Two immunologically and developmentally distinct chondroitin sulfate proteolglycans in embryonic chick brain.

Two different chondroitin sulfate proteoglycans (CSPG) in embryonic chick brain were distinguished by immunoreactivity either with S103L, a rat monoclonal antibody which reacts specifically with an 11-amino-acid region in the chondroitin sulfate domain of the core protein of chick cartilage CSPG (Krueger, R. C., Jr., Fields, T. A., Mensch, J. R., and Schwartz, N. B. (1990) J. Biol. Chem. 265, 12088-12097), or with HNK-1, a mouse monoclonal antibody which reacts with a 3-sulfoglucuronic acid residue on neural glycolipids and glycoproteins (Chou, D. K. H., Ilyas, A., Evans, J. E. Costello, C., Quarles, R. H., and Jungawala, F. B. (1986) J. Biol. Chem. 261, 11717-11725) but not with both antibodies. This specific immunoreactivity was used to separate the two CSPGs for further characterization. The S103L reactive brain proteoglycan had a core protein of similar size to cartilage CSPG (370 kDa) but exhibited a smaller hydrodynamic size (K(av) of 0.308). It was substituted predominantly with chondroitin sulfate chains and virtually no keratan sulfate chains. The HNK-1 reactive CSPG had a smaller core protein (340 kDa), an even smaller hydrodynamic size (K(av) of 0.564), and was substituted with both chondroitin sulfate and keratan sulfate chains. Glycosidase digestion patterns with endo-beta-galactosidase, N-glycosidase F, neuraminidase, and O-glycosidase, and reactivity with an antibody to the hyaluronate binding region also showed significant differences between the two brain CSPGs. Expression of the S103L reactive brain CSPG was developmentally regulated from embryonic day 7 through 19 with a peak in core protein on day 13, and in mRNA expression at day 10. In contrast the HNK-1 reactive brain CSPG was constitutively present from day 7 through hatching. These data suggest that these two distinct core proteins are immunologically and biochemically unique translation products of two different CSPG genes.     

Exposure to polychlorinated biphenyls causes endothelial cell dysfunction

Environmental chemicals, such as polychlorinated biphenyls (PCBs), may be atherogenic by disrupting normal functions of the vascular endothelium. To investigate this hypothesis, porcine pulmonary artery-derived endothelial cells were exposed to 3,3′,4,4′-tetrachlorobiphenyl (PCB 77), 2,3,4,4′,5-pentachlorobiphenyl (PCB 114), or 2,2′,4,4′,5,5′-hexachlorobiphenyl (PCB 153) for up to 24 hours. These PCBs were selected for their varying binding avidities with the aryl hydrocarbon (Ah) receptor and differences in their induction of cytochrome P450. PCB 77 and PCB 114 significantly disrupted, in a dose-dependent manner, endothelial barrier function by allowing an increase in albumin transfer across endothelial monolayers. These PCBs also contributed markedly to cellular oxidative stress, as measured by 2,7-dichlorofluorescin (DCF) fluorescence and lipid hydroperoxides, and caused a significant increase in intracellular calcium ([Ca²⁺]_i) levels. Enhanced oxidative stress and [Ca²⁺]_i in PCB 77- and PCB 114-treated cells were accompanied by increased activity and content of cytochrome P450 1A and by a decrease in the vitamin E content in the culture medium. In contrast to the effects of PCB 77 and PCB 114, cell exposure to PCB 153 had no effect on cellular oxidation, [Ca²⁺]_i, or endothelial barrier function. These results suggest that certain PCBs may play a role in the development of atherosclerosis by causing endothelial cell dysfunction and a decrease in the barrier function of the vascular endothelium. It is possible that interaction of PCBs with the Ah receptor and activation of the cytochrome P450 1A subfamily are involved in this pathology. © 1995 John Wiley & Sons, Inc.     

Regulation of the expression of histone H3.3 by differential polyadenylation.

Previously we have shown that the 3' untranslated regions (UTRs) of the replacement histone genes H3.3.A and H3.3B of Drosophila melanogaster differ in their nucleotide sequences and have different polyadenylation sites. To understand their functional relevance, which might explain the presence and evolutionary conservation of 2 different H3.3 genes, green fluorescent protein (GFP) constructs with different 3' UTR sections were studied by the expression of GFP as a marker protein. Here we show that the polyadenylation signals modify the cell-specific translation of the histone replacement variants in testes and ovaries. The H3.3A gene may be required to provide postmeiotic histone H3.3 in the male germ line in transition to chromatin packaging in sperm.     

The H3 chaperone function of NASP is conserved in Arabidopsis

Histones are abundant cellular proteins but, if not incorporated into chromatin, they are usually bound by histone chaperones. Here, we identify Arabidopsis NASP as a chaperone for histones H3.1 and H3.3. NASP interacts in vitro with monomeric H3.1 and H3.3 as well as with histone H3.1–H4 and H3.3–H4 dimers. However, NASP does not bind to monomeric H4. NASP shifts the equilibrium between histone dimers and tetramers towards tetramers but does not interact with tetramers in vitro. Arabidopsis NASP promotes [H3–H4]₂ tetrasome formation, possibly by providing preassembled histone tetramers. However, NASP does not promote disassembly of in vitro preassembled tetrasomes. In contrast to its mammalian homolog, Arabidopsis NASP is a predominantly nuclear protein. In vivo, NASP binds mainly monomeric H3.1 and H3.3. Pulldown experiments indicated that NASP may also interact with the histone chaperone MSI1 and a HSC70 heat shock protein.     

Change of cytochrome c structure during development of the mouse.

The structure of cytochrome c during mouse development is investigated. For this purpose the amino acid sequence of cytochrome c of the adult mouse had to be determined. The structure of cytochrome c of adult differentiated mouse cells differs in two amino acid residues from the known amino acid sequence of rabbit cytochrome c. No indication of different forms of cytochrome c in the adult differentiated cells was obtained. The structure of cytochrome c from 11.5-day-old mouse embryos is identical with that of adult mouse tissues. Since germ cells after meiotic division are the immediate precursors of a new individual, the structure of cytochrome c from sperm-containing mice testes was investigated. By means of chromatography of the cytochrome c and of peptide maps and amino acid analyses of its tryptic peptides, it is shown that mouse testis contains two isocytochromes c in about equal amount. The structure of one of these two isocytochromes c is identical with the structure of the adult-type cytochrome c of mouse. The testis-specific cytochrome c, which is assumed to be located in the sperm cells, differs in 13 of its 104 amino acid residues from the adult-type cytochrome c. From comparison of the primary and the spatial structures of the adult-type and the sperm-type isocytochromes c with the known structures of cytochrome c of more than 65 different species it is concluded that the duplication of the cytochrome c structural gene, causing the existence of the two ontogenetic-specific isocytochromes c in mouse, has occurred early in the evolution of eucaryotes.