Regulation of the Chlamydia trachomatis histone H1-like protein Hc2 is IspE dependent and IhtA independent

The chlamydial histone-like proteins, Hc1 and Hc2, function as global regulators of chromatin structure and gene expression. Hc1 and Hc2 expression and activity are developmentally regulated. A small metabolite that disrupts Hc1 interaction with DNA also disrupts Hc2 interactions; however, the small regulatory RNA that inhibits Hc1 translation is specific to Hc1.     

Selective inhibition of RecA functions by the Hc1 nucleoid condensation protein from Chlamydia trachomatis

During the normal biphasic life cycle of Chlamydia trachomatis, the histone-like protein Hc1 promotes the condensation of nucleoids in elementary bodies, it may also displace nucleoproteins, including repair functions from chromatin. Hc1 was found to effectively inhibit the recombination and repair of the weak binding RecA430 mutant protein from Escherichia coli, but had minimal effects on the parental RecA(+) protein. Expression of Hc1 was also found to inhibit the repair activities of the C. trachomatis RecA protein but not recombination. These results suggest that chlamydial RecA may have evolved mechanisms to minimize Hc1 competition for recombinational activities.     

Cysteine-containing histone H1-like (PL-I) proteins of sperm.

We have determined the presence of cysteine in the protein PL-I from the sperm of the surf clam Spisula solidissima. The existence of cysteine in this histone H1-related protein is responsible for its previously described aggregation behavior. The location of this residue, within the trypsin-resistant domain of the protein, has been established. We have also shown that cysteine is ubiquitously present in the PL-I proteins from the sperm of other bivalve mollusks but is absent from other PL of smaller molecular mass (PL-II, PL-III, PL-IV). We have also found cysteine to be present in the PL-I from a tunicate (Chelysoma productum) but absent in a PL-I from a fish (Mullus barbatus). The possible significance of the unusual occurrence of cysteine in these histone-H1-related proteins is discussed.     

Sequence specific binding of chlamydial histone H1-like protein.

Chlamydia trachomatis is one of the few prokaryotic organisms known to contain proteins that bear homology to eukaryotic histone H1. Changes in macromolecular conformation of DNA mediated by the histone H1-like protein (Hc1) appear to regulate stage specific differentiation. We have developed a cross-linking immunoprecipitation protocol to examine in vivo protein-DNA interaction by immune precipitating chlamydial Hc1 cross linked to DNA. Our results strongly support the presence of sequence specific binding sites on the chlamydial plasmid and hc1 gene upstream of its open reading frame. The preferential binding sites were mapped to 520 bp BamHI-XhoI and 547 bp BamHI-DraI DNA fragments on the plasmid and hc1 respectively. Comparison of these two DNA sequences using Bestfit program has identified a 24 bp region with >75% identity that is unique to the chlamydial genome. Double-stranded DNA prepared by annealing complementary oligonucleotides corresponding to the conserved 24 bp region bind Hc1, in contrast to control sequences with similar A+T ratios. Further, Hc1 binds to DNA in a strand specific fashion, with preferential binding for only one strand. The site specific affinity to plasmid DNA was also demonstrated by atomic force microscopy data images. Binding was always followed by coiling, shrinking and aggregation of the affected DNA. Very low protein-DNA ratio was required if incubations were carried out in solution. However, if DNA was partially immobilized on mica substrate individual strands with dark foci were still visible even after the addition of excess Hc1.     

Mosaic structure of intragenic repetitive elements in histone H1-like protein Hc2 varies within serovars of <Emphasis Type="Italic">Chlamydia trachomatis</Emphasis>

Background  

The histone-like protein Hc2 binds DNA in Chlamydia trachomatis and is known to vary in size between 165 and 237 amino acids, which is caused by different numbers of lysine-rich pentamers. A more complex structure was seen in this study when sequences from 378 specimens covering the hctB gene, which encodes Hc2, were compared.     

Selective repression of translation by the brome mosaic virus 1a RNA replication protein

Differential expression of viral replication proteins is essential for successful infection. We report here that overexpression of the brome mosaic virus (BMV) 1a protein can repress viral RNA replication in a dosage-dependent manner. Using RNA replication-incompetent reporter constructs, repression of translation from BMV RNA1 and RNA2 was observed, suggesting that the effect on translation of the BMV RNA replication proteins is responsible for the decrease in RNA levels. Furthermore, repression of translation by 1a required the B box in the 5'-untranslated region (5' UTR); BMV RNA3 that lacks a B box in its 5' UTR is not subject to 1a-mediated translational inhibition. Mutations in either the methyltransferase or the helicase-like domains of 1a reduced the repression of replication and translation. These results suggest that in addition to its known functions in BMV RNA synthesis, 1a also regulates viral gene expression.     

Nucleus-encoded histone H1-like proteins are associated with kinetoplast DNA in the trypanosomatid Crithidia fasciculata.

Kinetoplast DNA (kDNA), the mitochondrial DNA of trypanosomatids, consists of thousands of minicircles and 20 to 30 maxicircles catenated into a single large network and exists in the cell as a highly organized compact disc structure. To investigate the role of kinetoplast-associated proteins in organizing and condensing kDNA networks into this disc structure, we have cloned three genes encoding kinetoplast-associated proteins. The KAP2, KAP3, and KAP4 genes encode proteins p18, p17, and p16, respectively. These proteins are small basic proteins rich in lysine and alanine residues and contain 9-amino-acid cleavable presequences. Proteins p17 and p18 are closely related to each other, with 48% identical residues and carboxyl tails containing almost exclusively lysine, alanine, and serine or threonine residues. These proteins have been expressed as Met-His6-tagged recombinant proteins and purified by metal chelate chromatography. Each of the recombinant proteins is capable of compacting kDNA networks in vitro and was shown to bind preferentially to a specific fragment of minicircle DNA. Expression of each of these proteins in an Escherichia coli mutant lacking the HU protein rescued a defect in chromosome condensation and segregation in the mutant cells and restored a near-normal morphological appearance. Proteins p16, p17, and p18 have been localized within the cell by immunofluorescence methods and appear to be present throughout the kDNA. Electron-microscopic immunolocalization of p16 shows that p16 is present both within the kDNA disc and in the mitochondrial matrix at opposite edges of the kDNA disc. Our results suggest that nucleus-encoded H1-like proteins may be involved in the organization and segregation of kDNA networks in trypanosomatids.     

Interaction between non-histone chromatin protein HMGB1 and linker histone H1

The fundamental possibility of interaction between non-histone chromatin protein HMGB1 and linker histone H1 was studied in the solutions with different ionic strength by intrinsic UV-fluorescence, far and near-UV CD and spectrophotometry. The obtained data allow us to assume that the increase of histone H1 content in the HMGB1 solutions in a low ionic strength is accompanied by the destruction of HMGB1 associates. The interaction between proteins of HMGB1 and H1 causes the increase in the number of ordered regions in the protein molecules and the minor changes in their tertiary structure.