim1) axis. Top 10 loading variables that contributed to DIM 1 scores were of cytosolic proteins in heat shock, tyrosine, methylation, and extracellular matrix remodeling pathways. Statistical significance was set at P <0.05 as determined by robust linear model. N=7/group.

Chronic DNL343 dosing inhibits ISR overactivation in the brain, restores normal body weight, and prevents functional decline and neurodegeneration in the eIF2B mouse.

(A) Schematic of the prophylactic DNL343 dosing study in the eIF2B HOM mouse model. DNL343 treatment was initiated in pre-symptomatic animals at 10-17 weeks of age. Mice self-administered DNL343-formulated rodent chow to achieve levels equivalent to oral gavage doses of 0, 0.3, 1, 3 or 10 mg/kg. (B) Plasma DNL343 exposure measured biweekly from week 2-12 of dosing. (C) Terminal plasma and brain DNL343 exposure after 13 weeks of dosing. (D) Heatmap visualization of select brain ISR transcript markers in vehicle- and DNL343-treated wild-type and eIF2B HOM mice relative to vehicle-treated wild-type controls. (E) Body weight gain measured weekly. (F) Plasma NfL levels assessed at baseline and throughout the study duration. B and T indicate baseline and terminal timepoints, respectively. (G) The balance beam test was performed after 12 weeks of dosing and the time to cross the beam out of 30 seconds were recorded. (H-I) The number of hindfoot slips and falls during the balance beam test. Data are presented as mean ± SEM of N=9-18 mice per group. Statistical significance for DNL343 effect was set at P <0.05 as determined by a mixed-effect analysis followed by multiple comparison tests against vehicle-dosed animals of the same genotype at matching timepoints (E-F) or one-way ANOVA followed by multiple comparison tests against vehicle-dosed animals of the same genotype (G-I). (*, P <0.05. **, P <0.01, ***, P <0.001, ****, P <0.0001).

DNL343 dose-dependently normalized bulk brain and CSF protein and brain metabolite changes associated with ISR activation in the eIF2B HOM mouse.

(A) Heatmap visualization of differential expression of proteins in eIF2B HOM mice vs wild-type controls following treatment with vehicle or DNL343 for 13 weeks (N=3/group). Wild-type mice received vehicle or DNL343 at the 3 mg/kg dose level. Features with significant (P <0.05) dose responses were selected and clustered based on Euclidean distances. Results show two main clusters of responsive protein that were up-(top) or down-regulated (bottom) in a dose-dependent manner. (B) Single enrichment plot of pathway proteins that were most significantly enriched in DNL343-treated eIF2B HOM mice vs vehicle-treated eIF2B HOM mice. Ranks are created based on both the magnitude of change in expression and their significance. Proteins that are upregulated are towards lower ranks whereas those that are downregulated have higher ranks towards the right. Vertical bars indicate locations of each protein hit. (C) CSF proteomic shifts in the same mice shown in panel A are shown. Results show that significant elevation in abundance of CSF markers of microglial activation was decreased with DNL343 treatment at dose higher than 3 mg/kg body weight for two weeks. (D) Single enrichment plot of pathway proteins that were most significantly enriched in DNL343-treated eIF2B HOM mice vs vehicle-treated eIF2B HOM mice. Ranks are created based on both the magnitude of change in expression and their significance. Proteins that are upregulated are towards lower ranks whereas those that are downregulated have higher ranks towards the right. Vertical bars indicate locations of each protein hit. (E) Heatmap visualization of metabolomic changes in the bulk brain of eIF2B HOM relative to wild-type mice. Statistical significance was set at P <0.05 as determined by robust linear model. N=5-10/group.

Exploratory biomarkers responsive to DNL343 in eIF2B mouse model and assessed in VWMD patient CSF and plasma

(A-B) Expression of Gdf15 mRNA and GDF-15 protein in the brain of eIF2B HOM or wild-type mice treated with DNL343 or vehicle. (C-D) GDF-15 protein levels in the CSF and plasma of VWMD patients and healthy controls (E-F) Expression of brain Gfap mRNA and plasma GFAP protein in eIF2B HOM or wild-type mice treated with DNL343 or vehicle. (G-H) GFAP protein levels in the CSF and plasma of VWMD patients and healthy controls. (I-J) TIMP-1 protein levels in the brain and CSF of eIF2B HOM or wild-type mice treated with DNL343 or vehicle. (K-L) TIMP-1 protein levels in the CSF and plasma of VWMD patients and healthy controls (M-N) Expression of the Ccl2 transcript, which encodes the MCP-1 protein, and levels of MCP-1 protein in the brain of eIF2B HOM or wild-type mice treated with DNL343 or vehicle. (O-P) MCP-1 protein levels in the CSF and plasma of VWMD patients and healthy controls. (Q-R) NfL protein levels in the CSF and plasma of VWMD patients and healthy controls. (S) Heatmap visualization of relative changes in NfL, GDF-15, GFAP and MCP-1 in the CSF of VWMD patients versus healthy controls, presented in log2 scale. VWMD patient ID#s correspond across Figure 6S (CSF) and Supplemental Figure 5E (plasma). Statistical significance was set at P <0.05. For all animal model panels, DNL343 dose is indicated on the x-axis and data is presented as mean ± SEM of N=9-18 mice per group. Statistical significance for DNL343 effect in the mouse model was determined by a one-way ANOVA followed by multiple comparison tests against vehicle-dosed animals of the same genotype (*, P <0.05. **, P <0.01, ***, P <0.001, ****, P <0.0001). Data from VWMD patients and healthy controls is presented as mean ± SEM. Statistical significance for the difference between samples from VWMD patients and healthy controls was assessed on log2 fold change data using Welch’s t test (*, P <0.05. **, P <0.01, ***, P <0.001, ****, P <0.0001).

Reduction in ISR activation in the CNS is associated with reversal and normalization of plasma biomarker of neurodegeneration and extension of life when DNL343 treatment was initiated towards end of disease stage in the eIF2B HOM mouse.

(A) Schematic of DNL343 therapeutic dosing studies in the eIF2B HOM mouse. DNL343 treatment was initiated when animals already presented with disease phenotypes at 19-26 or 24-33 weeks of age for 4 or up to 20 weeks, respectively. Mice self-administered DNL343-formulated rodent chow to achieve levels equivalent to oral gavage dose of 10 mg/kg. (B) DNL343 exposure was assessed in terminal plasma and in the brain after 4 weeks of dosing. (C). Body weight was measured at baseline and up to 4 weeks of dosing. (D) Heatmap visualization of select ISR transcript markers in the brain following vehicle- and DNL343 treatment for 4 weeks. (E-F) Plasma biomarker of neurodegeneration, NfL, and neuroinflammation, GFAP, was measured every 4 weeks for up to 20 weeks of dosing. (G) Kaplan-Meier graph shows that the reduced lifespan of the eIF2B HOM mice was extended when DNL343 treatment was initiated at 24-33 weeks of age. Data are presented as mean ± SEM of N=7-10 mice (panels B-D) or 10-13 mice per group (panels E-G). Statistical significance for DNL343 effect was set at P <0.05 as determined by a mixed-effect analysis followed by multiple comparison tests against vehicle-dosed animals of the same genotype at matching timepoints (C) or against baseline values for each group (E-F). Effect of DNL343 on eIF2B HOM survival was assessed with Log-rank test. (*, P <0.05. **, P <0.01, ***, P <0.001, ****, P <0.0001).

The ISR is activated in the brain of the eIF2B HOM mice.

(A) Heatmap visualization of ISR mRNA markers in the brains of mice that are wildtype (WILD), heterozygous (HET) or homozygous (HOM) for the Eif2b5 R191H knock-in mutation. (B) Volcano plot showing the comparisons of eIF2B HOM to wild-type bulk brain samples (N=9-12/group, respectively) by RNA sequencing. Blue and red circles denote significantly up- or down-regulated genes (FDR <5%), larger labelled points correspond to known ATF4 target genes. (C-D) Heatmap visualization of select ISR transcript markers in the PBMC and spleen. Animals were 13-19 weeks of age.

DNL343 formulated food is well tolerated in both wild-type and homozygous mutant mice & targeted DNL343 are achieved.

(A) Brain DNL343 exposures following consumption of food formulated with DNL343 at 3, 10, 30 and 100 mg/kg chow was equivalent to those following single oral gavage at 0.3, 1, 3, and 10 mg/kg body weight. (B) Food intake estimated based on the difference in hopper weight and adjusted for body weight. Statistical significance was set at P <0.05 as determined by a mixed-effect analysis followed by multiple comparison tests against vehicle-dosed animals of the same genotype at matching timepoints (*, P <0.05. **, P <0.01). (C) DNL343 intake was calculated based on estimated food intake and DNL343 concentration in the food. Data are presented as mean ± SEM of N=8-18 mice per group.

Confirmation of ISR associated proteomics changes in bulk brain and CSF in a cohort of 5-7-month-old mice, establishing evidence for metabolomic perturbations in the eIF2B HOM mice relative to the wild-type controls.

(A) Volcano visualization of altered proteins in eIF2B HOM as compared to wild-type mice (N=3 per genotype). A total of 4,197 proteins were quantified. Variables with absolute log2 FC ≥0.25 and P <0.05 are labeled. Proteins with larger symbols have log2 FC ≥0.5. Significant increases in SLC-mediated transmembrane transport proteins, serine metabolism, and decreases in lipid metabolism proteins that were shown in Figure 3 were also seen in this independent cohort. (B) Corresponding proteomic changes in CSF proteome are shown. Proteins with absolute log2 expression change >0.25 and P <0.05 are denoted in boxed labels. A total of 202 proteins were quantified and results show significant increases in abundance of protein biomarkers of brain microglial activation. (C) Metabolomic analysis of bulk brain associated with proteomic shifts shown in Panels A and B. Metabolites or lipids with absolute log2 FC >0.5 and P <0.05 are labeled. As predicted by significant decreases in lipid metabolism proteins noted in the bulk brain of eIF2B HOM mice, levels of cholesterol esters and 7-keto-Cholesterol (oxidized cholesterol) were highly elevated in the bulk brain. Despite increases in SLC-mediated transmembrane amino acid transporter expression, brain alanine, TCA cycle intermediates, and methyl-donor and thiamine metabolic co-factors were all lower in eIF2B HOM mice. Statistical significance was set at P <0.05 as determined by robust linear model. N=3/genotype.

Elevation in GDF-15 mRNA and protein levels in the eIF2B HOM brain and correction by DNL343 is reflected by changes in the CSF.

(A-B) GDF-15 is increased on both the mRNA and protein level in the brain of eIF2B HOM mice relative to wild-type controls and 4 weeks of DNL343 in diet treatment at a dose equivalent to 10 mg/kg reduced its level. (C) Measurement of GDF-15 in the mouse CSF is feasible and shows changes that recapitulate findings in the brain. Data from the animal model is presented as mean ± SEM of N=7-11 mice per group. Statistical significance for DNL343 effect in the mouse model was determined by a two-way ANOVA followed by multiple comparison tests against vehicle-dosed animals of the same genotype (****, P <0.0001).

Evaluation of biomarkers for VWMD in patient CSF and plasma

(A) CSF and plasma protein levels of GDF-15 in patients with VWMD and healthy controls with age at time of collection shown. Data points from the same patient collected at different ages are connected with a solid black line. (B-C) Protein levels of IL-18 and sTREM2 measured in CSF and plasma of VWMD patients and healthy controls. (D) NfL protein levels measured in CSF and plasma of VWMD patients and healthy controls and age at time of collection. Data points from the same patient collected at different ages are connected by a solid black line. (E) Level of denoted proteins in plasma shown as relative level compared to average of healthy controls on log2 scale in a heatmap. For patients with multiple samples, age increases from left to right across lanes. VWMD patient ID#s correspond across panel E (plasma) and Figure 6S (CSF). Plasma and CSF samples in the healthy control group are from non-matching/different individuals. Statistical significance for the difference between samples from VWMD patients and healthy controls was assessed on log2 fold change data using Welch’s t test (ns, not statistically significant).

Four weeks of DNL343 treatment initiated at late stage of disease did not rescue motor function but led to a trend of plasma NfL reduction.

(A) Balance beam test was performed after 4 weeks of dosing and time to cross the beam out of 30 seconds were recorded. (B) Plasma biomarker of neurodegeneration, NfL, was measured at baseline and after 4 weeks of DNL343 dosing. Data are presented as mean ± SEM of N=7-12 mice per group. Statistical significance for DNL343 effect was set at P <0.05 as determined by one-way ANOVA followed by multiple comparison tests against vehicle-dosed animals of the same genotype (A) or mixed-effect analysis followed by multiple comparison tests against vehicle-dosed animals of the same genotype at matching timepoints.

Baseline characteristic and age at the end of the 20-week DNL343 therapeutic dosing study in the eIF2B HOM model.

(A) Age at DNL343 treatment initiation was matched across all experimental groups. (B) Age of mice at the end of the 20-week study or when animals met at least one of the predetermined humane endpoints. X indicates mice that died or met a humane endpoint during the 20-week dosing study.