Effect of retinoic acid on growth and morphological differentiation of mouse NB2a neuroblastoma cells in culture

We have characterized the effects of retinoic acid (RA) on the growth, morphology and biosynthesis of cytoskeletal proteins in NB2a mouse neuroblastoma cells. In addition, the morphological and biochemical changes were compared to those induced by dibutyryl cyclic AMP (db cAMP). Growth inhibition by RA was concentration-dependent and was first detected 24 h after addition of RA. The proliferation of RA-treated NB2a was more dependent on serum than was the proliferation of untreated cultures and RA decreased the saturation density of NB2a cells grown in serum. Morphological changes induced by RA include the formation of an elaborate network of branching neurites in NB2a cells. In contrast, neurites induced by db cAMP or serum deprivation were bipolar and unbranching. Ultrastructural observations of neurites induced by RA revealed dendritic characteristics such as polysomes, spines and absence of intermediate filaments, while neurites induced by db cAMP had axonal characteristics such as filament bundles, absence of ribosomes, and the formation of membrane densities when neurite endings contacted another cell body. These morphological differences were also reflected in a number of changes in the biosynthesis of cytoskeletal proteins. These results suggest that NB2a cells treated with RA and db cAMP are a model system for the study of distinct stages of differentiation.

Expression and distribution of microtubule-associated protein 2 (MAP2) in neuroblastoma and primary neuronal cells

We examined the expression and distribution of microtubule-associated protein 2 (MAP2) during the differentiation in culture of both mouse NB2a neuroblastoma and primary embryonic rat neurons. The differentiation of NB2a cells was induced with retinoic acid (RA) which stimulated the extension of a highly branched neuritic network and dibutyryl cAMP which stimulated the outgrowth of long bipolar or monopolar processes. We found that although monoclonal antibodies to MAP2 stained the cell bodies of control and differentiated cells, only the RA-induced neurites were positive for this antigen. These data support our ultrastructural studies indicating that the RA-induced neurites were dendrite-like and that the dibutyryl cAMP-induced processes were axon-like. Studies on the biosynthesis of MAP2 indicated that RA induced a 2-3-fold increase in MAP2 synthesis in 24 h; however, this effect was transient, with the synthesis of MAP2 in RA-treated cells returning to control level by 72 h. Although biosynthetic studies suggested the synthesis of species at 250-300 kdalton, the major molecular weight form in the neuroblastoma cells was 230 kdalton. Immunocytochemical analysis of primary neurons showed staining of neuronal cell bodies and of short processes, but virtually no staining of the long axon-like processes. The staining of neuronal cell bodies and processes was evident at all stages of cell differentiation. This finding was corroborated by immunoblots which showed significant amounts of MAP2 throughout cell development. The molecular weight of the immunoreactive material was ca. 300 kdalton in both primary neurons and rat brain. Immunoblots also revealed that embryonic neurons expressed only MAP2B as they differentiated in culture for 14 days. Biosynthesis studies suggested that early in culture there was a modest increase in MAP2 synthesis, but no detectable change was observed thereafter. We concluded therefore that both neuroblastoma cells and primary neurons can differentiate neuritic processes, which show dendritic properties in terms of morphology and preferential distribution of MAP2.

Expression of aspartoacylase activity in cultured rat macroglial cells is limited to oligodendrocytes

N-acetyl-L-aspartate (NAA) is an important osmolyte in the vertebrate brain and eye, and its cyclical metabolism is accomplished in two separate compartments. In the brain, NAA is synthesized primarily in neurons, and after its regulated release, NAA is hydrolyzed by aspartoacylase, which is present in a glial-associated compartment. However, the precise nature of this hydrolytic compartment has remained obscure. It has been proposed that one role of aspartoacylase in the central nervous system (CNS) is as part of a molecular water pump (MWP) that uses the NAA intercompartmental cycle to remove nerve cell metabolic water against a water gradient and that oligodendrocytes comprise the second compartment in this metabolic sequence. The absence of aspartoacylase activity in Canavan disease (CD), a rare early onset genetic spongiform leukodystrophy, is associated with CNS edema, intramyelinic swelling and a progressive loss of oligdendrocytes. In order to evaluate the MWP hypothesis and its possible relationship to the etiology of CD further, both oligodendrocytes and astrocytes obtained from neonatal rat brain were grown in culture and tested for the presence of aspartoacylase activity. The results of this study show for the first time that aspartoacylase activity is expressed only in oligodendrocytes. The meaning of this observation in understanding the function of the NAA metabolic cycle is discussed.

Partition of tissue functions in epithelia: localization of enzymes in "mitochondria-rich" cells of toad urinary bladder

The mucosal epithelium of the toad urinary bladder reabsorbs sodium, acidifies the urine, and is responsive to neurohypophyseal hormnones. Mucosal epithelial cells, consisting of two major morphologic cell types, "mitochondria-rich" and "granular," were removed from the bladder and separated by density gradient centrifugation. The mitochondria-rich cells contained three times as much carbonic anhydrase activity as the granular cells. Oxytocin caused a 235 percent increase in the adenosine 3',5'-monophosphate content of mitochondria-rich cells but had no effect on the granular cells. The evidence indicates that the mitochondria-rich cell, which accounts for only 15 percent of the mucosal cells, plays a major role in the mediation of sodium ion and hydrogen ion transport in the toad bladder and is a specific site of action of neurohypophyseal hormones.

Phorbol ester stimulates the phosphorylation of rabbit erythrocyte band 4.1

The effect of phorbol esters on membrane phosphorylation was examined in intact rabbit erythrocytes prelabeled with [32P]orthophosphate. Tumor-promoting phorbol ester, phorbol 12-myristate 13-acetate, but not the inactive 4 alpha-phorbol 12,13-didecanoate, specifically stimulated the phosphorylation of two proteins in the erythrocyte membrane. They have apparent molecular weight of 100,000 dalton and 85,000 dalton. When intracellular calcium concentrations were raised by ionomycin, A23187, both the 85,000 dalton polypeptide and the 85K phosphoprotein were degraded. The 85,000 dalton phosphoprotein showed cross-reactivity with antiserum to human erythrocyte band 4.1. Based on its susceptibility to calcium-activated protease and its immunological property, the 85,000 dalton phosphoprotein was identified to be the band 4.1 of the erythrocyte membrane skeletal network.

Immunocytochemical localization of carbonic anhydrase in the spinal cords of normal and mutant (shiverer) adult mice with comparisons among fixation methods

The peroxidase-antiperoxidase technique was used for immunocytochemical localization of carbonic anhydrase in the mouse spinal cord to detect whether this antigen was normally present in myelinated fibers, in oligodendrocytes in both white and gray matter, and in astrocytes, and to determine where the carbonic anhydrase might be localized in the spinal cords of dysmyelinating mutant (shiverer) mice. The most favorable methods for treating tissue were: 1) immersion in formalin-ethanol-acetic acid followed by paraffin embedding, or 2) light fixation with paraformaldehyde and preparation of vibratome sections. Carnoy's solution, followed by paraffin embedding, extracted myelin from the tissue, while aqueous aldehydes, when used before paraffin embedding, reduced staining everywhere except at sites of compact myelin. The latter conclusion was based, in part, on the almost complete loss of this antigen from the shiverer cord, where compact myelin is known to be virtually absent but where membrane-bound carbonic anhydrase was demonstrated enzymatically. When the optimal methods were used with normal mouse cords, carbonic anhydrase was found throughout the white matter columns and in the oligodendrocytes in gray and white matter. The staining of the white matter was attributed to myelinated fibers because of the similarity in distribution to both a histological myelin stain and the immunocytochemical staining for myelin basic protein. In the mutant mice the oligodendrocyte cell bodies and processes, which were stained in all areas of the spinal cord, were particularly numerous at the periphery of the sections. In contrast to the oligodendrocytes, the fibrous astrocytes appeared to lack carbonic anhydrase, or to have lower than detectable levels, since the astrocyte marker, glial fibrillary acidic protein, had a very different distribution from that of carbonic anhydrase. Even finer localization was obtained in vibratome sections, where the antibody against carbonic anhydrase permitted visualization of the processes connecting oligodendrocytes to myelinated fibers in the normal adult spinal cord.

Characterization and biosynthesis of soluble and membrane-bound carbonic anhydrase in brain

Carbonic anhydrase from both the cytoplasmic and membrane fractions of the forebrains of rats was characterized with respect to enzymatic activity, immunoreactivity, and in vitro biosynthesis. A procedure for the rapid purification of both membrane-bound and soluble brain carbonic anhydrase is presented that permits retention of full enzymatic activity. Both forms of the enzyme were found to show specific activities of approximately 5500 Units/mg protein when CO2 hydrating activity was determined. In addition, they exhibited similar esterase activity when assayed with p-nitrophenyl acetate. The membrane-bound form, although requiring detergent for extraction from membranes, was freely soluble in aqueous buffers after purification. The molecular weights of both soluble and membrane-bound carbonic anhydrase are 30,000 daltons, and mixing experiments failed to show any significant differences with respect to size. The two forms also exhibit isoelectric points of 7.2. However, the two proteins were found to differ in two respects. Complement fixation indicated that antibodies to soluble carbonic anhydrase had a higher affinity for the soluble form than for the membrane-bound form. The failure to observe any precursor-product relationship between these two proteins with pulse chase studies and the establishment that carbonic anhydrase-like proteins are synthesized on both free polysomes and the rough endoplasmic reticulum indicated that these proteins are synthesized by two separate mechanisms. In vitro synthesis on both free and bound polysomes was determined by two independent methods using different antibodies and different analytical procedures. The basis for these findings and their physiologic importance are discussed.

Characteristics of an amiloride-sensitive sodium entry pathway in cultured rodent glial and neuroblastoma cells

We have studied the induction of an amiloride-sensitive sodium influx into C6 glioma, NIE, and NB2A neuroblastoma cell lines. In late log phase, cells grown continuously in the presence of 10% fetal calf serum showed Na+ influxes of approximately 25-30 nmol/mg protein min; less than 5% of this flux was inhibited by amiloride. Removal of serum for 24 h caused a decrease in the total Na+ influx to 15-20 nmol/mg protein/min. Upon readdition of serum to the incubation medium, there was an increase in total Na+ influx, depending on the cell type, of 20-400% within 2 min. This increment in Na+ influx represented an increase in amiloride-sensitive Na+ transport with an apparent K'1 of 0.4 mM. By adding serum back at various times after serum deprivation, it was determined that 4 h was required to observe a detectable increase in the amiloride-sensitive Na+ flux. Thus, serum removal results in the induction of the amiloride transport system which, however, remains latent until the reintroduction of serum to the medium. Addition of 5 micrograms/ml of cycloheximide blocked the increase in Na+ transport, indicating that de novo protein synthesis mediated this serum deprivation-induced increase in Na+ transport. Moreover, inhibition of de novo lipid synthesis by 0.1 mM fenfluramine also blocked the induction of this transport activity, suggesting that a coordinated synthesis of lipid and protein is required for the expression of this sodium transport site. We have also found that this serum stimulated Na+ influx did not saturate with Na+ concentration, up to 140 mM. Also, among commonly used inhibitors of passive Na+ entry into epithelial tissues, only amiloride was capable of inhibiting this transport system in these neural cell lines.

Properties and function of brain carbonic anhydrase

This chapter has described the characterization and biogenesis of soluble and membrane-bound CA in the central nervous system. The two forms of the enzyme appear to be quite similar in their molecular characteristics, however the data strongly indicate that they are synthesized on separate polysomal populations; the membrane-bound form resulting from synthesis on the RER. Our preliminary data suggest that the partitioning of mRNA for CA on the different polysomes results from the interaction of partial nascent chains with a specific receptor on the RER. We feel a function of membrane-associated synthesis is for the targeting of CA to sites in the cell where there are enzymes that can rapidly utilize the protons and bicarbonate produced by CA catalytic activity for ion exchange reactions. We have also presented arguments that CA may function as a bicarbonate source in the control of metabolism specifically in the acceleration of fatty acid synthesis in the oligodendrocyte.

Is Na + ATPase a myelin-associated enzyme?

The Na + K ATPase activity associated with purified myelin has been investigated. On the basis of marker enzyme studies, the Na + K ATPase activity of myelin was higher than could be accounted for by microsomal contamination. Fractions prepared from white matter-enriched areas of rat brain showed a threefold enrichment in Na + K ATPase activity in myelin as compared with the white matter homogenate. The ATPase activity in myelin was stimulated fourfold by treatment with sodium deoxycholate, but the activity in the whole brain homogenate and the microsomal fraction was only doubled. This discontinuity temperature for Na + K ATPase activity was significantly higher for the myelin fraction (29 degrees C) than for the microsomal fraction (21 degrees C), but the energies of activation, both above and below the discontinuity temperature, were the same for both fractions, Myelin Na + K ATPase had a lower affinity for strophanthidin than the microsomal enzyme, but both fractions were inhibited to the same extent by 10-3 M-strophanthidin. The evidence thus indicated that much of the ATPase activity of myelin is not the result of microsomal contamination. Although the possibility of axolemmal contamination cannot be ruled out conclusively, indirect evidence suggest that this is not a significant factor and that Na + K ATPase may be a myelin-associated enzyme.

Identification of aldosterone-induced proteins in the toad's urinary bladder

Aldosterone (the 8,11-hemiacetal 0f 11beta,21-dihydroxy-3,20-dioxo-4-pregnen-18-al) markedly stimulates sodium transport in a number of epithelial tissues. We have attempted to determine whether aldosterone induces the synthesis of specific protein(s) in the course of its action upon the toad urinary bladder. Paired hemibladders were incubated in media containing either [3H]methionine or [35S]methionine; aldosterone in physiologic concentrations was added to one bath and, after incubation, the intact "mitochondria-rich" (MR) and "granular" (G) mucosal cells were isolated. The ratio (3H/35S) was used to identify proteins whose synthesis was induced in the mucosal cells of the steroid-treated bladders. Using exclusion gel chromatography and isoelectric focusing, we identified several aldosterone-induced proteins in the supernatant (105,000 x g) fraction of the MR cell. None was evident in this fraction of the G cell. These proteins have apparent molecular weights ranging from 17,000 to 38,000 and the isoelectric point of the major component is 4.5. Corticosterone (11beta,21-dihydroxy-4-pregnene-3,20-dione) induced the synthesis of proteins in the G cells, but none of these proteins was similar in molecular weight to the aldosterone-induced proteins in the MR cell. Our findings support the hypothesis that aldosterone induces the synthesis of specific proteins and indicate that, in this tissue, these proteins are synthesized by the MR cell.

Protein interactions with lipid bilayers: the channels of kidney plasma membrane proteolipids

Proteolipids extracted from bovine kidney plasma membrane induce irreversible changes in the electrical properties of lipid bilayers formed from diphytanoyl phosphatidylcholine. The interaction with the proteolipid produces channels which are cation selective. At low protein concentrations (i.e., less than 0.6 microgram/ml), the single-channel conductance is approximately 10 pS in 100 mM KCl and 3 pS in 100 mM NaCl. In the presence of protein concentrations above 1 microgram/ml, another population of channels appears. These channels have a conductance of about 100 pS in 100 mM KCl and 30 pS in 100 mM NaCl. Further, these channels are voltage dependent in KCl, closing when the voltage is clamped at values greater than or equal to 30 mV. The steady-state membrane conductance, measured at low voltages, was found to increase proportional to a high power (2-3) of the proteolipid concentration present in one of the aqueous phases. In 100 mM NaCl, the conductance increases at protein concentrations above 5 microgram/ml, whereas in 100 mM KCl it increases at protein concentrations above 0.6 microgram/ml. These measurements indicate that the higher steady-state conductance observed in KCl at a given proteolipid concentration in a multi-channel membrane presumably results because more channel incorporate in the presence of KCl than in the presence of NaCl. The two major fractions which comprise the proteolipid complex were also tested on bilayers. It was found that both fractions are required to produce the effects described.

Heterogeneity of microtubule-associated protein (MAP2) in vertebrate brains

We have utilized monoclonal antibodies to investigate the antigenic diversity of MAP2-immunoreactive proteins in the nervous system of vertebrates. We found that domains defined by the monoclonal antibodies differed in their conservation across vertebrate evolution, ranging from wide cross-reactivity with almost all vertebrates (mammals, birds, reptiles and amphibians) to a very limited cross-reactivity with only few mammalian species. However, we did not find MAP2-immunoreactive proteins in fish species with either of the monoclonal or polyclonal antibodies. There was also a significant divergence in the apparent molecular weight of MAP2, even in closely related species. For example, different species of wild mice and strains of laboratory mice showed variations of up to 30 kDa in their apparent molecular mass. Using alkaline phosphatase, under conditions that dephosphorylate neurofilaments, we showed that the observed heterogeneity was not the result of variations in the phosphate content. The heterogeneity in molecular weight of MAP2 may, therefore, be the result of changes in primary structure, transcriptional variations or different post-translational modifications. The heterogeneity of MAP2, as well as its specific distribution and implicated interactions with other molecules, underscore the complexity of MAP2 and its potential for structural and functional diversity. The phylogenic analysis of such a complex molecule also provides a method to establish the uniqueness of monoclonal antibodies and the degree of their conservation for their corresponding epitopes.

Activation of amiloride-sensitive sodium transport in C6 glioma cells

We have characterized, in C6 cells, an amiloride-sensitive Na+ entry pathway that can exchange for H+. In this report we demonstrate that this cation-exchange system can be induced within 24-36 h by either serum removal or by dibutyryl cyclic AMP; however, these modes of induction are not additive and are manifest only after activation by serum. In these glioma cells we found that activation by serum can be mimicked in part by specific serum factors, i.e., epidermal growth factor and bradykinin. We attempted to characterize this activation process further using several cell biologic probes. We had previously shown that that activation process involves a calcium-dependent step with full activation obtained in the presence of the calcium ionophore A23187. The activation by serum was inhibited by preincubation with colchicine but not with dihydrocytochalasin B, suggesting a cytoskeletal involvement in the activation process. Activation by epidermal growth factor and bradykinin was found to be unaffected by colchicine, suggesting that other factors must be present in serum that confer sensitivity to colchicine. Incubation of the cells with phorbol myristoyl acetate results in the activation of amiloride-sensitive transport, suggesting that stimulation of protein kinase C may be integral to the activation process. Unlike the effects of serum, activation by phorbol myristoyl acetate is not inhibited by colchicine, indicating that this drug works in a way that bypasses the cytoskeletal-dependent step. Since diacylglycerol is the presumed endogenous activator of protein kinase C, we studied the effects of dioleylglycerol. This intermediate of phospholipid turnover was found to increase specifically the amiloride-sensitive sodium pathway.(ABSTRACT TRUNCATED AT 250 WORDS)

Peroxisomes in infantile phytanic acid storage disease: a cytochemical study of skin fibroblasts

Cultured skin fibroblasts from six patients demonstrating clinical signs and biochemical characteristics of infantile phytanic acid storage disease (IPSD) were examined by electron microscopy, using cytochemical procedures for the demonstration of peroxisomal catalase activity. In four of the six fibroblast cell lines peroxisomes strongly reactive for catalase were present in numbers similar to those found in normal fibroblasts. Liver biopsy tissue from one of these patients showed no typical hepatic peroxisomes, but did show small, marginally reactive bodies. In two other IPSD fibroblast cell lines peroxisomes with appreciable cytochemical reactivity were rare or absent. It seems, therefore, that infantile phytanic acid storage disease is heterogeneous with respect to the presence of cytochemically recognizable peroxisomes, at least in the cases studied here. Furthermore, peroxisomes may be markedly affected in one cell type - liver - and yet not affected in another - skin fibroblasts - within a single individual.

Presence of the plasma membrane proteolipid (plasmolipin) in myelin

Plasma membrane proteolipid (plasmolipin), which was originally isolated from kidney membranes, has also been shown to be present in brain. In this study, we examined the distribution of plasmolipin in brain regions, myelin, and oligodendroglial membranes. Immunoblot analysis of different brain regions revealed that plasmolipin levels were higher in regions rich in white matter. Plasmolipin was also detected in myelin, myelin subfractions, and oligodendroglial membranes. Immunocytochemical analysis of the cerebellum revealed that plasmolipin was localized in the myelinated tracts. Plasmolipin levels in myelin were enriched during five successive cycles of myelin purification, similar to the enrichment of myelin proteolipid apoprotein (PLP) and myelin basic protein (MBP). In contrast, levels of Na+,K(+)-ATPase and a 70-kDa protein were decreased. When myelin or white matter was extracted with chloroform/methanol, it contained, in addition to PLP, a significant amount of plasmolipin. Quantitative immunoblot analysis suggested that plasmolipin constitutes in the range of 2.2-4.8% of total myelin protein. Plasmolipin, purified from kidney membranes, was detected by silver stain on gels at 18 kDa and did not show immunological cross-reactivity with either PLP or MBP. Thus, it is concluded that plasmolipin is present in myelin, possibly as a component of the oligodendroglial plasma membrane, but is structurally and immunologically different from the previously characterized myelin proteolipids.

Carbonic anhydrase and 2',3' cyclic nucleotide 3'-phosphohydrolase activity in normal human brain and in demyelinating diseases

The activities of carbonic anhydrase and 2',3' cyclic nucleotide 3'-phosphohydrolase (CNPase) were measured in gray and white matter and in myelin from human brains obtained at autopsy. Carbonic anhydrase activity increased with age, and at all ages a major part of the activity was associated with membrane fractions. The percentage of membrane-bound carbonic anhydrase was lower than normal in white matter from Krabbe disease and adrenoleukodystrophy; isolated myelin had a low specific activity in these diseases. CNPase activity was decreased in both white matter and myelin, but was somewhat higher than normal in gray matter. Although the yield of myelin from a case of metachromatic leukodystrophy was markedly reduced, changes in the enzymes activities were minimal.

Cyclic AMP and sodium transport. Quantitative and temporal relationships in toad urinary bladder

The effects of oxytocin upon tissue cAMP content and short-circuit current (SCC) were measured in the urinary bladder of the toad, Bufo marinus. Tissue cAMP levels doubled before any increment in SCC was observed, the two hormone responses were quantitatively related, and a threshold level for an effect of cAMP upon sodium transport was demonstrated. The period of time over which cAMP levels continued to rise after the threshold level had been attained seemed invariant with hormone concentration. The rate at which cAMP levels rose increased with hormone concentration yielding hormone concentration-dependent maximal levels. The decay of cAMP levels was delayed when sodium influx was curtailed, suggesting a sodium-regulatory effect upon tissue cAMP levels.

Amyloid precursor protein is enriched in axolemma and periaxolemmal-myelin and associated clathrin-coated vesicles

The amyloid precursor protein (APP) is widely distributed within the CNS, where it is expressed in both neurons and glia. We have isolated axolemma and periaxolemmal-myelin from rat brain and have determined by Western blot that APPs, Mr 100-110 kDa, are major constituents of these membrane. Isolation of axolemma, periaxolemmal-myelin, and compact myelin show that while APP represents 1 and 0.6% of the proteins of these respective membranes, it is absent from compact myelin. These results indicate that APP transported down the axon is deposited at sites in the axolemma as well as the synapse, and that within the myelin complex, APP is targeted to the periaxolemmal domain. Both axolemma and periaxolemmal-myelin contained a 10.5 kDa APP peptide which, based on reactivity with anti-C-terminal APP antibodies but not with anti-N-terminal antibody, appears to be a membrane-associated C-terminal fragment. Western blots with antibodies to Alzheimer precursor-like proteins (APLP) indicate that APP immune reactivity is not a result of cross reactivity with APLPs. Isolation of axolemma from human autopsy material showed nearly identical results with a clear enrichment, relative to homogenate, of APP Mr 100-110 and the 10.5 kDa C-terminal peptide. The demonstration of APP in axolemma and periaxolemmal-myelin was replicated in membrane isolated from bovine brain. Bovine studies were extended to analysis of white matter clathrin-coated vesicles; these data show that coated vesicles isolated from white matter, under conditions that previous studies indicate are largely endocytic vesicles, contain levels of APP comparable to that found in axolemma and periaxolemmal-myelin. In addition, these vesicles contain cysteinyl and aspartyl proteases. Incubation of axolemma with cathepsin B at pH 6.0 caused a rapid loss in the immune reactivity of APP Mr 100-110 and Mr 10.5 when analyzed with antibodies to APP672-695. This appears to be the result of hydrolysis within the epitope and not proteolysis of APP or the C-terminal peptide, since no loss of reactivity was observed when analyzed with antibodies to sites more distal to the C-terminus. Thus, cathepsin B hydrolyses membrane bound APP close to the C-terminus and may be a useful tool for altering C-terminal APP function.

Carbonic anhydrase distributions in central and peripheral nervous system of the rat

Total and specific carbonic anhydrase activity was measured for 24 structures of the rat central and peripheral nervous system. In the CNS, white matter or regions containing largely white matter show a neuraxial distribution of enzyme activity; more cephalad structures display more activity. Gray matter regions do not show a rostrocaudal distribution and usually have lower activity than adjacent myelin-containing structures. PNS tissue shows neither the white-gray differences nor the rostrocaudal profile of CNS tissue. Subcellular fractionation of 18 regions of the CNS suggest that the predominance of membrane-bound carbonic anhydrase (60% of the total activity and independent of its magnitude) is a unique characteristic of all regions of the central nervous system.