Gene/Protein
Disease
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Enzyme
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Target Concepts:
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Query: UMLS:C0026850 (
muscular dystrophy
)
5,870
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Calpain I (
mu-calpain
) and II (m-calpain) are well known calcium-activated neutral cysteine proteases. Many reports have shown that activation of calpain is related to cataract formation, neuronal degeneration, blood clotting, ischemic injuries,
muscular dystrophy
and cornified cell envelope (CE) formation. Here, we report that insoluble CE formation was reduced after treatment with calpain I inhibitor (N-acetyl-leucyl-leucyl-norleucinal) on normal human epidermal keratinocytes (NHEK), whereas serine and thiol protease inhibitors had no effect on the reduction of CE. When NHEK cells were confluent, keratinocytes were treated with various concentrations (0.5 microM-0.5 mM) of calpain I inhibitor or serine and thiol protease inhibitors under calcium induced differentiation. Insoluble CE formation was reduced about 90% in the 50 microM calpain inhibitor I treated group by day 9 of culture, whereas insoluble CE was reduced only 10% in the same condition. Interestingly TGase activity was blocked by 90% in the 0.5 mM calpain inhibitor treated group within 72 h, whereas TGase activity was retained by 80% in the 0.5 mM serine protease inhibitor treated group at 7 day treatment. Therefore it can be suggested that cysteine protease calpains might be responsible for the activation of the TGase 1 enzyme to complete insoluble CE formation during epidermal differentiation.
...
PMID:Calpain inhibitors reduce the cornified cell envelope formation by inhibiting proteolytic processing of transglutaminase 1. 989 58
The overexpression of the cysteine protease calpain is associated with many diseases, including brain trauma, spinal cord injury, Alzheimer's disease, Parkinson's disease,
muscular dystrophy
, arthritis, and cataract. Calpastatin is the naturally occurring specific regulator of calpain activity. It has previously been reported that a 20-mer peptide truncated from region B of calpastatin inhibitory domain 1 (named CP1B) retains both the affinity and selectivity of calpastatin toward calpain, exhibiting a K(i) of 26 nM against
mu-calpain
, and is 1000-fold more selective for
mu-calpain
than cathepsin L. Both the wild-type and beta-Ala mutant CP1B peptides exhibit a propensity to adopt a looplike conformation between Glu10 and Lys13. A computational study of human wild-type CP1B and the beta-Ala mutants of this peptide was conducted. The resulting structural predictions were compared with the crystal structure of the calpain-calpastatin complex and were correlated with experimental IC(50) values. These findings suggest that the conformational preference of the loop region between Glu10 and Lys13 of CP1B in the absence of calpain may contribute to the inhibitory activity of this series of peptides against calpain.
...
PMID:Molecular modeling studies of peptide inhibitors highlight the importance of conformational prearrangement for inhibition of calpain. 2049 28
The contractile function of striated muscle cells is altered by oxidative/nitrosative stress, which can be observed under physiological conditions but also in diseases like heart failure or
muscular dystrophy
. Oxidative stress causes oxidative modifications of myofilament proteins and can impair myocyte contractility. Recent evidence also suggests an important effect of oxidative stress on muscle elasticity and passive stiffness via modifications of the giant protein titin. In this review we provide a short overview of known oxidative modifications in thin and thick filament proteins and then discuss in more detail those oxidative stress-related modifications altering titin stiffness directly or indirectly. Direct modifications of titin include reversible disulfide bonding within the cardiac-specific N2-Bus domain, which increases titin stiffness, and reversible S-glutathionylation of cryptic cysteines in immunoglobulin-like domains, which only takes place after the domains have unfolded and which reduces titin stiffness in cardiac and skeletal muscle. Indirect effects of oxidative stress on titin can occur via reversible modifications of protein kinase signalling pathways (especially the NO-cGMP-PKG axis), which alter the phosphorylation level of certain disordered titin domains and thereby modulate titin stiffness. Oxidative stress also activates proteases such as matrix-metalloproteinase-2 and (indirectly via increasing the intracellular calcium level)
calpain-1
, both of which cleave titin to irreversibly reduce titin-based stiffness. Although some of these mechanisms require confirmation in the in vivo setting, there is evidence that oxidative stress-related modifications of titin are relevant in the context of biomarker design and represent potential targets for therapeutic intervention in some forms of muscle and heart disease.
...
PMID:Emerging importance of oxidative stress in regulating striated muscle elasticity. 2537 78
The ubiquitous calpains,
calpain-1
and -2, play important roles in Ca
2+
-dependent membrane repair. Mechanically active tissues like skeletal muscle are particularly reliant on mechanisms to repair and remodel membrane injury, such as those caused by eccentric damage. We demonstrate that
calpain-1
and -2 are master effectors of Ca
2+
-dependent repair of mechanical plasma membrane scrape injuries, although they are dispensable for repair/removal of small wounds caused by pore-forming agents. Using CRISPR gene-edited human embryonic kidney 293 (HEK293) cell lines, we established that loss of both calpains-1 and -2 (
CAPNS1
-/-
) virtually ablates Ca
2+
-dependent repair of mechanical scrape injuries but does not affect injury or recovery from perforation by streptolysin-O or saponin. In contrast, cells with targeted knockout of either
calpain-1
(
CAPN1
-/-
) or -2 (
CAPN2
-/-
) show near-normal repair of mechanical injuries, inferring that both
calpain-1
and calpain-2 are equally capable of conducting the cascade of proteolytic cleavage events to reseal a membrane injury, including that of the known membrane repair agent dysferlin. A severe
muscular dystrophy
in a murine model with skeletal muscle knockout of
Capns1
highlights vital roles for
calpain-1
and/or -2 for health and viability of skeletal muscles not compensated for by calpain-3 (
CAPN3
). We propose that the dystrophic phenotype relates to loss of maintenance of plasma membrane/cytoskeletal networks by calpains-1 and -2 in response to directed and dysfunctional Ca
2+
-signaling, pathways hyperstimulated in the context of membrane injury. With
CAPN1
variants associated with spastic paraplegia, a severe dystrophy observed with muscle-specific loss of
calpain-1
and -2 activity identifies
CAPN2
and
CAPNS1
as plausible candidate neuromuscular disease genes.
...
PMID:Loss of calpains-1 and -2 prevents repair of plasma membrane scrape injuries, but not small pores, and induces a severe muscular dystrophy. 3234 80
