Characterization of calpain 3 transcripts in mammalian cells : expression of alternatively-spliced variants in non-muscle cell types

Abstract

An investigation of the expression profile of mRNA encoding Calpain 3, the causative agent in the inherited human muscular disease Limb Girdle Muscular Dystrophy Type 2A, was conducted in two representative mammalian species, human and mouse. Transcripts encoding Calpain 3 were identified from mammalian tissues other than skeletal muscle. In human Peripheral Blood Mononuclear Cells (PBMCs) these transcripts were identified in both the T-cell and B-cell compartments and in a number of human blood cell lines representing different haematopoietic lineages. Calpain 3 transcripts encoding the murine homologue were also described from mouse PBMCs and from murine tissues involved in haematopoiesis. In addition to the confirmation of Calpain 3 expression in non-skeletal muscle tissues in both these species, transcripts were identified with precise and defined deletions, which mapped to known exon-exon boundaries in the Calpain 3 gene from both species. These deletions constituted the removal by alternative splicing of skeletal muscle-specific components of the Calpain 3 protein known to regulate its function in this tissue.

Monoclonal antibodies to the Calpain 3 protein were used to confirm the presence of Calpain 3 protein in non-skeletal muscle tissues of both human and mouse. In humans the expression of Calpain 3 protein was confirmed in PBMCs and in the mouse, Calpain 3 expression was confirmed in tissues of the haematopoietic compartment. In both species the Calpain 3 protein expressed correlated with translation from a transcript lacking the skeletal muscle-specific components generated by alternative splicing. An attempt was made using a Yeast Two Hybrid assay to identify potential regulatory molecules of Calpain 3 in human PBMCs, but without a definitive candidate molecule being found.

A developmental model of muscle differentiation (murine C2C12 myoblast cells) was used to ascertain the expression profile of Calpain 3 in the early stages of myofibrillogenesis. Using Quantitative Real Time PCR the expression profile of Calpain 3 was assessed in differentiating C2C12 cells. These results showed that the absolute levels of Calpain 3 transcription were elevated during differentiation and that a temporal Calpain 3 isoform shift occurred during this process. This temporal shift in expression was from transcripts having identical deletions to those seen in the haematopoietic tissues, to full length transcripts representative of skeletal muscle-specific Calpain 3. The identification of Calpain 3 expression outside skeletal muscle tissue is novel and the isoforms expressed in these tissues are structurally more analogous to the ubiquitously expressed calpains. This has implications for LGMD2A where a loss of function of Calpain 3 in non-skeletal muscle tissue could be compensated for by the ubiquitous calpains, thus explaining the lack of any non-muscle tissue pathology in LGMD2A patients.