Cleavage of myelin basic protein by neutral protease activity of human white matter and myelin

Neuropsin promotes oligodendrocyte death, demyelination and axonal degeneration after spinal cord injury

Previous studies indicated that the expression of neuropsin, a serine protease, is induced in mature oligodendrocytes after injury to the CNS. The pathophysiology of spinal cord injury (SCI) involves primary and secondary mechanisms, the latter contributing further to permanent losses of function. To explore the role of neuropsin after SCI, histochemical and behavioral analyses were performed in wild-type (WT) and neuropsin-deficient (neuropsin(-/-)) mice using a crush injury model, a well-characterized and consistently reproducible model of SCI. In situ hybridization revealed that neuropsin mRNA expression was induced in the spinal cord white matter from WT mice after crush SCI, peaking at day 4. Neuropsin(-/-) mice showed attenuated demyelination, oligodendrocyte death, and axonal damage after SCI. Although axonal degeneration in the corticospinal tract was obvious caudal to the lesion site in both strains of mice after SCI, the number of surviving nerve fibers caudal to the lesion was significantly larger in neuropsin(-/-) mice than WT mice. Behavioral analysis revealed that the recovery at days 10-42 was significantly improved in neuropsin(-/-) mice compared with WT mice in spite of the severe initial hindlimb impairments due to SCI in both strains. These observations suggest that neuropsin is involved in the secondary phase of the pathogenesis of SCI mediated by demyelination, oligodendrocyte death, and axonal degeneration.

Involvement of neuropsin in the pathogenesis of experimental autoimmune encephalomyelitis

Inflammation, demyelination, and axonal damage of the central nervous system (CNS) are major pathological features of multiple sclerosis (MS). Proteolytic digestion of the blood-brain barrier and myelin protein by serine proteases is known to contribute to the development and progression of MS. Neuropsin, a serine protease, has a role in neuronal plasticity, and its expression has been shown to be upregulated in response to injury to the CNS. To determine the possible involvement of neuropsin in demyelinating diseases of the CNS, we examined its expression in myelin oligodendrocyte glycoprotein (MOG)-induced experimental autoimmune encephalomyelitis (EAE), a recognized animal model for MS. Neuropsin mRNA expression was induced in the spinal cord white matter of mice with EAE. Combined in situ hybridization and immunohistochemistry demonstrated that most of the cells expressing neuropsin mRNA showed immunoreactivity for CNPase, a cell-specific marker for oligodendrocytes. Mice lacking neuropsin (neuropsin-/-) exhibited an altered EAE progression characterized by delayed onset and progression of clinical symptoms as compared to wild-type mice. Neuropsin-/- mice also showed attenuated demyelination and delayed oligodendroglial death early during the course of EAE. These observations suggest that neuropsin is involved in the pathogenesis of EAE mediated by demyelination and oligodendroglial death.

Expression of Myelencephalon-Specific Protease after Cryogenic Lesioning of the Rat Parietal Cortex

The gene for myelencephalon-specific protease (MSP) is a member of the kallikrein gene family and in rats is expressed mainly in the central nervous system. Its function and alteration in brain injury have not yet been clarified. We examined the expression of MSP after cryogenic injury (CI) using in situ hybridization, immunohistochemistry, and Western blotting. Analysis of MSP mRNA by in situ hybridization revealed a higher level of expression around the cryogenic area than on the contralateral side at 2-7 days after CI, with peak expression occurring 7 days after CI. Immunohistochemical analysis demonstrated expression of MSP protein at 1 day after CI, in the same region in which MSP mRNA was observed, with peak expression again at 7 days after CI, in the area around the lesion. Double immunohistochemical labeling revealed that MSP was expressed mainly in oligodendrocytes. These results suggest that expression of MSP may be related to the turnover of myelin-associated proteins and extracellular matrix proteins after CI. The regulation of active MSP may be important in the physiological or pathological changes involved in remyelination or demyelination.

Differential expression of neuropsin and protease M/neurosin in oligodendrocytes after injury to the spinal cord

Neuropsin and protease M/neurosin are serine proteases expressed by neurons and glial cells, and serve a variety of functions in the central nervous system (CNS). The current study demonstrates changes in the expression of these proteases following hemisection of the mouse spinal cord. Within unlesioned spinal cord, neuropsin mRNA expression was occasionally observed in the gray but not white matter, while the level of protease M/neurosin mRNA was higher in the white matter. After injury to the spinal cord, neuropsin mRNA expression was induced in the white matter in the area immediately adjacent to the lesion, peaking at 4 days post-injury and disappearing by 14 days. Enhanced expression of protease M/neurosin mRNA was observed throughout the white and gray matter surrounding the lesion, peaking at 4 days and persisting for 14 days. Neuropsin mRNA was expressed predominantly by CNPase-positive oligodendrocytes. Furthermore, most of these cells were also associated with immunoreactivity for protease M/neurosin protein. Within unlesioned spinal cord, most protease M/neurosin mRNA-expressing cells were CNPase-positive oligodendrocytes, and a substantial fraction of these cells also showed immunoreactivity for NG2, a marker for oligodendrocyte progenitors. After injury, protease M/neurosin mRNA expression within NG2-positive cells was significantly decreased, while the constitutive expression in CNPase-positive oligodendrocytes appeared to be preserved. These findings suggest that each subpopulation of oligodendrocytes based on the expression of neuropsin and protease M/neurosin has different roles in the response of the spinal cord to injury as well as in normal homeostasis.

Expression of neuropsin in oligodendrocytes after injury to the CNS

Proteases are involved in a variety of processes including demyelination after injury to the central nervous system. Neuropsin is a serine protease, which is constitutively expressed in the neurons of the limbic system. In the present study, intrahippocampal kainate injection and enucleation were performed on adult mice. Neuropsin mRNA and protein expression was detected by in situ hybridization and immunohistochemistry. Double in situ hybridization confirmed that the mRNA expression was induced in oligodendrocytes. One day after kainate injection to the hippocampus, neuropsin mRNA was expressed, peaking 4-8 days postoperatively and disappearing at 14 days. Immunohistochemistry and immunoelectron microscopy revealed that neuropsin was expressed in the cell body of oligodendrocytes and myelin. To see if neuropsin degrades myelin protein, purified myelin was incubated with recombinant neuropsin. A decrease in the intensity of the bands of myelin basic protein was observed. These results indicate that neuropsin is involved in demyelination.

Protease M/neurosin mRNA is expressed in mature oligodendrocytes

No proteases have been identified to be oligodendrocyte-specific though there are phenomena in which proteases may be committed. We have cloned a cDNA for mouse homologue of protease M/neurosin, serine protease, and localized its mRNA in the mouse brain. The cDNA and the deduced amino acid sequences were 66% identical to those of human protease M/neurosin. In situ hybridization histochemistry revealed that the mRNA was localized in the mature oligodendrocytes which expressed proteolipid protein mRNA. Developmentally, protease M/neurosin mRNA was expressed by oligodendrocytes 2 to 7 days after the maturation. Thus, protease M/neurosin may be important to the processes occurring after the maturation of oligodendrocytes such as myelination or turnover of the proteins in the myelin.

Weak binding and removal of extrinsic proteinase activities of myelin membranes

The concurrent release of myelin basic protein (MBP) and extrinsic proteinases from isolated myelin membranes by aqueous solvents of high ionic strength is considered circumstantial evidence of a presumptive mutual interaction in situ. The joint release of proteins and proteinases from myelin membranes of bovine brain, depending on the ionic strength of aqueous solvents, was therefore examined; 25 mM Tris buffer released an average 1.4% of total myelin protein. It was attributable to about 25 different electrophoretic bands, but no apparent MBP. However, the extract potently mediated the limited proteolysis of added MBP at pH 4.0, 5.6, and 9.0. Because of the pH and the effects of specific inhibitors, proteolysis appears to be owing to activities of cathepsin B and D, and an alkaline metalloproteinase. The subsequent extraction of myelin membranes with buffered 300 mM NaCl released an additional 20% of total myelin protein, mainly MBP. The extracts, unlike those of untreated myelin membranes, no longer cleaved MBP at pH 5.6 and 9.0, and did so only slightly at pH 4.0. The results indicate that the bulk of soluble myelin-associated proteinases is much less tightly bound than MBP. The weak binding of the former and the prevalence of lysosomal cathepsin B- and D-like activities suggest that during their isolation, myelin membranes may adsorb soluble cellular proteins of tissue homogenates. At any rate the washing of myelin membranes with dilute buffer was found to largely remove soluble proteinase activities that are otherwise associated with salt-soluble MBP of myelin.

Detection of myelin basic protein isoforms by organic concentration

An effective technique was developed, which allowed rapid isolation of highly pure myelin basic protein (MBP) including its distinct isoforms. The procedure employs homogenization of central nervous system (CNS) tissue in chloroform, which specifically extracts MBP. Subsequently, methanol was used to convert the protein susceptible to quantitative transfer into the acidic aqueous phase. MBP was purified from bovine, chicken, fish, human, guinea-pig, mouse, rabbit, rat, and swine brains. Analysis on SDS-PAGE and immunoblotting using polyclonal MBP-specific serum recognized proteins corresponding to the sizes of previously identified MBP isoforms of 21.5, 18.5, 17.2, and 14.2 kDa and three predicted isoforms of 20.2, 16.0, and 13 kDa. The MBP obtained was readily soluble in water and possessed the capacity to induce experimental autoimmune encephalomyelitis in susceptible mice. The protein was also suitable for use as a substrate for protein kinases.

Myelin basic protein purified on an ion-exchange continuous polymer bed in the presence of ethylene glycol and salt possesses activity against p-nitrophenyl acetate

In this paper we describe a fast and mild method based on the use of a unique cation exchanger and buffers containing ethylene glycol and salt for the purification of the myelin basic protein (MBP; MW 18.5 kDa). MBP thus purified hydrolyses catalytically p-nitrophenyl acetate. This esterase activity facilitates not only the purification of MBP but also indicates that probably it is in its native state, i.e. there is a good chance that the purified molecules are structurally and chemically identical. This is a prerequisite to obtain crystals appropriate for x-ray diffraction and other studies.

Increased susceptibility to degradation by trypsin and subtilisin of in vitro peroxidized myelin proteins

We examined the possibility that the peroxidative damage to central nervous system myelin produced by reactive oxygen species (ROS), could modify the susceptibility of its proteins to the proteolytic action of proteases such as trypsin and subtilisin. Purified myelin membranes obtained from adult rat brains were "in vitro" peroxidized by two non-enzymatic systems: Fe3+ plus ascorbic acid and Cu2+ plus hydrogen peroxide. Myelin proteins were severely affected by peroxidation. There was an increase in the amount of carbonyl groups (CO), accompanied by an enhanced susceptibility to degradation by trypsin and subtilisin of myelin basic proteins (MBP) and of the major proteolipid protein (PLP). The effect upon the degradation of myelin protein is a possible consequence of the appearance in the structure of myelin proteins of peroxidative modifications that contribute to the recognition by proteolytic enzymes. This hypothesis is supported by the fact that if peroxidation of myelin membranes is done in the presence of EDTA, both CO formation and increased sensitivity to enzymatic breakdown disappear. These results suggest that the appearance of abnormal post-translational modifications in the myelin membrane produced by peroxidation could constitute a putative mechanism of modulating the capacity of myelin proteins to be metabolized by proteases.

Cleavage of the P0 glycoprotein of the rat peripheral nerve myelin: tentative identification of cleavage site and evidence for the precursor-product relationship

The incubation of sciatic nerve slices in Krebs Ringer bicarbonate (KRB) buffer (pH 7.4) at 37 degrees C, or the incubation of freshly isolated myelin in ammonium bicarbonate buffer (pH 8), resulted in the generation of a 24 kDa protein with a concomitant decrease of P0 protein. The conversion of P0 into 24 kDa protein was blocked by heating isolated myelin at 100 degrees C for 5 min suggesting that the reaction is enzyme mediated. Inclusion of the protease inhibitors and chelating agent to isolated myelin did not prevent the formation of 24 kDa protein. Similarly, addition of CaCl2 to isolated myelin did not accentuate the formation of 24 kDa protein suggesting that the conversion of P0 into 24 kDa protein may not be due to Ca2+ activated protease. It is postulated that the formation of 24 kDa protein may be due to neutral protease and/or metalloproteinase associated with the PNS myelin. 24 kDa protein was purified and characterized. The N-terminal sequence of 1-17 amino acid residues of 24 kDa protein was identical to P0. 24 kDa protein was immunostained and immunoprecipitated with anti-P0 antiserum indicating the immunological similarities between P0 and 24 kDa protein. Labeling of 24 kDa protein with [35S]methionine provided evidence that P0 may be in all probability cleaved between Met-168 and Met-193. Further studies were carried out to demonstrate that 24 kDa protein was phosphorylated, glycosylated and acylated like P0. Phosphorylation of 24 kDa protein in the nerve slices was increased five-fold by phorbol esters and phosphoserine was the only phosphoamino acid identified after partial acid hydrolysis of 24 kDa protein.(ABSTRACT TRUNCATED AT 250 WORDS)

An in vitro micromethod for the quantitative assessment of central demyelination

We report the development of a simple and reliable method for the study of demyelination in vitro based on the measurement of 2':3'-cyclic nucleotide 3'-phosphodiesterase in isolated myelin. Using only small quantities of myelin (equivalent to 100 micrograms of myelin protein) the system was tested under conditions that are believed to approximate those found at the site of an inflammatory demyelinating lesion. Treatment with a combination of trypsin, phospholipase A2, and lysophosphatidylcholine was used to evaluate the method. This microsystem has the potential not only for testing the myelinotoxicity of soluble factors but also for investigating the involvement of inflammatory cells in the demyelinating process. Myelin degradation by elicited peritoneal macrophages could be demonstrated at relatively high densities of these cells. Nylon wool purified lymph node T cells from myelin basic protein-primed SJL/J mice, after selective expansion with antigen and interleukin 2, failed to induce any significant myelin breakdown unless a limited number of syngeneic activated macrophages were also present. T cells from mice that had been inoculated with keyhole limpet haemocyanin failed to show any effect. The advantages of this technique over other in vitro systems are that it enables the study of demyelination using syngeneic sources of myelin and defined cell populations.

Soluble and bound acid protease activity of myelin from bovine cerebral white matter and spinal cord

Isolated myelin of bovine spinal cord was found to degrade exogenous myelin basic protein (MBP) at pH 4.4. Electrophoretic peptide patterns were consistent with limited proteolysis of MBP. Some of the proteolytic activity was soluble at increased ionic strength, some remained bound, withstanding extraction at 37 degrees C for up to 12 hr. While being measurable with exogenous MBP, bound protease degraded neither bound MBP nor any other major intrinsic myelin protein. Both soluble and bound protease activity was completely inhibited by pepstatin A. The patterns of limited proteolysis of MBP they produced were identical. Myelin of cerebral white matter also exhibited soluble and bound acid protease activity which was likewise inhibited by pepstatin A. Protease activity of spinal cord and cerebral myelin is therefore suggested to be due to a cathepsin D-like endopeptidase, present in a loosely and tightly bound form. Both forms increased by 50 to 80% in activity when myelin was isolated from mixtures of white and cortical gray matter. While increased soluble activity of myelin is consistent with binding of cathepsin D of lysosomal origin during the isolation of myelin the tightly bound form might point to a principal mechanism through which exogenous proteins may become attached to the myelin sheath in vivo.

Cation-mediated release and proteolytic cleavage of basic protein of isolated human myelin at acid pH

Myelin from human brain was incubated at pH 4.4 with metal salts, including KCl, NaCl, CaCl2, and MgSO4, to elicit cation-dependent autoproteolysis of myelin proteins. Incubation of myelin resulted in soluble proteolytic breakdown products of Mr smaller than those of the three original myelin basic proteins (MBPs). Comparable polypeptides were essentially absent from residual myelin. Proteolysis was strongly stimulated by increasing millimolar concentrations of K+, Na+, and Mg2+ and only moderately by Ca2+. Breakdown products were traced to MBP by immunostaining. Their origin from MBP was also indicated by identical electrophoretic cleavage patterns from endogenous myelin protein and exogenous MBP. All four metal salts, in addition to activating endogenous proteolysis, also caused a biphasic extraction of MBP. Electrophoresis of myelin revealed a quick initial and a slow further loss of protein, eventually leading to the removal of up to 78% of original MBP. The results are consistent with a concurrent extraction of MBP and activation of latent-bound acid protease activity by metal cations. It is therefore suggested that, in particular disease states, unfavorable changes in electrolytes and pH of white matter may cause a selective loss and proteolytic cleavage of MBP.

Calcium-dependent neutral protease activity of myelin from bovine spinal cord: evidence for soluble cleavage products of myelin proteins

Myelin basic protein (MBP) is degraded by a calcium-stimulated protease of myelin. An attempt was made to demonstrate soluble endopeptic cleavage products of this reaction. Myelin from bovine spinal cord was incubated at pH 7.5 with 5 mM CaCl2. Protein patterns were evaluated by quantitative polyacrylamide gel electrophoresis. A selective decrease in MBP of residual myelin was accompanied by trace amounts of insoluble cleavage products only. In contrast, the buffer media contained at least 3 distinct peptides of approximate Mr's between 8 and 11 kDa. They comprised approximately 70% of total soluble protein. There was a striking concentration-dependent effect of millimolar CaCl2 on the release of both undegraded MBP and proteolytic polypeptides along with a novel polypeptide of 15 kDa. The results suggest that calcium ions are strongly affecting the retention of loosely bound myelin protein.

A rapid method for purification of myelin basic protein

A rapid procedure for purification of myelin basic protein has been developed. White matter is delipidated with 2-butanol, and the residue is extracted at pH 7.5 and 8.5. Myelin basic protein is solubilized by extraction in acetate buffer, pH 4.5. The entire procedure requires less than 4 h, and gives homogeneous protein essentially free of protease activity. This procedure can be scaled down to process milligram amounts of white matter; thus it can be very useful for purification of myelin basic protein from very limited amounts of human white matter obtained during surgery.

Immunochemical evidence of phosphorylation of a new 23K basic protein in rat brain myelin

Myelin from developing rat brain (8-44 day-old rat) was incubated in vitro with [gamma-32P]ATP to determine how many basic proteins were phosphorylated. Myelin proteins were separated by polyacrylamide gel electrophoresis and transferred to nitrocellulose sheets. The nitrocellulose sheets were stained with antisera to human basic protein by the immunoblot technique. Five basic proteins with molecular weights of 23K, 21.5K, 18.5K, 17K, and 14K were distinctly immunostained. These basic proteins were found to be phosphorylated when the same nitrocellulose sheets were exposed to x-ray film. The in vitro phosphorylation of 23K and 21.5K basic proteins appear to decrease with maturation of the brain. The result of this study suggests that intense phosphorylation of various forms of basic proteins, in particular 23K and 21.5K basic proteins, during the initial stages of myelin formation, may play a pivotal role in the compaction of myelin membrane.

Complement potentiates the degradation of myelin proteins by plasmin: implications for a mechanism of inflammatory demyelination

A previous finding, that the basic protein in lyophilized bovine myelin was degraded by macrophage-conditioned media in the presence of plasminogen, suggested that the macrophage-secreted plasminogen activator, along with plasminogen, might have a role in destruction of myelin during inflammatory demyelination. To approximate more closely the conditions expected in vivo, plasmin, or macrophage supernatants plus plasminogen, were incubated with freshly homogenized bovine white matter or freshly isolated myelin, as distinguished from lyophilized myelin. Under these conditions basic protein was not degraded. Phospholipase or lysolecithin potentiated the degradation of basic protein in fresh bovine myelin by plasmin; however, the cultured macrophages did not secrete significant amounts of phospholipase and plasminogen activator simultaneously into the culture media after activation with any of several different agents. Recently myelin was shown to activate complement. After preincubation of fresh myelin with guinea pig serum, as a source of complement, the basic and proteolipid proteins were vulnerable to plasmin or to macrophage-conditioned media plus plasminogen. C3-depleted and C4-deficient sera were not effective, suggesting that these complement components were required for the serum effect. Hypothetically, then, degradation of myelin proteins in the CNS could be initiated by plasminogen activator, secreted by infiltrating macrophages, plus complement and plasminogen, which could enter the CNS through lesions in the blood-brain barrier.

Acid endopeptidase activity of human myelin, elicited by using exogenous myelin basic protein as enzyme substrate

Purified human myelin was incubated with exogenous myelin basic protein (MBP) at pH 4.0 to see if there is acid proteinase activity associated with myelin. Following incubation for 12 h up to 70% of MBP was degraded. On electrophoresis peptide fragments of MBP between 15.8 and 9.4 kDa were consistent with an endopeptic cleavage of MBP. Unlike the exogenous substrate MBP associated with myelin was only slightly degraded under the experimental conditions used. The results show that proteinase activity associated with isolated myelin may be elicited and further evaluated by using MBP as enzyme substrate.

Sequential limited proteolysis of myelin basic protein by neutral protease activities of bovine brain

Acid extracts of delipidated white matter of bovine brain were prepared, and their proteolytic activities toward myelin basic protein (MBP) were evaluated at pH 3 and pH 7. This was done by measuring changes in total protein using a selective dye-binding assay, and by evaluating peptide patterns by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and densitometry. At pH 7 greater than 50% of total protein and about 75% of MBP were degraded after 48 h, whereas at pH 3 it was less than 20% altogether. Neutral proteolysis of MBP entailed up to 12 different proteolytic peptide fragments in the molecular weight range of 17.5 to 6 kd. Its enzymatic nature was verified using protease inhibitors, including N-ethylmaleimide, phenylmethylsulfonyl fluoride, o-phenanthroline, and EDTA, as well as pepstatin A and alpha 2-macroglobulin. Both transient changes in percentages of some intermediate peptides and differential effects of individual inhibitors on electrophoretic peptide patterns strongly suggest a sequential type of limited proteolysis. The results also indicate that acid extracts contained several endopeptidases of which a cysteine protease appears to initiate the breakdown of MBP.

Elucidation of cathepsin B-like activity associated with extracts of human myelin basic protein

Myelin basic protein (MBP) extracted from human delipidated white matter was found to be degraded at pH 3.0 by endogenous proteolytic activities of extracts. Electrophoretic peptide patterns were consistent with limited proteolysis of MBP. Based on pH, activation by EDTA and DTE, and inhibition by p-CMPS, E-64 and, in particular, by leupeptin, the protease involved was tentatively identified as cathepsin B or a cathepsin B-like enzyme. As pepstatin failed to inhibit acid proteolysis of MBP cathepsin D was ruled out.