Calcium-activated neutral proteinase (calpain) in rat brain during development: compartmentation and role in myelination

Functions and distribution of calpain-calpastatin system components in brain during mammal ontogeny

Calpain and calpastatin are the key components of the calcium-dependent proteolytic system. Calpains are regulatory, calcium-dependent, cytoplasmic proteinases, and calpastatin is the endogenous inhibitor of calpains. Due to the correlation between changes in the activity of the calpain-calpastatin system in the brain and central nervous system (CNS) pathology states, this proteolytic system is a prime focus of research on CNS pathological processes, generally characterized by calpain activity upregulation. The present review aims to generalize existing data on cerebral calpain distribution and function through mammalian ontogenesis. Special attention is given to the most recent studies on the topic as more information on calpain-calpastatin system involvement in normal CNS development and functioning has become available. We also discuss data on calpain and calpastatin activity and production in different brain regions during ontogenesis as comparative analysis of these results in association with ontogeny processes can reveal brain regions and developmental stages with pronounced function of the calpain system.

Distinct Changes in Calpain and Calpastatin during PNS Myelination and Demyelination in Rodent Models

Myelin forming around axons provides electrical insulation and ensures rapid and efficient transmission of electrical impulses. Disruptions to myelinated nerves often result in nerve conduction failure along with neurological symptoms and long-term disability. In the central nervous system, calpains, a family of calcium dependent cysteine proteases, have been shown to have a role in developmental myelination and in demyelinating diseases. The roles of calpains in myelination and demyelination in the peripheral nervous system remain unclear. Here, we show a transient increase of activated CAPN1, a major calpain isoform, in postnatal rat sciatic nerves when myelin is actively formed. Expression of the endogenous calpain inhibitor, calpastatin, showed a steady decrease throughout the period of peripheral nerve development. In the sciatic nerves of Trembler-J mice characterized by dysmyelination, expression levels of CAPN1 and calpastatin and calpain activity were significantly increased. In lysolecithin-induced acute demyelination in adult rat sciatic nerves, we show an increase of CAPN1 and decrease of calpastatin expression. These changes in the calpain-calpastatin system are distinct from those during central nervous system development or in acute axonal degeneration in peripheral nerves. Our results suggest that the calpain-calpastatin system has putative roles in myelination and demyelinating diseases of peripheral nerves.

Calpain 1 and Calpastatin expression is developmentally regulated in rat brain

Calpains and caspases are cysteine endopeptidases which share many similar substrates. Caspases are essential for caspase-dependent apoptotic death where calpains may play an augmentive role, while calpains are strongly implicated in necrotic cell death morphologies. Previous studies have demonstrated a down-regulation in the expression of many components of the caspase-dependent cell death pathway during CNS development. We therefore sought to determine if there is a corresponding upregulation of calpains. The major CNS calpains are the mu-and m-isoforms, composed of the unique 80 kDa calpain 1 and 2 subunits, respectively, and the shared 28 kDa small subunit. In rat brain, relative protein and mRNA levels of calpain 1, calpain 2, caspase 3, and the endogenous calpain inhibitor-calpastatin, were evaluated using western blot and real-time RT-PCR. The developmental time points examined ranged from embryonic day 18 until postnatal day 90. Calpain 1 and calpastatin protein and mRNA levels were low at early developmental time points and increased dramatically by P30. Conversely, caspase-3 expression was greatest at E18, and was rapidly downregulated by P30. Calpain 2 protein and mRNA levels were relatively constant throughout the E18-P90 age range examined. The inverse relationship of calpain 1 and caspase 3 levels during CNS development is consistent with the shift from caspase-dependent to caspase-independent cell death mechanisms following CNS injury in neonatal vs. adult rat brain.

Alpha-II-spectrin after controlled cortical impact in the immature rat brain

Proteolytic processing plays an important role in regulating a wide range of important cellular functions, including processing of cytoskeletal proteins. Loss of cytoskeletal proteins such as spectrin is an important characteristic in a variety of acute central nervous system injuries including ischemia, spinal cord injury and traumatic brain injury (TBI). The literature contains extensive information on the proteolytic degradation of alpha-II-spectrin after TBI in the adult brain. By contrast, there is limited knowledge on the characteristics and relevance of these important processes in the immature brain. The present experiments examine TBI-induced proteolytic processing of alpha-II-spectrin after TBI in the immature rat brain. Distinct proteolytic products resulting from the degradation of the cytoskeletal protein alpha-II-spectrin by calpain and caspase 3 were readily detectable in cortical brain parenchyma and cerebrospinal fluid after TBI in immature rats.

Histo-clinical variation in multiple sclerosis: Heterogeneous proteolytic immunogenic processing

Multiple sclerosis (MS) presents an incredible histo-clinical variation. It consists of an unpredictable series of relapses, remissions and stationary phases. The initial symptoms vary considerably. Any hypothesis of the pathology of MS must include an explanation of this oddity. Current theory suggests that MS is a collection of diseases which produce generally the same result. However, this is not a satisfactory explanation. MS appears as an enormous continuum of disease paths rather than a finite group of well-defined courses. A hypothesis is presented that histo-clinical variation in MS is due to variable proteolytic processing of several potential immunogens. MS is generally thought to be caused by an autoimmune attack on myelin components. Several myelin proteins, myelin basic protein, lipoprotein, oligodendrocyte related glycoprotein and oligodendrocyte basic protein, are encephalitogenic. Within these proteins are short sequences, which themselves are encephalitogenic. In order for potential immunogens to be "seen" by the immune system they first must be processed. This processing is performed by intracellular and extracellular proteases. A large number of different proteases are located throughout the central nervous system. Their concentrations vary with location and time. Most are under strict control. While myelin has a consistent structure, the action of proteases can present variable concentrations of immunogenic peptides. Because of the differences in location, concentration and control of the central nervous system's (CNS) proteases, the same potential immunogen could be presented to the immune system in different locations within the CNS at different times. At a given time and location, the immune system may be presented with no potential immunogens, one potential immunogen or possibly many immunogens. Therefore, because of the dynamic characteristic of presentation, one would expect to see the initial MS symptoms to be variable. This variability would be continued with subsequent symptoms. This is what is seen in multiple sclerosis. A procedure for testing this hypothesis is presented.

Developmental regulation of tissue transglutaminase in the mouse forebrain

Tissue transglutaminase (tTG) is a multifunctional enzyme that catalyzes both transamidation and GTPase reactions. In cell culture models tTG-mediated transamidation positively regulates many processes that occur in vivo during the mammalian brain growth spurt (BGS), including neuronal differentiation, neurite outgrowth, synaptogenesis and cell death mechanisms. However, little is known about the levels of tTG expression and transglutaminase (TG) activity during mammalian brain development. In this study, C57BL/6 mouse forebrains were collected at embryonic day (E) 12, E14, E17, postnatal day (P) 0, P7 and P56 and analyzed for tTG expression and TG activity. RT-PCR analysis demonstrated that tTG mRNA content increases during mouse forebrain development, whereas immunoblot analysis demonstrated that tTG protein content decreases during this time. TG activity was low in prenatal mouse forebrain but increased fivefold to peak at P0, which corresponds with the beginning of the mouse BGS. Further analysis demonstrated that the lack of temporal correlation between tTG protein content and TG activity is the result of an endogenous inhibitor of tTG that is present in prenatal but not postnatal mouse forebrain. These results demonstrate for the first time that tTG enzymatic activity in the mammalian forebrain is developmentally regulated by post-translational mechanisms.

Higher calpastatin levels correlate with resistance to calpain-mediated proteolysis and neuronal apoptosis in juvenile rats after spinal cord injury

While the average age for patients admitted with spinal cord injury is 32 years, patients under the age of 16 account for 5% of spinal cord injured persons. For these younger patients, an increased mortality up to 24 h post-injury has been reported, however, survivors may regain more function than their adult counterparts, suggesting that age may play a role in injury tolerance. While the use of growth factors as a therapy for spinal cord injury is well researched, the response of the developing cord to secondary injury has not been thoroughly investigated. Following spinal cord injury, Ca(2+) influx can activate enzymes such as calpain, a Ca(2+)-dependent protease, which plays a role in the pathogenesis of spinal cord injury in rats. The present investigation revealed that following spinal cord injury, calpain upregulation was significantly less (15.3%) in the 21-day-old rats than in either 45-day-old (70%) or 90-day-old (99.6%) rats, as shown by Western blot and in situ immunofluorescent studies. Expression of the endogenous calpain inhibitor, calpastatin, was significantly higher in juvenile rats than adult rats. Juvenile rats with spinal cord injury also showed a reduced Bax:Bcl-2 ratio (4:1 vs. 6:1), reduced caspase-3 staining, reduced myelin loss (3% vs. 18%), and less neuronal DNA damage, as compared to older rats. These results suggest that increased calpastatin levels found in juvenile rats muted calpain activity and neuronal apoptosis, following spinal cord injury.

Calpain inhibitor 2 prevents axonal degeneration of opossum optic nerve fibers

The ultrastructural change that characterizes the onset of Wallerian degeneration is the disintegration of axoplasmic microtubules and neurofilaments, which are converted into an amorphous and granular material, followed by myelin breakdown. The mechanism underlying such processes is an increase in the amount of intracellular calcium, leading to activation of proteases called calpains. The aim of this study was to evaluate by quantitative ultrastructural analysis whether nerve fibers can be preserved by the use of an exogenous inhibitor of these proteases (calpain inhibitor-2, Mu-F-hF-FMK), after optic nerve crush. For that, the left optic nerves of opossums, Didelphis aurita, were crushed with the aid of a fine forceps, and half of them received a calpain inhibitor mixed with Elvax resin. Ninety-six hours after the lesion, the animals were reanesthetized and transcardially perfused, and the optic nerves were removed, the right ones being used as normal nerves. Afterward, the optic nerves were dissected and processed for routine transmission electron microscopy and quantitative and statistical analysis. The results of this analysis showed that the group that received the calpain inhibitor presented a reduction of astrogliosis, maintaining the optic nerve structure in an organized state; a significant decrease in the number of degenerating fibers; and a significant increase in the number of fibers with preserved cytoskeleton and preservation of axonal and myelin area and integrity, reducing the enlargement and edema of the axon. In conclusion, our findings suggest that calpain inhibitor is able to provide neuroprotection of the central nervous system fibers after a crush lesion.

Calpain and calpastatin expression in primary oligodendrocyte culture: preferential localization of membrane calpain in cell processes

The cellular localization of calpain is important in understanding the roles that calpain may play in physiological function. We, therefore, examined calpain expression, activity, and immunofluorescent localization in primary cultures of rat oligodendrocytes. The mRNA expression of m-calpain was 64.8% (P = 0.0033) and 50.5% (P = 0.0254) higher than that of mu-calpain and calpastatin, respectively, in primary culture oligodendrocytes. The levels of mRNA expression of mu-calpain and calpastatin were not significantly different. As revealed by Western blotting, cultured oligodendrocytes contained a 70 kD major band identified by membrane m-calpain antibody, a 80 kD band recognized by cytosolic m-calpain antibody, and calpastatin bands ranging from 45 to 100 kD detected by a calpastatin antibody. Calpain activity in oligodendrocytes was determined by Ca(2+)-dependent 71.2% degradation of endogenous myelin basic protein compared with control; this activity was inhibited significantly (P = 0.0111) by EGTA and also substantially by calpeptin. Localization of calpain in cultured oligodendrocytes revealed strong membrane m-calpain immunofluorescence in the oligodendrocyte cell body and its processes. In contrast, the cytosolic antibody stained primarily the oligodendrocyte cell body, whereas the processes were stained very weakly or not at all. These results indicate that the major form of calpain in glial cells is myelin (membrane) m-calpain. The dissimilar localization of cytosolic and membrane m-calpain may indicate that each isoform has a unique role in oligodendrocyte function.

Delay of CNTF decrease following peripheral nerve injury in C57BL/Wld mice

In peripheral nerves, ciliary neurotrophic factor (CNTF) is localized to a subset of Schwann cells and is decreased in synthesis during Wallerian degeneration. This pattern of expression is similar to that of myelin protein genes. In the present study, C57BL/Wld mice, which exhibit delayed Wallerian degeneration, were used to determine the role of axonal contact on the regulation of CNTF synthesis. Western blot analysis showed that CNTF immunoreactivity in Wld nerves remained almost normal even 10 days after ligation when it was almost undetectable in control mice. Reverse transcriptase polymerase chain reaction (RT-PCR) analysis revealed that 4 days after ligation, concentrations of CNTF mRNA in Wld mice had decreased much less than in control mice, but that at 10 days CNTF mRNA concentrations in Wld and control mice were comparably low. These observations suggest that maintenance of axonal contact in the absence of axonal transport from the cell body delays the decrease of CNTF mRNA normally seen after injury. Also, during Wallerian degeneration in Wld mice, the decrease of CNTF protein is delayed for many days longer than the decrease in CNTF mRNA.

A new mechanism of methylprednisolone and other corticosteroids action demonstrated in vitro: inhibition of a proteinase (calpain) prevents myelin and cytoskeletal protein degradation

The affect of methylprednisolone (MP), an anti-inflammatory drug upon purified calpain and the Ca2+-mediated degradation of endogenous proteins of spinal cord homogenate in vitro has been examined. Activity of calpain purified from rabbit muscle was greatly inhibited in a dose-dependent fashion by MP. A 50% inhibition was obtained with 3.2 mM MP concentration and the activity was inhibited further (80%) at 8.1 mM. More potent inhibition of the purified enzyme (70-80%) was produced by dexamethasone (3.9 mM) and prednisolone (4.1 mM). Calpain-mediated degradation of myelin basic protein (MBP) was also inhibited by MP as was cathepsin B-mediated MBP breakdown. The effect of MP and other steroids upon calcium-mediated degradation of spinal cord homogenate was also evaluated. SDS-PAGE analysis revealed significant inhibition of neurofilament protein breakdown by MP and other corticosteroids. This inhibitory effect was much less than that exerted by the calpain inhibitors calpeptin and/or E64-d. These results indicate that MP acts as a proteinase (calpain) inhibitor and define a new mechanism for its actions.

Immature properties of large-conductance calcium-activated potassium channels in rat neuroepithelium

The pharmacological and biophysical properties of large-conductance Ca-activated K (BK) channels from embryonic rat telencephalic neuroepithelium were investigated with in situ patch-clamp techniques. A fraction of these channels exhibited properties characteristic of BK channels recorded in well differentiated cells, including normal gating mode (BKN channels). The vast majority of BK channels expressed distinctive properties, the most conspicuous being their buzz gating mode (BKB channels). BKB channels were insensitive to a concentration of charybdotoxin that completely and reversibly blocked BKN channels. In contrast with the strict dependence of BKN channel activation on cytoplasmic Ca, BKB channels displayed substantially high open probability (Po) after inside-out patch excision in a Ca-free medium. Intracellular trypsin down-regulated the Po of BKB channels, which then exhibited a greater sensitivity to cytoplasmic Ca, mainly in the positive direction (increased Po with increased Ca). This suggested a modulatory role for Ca as opposed to its gating role in BKN channels. Ca ions also reduced current amplitude of both types of channels. BKB channels were less voltage sensitive than BKN channels, but this was not correlated with their lower Ca sensitivity. We speculate that BKB channels may represent immature forms in the developmental expression of BK channels.

The localization of mcalpain in myelin: immunocytochemical evidence in different areas of rat brain and nerves

A major part of brain mcalpain activity has been found associated with myelin, but its presence in the myelin sheath has not been clearly demonstrated by microscopic (morphological) means. Using myelin mcalpain antisera the localization of mcalpain has been investigated in tissue of rat CNS and PNS by immunohistochemical methods. These experiments also have been carried out by double labeling studies using antibodies to myelin basic protein (MBP) and neurofilament protein (NFP). Our results indicate calpain/MBP immunoreactivity in the myelin sheath surrounding the axon while NFP antibody stained inside the axon in spinal cord; pons, cerebellum, trigeminal nerve, and sciatic nerve. Patches of light immunoreactivity of calpain were also seen in the axonal cytoplasm. The calpain immunostaining of myelin was similar to that of MBP staining indicating the presence of calpain in myelin. This finding supports the view that calpain is a constituent of myelin, may be involved in the normal turnover of myelin proteins. In pathological situations such as in demyelinating and other brain degenerative diseases, myelin may be autodigestive.

Effect of diet on tissue protease activity

Rats 1, 3, 12, and 24 months old were fed diets low in protein (8% casein), and proteolytic activity in tissue from brain, liver, and lung was determined. After a low-protein diet was fed for 4 weeks to 1-month-old rats, there was a significant increase in cathepsin D activity in liver, and calpain activity was increased in lung. Little change was seen in proteolytic activity in brain. In 12-month-old rats, there was an increase in cathepsin D activity in brain and liver. In 24-month-old rats, cathepsin D activity in the liver and calpain activity in lung were increased. There was no change in proteolytic activity in the brain. When animals were fed diets supplemented with fatty acids or antioxidants for 2 months, in 3-month-old rats calpain activity was increased in brain but decreased in lung. Cathepsin D activity was significantly increased in young and adult animals in brain and in liver. These observations suggest that diet changes result in significant alteration in tissue calpain and cathepsin D levels, and possibly activity, in vivo. Generally, changes are greater for cathepsin D than for calpain, and are smaller in brain than in other tissues.

The calpain-calpastatin system is regulated differently during human neuroblastoma cell differentiation to Schwannian and neuronal cells

Changes in expression of calpains and calpastatin during differentiation in GOTO cells were examined using antibodies specific to calpains and calpastatin. Neuronal differentiation induced by dibutyryl cyclic AMP elicited a remarkable decrease in m-calpain. No marked changes in the levels of calpains were found in bromodeoxyuridine-induced Schwannian differentiation. Calpastatin was detected as a single band of 110k in undifferentiated and in neuronally differentiated cells by Western blot analysis. However, the appearance of a 120k species was detected in Schwannian differentiation associated with morphological change. The data show that marked changes in m-calpain and calpastatin occur in a differentiation-specific manner.

Calpain activity in adult and aged human brain regions

We assayed calpain activity in 27 human brain regions from adult (43-65 years of age) and aged (66-83 years of age) postmortem tissue samples. Calpain I (microM Ca-requiring) activity was 10% or less of the total activity; it was below detectable levels in a number of areas, and so data are are expressed as total (microM + mM Ca-dependent) calpain activity. The distribution of the enzyme was regionally heterogeneous. Highest activity was found in the spinal cord, followed by the amygdala, and levels in mesencephalic areas and in cerebellar grey matter were also high. Levels in cerebellar white matter, tegmentum, pons, and putamen were low, and activity in cortical areas was also relatively low. Although in some areas activity seemed higher with aging, the differences were not statistically significant. We previously found that the regional distribution of cathepsin D in human and in rat brain is similar, this seems to be true for calpain activity as well. The increase of protease activity with age found in rat brain is not found in human areas, as was shown previously with cathepsin D, and in the present study with calpain.

Developmentally transient expression of acetylcholinesterase within cortical pyramidal neurons of the rat brain

Using a histochemical method for the visualization of cholinesterase activity in neurons, we have observed developmentally transient expression of acetylcholinesterase (AChE) in cortical pyramidal neurons of the rat brain. Depending on the extent of the deposition of AChE reaction product, several types of cortical neurons could be visualized. We designated neurons with moderate-to-high staining intensity as AChEH and neurons with relatively lower staining intensity as AChEL. At birth (P0), very little AChE activity was found within cortical neurons. Between P1-P4, there was a gradual emergence of AChE-stained cortical neurons. At this stage, the majority of these neurons were of the AChEL type. At P5-P7 we observed an abrupt increase in AChE-stained cortical neurons. The number and the staining intensity of these neurons was at a peak at P8-P10. At this age range, the majority of these neurons were of the AChEH variety and displayed morphological characteristics of cortical pyramidal neurons. At P11-P15, there was an abrupt decrease in the number of AChEH neurons. After P15, the density and staining intensity of cortical AChE-positive (cholinergic) axons gradually increased. Nevertheless, AChEL pyramidal neurons were detected through these fibers up to P21. At P21, a dense plexus of AChE-positive axons was observed in all cortical areas while very little AChE reaction product was visible in pyramidal neurons, and this pattern continued into adult life. When the adult cortex was denervated from its AChE-positive axons by lesions of the nucleus basalis magnocellularis, many AChEL pyramidal neurons were uncovered.(ABSTRACT TRUNCATED AT 250 WORDS)