The calpain small subunit regulates cell-substrate mechanical interactions during fibroblast migration.

Cell migration involves the dynamic formation and release of cell-substrate adhesions, where the exertion and detection of mechanical forces take place. Members of the calpain family of calcium-dependent proteases are believed to have a central role in these processes, possibly through the regulation of focal adhesion dynamics. The ubiquitous calpains, calpain 1 (mu-calpain) and calpain 2 (m-calpain), are heterodimers consisting of large catalytic subunits encoded by the Capn1 and Capn2 genes, respectively, and the small regulatory subunit encoded by Capn4.

Genetic disruption of calpain correlates with loss of membrane blebbing and differential expression of RhoGDI-1, cofilin and tropomyosin.

Dynamic regulation of the actin cytoskeleton is important for cell motility, spreading and the formation of membrane surface extensions such as lamellipodia, ruffles and blebs. The ubiquitous calpains contribute to integrin-mediated cytoskeletal remodelling during cell migration and spreading, by cleavage of focal adhesion components and signalling molecules. In the present study, the live-cell morphology of calpain-knockout and wild-type cells was examined by time-lapse fluorescence microscopy, and a role of calpain in mediating the formation of sporadic membrane blebs was established.

Conditional disruption of ubiquitous calpains in the mouse.

Ubiquitous mu- and m-calpain proteases are implicated in development and apoptosis. They are heterodimers consisting of 80-kDa catalytic subunits encoded by capn1 and capn2, respectively, and a common 28-kDa regulatory subunit encoded by capn4. The regulatory subunit is required to maintain stability and activity of mu- and m-calpains; thus, genetic disruption of capn4 was predicted to eliminate both calpain activities.

Ubiquitous calpains promote caspase-12 and JNK activation during endoplasmic reticulum stress-induced apoptosis.

Ubiquitously expressed mu- and m-calpain proteases are implicated in development and apoptosis. They consist of 80-kDa catalytic subunits encoded by the capn1 and capn2 genes, respectively, and a common 28-kDa regulatory subunit encoded by the capn4 gene. The regulatory subunit is required to maintain the stability and activity of mu- and m-calpains.

m-Calpain is required for preimplantation embryonic development in mice.

Background: Mu-calpain and m-calpain are ubiquitously expressed proteases implicated in cellular migration, cell cycle progression, degenerative processes and cell death. These heterodimeric enzymes are composed of distinct catalytic subunits, encoded by Capn1 (mu-calpain) or Capn2 (m-calpain), and a common regulatory subunit encoded by Capn4. Disruption of the mouse Capn4 gene abolished both mu-calpain and m-calpain activity, and resulted in embryonic lethality, thereby suggesting essential roles for one or both of these enzymes during mammalian embryogenesis.

Activation of calpain by Ca2+: roles of the large subunit N-terminal and domain III-IV linker peptides.

The calpains are a family of cysteine proteases with closely related amino acid sequences, but a wide range of Ca(2+) requirements (K(d)). For m-calpain, K(d) is approximately 325microM, for mu-calpain it is approximately 50microM, and for calpain 3 it is not strictly known but may be approximately 0.1microM.

Expression of human, mouse, and rat m-calpains in Escherichia coli and in murine fibroblasts.

The two best known calpains, micro- and m-calpain, are Ca(2+)-dependent cysteine proteases found in all mammalian tissues. They are probably involved in many Ca(2+)-linked signal pathways, although the details are not yet clear. The enzymes are heterodimers of a specific large subunit (micro-80k or m-80k) and a common small subunit (28k).

Crystal structure of a micro-like calpain reveals a partially activated conformation with low Ca2+ requirement.

The two Ca2+-dependent cysteine proteases, micro- and m-calpain, are involved in various Ca2+-linked signal pathways but differ markedly in their Ca2+ requirements for activation. We have determined the structure of a micro-like calpain, which has 85% micro-calpain sequence (the first 48 and the last 62 residues of the large subunit are those from m-calpain) and a low Ca2+ requirement. This construct was used because micro-calpain itself is too poorly expressed.

A second binding site revealed by C-terminal truncation of calpain small subunit, a penta-EF-hand protein.

The subunits in calpain and in the related penta-EF-hand (PEF) proteins are bound through contacts between the unpaired EF-hand 5 from each subunit. To study subunit binding further, a tetra-EF-hand 18 kDa N- and C-terminally truncated form of the calpain small subunit was prepared (18k). This protein does not combine with the calpain large subunit to form active calpain, but forms homodimers in solution, as shown by ultracentrifugation.

Glutamate substitutions at a PKA consensus site are consistent with inactivation of calpain by phosphorylation.

Regulation of calpain by phosphorylation has often been suggested, but has proved difficult to detect. Calpains extracted from mammalian tissue are reported to contain 2-4 mol phosphate/mol of enzyme distributed over multiple sites, but phosphate groups are not detectable in the X-ray structures of recombinant calpain. Some serine and threonine residues in the large subunit of rat m-calpain were converted to aspartic or glutamic acid residues, at sites suggested by previous studies, to assess the probable effects of phosphate groups on the enzyme.

Calpains mediate p53 activation and neuronal death evoked by DNA damage.

DNA damage is an initiator of neuronal death implicated in neuropathological conditions such as stroke. Previous evidence has shown that apoptotic death of embryonic cortical neurons treated with the DNA damaging agent camptothecin is dependent upon the tumor suppressor p53, an upstream death mediator, and more distal death effectors such as caspases. We show here that the calcium-regulated cysteine proteases, calpains, are activated during DNA damage induced by camptothecin treatment.

Purification, crystallization and preliminary X-ray analysis of a mu-like calpain.

The X-ray structure of m-calpain in the absence of Ca(2+) has been described, but it has not been possible to obtain sufficient mu-calpain for structure determination. Comparison of the two structures is of interest in attempting to understand their different Ca(2+) requirements. Here, the crystallization in the absence of Ca(2+) of an inactive mutant hybrid calpain (MW approximately 100 kDa), which contains 85% of the rat mu-calpain sequence and is well expressed in Escherichia coli, is described.

Calpain is required for MMP-2 and u-PA expression in SV40 large T-antigen-immortalized cells.

The absence of both mu- and m-calpain activity, caused by disruption of the capn4 gene in mice, retarded migration, and disrupted the cytoskeleton, both in primary capn4(-/-) embryonic fibroblasts (mEF) and in capn4(-/-) mEF immortalized with SV40 large T-antigen (TAg). These results are thought to reflect the role of calpain in integrin signaling to the cytoskeleton. The integrins are also involved, together with matrix metalloproteinases (MMP) and plasminogen activators (PA), in cellular invasion.

Origins of the difference in Ca2+ requirement for activation of mu- and m-calpain.

The mu- and m-calpains are closely related Ca(2+)-dependent cysteine proteases having different in vitro Ca(2+) requirements ( K (d)), of approx. 25 and 325 microM respectively. The two isoforms are heterodimers of slightly different large (80 kDa) subunits and an identical small (28 kDa) subunit, so that the difference in K (d) values must reside in the large subunits.

A Ca(2+) switch aligns the active site of calpain.

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.

v-Src-induced modulation of the calpain-calpastatin proteolytic system regulates transformation.

v-Src-induced oncogenic transformation is characterized by alterations in cell morphology, adhesion, motility, survival, and proliferation. To further elucidate some of the signaling pathways downstream of v-Src that are responsible for the transformed cell phenotype, we have investigated the role that the calpain-calpastatin proteolytic system plays during oncogenic transformation induced by v-Src. We recently reported that v-Src-induced transformation of chicken embryo fibroblasts is accompanied by calpain-mediated proteolytic cleavage of the focal adhesion kinase (FAK) and disassembly of the focal adhesion complex.

Reduced cell migration and disruption of the actin cytoskeleton in calpain-deficient embryonic fibroblasts.

The physiological functions and substrates of the calcium-dependent protease calpain remain only partly understood. The mu- and m-calpains consist of a mu- or m-80-kDa large subunit (genes Capn1 and Capn2), and a common 28-kDa small subunit (Capn4). To assess the role of calpain in migration, we used fibroblasts obtained from Capn4(-/-) mouse embryos.

Dissociation and aggregation of calpain in the presence of calcium.

Calpain is a heterodimeric Ca(2+)-dependent cysteine protease consisting of a large (80 kDa) catalytic subunit and a small (28 kDa) regulatory subunit. The effects of Ca(2+) on the enzyme include activation, aggregation, and autolysis. They may also include subunit dissociation, which has been the subject of some debate.

Mutations in calpain 3 associated with limb girdle muscular dystrophy: analysis by molecular modeling and by mutation in m-calpain.

Limb-girdle muscular dystrophy type 2A (LGMD2A) is an autosomal recessive disorder characterized by selective atrophy of the proximal limb muscles. Its occurrence is correlated, in a large number of patients, with defects in the human CAPN3 gene, a gene that encodes the skeletal muscle-specific member of the calpain family, calpain 3 (or p94). Because calpain 3 is difficult to study due to its rapid autolysis, we have developed a molecular model of calpain 3 based on the recently reported crystal structures of m-calpain and on the high-sequence homology between p94 and m-calpain (47% sequence identity).

Ca(2+)-induced structural changes in rat m-calpain revealed by partial proteolysis.

Partial proteolysis by exogenous proteases in the presence and absence of Ca(2+) was used to map the protease-resistant domains in m-calpain, and to obtain evidence for the conformational changes induced in this thiol protease by Ca(2+). The complication of autoproteolysis was avoided by using the inactive Cys105Ser calpain mutant. Both trypsin and chymotrypsin produced similar cleavage patterns from the large subunit (domains I-IV), while the small subunit (domain VI) was largely unaffected.

Calpain mutants with increased Ca2+ sensitivity and implications for the role of the C(2)-like domain.

The ubiquitous calpain isoforms (mu- and m-calpain) are Ca(2+)-dependent cysteine proteases that require surprisingly high Ca(2+) concentrations for activation in vitro ( approximately 50 and approximately 300 microm, respectively). The molecular basis of such a high requirement for Ca(2+) in vitro is not known. In this study, we substantially reduced the concentration of Ca(2+) required for the activation of m-calpain in vitro through the specific disruption of interdomain interactions by structure-guided site-directed mutagenesis.

Disruption of the murine calpain small subunit gene, Capn4: calpain is essential for embryonic development but not for cell growth and division.

Calpains are a family of Ca(2+)-dependent intracellular cysteine proteases, including the ubiquitously expressed micro- and m-calpains. Both mu- and m-calpains are heterodimers, consisting of a distinct large 80-kDa catalytic subunit, encoded by the genes Capn1 and Capn2, and a common small 28-kDa regulatory subunit (Capn4). The physiological roles and possible functional distinctions of mu- and m-calpains remain unclear, but suggested functions include participation in cell division and migration, integrin-mediated signal transduction, apoptosis, and regulation of cellular control proteins such as cyclin D1 and p53.