Assembly of transcriptionally active chromatin in vitro: a possible role for topoisomerase II

Some models of in vitro chromatin assembly suggest a biphasic molecular mechanism. The first phase, nucleosome formation, is comprised of the formation of histone-DNA complexes which mature into a canonical nucleosome structure. The second phase represents the process by which these nucleosomes become properly spaced with a regular periodicity on the DNA. In this report, we examine the role of DNA topoisomerases in the latter phase of chromatin assembly. To study this process, we use a Xenopus laevis cell-free extract, which assembles quantitative amounts of chromatin on circular DNA templates, and the type II topoisomerase-specific antitumor drugs VM-26 and endrofloxicin. Our results suggest that nucleosome formation is unaffected by the presence of VM-26 or endrofloxicin. However, periodic spacing of nucleosomes is inhibited significantly by these drugs. In the absence of proper chromatin assembly, circular DNA molecules are processed into nucleoprotein complexes which are transcribed poorly. Taken together, these results indicate that the antitumor drugs VM-26 and endrofloxicin influence gene expression indirectly by blocking the periodic spacing of nucleosomes.     

Interactions of chloride and amiloride with the renal Na+/H/ antiporter

Amiloride is a reversible inhibitor of the Na+/H+ antiporter which acts at the external aspect of the transport system. The kinetics of inhibition of the Na+/H+ antiporter with amiloride have been controversial, with the usual finding of simple competitive inhibition, but with other reports of mixed and noncompetitive inhibition of the transporter by amiloride. The present experiments demonstrate that the chloride content of the external transport buffer affects the kinetics of amiloride inhibition. Either simple competitive or mixed inhibition by amiloride was observed in the same vesicle preparations depending on the presence of chloride or gluconate in the buffer. The effect of chloride on the inhibitory effect of amiloride was dependent on the concentration of chloride and amiloride. Similar effects were observed with more potent analogues of amiloride. These findings suggest that the external aspect of the antiporter has a site or sites at which the inhibitory effects of amiloride on the Na+/H+ antiporter can be modified by chloride, even though chloride has only slight effects on the kinetics of the Na+/H+ antiporter in the absence of amiloride.     

The promoters of Arabidopsis thaliana genes AtCOX17-1 and -2, encoding a copper chaperone involved in cytochrome c oxidase biogenesis, are preferentially active in roots and anthers and induced by biotic and abiotic stress

AtCOX17 genes encode Arabidopsis thaliana homologs of the yeast metallochaperone Cox17p, involved in the delivery of copper for cytochrome c oxidase (COX) assembly. Two different AtCOX17 genes, located in chromosomes 1 and 3, are present in the Arabidopsis genome. Sequences available in data banks indicate that the presence of two genes is a common feature in monocots, but not in dicots, suggesting that Arabidopsis genes may be the result of a recent duplication. Sequences upstream from the translation start sites of AtCOX17 genes, which include an intron located in the 5' leader region, were introduced into plants in front of the gus gene. For both genes, expression was localized preferentially in young roots and anthers, but almost 10-fold higher β-glucuronidase activity levels were observed in plants transformed with AtCOX17-1 upstream regions. Both promoters were induced to different extents by wounding, treatment of leaves with the bacterial pathogen Pseudomonas syringae and incubation with agents that produce oxidative stress and metals. AtCOX17-2 showed similar responses to these factors, while AtCOX17-1 was more strongly induced by relatively low (10–100 μ M ) copper. The results indicate that both AtCOX17 genes have similar, though not identical, expression characteristics and suggest the existence in their promoters of elements involved in tissue-specific expression and in responses to factors that may produce mitochondrial or cell damage. It can be speculated that Arabidopsis COX17 accumulates under stress conditions to actively replace damaged or inactive cytochrome c oxidase to sustain cyanide-sensitive respiration in plant cells.