Nucleotide sequence of the gene encoding the major capsid protein of herpesvirus of turkeys.

The gene encoding the major capsid protein (MCP) VP5 of herpesvirus of turkeys (HVT) was identified and sequenced. It has a single open reading frame of 4236 nucleotides encoding 1412 aa protein. The gene is flanked by VP23 and UL20 sequences and is localized in the unique long region (UL) within the BamHI-B fragment. Comparison of amino acid homology has shown its clear position among the alpha-herpesviruses rather than beta- or gamma-herpesviruses. The VP5 is expressed from polycistronic mRNA together with the UL20 and the VP23 genes. The 7,2 kb RNA transcript is lacking any promoter elements or polyA signal in intergenomic regions between VP5 and UL20 or VP5 and VP23 genes, respectively. Multiple alignment of known major capsid protein sequences of all herpesvirus groups revealed presence of seven highly homologous clusters suggesting-that the corresponding protein domains might play an important role in folding of MCP and assembly of herpesvirus capsid.

In vivo and in vitro cloning and phenotype characterization of tellurite resistance determinant conferred by plasmid pTE53 of a clinical isolate of Escherichia coli.

A determinant encoding resistance against potassium tellurite (Te(r)) was discovered in a clinical isolate of Escherichia coli strain KL53. The strain formed typical black colonies on solid LB medium with tellurite. The determinant was located on a large conjugative plasmid designated pTE53. Electron-dense particles were observed in cells harboring pTE53 by electron microscopy. X-Ray identification analysis identified these deposits as elemental tellurium and X-ray diffraction analysis showed patterns typical of crystalline structures. Comparison with JCPDS 4-0554 (Joint Committee on Powder Diffraction Standards) reference data confirmed that these crystals were pure tellurium crystals. In common with other characterized Te(r) determinants, accumulation studies with radioactively labeled tellurite showed that reduced uptake of tellurite did not contribute to the resistance mechanism. Tellurite accumulation rates for E. coli strain AB1157 harboring pTE53 were twice higher than for the plasmid-free host strain. In addition, no efflux mechanism was detected. The potassium tellurite resistance determinant of plasmid pTE53 was cloned using both in vitro and in vivo techniques in low-copy-number vectors pACYC184 and mini-Mu derivative pPR46. Cloning of the functional Te(r) determinant into high-copy cloning vectors pTZ19R and mini-Mu derivatives pBEf and pJT2 was not successful. During in vivo cloning experiments, clones with unusual "white colony" phenotypes were found on solid LB with tellurite. All these clones were Mucts62 lysogens. Their tellurite resistance levels were in the same order as the wild type strains. Clones with the "white" phenotype had a 3.6 times lower content of tellurium than the tellurite-reducing strain. Transformation of a "white" mutant with a recombinant pACYC184 based Te(r) plasmid did not change the phenotype. However, when one clone was cured from Mucts62 the "white" phenotype reverted to the wild-type "black" phenotype. It was suggested that the "white" phenotype was the result of an insertional inactivation of an unknown chromosomal gene by Mucts62, which reduced the tellurite uptake.