Regional and subcellular distribution of choline acetyltransferase in the brain of rats

—Homogenates of corpus striatum, cerebral cortex and hypothalamus excised from rat brain were fractionated on discontinuous Ficoll and sucrose density gradients, and the distribution of choline acetyltransferase (ChAc) in the mitochondrial and synaptosomal fractions was determined. In the hypothalamic and cortical regions the fractions enriched in synaptosomes showed much higher activity of ChAc than those containing mainly mitochondria. On the other hand, the corpus striatum showed an equal distribution of ChAc activity in those two fractions. The localization of ChAc was also studied in the postnuclear supernatants obtained from three brain regions, using continuous sucrose density gradients. The distribution of ChAc was compared to that of monoamine oxidase (MAO), potassium and protein. When the pellets obtained from the fractions collected from the gradient were suspended in sucrose, the peak of ChAc activity was close to that of MAO in all three brain regions. When 0.1 mm EDTA +1% butanol was used in order to liberate the occluded form of ChAc, the maximum liberation occurred in lighter fractions, resulting in a shift of the activity peak toward the top of the gradient. This was found with fractions from hypothalamic and cortical regions. In the striatum, the liberated ChAc remained in the same fractions as the occluded enzyme. The results indicate that ChAc is liberated only in those fractions where it is present in synaptosomes. In agreement with the results on the discontinuous gradients this occurs in particles of lower density than mitochondria in cortex and hypo-thalamus, but in particles of similar density to mitochondria in the corpus striatum, indicating regional differences in the distribution of ChAc in the brain. K+ containing particles centrifuged in less dense fractions than those containing ChAc, indicating that synaptosomes are heterogeneous with respect to these two marker substances.     

Regional distributions of somatostatin and cholecystokinin-like immunoreactivities in rat and bovine brain

The distribution of somatostatin- and cholecystokinin octapeptide (CCK-8)-like immunoreactivities in the central nervous system of bovine and rat has been studied using a sensitive and specific radioimmunoassay. The most interesting information is the high concentration of CCK-8 in the various cortical areas in rat and bovine. The nuclei of amygdala contain the highest amount of octapeptide in rat while in bovine brain, this structure contains the second highest concentration after polus frontalis.     

Regional, cellular and subcellular distribution of calcium-activated cyclic nucleotide phosphodiesterase and calcium-dependent regulator in porcine brain.

Abstract— Cyclic nucleotide phosphodiesterase activity (calcium-dependent and calcium-independent) and CDR (calcium-dependent regulator protein of phosphodiesterase) are present in all ten brain regions examined, with the specific activity of both being highest in areas predominating in grey matter and lowest in areas consisting largely of white matter. Fractionation of cerebral cortex into neuronal and glial perikarya shows that cyclic nucleotide phosphodiesterase and CDR are present at approximately equal levels in both cell types. Subcellular fractionation reveals that calcium-sensitive enzyme specific activity, as well as CDR are highly localized in the 100,000 g supernatant fraction. Regional, cellular and subcellular distribution studies indicate that the distribution of CDR closely parallels the distribution of enzyme specific activity, suggesting that the levels of cyclic nucleotide phosphodiesterase and CDR may be synchronized.     

Submitochondrial and subcellular distributions of the carnitine-acylcarnitine carrier

The submitochondrial and subcellular distributions of the carnitine-acylcarnitine translocase (CAC) have been studied. CAC is enriched to a much lesser extent than the carnitine palmitoyltransferases within the contact sites of mitochondria. A high-abundance protein of identical molecular size as the mitochondrial CAC that is immunoreactive with an anti-peptide antibody raised against a linear epitope of mitochondrial CAC is present in peroxisomes but not in microsomes. This suggests that CAC is targeted to at least two different locations within the liver cell and that acylcarnitine transport into peroxisomes is CAC mediated.     

Enzymic inactivation of neurotensin by hypothalamic and brain extracts of the rat.

A sensitive and specific radioimmunoassay has been developed to study inactivation of neurotensin by hypothalamic and brain peptidases. Degrading activity of peptidases from both hypothalamus and brain seems to have similar activity. These peptidases are temperature- and time- dependent. Brain and hypothalamic enzymes of particulate fractions can be differentiated on the basis of the pH effects; brain peptidase(s) has (have) maximal activity at pH 7.4 and hypothalamic peptidase(s) displaying a maximal activity at pH 5.8. Kidneys and liver extracts contain enzyme(s) degrading neurotensin.     

Current topics: brain penetrating neurotensin analog

Neurotensin (NT) is a neuropeptide found in the central nervous system and gastrointestinal tract. It is closely associated with dopaminergic and other neurotransmitter systems, and evidence supports a role for NT in various neuropsychiatric disorders. Because NT is readily degraded by peptidases, our group has developed various NT agonists that can be injected systemically, cross the blood brain barrier (BBB), yet retain the characteristics of native NT. The most widely studied and successful of these compounds, called NT69L, holds promise as a therapeutic agent for Parkinson's disease, schizophrenia, psychostimulant abuse and nicotine dependence, and serves as a tool to study the cellular and molecular effects of NT.     

Purification of the neurotensin receptor from bovine brain

The neurotensin receptor protein, solubilized with digitonin/asolectin from bovine cerebral cortex membranes, was purified to apparent homogeneity by affinity chromatography using immobilized neurotensin. The product exhibits saturable and specific binding of [3,11-tyrosyl-3,5-3H]neurotensin with an apparent affinity (Kd = 5.5 nM) comparable to that measured in intact membranes and crude soluble extracts. The affinity-purified material, after reduction with 100 mM dithiothreitol, in denaturing gel electrophoresis showed a single polypeptide of Mr 72,000. Under nonreducing conditions the apparent Mr, however, was 50,000, suggesting the presence of intramolecular disulfide bonds. The purified neurotensin receptor was judged to be homogeneous, in that (i) only a single polypeptide was detectable; and (ii) the overall purification was 30,000-50,000-fold, giving a specific neurotensin-binding activity close to the theoretical maximum.     

Disialoganglioside GDla of rat brain subcellular particles during development.

The increase observed in the amount of the disialoganglioside GDlof the rat cerebrum during development between 21 and 81 days of age accounted for nearly 40% of the overall increase in total ganglioside in the tissue during the same period. Subcellular fractionation showed the microsomal fraction to contribute by far the most towards this increase in Cerebral ganglioside GDla. It is suggested that microsomal ganglioside GDla may serve as a marker for dendritic arborization in the rat cerebrum.     

Solubilization and characterization of active neurotensin receptors from mouse brain

Neurotensin receptors were solubilized from mouse brain using the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid (CHAPS). The binding of 125I-labeled [Tyr3]neurotensin to the soluble fraction was time-dependent, saturable, and reversible. Unlabeled neurotensin and its analogues acetylneurotensin (8-13), neurotensin (9-13), and neurotensin (1-12) competitively antagonized the binding of 125I-labeled [Tyr3]neurotensin to CHAPS-solubilized extracts with relative potencies similar to those observed with membrane-bound receptors. Scatchard analysis of equilibrium binding data indicated that the soluble extract contained a single class of neurotensin binding sites with a Kd of 0.36 nM and a Bm of 63 fmol/mg. As already observed with membrane-bound receptors, the affinity of neurotensin for the soluble binding activity was decreased by Na+ ions. By contrast, soluble receptors were no longer sensitive to GTP and the antihistamine drug levocabastine. A molecular weight of about 100,000 was determined for soluble neurotensin receptors both under native conditions by gel filtration on Ultrogel AcA 34 and under denaturating conditions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after photoaffinity labeling.     

Alterations in regional brain neurotensin concentrations produced by atypical antipsychotic drugs.

Classical antipsychotic drugs, such as haloperidol, have been shown to increase the concentrations of neurotensin (NT) selectively in the nucleus accumbens and caudate nucleus of the rat. Several novel, putative antipsychotic drugs have also been found to produce increases in NT content in one or both of these brain regions. The present study sought to compare the effects of chronic treatment with three clinically efficacious atypical antipsychotic drugs, sulpiride, rimcazole and remoxipride, on regional brain NT concentrations to those of haloperidol. The concentrations of NT in five discrete brain regions were determined by a sensitive and specific radioimmunoassay. As previously reported, haloperidol increased NT concentrations in both the nucleus accumbens and caudate nucleus. Sulpiride and rimcazole produced significant increases in the concentration of NT in the caudate. NT concentrations were unaltered in any brain region by remoxipride at either of the doses tested. These data provide additional evidence for specific increases in regional brain NT concentrations produced by antipsychotic drugs.     

Distribution and metabolism of glycoproteins and glycosaminoglycans in subcellular fractions of brain.

The distribution, carbohydrate composition, and metabolism of glycoproteins have been studied in mitochondria, microsomes, axons, and whole rat brain, as well as in various synaptosomal subfractions, including the soluble protein, mitochondria, and synaptic membranes. Approximately 90% of the brain glycoproteins occur in the particulate fraction, and they are present in particularly high amounts in synaptic and microsomal membranes, where the concentration of glycoprotein carbohydrate is 2-3% of the lipid-free dry weight. Treatment of purified synaptic membranes with 0.2% Triton X-100 extracted 70% of the glycoprotein carbohydrate but only 35% of the lipid-free protein residue, and the resulting synaptic membrane subfractions differed significantly in carbohydrate composition. The glycoproteins which are not extracted by Triton X-100 also have a more rapid turnover, as indicated by the 80-155% higher specific activity of hexosamine and sialic acid 1 day after labeling with [3H]glucosamine in vivo. The specific activity of sialic acid in the synaptosomal soluble glycoproteins 2 hr after labeling was greater than 100 times that of the synaptosomal particulate fraction, whereas the difference in hexosamine specific activity in these two fractions was only twofold, and by 22 hr there was little or no difference in the specific activities of sialic acid and hexosamine in synaptosomal soluble as compared to membrane glycoproteins. These data indicate that sialic acid may be added locally to synaptosomal soluble glycoproteins before there is significant labeling of nerve ending glycoproteins by axoplasmic transport. Fifty to sixty percent of the hyaluronic acid and heparan sulfate of brain is located in the various membranes comprising the microsomal fraction, whereas half of the chondroitin sulfate is soluble and only one-third is in microsomal membranes. When microsomes are subfractionated on a discontinuous density gradient over half of the hyaluronic acid and chondroitin sulfate are found in membranes with a density less than that of 0.5 M sucrose (representing a six- to sevenfold enrichment over their concentrations in the membranes applied to the gradient), whereas half of the heparan sulfate is present in membranes with a density greater than that of 0.8 M.     

Complex subcellular distributions of enzymatic markers in intestinal epithelial cells

Summary Current procedures for isolating intestinal epithelial cell surface and intracellular membranes are based on the assumption that each organelle is marked by some unique constitutent. This assumption seemed inconsistent with the dynamic picture of subcellular organization emerging from studies of membrane turnover and recycling. Therefore, we have designed an alternative fractionation which is independent ofa priori marker assignments. We subjected mucosal homogenates to a sequence of separations based on sedimentation coefficient, equilibrium density, and partitioning in aqueous polymer twophase systems. The resulting distributions of protein and enzymatic markers define a total of 17 physically and biochemically distinct membrane populations. Among these are: basal-lateral membranes, with Na,K-ATPase enriched 21-fold; brush-border membranes, with alkaline phosphatase enriched as much as 38-fold; two populations apparently derived from the endoplasmic reticulum; a series of five populations believed to have been derived from the Golgi complex; and a series of five acid phosphatase-rich populations which we cannot identify unequivocally. Each of the five enzymatic markers we have followed is associated with a multiplicity of membrane populations. Basallateral, endoplasmic reticulum, and Golgi membranes contain alkaline phosphatase at the same specific activity as the initial homogenate. Similarly, Na,K-ATPase appears to be associated branes at specific activities two-to seven-fold that of the initial homogenate.     

Mast cell binding of neurotensin. I. Iodination of neurotensin and characterization of the interaction of neurotensin with mast cell receptor sites.

Neurotensin was iodinated at equimolar concentrations of peptide, iodide, and chloramine-T, producing a labeled peptide with a specific activity of 1000 to 2000 Ci/mmol. Rat mast cells specifically and reversibly bound 1.27 pmol of neurotensin/10(6) cells with a reversible affinity, KD, of 154 nM. Optimum specific binding occurred betwen pH 6.8 and 7.2 under hypotonic conditions and dropped sharply as buffer concentration increased beyond 10 mM. The divalent cations Ca2+ and Mg2+ prevented binding with 50% inhibition at 1.5 and 4 mM, respectively. Binding was strongly and equally inhibited by the sodium and potassium salts of chloride, bromide, and iodide, and to a lesser degree by LiCl. Maximum binding of 125I-neurotensin occurred within 10 min at 0 degrees, and within 1.5 to 2 min binding was reduced to half-maximum in the presence of excess unlabeled neurotensin or upon 20-fold dilution in buffer. Both CaCl2 and NaCl were able to dissociate 60% of the total bound neurotensin: half the label bound was removed in 4 to 6 min. EDTA inhibited the binding only at high concentrations and no requirement was found for sulfhydryl groups, ATP, or a glycoprotein in the binding of neurotensin.