The calpain system originally comprised three molecules: two Ca2+-dependent proteases, mu-calpain and m-calpain, and a third polypeptide, calpastatin, whose only known function is to inhibit the two calpains. Both mu- and m-calpain are heterodimers containing an identical 28-kDa subunit and an 80-kDa subunit that shares 55-65% sequence homology between the two proteases. The crystallographic structure of m-calpain reveals six "domains" in the 80-kDa subunit: 1). a 19-amino acid NH2-terminal sequence; 2). and 3). two domains that constitute the active site, IIa and IIb; 4). domain III; 5). an 18-amino acid extended sequence linking domain III to domain IV; and 6). domain IV, which resembles the penta EF-hand family of polypeptides. The single calpastatin gene can produce eight or more calpastatin polypeptides ranging from 17 to 85 kDa by use of different promoters and alternative splicing events. The physiological significance of these different calpastatins is unclear, although all bind to three different places on the calpain molecule; binding to at least two of the sites is Ca2+ dependent. Since 1989, cDNA cloning has identified 12 additional mRNAs in mammals that encode polypeptides homologous to domains IIa and IIb of the 80-kDa subunit of mu- and m-calpain, and calpain-like mRNAs have been identified in other organisms. The molecules encoded by these mRNAs have not been isolated, so little is known about their properties. How calpain activity is regulated in cells is still unclear, but the calpains ostensibly participate in a variety of cellular processes including remodeling of cytoskeletal/membrane attachments, different signal transduction pathways, and apoptosis. Deregulated calpain activity following loss of Ca2+ homeostasis results in tissue damage in response to events such as myocardial infarcts, stroke, and brain trauma.

The Calpain System

Multiple sclerosis (MS) is an inflammatory-mediated demyelinating disease of the human central nervous system. The clinical disease course is variable, usually starts with reversible episodes of neurological disability in the third or fourth decade of life, and transforms into a disease of continuous and irreversible neurological decline by the sixth or seventh decade. We review data that support neurodegeneration as the major cause of irreversible neurological disability in MS patients. We question whether inflammatory demyelination is primary or secondary in the disease process and discuss the challenges of elucidating the cause of MS and developing therapies that will delay or prevent the irreversible and progressive neurological decline that most MS patients endure.

Multiple Sclerosis: An Immune or Neurodegenerative Disorder?

Calpains and caspases are two cysteine protease families that play important roles in regulating pathological cell death. Here, we report that m-calpain may be responsible for cleaving procaspase-12, a caspase localized in the ER, to generate active caspase-12. In addition, calpain may be responsible for cleaving the loop region in Bcl-xL and, therefore, turning an antiapoptotic molecule into a proapoptotic molecule. We propose that disturbance to intracellular calcium storage as a result of ischemic injury or amyloid beta peptide cytotoxicity may induce apoptosis through calpain- mediated caspase-12 activation and Bcl-xL inactivation. These data suggest a novel apoptotic pathway involving calcium-mediated calpain activation and cross-talks between calpain and caspase families.

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Cross-talk between two cysteine protease families. Activation of caspase-12 by calpain in apoptosis.

Spinal cord injury (SCI) is a devastating and common neurologic disorder that has profound influences on modern society from physical, psychosocial, and socioeconomic perspectives. Accordingly, the present decade has been labeled the Decade of the Spine to emphasize the importance of SCI and other spinal disorders. Spinal cord injury may be divided into both primary and secondary mechanisms of injury. The primary injury, in large part, determines a given patient's neurologic grade on admission and thereby is the strongest prognostic indicator. However, secondary mechanisms of injury can exacerbate damage and limit restorative processes, and hence, contribute to overall morbidity and mortality. A burgeoning body of evidence has facilitated our understanding of these secondary mechanisms of injury that are amenable to pharmacological interventions, unlike the primary injury itself. Secondary mechanisms of injury encompass an array of perturbances and include neurogenic shock, vascular insults such as hemorrhage and ischemia-reperfusion, excitotoxicity, calcium-mediated secondary injury and fluid-electrolyte disturbances, immunologic injury, apoptosis, disturbances in mitochondrion function, and other miscellaneous processes. Comprehension of secondary mechanisms of injury serves as a basis for the development and application of targeted pharmacological strategies to confer neuroprotection and restoration while mitigating ongoing neural injury. The first article in this series will comprehensively review the pathophysiology of SCI while emphasizing those mechanisms for which pharmacologic therapy has been developed, and the second article reviews the pharmacologic interventions for SCI.

/pdf/acute-spinal-cord-injury-part-i-pathophysiologic-mechanisms-1qib453h2b.pdf

Acute spinal cord injury, part I: pathophysiologic mechanisms.

Following an initial impact after spinal cord injury (SCI), there is a cascade of downstream events termed 'secondary injury', which culminate in progressive degenerative events in the spinal cord. These secondary injury mechanisms include, but are not limited to, ischemia, inflammation, free radical-induced cell death, glutamate excitotoxicity, cytoskeletal degradation and induction of extrinsic and intrinsic apoptotic pathways. There is emerging evidence that glutamate excitotoxicity plays a key role not only in neuronal cell death but also in delayed posttraumatic spinal cord white matter degeneration. Importantly however, the differences in cellular composition and expression of specific types of glutamate receptors in grey versus white matter require a compartmentalized approach to understand the mechanisms of secondary injury after SCI. This review examines mechanisms of secondary white matter injury with particular emphasis on glutamate excitotoxicity and the potential link of this mechanism to apoptosis. Recent studies have provided new insights into the mechanisms of glutamate release and its potential targets, as well as the downstream pathways associated with glutamate receptor activation in specific types of cells. Evidence from molecular and functional expression of glutamatergic AMPA receptors in white matter glia (and possibly axons), the protective effects of AMPA/kainate antagonists in posttraumatic white matter axonal function, and the vulnerability of oligodendrocytes to excitotoxic cell death suggest that glutamate excitotoxicity is associated with oligodendrocyte apoptosis. The latter mechanism appears key to glutamatergic white matter degeneration after SCI and may represent an attractive therapeutic target.

The role of excitotoxicity in secondary mechanisms of spinal cord injury: a review with an emphasis on the implications for white matter degeneration.

In autoimmune demyelinating diseases such as multiple sclerosis (MS), the degradation of myelin proteins results in destabilization of the myelin sheath. Thus, proteases have been implicated in myelin protein degradation, and recent studies have demonstrated increased expression and activity of a calcium-activated neutral proteinase (calpain) in experimental allergic encephalomyelitis, the corresponding animal model of MS. In the present study, calpain activity and expression (at translational and transcriptional levels) were evaluated in white matter from human patients with MS and Parkinson’s and Alzheimer’s diseases and compared with that of white matter from normal controls. Western blot analysis revealed that levels of the active form of calpain and calpain-specific degradation products (fodrin) were increased by 90.1% and 52.7%, respectively, in MS plaques compared with normal white matter. Calpain translational expression was up-regulated by 462.5% in MS plaques compared with controls, although levels of the specific endogenous inhibitor, calpastatin, were not altered significantly. At the transcriptional level, no significant changes in calpain or calpastatin expression were detected by reverse transcription–PCR. Using double immunofluorescent labeling, increased calpain expression was observed in reactive astrocytes, activated T cells, and activated mononuclear phagocytes in and adjacent to demyelinating lesions. Calpain activity and translational expression were not increased significantly in white matter from patients with Parkinson’s or Alzheimer’s diseases compared with that of normal controls. Because calpain degrades all major myelin proteins, the increased activity and expression of this proteinase may play a critical role in myelinolysis in autoimmune demyelinating diseases such as MS.

https://www.pnas.org/content/pnas/96/20/11486.full.pdf

A putative mechanism of demyelination in multiple sclerosis by a proteolytic enzyme, calpain.

In autoimmune demyelinating diseases such as multiple sclerosis (MS), the degradation of myelin proteins results in destabilization of the myelin sheath. Thus, proteases have been implicated in myelin protein degradation, and recent studies have demonstrated increased expression and activity of a calcium-activated neutral proteinase (calpain) in experimental allergic encephalomyelitis, the corresponding animal model of MS. In the present study, calpain activity and expression (at translational and transcriptional levels) were evaluated in white matter from human patients with MS and Parkinson's and Alzheimer's diseases and compared with that of white matter from normal controls. Western blot analysis revealed that levels of the active form of calpain and calpain- specific degradation products (fodrin) were increased by 90.1% and 52.7%, respectively, in MS plaques compared with normal white matter. Calpain translational expression was up-regulated by 462.5% in MS plaques compared with con- trols, although levels of the specific endogenous inhibitor, calpastatin, were not altered significantly. At the transcrip- tional level, no significant changes in calpain or calpastatin expression were detected by reverse transcription-PCR. Using double immunof luorescent labeling, increased calpain expres- sion was observed in reactive astrocytes, activated T cells, and activated mononuclear phagocytes in and adjacent to demy- elinating lesions. Calpain activity and translational expres- sion were not increased significantly in white matter from patients with Parkinson's or Alzheimer's diseases compared with that of normal controls. Because calpain degrades all major myelin proteins, the increased activity and expression of this proteinase may play a critical role in myelinolysis in autoimmune demyelinating diseases such as MS.

A putative mechanism of demyelination in multiple sclerosis by a proteolytic enzyme, calpain (calcium-activated neutral proteinaseyexperimental allergic encephalomyelitisycalpastatinyParkinson's diseaseyAlzheimer's disease)

In demyelinating diseases such as multiple sclerosis (MS), myelin membrane structure is destabilized as myelin proteins are lost. Calcium-activated neutral proteinase (calpain) is believed to participate in myelin protein degradation because known calpain substrates [myelin basic protein (MBP); myelin-associated glycoprotein] are degraded in this disease. In exploring the role of calpain in demyelinating diseases, we examined calpain expression in Lewis rats with acute experimental allergic encephalomyelitis (EAE), an animal model for MS. Using double-immunofluorescence labeling to identify cells expressing calpain, we labeled rat spinal cord sections for calpain with a polyclonal millicalpain antibody and with mAbs for glial (GFAP, OX42, GalC) and inflammatory (CD2, ED2, interferon γ) cell-specific markers. Calpain expression was increased in activated microglia (OX42) and infiltrating macrophages (ED2) compared with controls. Oligodendrocytes (galactocerebroside) and astrocytes (GFAP) had constitutive calpain expression in normal spinal cords whereas reactive astrocytes in spinal cords from animals with EAE exhibited markedly increased calpain levels compared with astrocytes in adjuvant controls. Oligodendrocytes in spinal cords from rats with EAE expressed increased calpain levels in some areas, but overall the increases in calpain expression were small. Most T cells in grade 4 EAE expressed low levels of calpain, but interferon γ-positive cells demonstrated markedly increased calpain expression. These findings suggest that increased levels of calpain in activated glial and inflammatory cells in EAE may contribute to myelin destruction in demyelinating diseases such as MS.

https://www.pnas.org/content/pnas/95/10/5768.full.pdf

Increased calpain expression in activated glial and inflammatory cells in experimental allergic encephalomyelitis

The demonstration of increased calpain activity, immunostaining, and expression at the gene (mRNA) and protein levels concomitant with ultrastructural degeneration and loss of axon and myelin proteins in lesioned cord have implicated a pivotal role for calpain in tissue destruction in spinal cord injury (SCI). Calpain, stimulated by free radicals, also mediates apoptotic cell death. These findings suggested that the use of calpain and lipid peroxidation drugs as therapeutic agents would protect cells and maintain the axon-myelin structural unit by preventing protein degradation. In order to examine this hypothesis, we treated SCI animals with calpain inhibitors (calpeptin) and/or methylprednisolone (MP), an antiinflammatory and free-radical inhibitor. SCI (40 g/cm) was induced by weight-drop, and 1 mg calpeptin or 165 mg MP/kg were given intravenously (i.v.) for 24 hours. Untreated injured animals receiving vehicle served as controls. Lesion 68-kDa and 200-kDa neurofilament proteins (NFPs) were analyzed by sodium dodecylsulfate polyarcylamide gel electrophoresis (SDS-PAGE) and chemiluminescence, and the extent of protein loss was quantitated. Loss of protein in the lesion of untreated cord amounted to 47% compared to sham control, while that for calpeptin- or MP-treated rats was 25-30%. Combination treatment with calpeptin and MP was slightly more effective in preventing NFP degradation, compared to either when used alone. Apopotic cell death in SCI as characterized by internucleosomal DNA fragmentation was also reduced following treatment with the inhibitors. The inhibition of cytoskeletal protein degradation suggests that calpain and free-radical inhibitors may rescue cells and preserve and maintain membrane structure by preventing protein breakdown, preserving motor function, and being neuroprotective.

Role of Calpain in Spinal Cord Injury: Effects of Calpain and Free Radical Inhibitorsa.

In demyelinating diseases such as multiple sclerosis (MS), myelin membrane structure is destabilized as myelin proteins are lost. Calcium-activated neutral proteinase (calpain) is believed to participate in myelin protein degra- dation because known calpain substrates (myelin basic pro- tein (MBP); myelin-associated glycoprotein) are degraded in this disease. In exploring the role of calpain in demyelinating diseases, we examined calpain expression in Lewis rats with acute experimental allergic encephalomyelitis (EAE), an an- imal model for MS. Using double-immunof luorescence label- ing to identify cells expressing calpain, we labeled rat spinal cord sections for calpain with a polyclonal millicalpain anti- body and with mAbs for glial (GFAP, OX42, GalC) and inf lammatory (CD2, ED2, interferon g) cell-specific markers. Calpain expression was increased in activated microglia (OX42) and infiltrating macrophages (ED2) compared with controls. Oligodendrocytes (galactocerebroside) and astro- cytes (GFAP) had constitutive calpain expression in normal spinal cords whereas reactive astrocytes in spinal cords from animals with EAE exhibited markedly increased calpain levels compared with astrocytes in adjuvant controls. Oligodendro- cytes in spinal cords from rats with EAE expressed increased calpain levels in some areas, but overall the increases in calpain expression were small. Most T cells in grade 4 EAE expressed low levels of calpain, but interferon g-positive cells demonstrated markedly increased calpain expression. These findings suggest that increased levels of calpain in activated glial and inf lammatory cells in EAE may contribute to myelin destruction in demyelinating diseases such as MS.

Increased calpain expression in activated glial and inflammatory cells in experimental allergic encephalomyelitis (multiple sclerosisycalcium-activated neutral proteinaseyneutral proteaseydemyelination)

Donald C. Shields

Papers

A putative mechanism of demyelination in multiple sclerosis by a proteolytic enzyme, calpain.

A putative mechanism of demyelination in multiple sclerosis by a proteolytic enzyme, calpain (calcium-activated neutral proteinaseyexperimental allergic encephalomyelitisycalpastatinyParkinson's diseaseyAlzheimer's disease)

Increased calpain expression in activated glial and inflammatory cells in experimental allergic encephalomyelitis

Role of Calpain in Spinal Cord Injury: Effects of Calpain and Free Radical Inhibitorsa.

Increased calpain expression in activated glial and inflammatory cells in experimental allergic encephalomyelitis (multiple sclerosisycalcium-activated neutral proteinaseyneutral proteaseydemyelination)