HPV-16 E5 down-regulates expression of surface HLA class I and reduces recognition by CD8 T cells.

HPV-16 is the major causes of cervical cancer. Persistence of infection is a necessary event for progression of the infection to cancer. Among other factors, virus persistence is due the viral proteins fighting the immune response. HPV-16 E5 down-regulates MHC/HLA class I, which is much reduced on the cell surface and accumulates in the Golgi apparatus in cells expressing E5. This effect is observed also in W12 cells, which mimic early cervical intraepithelial progression to cervical cancer. The functional effect of MHC I down-regulation on human CD8 T cells is not known, because of the need for HLA-matched, HPV-specific T cells that recognise E5 expressing-cells. Here we employ a heterologous cell/MHC I system which uses mouse cells expressing both E5 and HLA-A2, and A2-restricted CTLs; we show that the E5-induced reduction of HLA-A2 has a functional impact by reducing recognition of E5 expressing cells by HPV specific CD8+ T cells.

Antimicrobial properties of pyridine-2,6-dithiocarboxylic acid, a metal chelator produced by Pseudomonas spp.

Pyridine-2,6-dithiocarboxylic acid (pdtc) is a metal chelator produced by Pseudomonas spp. It has been shown to be involved in the biodegradation of carbon tetrachloride; however, little is known about its biological function. In this study, we examined the antimicrobial properties of pdtc and the mechanism of its antibiotic activity. The growth of Pseudomonas stutzeri strain KC, a pdtc-producing strain, was significantly enhanced by 32 microM pdtc. All nonpseudomonads and two strains of P. stutzeri were sensitive to 16 to 32 microM pdtc. In general, fluorescent pseudomonads were resistant to all concentrations tested. In competition experiments, strain KC demonstrated antagonism toward Escherichia coli. This effect was partially alleviated by 100 microM FeCl3. Less antagonism was observed in mutant derivatives of strain KC (CTN1 and KC657) which lack the ability to produce pdtc. A competitive advantage was restored to strain CTN1 by cosmid pT31, which restores pdtc production. pT31 also enhanced the pdtc resistance of all pdtc-sensitive strains, indicating that this plasmid contains elements responsible for resistance to pdtc. The antimicrobial effect of pdtc was reduced by the addition of Fe(III), Co(III), and Cu(II) and enhanced by Zn(II). Analyses by mass spectrometry determined that Cu(I):pdtc and Co(III):pdtc2 form immediately under our experimental conditions. Our results suggest that pdtc is an antagonist and that metal sequestration is the primary mechanism of its antimicrobial activity. It is also possible that Zn(II), if present, may play a role in pdtc toxicity.

A Pseudomonas stutzeri gene cluster encoding the biosynthesis of the CCl4-dechlorination agent pyridine-2,6-bis(thiocarboxylic acid).

A spontaneous mutant of Pseudomonas stutzeri strain KC lacked the carbon tetrachloride (CCl4) transformation ability of wild-type KC. Analysis of restriction digests separated by pulsed-field gel electrophoresis (PFGE) indicated that the mutant strain CTN1 differed from strain KC by deletion of approximately 170 kb of chromosomal DNA. CTN1 did not produce pyridine-2,6-bis(thiocarboxylic acid) (PDTC), the agent determined to be responsible for CCl4 dechlorination in cultures of strain KC. Cosmids from a genomic library of strain KC containing DNA from within the deleted region were identified by hybridization with a 148 kb genomic Spel fragment absent in strain CTN1. Several cosmids identified in this manner were further screened for complementation of the PDTC biosynthesis-negative (Pdt -) phenotype. One cosmid (pT31) complemented the Pdt- phenotype of CTN1 and conferred CCl4 transformation activity and PDTC production upon other pseudomonads. Southern analysis showed that none of three other P. stutzeri strains representing three genomovars contained DNA that would hybridize with the 25,746 bp insert of pT31. Transposon mutagenesis of pT31 identified open reading frames (ORFs) whose disruption affected the ability to make PDTC in the strain CTN1 background. These data describe the pdt locus of strain KC as residing in a non-essential region of the chromosome subject to spontaneous deletion. The pdt locus is necessary for PDTC biosynthesis in strain KC and is sufficient for PDTC biosynthesis by other pseudomonads but is not a common feature of P. stutzeri strains.