Characterization of the definitive classical calpain family of vertebrates using phylogenetic,evolutionary and expression analyses

The calpains are a superfamily of proteases with extensive relevance to human health and welfare. Vast research attention is given to the vertebrate ‘classical’ subfamily, making it surprising that the evolutionary origins, distribution and relationships of these genes is poorly characterized. Consequently, there exists uncertainty about the conservation of gene family structure, function and expression that has been principally defined from work with mammals. Here, more than 200 vertebrate classical calpains were incorporated in phylogenetic analyses spanning an unprecedented range of taxa, including jawless and cartilaginous fish. We demonstrate that the common vertebrate ancestor had at least six classical calpains, including a single gene that gave rise to CAPN11, 1, 2 and 8 in the early jawed fish lineage, plus CAPN3, 9, 12, 13 and a novel calpain gene, hereafter named CAPN17. We reveal that while all vertebrate classical calpains have been subject to persistent purifying selection during evolution, the degree and nature of selective pressure has often been lineage-dependent. The tissue expression of the complete classic calpain family was assessed in representative teleost fish, amphibians, reptiles and mammals. This highlighted systematic divergence in expression across vertebrate taxa, with most classic calpain genes from fish and amphibians having more extensive tissue distribution than in amniotes. Our data suggest that classical calpain functions have frequently diverged during vertebrate evolution and challenge the ongoing value of the established system of classifying calpains by expression.     

Four genes for the calpain family locate on four distinct human chromosomes

Calcium dependent proteases (calpains, CAPNs, E.C.3.4.22.17) constitute a family of proteins which share a homologous cysteine-protease domain (large subunits, L1, L2, and L3) and an E-F hand Ca2(+)-binding domain (L1, L2, L3, and small subunit, S). We have mapped the genes for four calpain proteins (L1, L2, L3, and S) on four distinct human chromosomes by a combination of spot-blot hybridization to flow-sorted chromosomes and Southern hybridization of DNAs from a human x mouse hybrid cell panel. The genes for calpain L1 (CAPN1, large subunit of calpain I), L2 (CAPN2, large subunit of calpain II), L3 (CAPN3, a protein related to the large subunits), and S (CAPN4, a small subunit common to calpains I and II) were assigned to human chromosomes 11, 1, 15, and 19, respectively.     

Role of calpains in diabetes mellitus: a mini review

Type 2 diabetes mellitus (T2DM) is characterized by defects in haepatic glucose production, insulin action and insulin secretion, which can also lead to a variety of secondary disorders. The disease can lead to death without treatment and it has been predicted that T2DM will affect 215 million people world-wide by 2010. T2DM is a multifactorial condition whose precise genetic causes and biochemical defects have not been fully elucidated but at both levels, calpains appear to play a role. Positional cloning studies mapped T2DM susceptibility to CAPN10, the gene encoding the intracellular cysteine protease, calpain 10. Further studies have shown a number of non-coding polymorphisms in CAPN10 to be functionally associated with T2DM whilst the identification of coding polymorphisms, suggested that mutant calpain 10 proteins may also contribute to the disease. The presence of both calpain 10 and its mRNA have been demonstrated in tissues from several mammalian species whilst calpain 10 appears to be associated with pathways involved in glucose metabolism, insulin secretion and insulin action. It appears that other calpains may also participate in these pathways and here we present an overview of recent studies on calpains and their putative role in T2DM.     

Role of calpains in diabetes mellitus: A mini review

Type 2 diabetes mellitus (T2DM) is characterized by defects in haepatic glucose production, insulin action and insulin secretion, which can also lead to a variety of secondary disorders. The disease can lead to death without treatment and it has been predicted that T2DM will affect 215 million people world-wide by 2010. T2DM is a multifactorial condition whose precise genetic causes and biochemical defects have not been fully elucidated but at both levels, calpains appear to play a role. Positional cloning studies mapped T2DM susceptibility to CAPN10, the gene encoding the intracellular cysteine protease, calpain 10. Further studies have shown a number of non-coding polymorphisms in CAPN10 to be functionally associated with T2DM whilst the identification of coding polymorphisms, suggested that mutant calpain 10 proteins may also contribute to the disease. The presence of both calpain 10 and its mRNA have been demonstrated in tissues from several mammalian species whilst calpain 10 appears to be associated with pathways involved in glucose metabolism, insulin secretion and insulin action. It appears that other calpains may also participate in these pathways and here we present an overview of recent studies on calpains and their putative role in T2DM. (Mol Cell Biochem 261: 161–167, 2004)     

Calpain-related diseases

Calpains are calcium-modulated proteases which respond to Ca2+ signals by removing limited portions of protein substrates, thereby irreversibly modifying their function(s). Members of this protease family are present in a variety of organisms ranging from mammals to plants; some of them are ubiquitously expressed, while others are tissue specific. Although calpains are apparently involved in a multitude of physiological and pathological events, their functions are still poorly understood. In two cases, however, the alteration of a member of the calpain family has been clearly identified as being responsible for a human disease: the loss of function of calpain 3 causes limb girdle muscular dystrophy type 2A, and mutations in the gene coding for calpain 10 have been shown to correlate with non-insulin-dependent diabetes.     

Impact of genetic insights into calpain biology

Calpain has long been an enigmatic enzyme, although it is involved in a variety of biological phenomena. Recent progress in calpain genetics has highlighted numerous physiological contexts in which the functions of calpain are of great significance. This review focuses on recent findings in the field of calpain genetics and the importance of calpain function. Calpain is an intracellular Ca(2+)-dependent cysteine protease (EC 3.4.22.17; Clan CA, family C02) found in almost all eukaryotes. It is also present in a few bacteria, but not in archaebacteria. Calpain has limited proteolytic activity; rather, it transforms or modulates the structure and/or activity of its substrates. It is, therefore, referred to as a 'modulator protease'. Within the human genome, 15 genes (CAPN1-3, CAPN5-16) encode a calpain-like protease (CysPc) domain along with several different functional domains. Thus, calpains can be regarded as a distinct family of versatile enzymes that fulfil numerous tasks in vivo. Genetic studies show that a variety of defects in many different organisms, including lethality, muscular dystrophies and gastropathy, actually stem from calpain deficiencies. The cause-effect relationships identified by these studies form the basis for ongoing and future studies regarding the physiological role of calpains.     

The calpains: modular designs and functional diversity

The calpain family is named for the calcium dependence of the papain-like, thiol protease activity of the well-studied ubiquitous vertebrate enzymes calpain-1 (μ-calpain) and calpain-2 (m-calpain). Proteins showing sequence relatedness to the catalytic core domains of these enzymes are included in this ancient and diverse eukaryotic protein family. Calpains are examples of highly modular organization, with several varieties of amino-terminal or carboxy-terminal modules flanking a conserved core. Acquisition of the penta-EF-hand module involved in calcium binding (and the formation of heterodimers for some calpains) seems to be a relatively late event in calpain evolution. Several alternative mechanisms for binding calcium and associating with membranes/phospholipids are found throughout the family. The gene family is expanded in mammals, trypanosomes and ciliates, with up to 26 members in Tetrahymena, for example; in striking contrast to this, only a single calpain gene is present in many other protozoa and in plants. The many isoforms of calpain and their multiple splice variants complicate the discussion and analysis of the family, and challenge researchers to ascertain the relationships between calpain gene sequences, protein isoforms and their distinct or overlapping functions. In mammals and plants it is clear that a calpain plays an essential role in development. There is increasing evidence that ubiquitous calpains participate in a variety of signal transduction pathways and function in important cellular processes of life and death. In contrast to relatively promiscuous degradative proteases, calpains cleave only a restricted set of protein substrates and use complex substrate-recognition mechanisms, involving primary and secondary structural features of target proteins. The detailed physiological significance of both proteolytically active calpains and those lacking key catalytic residues requires further study.     

CAPN 8: isolation of a new mouse calpain-isoenzyme.

Recent molecular biological approaches indicate that calpain, also named CANP for calcium-activated neutral protease and originally characterized as an intracellular cytoplasmatic nonlysosomal cysteine protease that requires calcium ions for activity, constitutes a large superfamily consisting of ubiquitous and tissue specific homologues, which are widely distributed in cells of various organisms from human to fungus. Due to the increasing number of substrates along with the involvement of calpain isoenzymes in mammalian diseases, especially in malignancies, members of the calpain superfamily seem to be important biomodulators in physiological as well as pathological cell function. Here we report the characterisation of a new calpain, named CAPN 8 with a different C-terminal domain, implicating a putative new regulatory mechanism. Northern blot analysis revealed an ubiquitous expression with different RNA levels in all tissues examined. Highest levels were found in brain, kidney, and digestive tract, suggesting a specific regulatory function of CAPN 8 in these tissues.     

Targeted suppression of μ‐calpain and caspase 9 expression and its effect on caspase 3 and caspase 7 in satellite cells of Korean Hanwoo cattle

The calpains play an important role in cell death and cell signalling. Caspases catalyse wholesale destruction of cellular proteins which is a major cause of cellular death. The current study looks at the function of μ‐calpain and caspase 9, using RNAi (RNA interference)‐mediated silencing, and to observe the mRNA expression level of caspase genes during satellite cell growth. The satellite cells were treated with siRNA (small interfering RNA) of μ‐calpain and caspase 9 separately. There was reduction of 16 and 24% in CAPN1 (calpain1)‐siRNA2 and CAPN1‐siRNA3 transfected cells respectively, whereas it was 60 and 56% in CAPN1‐siRNA1 and CAPN1‐siRNA4 transfected cells respectively. CAPN1‐siRNA4 and CAPN1‐siRNA1 treated cells showed more reduction in caspase 3 and 7 gene expression. CARD9 (caspase recruitment domain 9)‐siRNA1 and CARD9‐siRNA2‐treated cells showed reduction of 40 and 49% respectively. CARD9‐siRNA1 and CARD9‐siRNA2 showed an increase in caspase 3 gene expression, whereas CARD9‐siRNA2 showed reduction in caspase 7 gene expression. These results suggest a strong cross‐talk between μ‐calpain and the caspase enzyme systems. Suppression of target genes, such as μ‐calpain and caspase 9, might have genuine potential in the treatment of skeletal muscle atrophy.     

Calpains: an elaborate proteolytic system

Calpain is an intracellular Ca(2+)-dependent cysteine protease (EC 3.4.22.17; Clan CA, family C02). Recent expansion of sequence data across the species definitively shows that calpain has been present throughout evolution; calpains are found in almost all eukaryotes and some bacteria, but not in archaebacteria. Fifteen genes within the human genome encode a calpain-like protease domain. Interestingly, some human calpains, particularly those with non-classical domain structures, are very similar to calpain homologs identified in evolutionarily distant organisms. Three-dimensional structural analyses have helped to identify calpain's unique mechanism of activation; the calpain protease domain comprises two core domains that fuse to form a functional protease only when bound to Ca(2+)via well-conserved amino acids. This finding highlights the mechanistic characteristics shared by the numerous calpain homologs, despite the fact that they have divergent domain structures. In other words, calpains function through the same mechanism but are regulated independently. This article reviews the recent progress in calpain research, focusing on those studies that have helped to elucidate its mechanism of action. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

Calpain对细胞骨架蛋白tau降解作用的研究(英文)

Calpain是钙依赖性中性蛋白酶 ,根据其对钙敏感性的不同 ,可分为m 和 μ calpain两型 .分别用不同浓度CaCl2 溶液孵育Wistar大鼠脑皮质匀浆液 ,并用蛋白质印迹和定量图像分析技术检测不同亚型calpain对tau蛋白的降解作用 .研究发现 :在 3 7℃用 1mmol/LCa2 孵育底物 15min ,可见tau蛋白明显降解 ,并在分子质量为 2 9ku处出现tau蛋白降解片段 ;当Ca2 浓度为 5mmol/L时 ,tau蛋白几乎全部被降解 ;这种tau蛋白降解可被calpain特异性抑制剂完全逆转 .进一步的研究发现 ,分别用 μ calpain抑制剂 (0 0 5μmol/Lcalpastatin) ,m calpain抑制剂 (10 0 μmol/LcalpaininhibitorⅣ )或总calpain抑制剂 (552 μmol/Lcalpeptin)与 1mmol/LCa2 共同孵育Wistar大鼠脑皮质匀浆液 ,Ca2 激活的tau蛋白降解分别被抑制8 6% ,92 5%和 97 8% .结果表明一定浓度的Ca2 可同时激活 μ calpain和m calpain ,这两种亚型calpain均参与降解tau蛋白 ,但m calpain的作用比 μ calpain更强     

Molecular cloning and RNA expression of a novel Drosophila calpain,Calpain C

The calpains are Ca(2+)-activated cysteine proteases whose biochemical properties have been extensively characterized in vitro. Less is known, however, about the physiological role of calpains. In this respect, Drosophila melanogaster is a useful experimental organism to study calpain activity and regulation in vivo. The sequencing of the fly genome has been recently completed and a novel calpain homologue has been identified in the CG3692 gene product. We embarked on the cloning and characterization of this putative novel calpain. We demonstrate that the actual calpain is different from the predicted protein and we provide experimental evidence for the correction of the genomic annotation. This novel protein, Calpain C, must be catalytically inactive, having mutated active site residues but is otherwise structurally similar to the other known fly calpains. Moreover, we analysed Calpain C RNA expression during Drosophila development by RT-PCR and RNA in situ hybridization, which revealed strong expression in the salivary glands.     

Changes in calpain and caspase gene expression at the mRNA level during bovine muscle satellite cell myogenesis and the correlation between the cell model and the muscle tissue

The calpain proteolytic system plays a central role in cell death and cell signaling. Caspases are a family of proteases implicated in apoptosis. The objective of this study was to explore the regulation and change trend of calpains (CAPN1 and CAPN3) and caspases (caspase-3, caspase-7, and caspase-9) expression at the mRNA level in Luxi cattle skeletal muscle satellite cells during proliferation and differentiation into myotubes. We also sought to assess whether there is a relationship between the muscle satellite cell model and skeletal muscle tissue. Satellite cells were isolated from longissimus dorsi muscle from Luxi cattle and cultured in vitro. Immunofluorescence was used to characterize satellite cells. Our study was divided into three groups: stage one, satellite cells proliferated at 50- and 80-% confluence; stage two, satellite cells differentiated at days 1, 3, 5, 7, and 15; stage three, not the satellite cells but the skeletal muscle tissue. Real-time PCR was used to quantify expression of calpains and the caspases at the mRNA level. These data demonstrated that CAPN1, CAPN3, CASP7, Myf5, and MyoG gene expression significantly increased from satellite cell proliferation to differentiation phases (P < 0.05). In contrast, CASP3 and CASP9 gene expression was significantly down-regulated during myogenesis (P < 0.05). Moreover, we put the CAPN1, CAPN3, CASP3, CASP7, CASP9, Myf5, and MyoG together to say that these genes expression had no significant correlation between the satellite cell model and the skeletal muscle tissue (P > 0.05). Here, we conclude that calpains (CAPN1 and CAPN3), caspases (caspase-3, caspase-7, and caspase-9), and Myf5 and MyoG all have important roles in satellite cell myogenesis. However, there is no relationship between the cell model and muscle tissue.     

牦牛CAPN1基因的克隆与序列分析

CAPN1是影响肌肉嫩度的数量性状位点 (QTL)的候选基因。根据GenBank发表的普通牛CAPN1基因序列设计特异性引物,以天祝白牦牛cDNA为模板,分段进行PCR扩增,克隆,测序。应用生物软件BioEdit对各测序结果进行序列拼接共获得牦牛CAPN1 cDNA 片段2267bp,其中包含一个2151bp的完整的开放阅读框(ORF),以及3’和5’末端非编码区的部分序列(77bp和166bp) 。分析表明：牦牛CAPN1基因编码区全长2151bp,共编码716个氨基酸。与已报道的牛,猪,人小鼠的序列进行比较,核苷酸同源性分别为99.3%,93.9%,90.0% ,85.5% 。预测氨基酸的同源性分别为99.4%,96.1%,94.6%,89.0%,并且对牦牛CAPN1四个结构域分别进行NCBI BLAST发现四个结构域在以上四个物种中都显示出很好的保守性,最为保守的在结构域Ⅳ(>96%)。牦牛与牛产生的 14个核苷酸突变中,有3个产生了氨基酸突变,均发生在结构域Ⅲ。构建分子系统进化树表明：聚类结果与传统分类学相符。     

Calpains — An elaborate proteolytic system

Calpain is an intracellular Ca²⁺-dependent cysteine protease (EC 3.4.22.17; Clan CA, family C02). Recent expansion of sequence data across the species definitively shows that calpain has been present throughout evolution; calpains are found in almost all eukaryotes and some bacteria, but not in archaebacteria. Fifteen genes within the human genome encode a calpain-like protease domain. Interestingly, some human calpains, particularly those with non-classical domain structures, are very similar to calpain homologs identified in evolutionarily distant organisms. Three-dimensional structural analyses have helped to identify calpain's unique mechanism of activation; the calpain protease domain comprises two core domains that fuse to form a functional protease only when bound to Ca²⁺via well-conserved amino acids. This finding highlights the mechanistic characteristics shared by the numerous calpain homologs, despite the fact that they have divergent domain structures. In other words, calpains function through the same mechanism but are regulated independently. This article reviews the recent progress in calpain research, focusing on those studies that have helped to elucidate its mechanism of action. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.     

Epistasis between calpain 1 and its inhibitor calpastatin within breeds of cattle

The calpain gene family and its inhibitors have diverse effects, many related to protein turnover, which appear to affect a range of phenotypes such as diabetes, exercise-induced muscle injury, and pathological events associated with degenerative neural diseases in humans, fertility, longevity, and postmortem effects on meat tenderness in livestock species. The calpains are inhibited by calpastatin, which binds directly to calpain. Here we report the direct measurement of epistatic interactions of causative mutations for quantitative trait loci (QTL) at calpain 1 (CAPN1), located on chromosome 29, with causative mutations for QTL variation at calpastatin (CAST), located on chromosome 7, in cattle. First we identified potential causative mutations at CAST and then genotyped these along with putative causative mutations at CAPN1 in >1500 cattle of seven breeds. The maximum allele substitution effect on the phenotype of the CAPN1:c.947G>C single nucleotide polymorphism (SNP) was 0.14 sigma(p) (P = 0.0003) and of the CAST:c.155C>T SNP was also 0.14 sigma(p) (P = 0.0011) when measured across breeds. We found significant epistasis between SNPs at CAPN1 and CAST in both taurine and zebu derived breeds. There were more additive x dominance components of epistasis than additive x additive and dominance x dominance components combined. A minority of breed comparisons did not show epistasis, suggesting that genetic variation at other genes may influence the degree of epistasis found in this system.     

Sidekicks: synaptic adhesion molecules that promote lamina-specific connectivity in the retina

Ca(2+) signaling by calpains leads to controlled proteolysis during processes ranging from cytoskeleton remodeling in mammals to sex determination in nematodes. Deregulated Ca(2+) levels result in aberrant proteolysis by calpains, which contributes to tissue damage in heart and brain ischemias as well as neurodegeneration in Alzheimer's disease. Here we show that activation of the protease core of mu calpain requires cooperative binding of two Ca(2+) atoms at two non-EF-hand sites revealed in the 2.1 A crystal structure. Conservation of the Ca(2+) binding residues defines an ancestral general mechanism of activation for most calpain isoforms, including some that lack EF-hand domains. The protease region is not affected by the endogenous inhibitor, calpastatin, and may contribute to calpain-mediated pathologies when the core is released by autoproteolysis.     

The crystal structures of human calpains 1 and 9 imply diverse mechanisms of action and auto-inhibition

Calpains are calcium activated cysteine proteases found throughout the animal, plant, and fungi kingdoms; 14 isoforms have been described in the human genome. Calpains have been implicated in multiple models of human disease; for instance, calpain 1 is activated in the brains of individuals with Alzheimer's disease, and the digestive tract specific calpain 9 is down-regulated in gastric cancer cell lines. We have solved the structures of human calpain 1 and calpain 9 protease cores using crystallographic methods; both structures have clear implications for the function of non-catalytic domains of full-length calpains in the calcium-mediated activation of the enzyme. The structure of minicalpain 1 is similar to previously solved structures of the protease core. Auto-inhibition in this system is most likely through rearrangements of a central helical/loop region near the active site cysteine, which occlude the substrate binding site. However, the structure of minicalpain 9 indicates that auto-inhibition in this enzyme is mediated through large intra-domain movements that misalign the catalytic triad. This disruption is reminiscent of the full-length inactive calpain conformation. The structures of the highly conserved, ubiquitously expressed human calpain 1 and the more tissue specific human calpain 9 indicate that although there are high levels of sequence conservation throughout the calpain family, isolated structures of family members are insufficient to explain the molecular mechanism of activation for this group of proteins.