Sirus A. Kohan

Differential distribution of the putative vesicular transporter for acetylcholine in the rat central nervous system.

The organization and distribution of the mRNA for the putative vesicular transporter for acetylcholine (VAChT) was studied in the rat brain by use of digoxigenin-labeled riboprobes and in situ hybridization technology. Signal was observed in all neural regions deduced to contain cholinergic somata on the basis of previous histochemical investigations employing choline acetyltransferase riboprobes and prior immunocytochemical studies with antibodies against choline acetyltransferase. It was absent in areas believed to contain no cholinergic neurons. Anti-sense riboprobes hybridized to the mRNA for the putative VAChT: (a) the projection neurons of the various nuclei of the basal nuclear complex, (b) the local circuit cells of the dorsal and ventral striata, (c) the projection neurons of the mesopontine complex, (d) perikarya in the ventral 2/3 of the medial habenula, (e) the somatic motor and autonomic cells of cranial nerves 3-7 and 9-12, as well as perikarya in the dorsal and ventral cochlear nuclei presumably giving rise to efferent fibers of cranial nerve 8, and (f) the alpha-motor and gamma-efferent motor neurons of the spinal cord. In addition, the mRNA for the VAChT was found in a few somata, probably ectopically located cells of the basal nuclear complex, in the internal capsule, central nucleus of the amygdala, entopeduncular nucleus, and zona incerta. It was also detected in some cell bodies in the reticular part of the substantia nigra, probably the rostral extension of the mesopontine complex, in the parabigeminal nucleus, and around the central canal in the spinal cord but not in cortical, hippocampal, and cerebellar perikarya. It is concluded that, like choline acetyltransferase, the mRNA for the putative acetylcholine vesicular transporter is another specific marker for neurons utilizing acetylcholine as a neurotransmitter. Further investigations of that transporter could have important implications for various diseases involving cholinergic systems, such as Alzheimers disease.

Intrinsic membrane association of Drosophila cysteine string proteins

Cysteine string proteins (csps) are highly conserved constituents of vertebrate and invertebrate secretory organelles. Biochemical and immunoprecipitation experiments implied that vertebrate csps were integral membrane proteins that were tethered to the outer leaflet of secretory vesicles via the fatty acyl residues of their extensively acylated cysteine string. Independently, work of others suggested that Drosophila csps were peripheral membrane proteins that were anchored to membranes by a mechanism that was independent of the cysteine string and its fatty acyl residues. We extended these investigation and found first that sodium carbonate treatment partially stripped both csps and the integral membrane protein, synaptotagmin, from Drosophila membranes. Concomitantly, carbonate released fatty acids into the medium, arguing that it has a mild, solubilizing effect on these membranes. Second, we observed that Drosophila csps behaved like integral membrane proteins in Triton X‐114 partitioning experiments. Third, we found that when membrane‐bound csps were deacylated, they remained membrane bound. Moreover, it appeared that hydrophobic interactions were necessary for this persistent membrane association of csps. Thus, neither reducing conditions, urea, nor chaotropic agents displaced deacylated csps from membranes. Only detergents were effective in solubilizing deacylated csps. Finally, by virtue of the inaccessibility of deacylated csps to thiol alkylation by the membrane‐impermeant alkylating reagent, iodoacetic acid, we inferred that it was the cysteine string domain that mediated the membrane association of deacylated csps. Thus, we conclude that under physiological conditions csps are integral membrane proteins of secretory organelles, and that the cysteine string domain plays a vital role in the membrane association of these proteins.

αA-crystallin and αB-crystallin reside in separate subcellular compartments in the developing ocular lens.

Background: The small heat shock proteins, αA-crystallin and αB-crystallin are considered to be two subunits of one single monolithic lens protein, α-crystallin. Results: αA-Crystallin and αB-crystallin fractionate independent of each other and in two separate membrane compartments. Conclusion: αA-Crystallin and αB-crystallin are two independent proteins in the lens. Significance: These data provide functional insight into why αA-crystallin and αB-crystallin null mice have disparate phenotypes. αA-Crystallin (αA) and αB-crystallin (αB), the two prominent members of the small heat shock family of proteins are considered to be two subunits of one multimeric protein, α-crystallin, within the ocular lens. Outside of the ocular lens, however, αA and αB are known to be two independent proteins, with mutually exclusive expression in many tissues. This dichotomous view is buoyed by the high expression of αA and αB in the lens and their co-fractionation from lens extracts as one multimeric entity, α-crystallin. To understand the biological function(s) of each of these two proteins, it is important to investigate the biological basis of this perceived dichotomy; in this report, we address the question whether αA and αB exist as independent proteins in the ocular lens. Discontinuous sucrose density gradient fractionation and immunoconfocal localization reveal that in early developing rat lens αA is a membrane-associated small heat shock protein similar to αB but with remarkable differences. Employing an established protocol, we demonstrate that αB predominantly sediments with rough endoplasmic reticulum, whereas αA fractionates with smooth membranes. These biochemical observations were corroborated with immunogold labeling and transmission electron microscopy. Importantly, in the rat heart also, which does not contain αA, αB fractionates with rough endoplasmic reticulum, suggesting that αA has no influence on the distribution of αB. These data demonstrate presence of αA and αB in two separate subcellular membrane compartments, pointing to their independent existence in the developing ocular lens.

Inhibition of the Expression of the Small Heat Shock Protein αB-crystallin Inhibits Exosome Secretion in Human Retinal Pigment Epithelial Cells in Culture

Exosomes carry cell type-specific molecular cargo to extracellular destinations and therefore act as lateral vectors of intercellular communication and transfer of genetic information from one cell to the other. We have shown previously that the small heat shock protein αB-crystallin (αB) is exported out of the adult human retinal pigment epithelial cells (ARPE19) packaged in exosomes. Here, we demonstrate that inhibition of the expression of αB via shRNA inhibits exosome secretion from ARPE19 cells indicating that exosomal cargo may have a role in exosome biogenesis (synthesis and/or secretion). Sucrose density gradient fractionation of the culture medium and cellular extracts suggests continued synthesis of exosomes but an inhibition of exosome secretion. In cells where αB expression was inhibited, the distribution of CD63 (LAMP3), an exosome marker, is markedly altered from the normal dispersed pattern to a stacked perinuclear presence. Interestingly, the total anti-CD63(LAMP3) immunofluorescence in the native and αB-inhibited cells remains unchanged suggesting continued exosome synthesis under conditions of impaired exosome secretion. Importantly, inhibition of the expression of αB results in a phenotype of the RPE cell that contains an increased number of vacuoles and enlarged (fused) vesicles that show increased presence of CD63(LAMP3) and LAMP1 indicating enhancement of the endolysosomal compartment. This is further corroborated by increased Rab7 labeling of this compartment (RabGTPase 7 is known to be associated with late endosome maturation). These data collectively point to a regulatory role for αB in exosome biogenesis possibly via its involvement at a branch point in the endocytic pathway that facilitates secretion of exosomes.

Cysteine string protein β is prominently associated with nerve terminals and secretory organelles in mouse brain

Cysteine string proteins (CSPs) are associated with regulated secretory organelles in organisms ranging from fruit flies to man. Mammals have three csp genes (alpha, beta and gamma), and previous work indicated that expression of the csp-beta and -gamma genes was restricted to the testes. For the current investigation, antibodies specific for CSP-beta were developed. Unexpectedly, immunoblot analysis indicated that CSP-beta was prominently expressed throughout mouse brain. Upon sub-cellular fractionation, CSP-beta was enriched in synaptosomes and synaptic vesicle fractions. Interestingly, CSP-beta existed almost exclusively as part of a high mass complex both in testis and brain. This complex required aggressive denaturation to release monomeric CSP-beta. By Northern analysis CSP-beta mRNA was present at very low abundance as a approximately 1.0kb species in mouse brain. Collectively, the enrichment of CSP-beta in synaptosomes and the association of CSP-beta with synaptic vesicles suggest that CSP-beta, like CSP-alpha, may be an important component of the regulated secretory machinery in mouse brain.