Immunisation with recombinant BCG expressing the cottontail rabbit papillomavirus (CRPV) L1 gene provides protection from CRPV challenge.

Recombinant Bacille Calmette-Guerin (rBCG) could potentially be the vaccine vehicle of choice to deliver foreign antigens from multiple pathogens. In this study we have used the cottontail rabbit papillomavirus (CRPV) rabbit model to provide a "proof of concept" that immunisation with rBCG expressing the CRPV major capsid protein, L1 (rBCG/CRPVL1), will protect outbred New Zealand White rabbits against CRPV challenge. Rabbits immunised with rBCG/CRPVL1 (10(7) cfu/ml) were protected 5 weeks post-CRPV challenge. Rabbits immunised with rBCG/CRPVL1 (10(5) cfu/ml) had papillomas, which were smaller and took longer to appear than the control rabbits. None of the negative control rabbits vaccinated with rBCG expressing an irrelevant gene or PBS were protected from CRPV challenge. Sera from rabbits immunised with rBCG/CRPVL1 (10(7) cfu/ml) were able to neutralise 54.5% of CRPV at serum dilutions of 1:200. These results provide evidence that BCG could potentially be used as a vaccine delivery vehicle for human papillomavirus proteins as a possible prophylactic vaccine.

Expression of different group A streptococcal M proteins in an isogenic background demonstrates diversity in adherence to and invasion of eukaryotic cells.

The M protein of group A streptococcus (GAS) is considered to be a major virulence factor because it renders GAS resistant to phagocytosis and allows bacterial growth in human blood. There are more than 80 known serotypes of M proteins, and protective opsonic antibodies produced during disease in humans are serotype specific. M proteins also mediate bacterial adherence to epithelial cells of skin and pharynx. GAS strains vary in the genomic organization of the mga regulon, which contains the genes encoding M and M-like proteins and other virulence factors. This diversity of organization makes it difficult to assess virulence of M proteins of different serotypes, unless they can be expressed in an isogenic background. Here, we express M proteins of different serotypes in the M protein- and protein F1-deficient GAS strain, SAM2, which also lacks M-like proteins. Genes encoding M proteins of different serotypes (emmXs) have been integrated into the SAM2 chromosome in frame with the emm6.1 promoter and its mga regulon, resulting in similar levels of emmX expression. Although SAM2 exhibits a very low level of adherence to and invasion of HEp-2 and HaCaT cells, a SAM2-derived strain expressing M6 protein adheres to and invades both cell types. In contrast, the isogenic strain expressing M18 protein adheres to both cell types, but invades with a very low efficiency. A strain expressing M3 protein adheres to both types of cells, but its invasion of HEp-2 cells is serum dependent. A GAS strain expressing M6 protein does not compete with the isogenic strain expressing M18 protein for adherence to or invasion of HaCaT cells. We conclude that M proteins of different serotypes recognize different repertoires of receptors on the surfaces of eukaryotic cells.

Functional and physical interactions between partial molecules of STE6, a yeast ATP-binding cassette protein.

The Saccharomyces cerevisiae a-factor transporter, STE6, is a member of the ATP binding cassette (ABC) transporter superfamily. ABC proteins consist of four modular units that comprise two membrane-spanning domains (MSDs) and two nucleotide-binding domains (NBDs). Like many ABC proteins, STE6 contains these four domains in a single polypeptide; certain other ABC proteins are encoded as pairs of "half-molecules" or are further subdivided. Our previous studies demonstrated that STE6 can be expressed as two half-molecules that are functional when co-expressed. Here we dissect the interactions between modules of STE6 in greater detail. We show by co-immunoprecipitation that STE6 half-molecules interact physically, supporting the view that they co-assemble in vivo to form a functional transporter. We also demonstrate a physical interaction between a STE6 half-molecule and full-length STE6; such complexes appear to be functional, based on the striking finding that the defective activity of full-length STE6 mutated in one of its NBDs can be corrected by co-expression of the corresponding "wild-type" half-molecule. We also show that a quarter-molecule consisting solely of the N-terminal MSD of STE6 can interact physically and functionally with a C-terminal three-quarter molecule of STE6, indicating that information directing the assembly of STE6 from partial molecules is contained, at least in part, within its membrane spans.

Metabolic instability and constitutive endocytosis of STE6, the a-factor transporter of Saccharomyces cerevisiae.

STE6, a member of the ATP binding cassette (ABC) transporter superfamily, is a membrane protein required for the export of the a-factor mating pheromone in Saccharomyces cerevisiae. To initiate a study of the intracellular trafficking of STE6, we have examined its half-life and localization. We report here that STE6 is metabolically unstable in a wild-type strain, and that this instability is blocked in a pep4 mutant, suggesting that degradation of STE6 occurs in the vacuole and is dependent upon vacuolar proteases. In agreement with a model whereby STE6 is routed to the vacuole via endocytosis from the plasma membrane, we show that degradation of STE6 is substantially reduced at nonpermissive temperature in mutants defective in delivery of proteins to the plasma membrane (sec6) or in endocytosis (end3 and end4). Whereas STE6 appears to undergo constitutive internalization from the plasma membrane, as do the pheromone receptors STE2 and STE3, we show that two other proteins, the plasma membrane ATPase (PMA1) and the general amino acid permease (GAP1), are significantly more stable than STE6, indicating that rapid turnover in the vacuole is not a fate common to all plasma membrane proteins in yeast. Investigation of STE6 partial molecules (half- and quarter-molecules) indicates that both halves of STE6 contain sufficient information to mediate internalization. Examination of STE6 localization by indirect immunofluorescence indicates that STE6 is found in a punctate, possibly vesicular, intracellular pattern, distinct from the rim-staining pattern characteristic of PMA1. The punctate pattern is consistent with the view that most of the STE6 molecules present in a cell at any given moment could be en route either to or from the plasma membrane. In a pep4 mutant, STE6 is concentrated in the vacuole, providing further evidence that the vacuole is the site of STE6 degradation, while in an end4 mutant STE6 exhibits rim-staining, indicating that it can accumulate in the plasma membrane when internalization is blocked. Taken together, the results presented here suggest that STE6 first travels to the plasma membrane and subsequently undergoes endocytosis and degradation in the vacuole, with perhaps only a transient residence at the plasma membrane; an alternative model, in which STE6 circumvents the plasma membrane, is also discussed.

Nucleotide sequence of the yeast STE14 gene, which encodes farnesylcysteine carboxyl methyltransferase, and demonstration of its essential role in a-factor export.

Eukaryotic proteins initially synthesized with a C-terminal CAAX motif (C is Cys, A is aliphatic, and X can be one of several amino acids) undergo a series of modifications involving isoprenylation of the Cys residue, proteolysis of AAX, and alpha-carboxyl methyl esterification of the newly formed isoprenyl cysteine. We have previously demonstrated that STE14 encodes the enzyme which mediates carboxyl methylation of the Saccharomyces cerevisiae CAAX proteins a-factor, RAS1, and RAS2. Here we report the nucleotide sequence of STE14, which indicates that STE14 encodes a protein of 239 amino acids, predicted to contain multiple membrane-spanning segments. Mapping data indicate that STE14 resides on chromosome IV, tightly linked to ADE8. By analysis of ste14 null alleles, we demonstrated that MATa ste14 mutants are unable to mate but are viable and exhibit no apparent growth defects. Additional analysis of ste14 ras 1 and ste14 ras2 double mutants, which grow normally, reinforces our previous conclusion that RAS function is not significantly influenced by its methylation status. We examine a-factor biogenesis in a ste14 null mutant by metabolic labeling and immunoprecipitation and demonstrate that although proteolytic processing and membrane localization of a-factor are normal, the ste14 null mutant exhibits a profound block in a-factor export. This observation suggests that the methyl group is likely to be a critical recognition determinant for the a-factor transporter, STE6, thus providing insight into the substrate specificity of STE6 and also supporting the hypothesis that carboxyl methylation can have a dramatic impact on protein-protein interactions.

Mutational analysis of the yeast a-factor transporter STE6, a member of the ATP binding cassette (ABC) protein superfamily.

STE6, the yeast a-factor transporter, is a member of the ATP binding cassette protein superfamily, which also includes the mammalian multidrug resistance protein and the cystic fibrosis gene product. These proteins contain two homologous halves, each with six membrane spanning segments and a predicted ATP nucleotide binding domain. To assess the importance of the two halves of STE6, and to examine the functional significance of residues conserved among members of the ATP binding cassette superfamily, we introduced mutations into the nucleotide binding domains of STE6. Our analysis demonstrates that both halves of STE6 are critical for function and that some, but not all, mutations analogous to those known to result in cystic fibrosis impair STE6 activity. To examine further the functional contribution of each half of the STE6 protein, we severed the STE6 coding sequence and expressed the two halves of the transporter as separate polypeptides. Whereas 'half-molecules' are unable to provide transport function individually, co-expression of both half-molecules in the same cell leads to functional reconstitution of STE6-mediated a-factor transport.

The DNA binding arm of lambda repressor: critical contacts from a flexible region.

Segments of protein that do not adopt a well-ordered conformation in the absence of DNA can still contribute to site-specific recognition of DNA. The first six residues (NH2-Ser1-Thr2-Lys3-Lys4-Lys5-Pro6-) of phage lambda repressor are flexible but are important for site-specific binding. Low-temperature x-ray crystallography and codondirected saturation mutagenesis were used to study the role of this segment. All of the functional sequences have the form [X]1-[X]2-[Lys or Arg]3-[Lys]4-[Lys or Arg]5-[X]6. A high-resolution (1.8 angstrom) crystal structure shows that Lys3 and Lys4 each make multiple hydrogen bonds with guanines and that Lys5 interacts with the phosphate backbone. The symmetry of the complex breaks down near the center of the site, and these results suggest a revision in the traditional alignment of the six lambda operator sites.