Duchenne muscular dystrophy (DMD) is a lethal, X-linked disease characterized by progressive muscle degeneration. The condition is driven by out-of-frame mutations in the dystrophin gene, and the absence of a functional dystrophin protein ultimately leads to instability of the sarcolemma, skeletal muscle necrosis, and atrophy. While the structural changes that occur in dystrophic muscle are well characterized, resulting changes in muscle-specific gene expression that take place in dystrophin’s absence remain largely uncharacterized, as they are potentially obscured by the characteristic chronic inflammation in dystrophin deficient muscle.

The conservation of the dystrophin gene across metazoans suggests that both vertebrate and invertebrate model systems can provide valuable contributions to the understanding of DMD initiation and progression. Specifically, the invertebrate C. elegans possesses a dystrophin protein ortholog, dys-1, and a mild inflammatory response that is inactive in the muscle, allowing for the characterization of transcriptome rearrangements affecting disease progression independently of inflammation. Furthermore, C. elegans do not possess a satellite cell equivalent, meaning muscle regeneration does not occur. This makes C. elegans unique in that they allow for the study of dystrophin deficiencies without muscle regeneration that may obscure detection of subtle but consequential changes in gene expression.

I hypothesize that gaining a comprehensive definition of both the structural and signaling roles of dystrophin in C. elegans will improve the community’s understanding of the progression of DMD as a whole. To address this hypothesis, I have performed a phylogenetic analysis on the conservation of each member of the dystrophin associated protein complex (DAPC) across 10 species, established an in vivo system to identify muscle-specific changes in gene expression in the dystrophin-deficient C. elegans, and performed a functional analysis to test the biological significance of changes in gene expression identified in my sequencing results. The results from this study indicate that in C. elegans, dystrophin may have a signaling role early in development, and its absence may activate compensatory mechanisms that counteract disease progression. Furthermore, these findings allow for the identification of transcriptome changes that potentially serve as both independent drivers of disease and potential therapeutic targets for the treatment of DMD.

In eukaryotes, most messenger RNA precursors (pre-mRNA) undergo extensive processing, leading to the cleavage of the transcript followed by the addition of a poly(A) tail. This process is executed by a large complex known as the Cleavage and Polyadenylation Complex (CPC). Its central subcomplex, the Cleavage and Polyadenylation Specificity Factor (CPSF) complex is responsible for recognizing a short hexameric element AAUAAA located at the 3’end in the nascent mRNA molecule and catalyzing the pre-mRNA cleavage. In the round nematode C. elegans, the cleavage reaction is executed by a subunit of this complex named CPSF3, a highly conserved RNA endonuclease. While the crystal structure of its human ortholog CPSF73 has been recently identified, we still do not understand the molecular mechanisms and sequence specificity used by this protein to induce cleavage, which in turn would help to understand how this process is executed in detail. Additionally, we do not understand in additional factors are needed for this process. In order to address these issues, we performed a comparative analysis of the CPSF3 protein in higher eukaryotes to identify conserved functional domains. The overall percent identities for members of the CPSF complex range from 33.68% to 56.49%, suggesting that the human and C. elegans orthologs retain a high level of conservation. CPSF73 is the protein with the overall highest percent identity of the CPSF complex, with its active site-containing domain possessing 74.60% identity with CPSF3. Additionally, we gathered and expressed using a bacterial expression system CPSF3 and a mutant, which is unable to perform the cleavage reaction, and developed an in vitro cleavage assay to test whether CPSF3 activity is necessary and sufficient to induce nascent mRNA cleavage. This project establishes tools to better understand how CPSF3 functions within the CPC and sheds light on the biology surrounding the transcription process as a whole.

Duchenne muscular dystrophy (DMD) is a lethal, X-linked disease which occurs in approximately 1 in 3,500 male births. This disease is characterized by progressive muscle wasting and causes premature death. One of the earliest symptoms of this disease is mitochondrial dysfunction. Dystrophin is a protein found under the sarcolemma. The N terminus binds to actin and the C terminus binds to dystrophin glycoprotein complex (DGC). DMD is caused by mutations in the dystrophin gene. C. elegans possess an ortholog of dystrophin, DYS-1. Though there is evidence that C. elegans can be used as a model organism to model DMD, nematode DGC has not been well characterized. Additionally, while we know that mitochondrial dysfunction has been found in humans and other model organisms, this has not been well defined in C. elegans. In order to address these issues, we crossed the SJ4103 worm strain (myo-3p::GFP(mit)) with dys-1(cx18) in order to visualize and quantify changes in mitochondria in a dys-1 background. SJ4103;cx18 nematodes were found to have less mitochondrial than SJ4103 which suggests mitochondrial dysfunction does occur in dys-1 worms. Furthermore, mitochondrial dysfunction was studied by knocking down members of the DGC, dys-1, dyb-1, sgn-1, sgca-1, and sgcb-1 in SJ4103 strain. Knock down of each gene resulted in decrease in abundance of mitochondria which suggests that each member of the DGC contributes to the overall health of nematode muscle. The ORF of dyb-1 was successfully cloned and tagged with GFP in order to visualize this DGC member C. elegans. Imaging of the transgenic dyb-1::GFP worm shows green fluoresce expressed in which suggests that dyb-1 is a functional component of the muscle fibers. This project will enable us to better understand the effects of dystrophin deficiency on mitochondrial function as well as visualize the expression of certain members of the DGC in order to establish C. elegans as a good model organism to study this disease.