Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The proteins nCL-2 and nCL-2' are members of the Ca2+-dependent cysteine protease (calpain) superfamily, with stomach-specific expression. Like other typical calpains, nCL-2 has three distinct domains, a protease, a C2-like, and a 5EF-hand Ca2+-binding domain, as well as the N-terminal propeptide region. On the other hand, nCL-2' lacks the C2-like and 5EF-hand domains but is otherwise identical to nCL-2, except for the three C-terminal residues. To examine the stomach-specific and presumed alternative expression mechanisms of nCL-2 and nCL-2', we have cloned and characterized the mouse gene for nCL-2 and nCL-2'. The mouse nCL-2 gene contains at least 23 exons, spanning more than 50 kb, and possesses an exon specific for nCL-2' in the middle. Therefore, nCL-2 and nCL-2' are generated by alternative splicing of the same gene, Capn8. Capn8 shows the highly conserved gene organization of the other typical calpain large subunit genes, CAPN1, CAPN2, CAPN3, CAPN9, CAPN11, and Capn12, except for the unique exon between exon 9 and exon 10 of Capn8, which encodes the 3' half of the nCL-2' transcript. No such exon in the corresponding regions was found in CAPN1, CAPN2, CAPN3, CAPN9, or CAPN11. Gene and cDNA structures of a presumed human orthologue of mouse nCL-2, CAPN8, were determined, revealing that it overlaps human CAPN2, the gene for the m-calpain large subunit, in head-to-head orientation at 1q32-41. These features of Capn8 and CAPN8 illustrate a process of calpain gene evolution, i.e., the protease, C2-like, and 5EF-hand domains presumably functioned as independent genes, and the calpain superfamily has evolved by ordered fusions of these ancestral gene units, with subsequent amplifications.
J Mol Evol 2001 Sep
PMID:Both the conserved and the unique gene structure of stomach-specific calpains reveal processes of calpain gene evolution. 1152 6

The most studied members of the calpain protease superfamily are CAPN1 and 2, which are conserved across vertebrates. Another similar family member called mu/m-CAPN has been identified in birds alone. Here, we establish that mu/m-CAPN shares one-to-one orthology with CAPN11, previously described only in eutherians (placental mammals). We use the name CAPN11 for this family member and identify orthologues across vertebrate lineages, which form a monophyletic phylogenetic clade directly ancestral to CAPN1 and 2. In lineages branching before therians (live-bearing mammals), the CAPN11 coding region has evolved under strong purifying selection, with low nonsynonymous (d(N)) versus synonymous (d(S)) substitution rates (d(N)/d(S) = 0.076 across pretherians), and its transcripts were detected widely across different tissues. These characteristics are present in CAPN1 and 2 across vertebrate lineages and indicate that pretherian CAPN11 likewise has conserved a wide physiological function. However, an approximately 7-fold elevation in d(N)/d(S) is evident along the CAPN11 branch splitting eutherians from platypus, paralleled by a shift to "testis-specific" gene regulation. Estimates of d(N)/d(S) in eutherians were approximately 3-fold elevated compared with pretherians and coding and transcriptional-level evidence suggests that CAPN11 is functionally absent in marsupials. Many CAPN11 sites are functionally constrained in eutherians to conserve a residue with radically different biochemical properties to a fixed state shared between pretherian CAPN11 and CAPN1 and 2. Protein homology modeling demonstrated that many such eutherian-specific residue replacements modify or ablate interactions with the calpain inhibitor calpastatin that are observed in both pretherian orthologues and CAPN1/2. We propose a model akin to the Dykhuizen-Hartl effect, where inefficient purifying selection and increased genetic drift associated with a reduction in effective population size, drove the fixation of mutations in regulatory and coding regions of CAPN11 of a common marsupial-eutherian ancestor. A subset of these changes had a cumulative adaptive advantage in a eutherian ancestor because of lineage-specific aspects of sperm physiology, whereas in marsupials, no advantage was realized and the gene was disabled. This work supports that functional divergence among gene family member orthologues is possible in the absence of widespread positive selection.
Mol Biol Evol 2010 Aug
PMID:A newly classified vertebrate calpain protease, directly ancestral to CAPN1 and 2, episodically evolved a restricted physiological function in placental mammals. 2022 56