Project description:Mutations in fukutin-related protein (FKRP) gene are characterized with a lack of functionally glycosylated α-dystroglycan (F-α-DG). Surprisingly a small number of muscle fibers express strong F-α-DG. Here we investigate restoration of F-α-DG in FKRP mutant muscle and showed that the restoration of glycosylation is associated with muscle regeneration and dependent of the expression of both LARGE and partially functional FKRP. F-α-DG in regenerating fibers reaches normal levels and lasts for more than 4 weeks, however, no up-regulation of the LARGE and FKRP is detected during the regeneration process. These results suggest that FKRP P448L mutation clinically associated with severe CMD retains at least partial functions. Identification of factor(s) other than LARGE and FKRP could create new approaches for restoration of F-α-DG in mature muscle fibers with defects in FKRP function. We employed microarrays to detail changes in gene expression associated with muscle regeneration in wild-type and FKRP mutant skeletal muscle, and have identified a group of genes with altered expression between these mice during this regeneration process.

Project description:Primary outcome(s): Measure auto-lysosome function in the cytoplasm by electron microscopy to examine the changes in the number of autophagy.

Project description:Previous studies of age-related transcriptional changes indicate that cognitive impairments are associated with differentially expressed genes DEGs linked to defined neural systems; however, studies that examine multiple regions of the hippocampus fail to find major links between behavior and transcription in the dentate gyrus DG. The DG is implicated in pattern separation PS and exhibits multiple age-related changes that may affect PS performance. We hypothesize that an age-related decline in PS performance is associated with distinct changes in transcriptional profile, most strongly within the DG compared to other hippocampal subregions. We used a water maze beacon discrimination task to characterize PS in young 5 mo and middle-age 12 mo male F344 rats, followed by a spatial reference memory test. Middle-age rats showed consistent deficits in discriminating two identical beacons compared to young. Reference memory was not different between these two age groups. Interestingly, with increasing spatial overlap between the cues, older animals appeared to compensate for impaired PS performance though greater reliance on spatial reference memory. mRNA sequencing of hippocampal subregions DG, CA1, and CA3 indicated that the DG of middle-age rats expressed more genes correlated with PS performance. In contrast, reliance on a spatial reference memory was associated with differential expression of genes in regions CA1 and CA3. These results indicate that the beacon task is sensitive to PS impairment as early as middle-age, and distinct gene profiles are observed in neural circuits that underlie different strategies used to solve the task.

Project description:BSA digest standards, MD and PS, maXis and ultraflex

Project description:Pluripotent stem (PS) cells enable the scalable production of tissue-specific derivatives with therapeutic potential for various clinical applications, including muscular dystrophies. Given the similarity to human counterparts, the non-human primate (NHP) is an ideal preclinical model to evaluate several questions, including delivery, biodistribution and immune response. While the generation of human induced PS (iPS) cell-derived myogenic progenitors is well established, there has been no data for NHP counterparts, probably due to the lack of an efficient system to differentiate NHP iPS cells towards the skeletal muscle lineage. Here we report the generation of three independent Macaca fascicularis iPS cell lines and their myogenic differentiation using PAX7 conditional expression. Whole transcriptome analysis confirmed the successful sequential induction of mesoderm, paraxial mesoderm, and myogenic lineages. NHP myogenic progenitors efficiently gave rise to myotubes under appropriate in vitro differentiation conditions and engrafted in vivo into TA muscles of NSG and FKRP-NSG mice. Lastly, we explored the pre-clinical potential of these NHP myogenic progenitors in a single wild-type NHP recipient, demonstrating engraftment and characterizing the interaction with the host immune response. These studies establish an NHP model system in which to study iPS cell-derived myogenic progenitors.

Project description:Autophagy is a conserved lysosomal-dependent cellular degradation process shown to play a key role in immune defense against Mycobacterium tuberculosis inside host macrophages. Induction of autophagy enhances mycobacterial phagosome acquisition of lysosomal hydrolases, resulting in the destruction of intracellular M. tuberculosis reference strain H37Rv and strains belonging to the East African Indian genotype. However, our previous study showed that strains belonging to the hypervirulent M. tuberculosis Beijing genotype have a special ability to resist autophagic killing but the mechanism involved remains unclear. In this study, we carried out whole transcriptome analyses of host macrophages infected with the autophagy resistant Beijing strain compared to that of H37Rv. Our results identified several genes that are differentially regulated in the Beijing strain-infected host cells including those function in the lysosome positioning pathway. Host macrophages depleted of Kxd1 and Pleckhm2, two proteins in this pathway, can now enhance the lysosomal hydrolase acquisition into the Beijing phagosomes and restrict the bacterial survival upon autophagy induction. High-content image analysis showed an increase in lysosome numbers at the cell periphery in host cells infected with the autophagy resistant Beijing strain in a Pleckhm2-dependent manner. Taken together, these data indicated that the M. tuberculosis Beijing strain escapes autophagic elimination by upregulating the lysosome positioning pathway resulting in an increase in lysosome relocation toward the cell periphery and therefore sparing the mycobacteria from autophagic restriction. Our work thus identified new strategy employed by M. tuberculosis to evade autophagy which may provide potential new targets for drug discovery against tuberculosis

Project description:Zinc is an essential element for animals and stored in de novo synthesized lysosome related organelles called bilobed granules in Caenorhabditis elegans. Defining how zinc regulated transcription drives the observed lysosome remodeling is key to understand zinc homeostasis processes. Here we describe a positively regulated zinc network controlled by HIZR-1 and HLH-30, the zinc sensor and the master regulator of the autophagy-lysosomal pathway in Caenorhabditis elegans, respectively; essential for connecting zinc homeostasis to lysosome biogenesis. Our studies indicate that either hizr-1 and hlh-30 are necessary and sufficient to activate transcription of lysosome-genes under high dietary zinc conditions. Consistent with the hizr-1 and hlh-30 dependency for high zinc response, we found DNA enhancer elements corresponding to the high zinc activation element consistently adjacent to E-boxes in the promoter regions of lysosome-genes. We defined a regulatory network based on the contribution of each transcription factor. Since zinc cannot be degraded, the autophagy-lysosomal pathway could play a key role in removing zinc excess

Project description:Engrams are considered to be substrates for memory storage, and the functional dysregulation of the engrams leads to cognition impairment.However, the cellular basis for these maladaptive changes lead to the forgetting of memories remains unclear. Here we found that the expression of autophagy protein 7 (Atg7) mRNA was dramatically upregulated in aged DG engrams, and led to the forgetting of contextual fear memory and the activation of surrounding microglia.To determine mechanism by which autophagy in DG engrams activates the surrounding microglia, mice were co-injected AAV-RAM-Cre either with AAV-Dio-Atg7-Flag or AAV-Dio- EYFP in dorsal dentate gyrus to overexpress ATG7 in the DG memory engrams. Microglia were separated using magnetic-activated cell sorting and subjected to RNA-Seq in dorsal hippocampus .Bioinformatics analysis shown overexpression of Atg7 in dorsal DG memory engrams caused an increase in the expression of Tlr2 in the surrounding microglia.Depletion of Toll-like receptor 2/4 (TLR2/4) in DG microglia prohibited excessive microglial activation and synapse elimination induced by the overexpression of ATG7 in DG engrams, and thus prevented forgetting. Furthermore, the expression of Rac1, a Rho-GTPases which regulates active forgetting in both fly and mice, was upregulated in aged engrams. Optogentic activation of Rac1 in DG engrams promoted the autophagy of the engrams, the activation of microglia, and the forgetting of fear memory. Invention of the Atg7 expression and microglia activation attenuated forgetting induced by activation of Rac1 in DG engrams. Together, our findings revealed autophagy-dependent synapse elimination of DG engrams by microglia as a novel forgetting mechanism.

Project description:Targeted differentiation of pluripotent stem (PS) cells into myotubes enables in vitro disease modeling of skeletal muscle diseases. Although various protocols achieve myogenic differentiation in vitro, resulting myotubes invariably display an embryonic identity. This is a major hurdle for accurately recapitulating disease phenotypes in vitro, as disease typically does not manifest in the embryonic muscle, but at more mature stages. To address this problem, we identified four factors from a small molecule screen whose combinatorial treatment resulted in myotubes with enhanced maturation, as shown by increased expression of fetal, neonatal and adult myosin heavy-chain isoforms. These molecular changes were confirmed by global chromatin accessibility and transcriptome studies. Importantly, we also observed this maturation in three-dimensional muscle bundles, which displayed improved in vitro contractile force generation in response to electrical stimulus. Thus, we established a model for in vitro muscle maturation from PS cells.

Project description:Intricate regulation of lysosome and autophagy processes is essential for maintaining cellular homeostasis and basal metabolism. While the consequences of disrupting or attenuating lysosome and autophagy systems have been extensively studied, little is known about the impact of hyper-activation of lysosomal and autophagy genes on homeostasis. Our research uncovers previously unknown transcriptional repression mechanism by upstream stimulatory factor 2 (USF2), which inhibits lysosomal and autophagy genes in nutrient-rich conditions. USF2 binds to the CLEAR motif within lysosomal genes along with HDAC1, which diminishes H3K27 acetylation levels, restrains chromatin accessibility, and lowers lysosomal gene expression. Under starvation, USF2 competes with TFEB, a master transcriptional activator of lysosomal and autophagy genes, to bind target gene promoters in phosphorylation-dependent manner. Phosphorylation of the S155 site by GSK3b plays a pivotal role in controlling USF2's DNA binding activity for the repression of lysosomal genes while GSK3b-mediated phosphorylation of TFEB enhances its cytoplasmic retention. Applying these discoveries has potential for treating diseases associated with protein aggregation, including alpha-1 antitrypsin deficiency. These findings demonstrate that the USF2 repression mechanism could be a potent therapeutic strategy for various lysosome and autophagy-related diseases.