Host-pathogen interactions are often driven by mechanisms that promote genetic variability. We have identified a group of temperate bacteriophages that generate diversity in a gene, designated mtd (major tropism determinant), which specifies tropism for receptor molecules on host Bordetella species. Tropism switching is the result of a template-dependent, reverse transcriptase-mediated process that introduces nucleotide substitutions at defined locations within mtd. This cassette-based mechanism is capable of providing a vast repertoire of potential ligand-receptor interactions.
The three-dimensional structure of DNA-filled, bacteriophage T4 isometric capsids has been determined by means of cryoelectron microscopy and image reconstruction techniques. The packing geometry of protein subunits on the capsid surface was confirmed to be that of the triangulation class T = 13. The reconstruction clearly shows pentamers, attributed to capsid protein gp24*, surrounded by hexamers of the major capsid protein, gp23*. Positions of the accessory proteins, Hoc and Soc, are also clearly delineated in the surface lattice. The Hoc protein is the most prominent surface feature and appears as an extended molecule with a rounded base from which a thin neck and a globular head protrude. One Hoc molecule associates with each hexamer. Nearly continuous "ridges" are formed at the periphery of the gp23* hexamers by an association of 12 Soc molecules; however, Soc is absent along the boundaries between the hexamers and the pentamers. The duplex DNA genome forms a highly condensed series of concentric layers, spaced about 2.36 nm apart, that follow the general contour of the inner wall of the protein capsid.
Liu et al. recently described a group of related temperate bacteriophages that infect Bordetella subspecies and undergo a unique template-dependent, reverse transcriptase-mediated tropism switching phenomenon (Liu et al., Science 295:2091-2094, 2002). Tropism switching results from the introduction of single nucleotide substitutions at defined locations in the VR1 (variable region 1) segment of the mtd (major tropism determinant) gene, which determines specificity for receptors on host bacteria. In this report, we describe the complete nucleotide sequences of the 42.5-to 42.7-kb double-stranded DNA genomes of three related phage isolates and characterize two additional regions of variability. Forty-nine coding sequences were identified. Of these coding sequences, bbp36 contained VR2 (variable region 2), which is highly dynamic and consists of a variable number of identical 19-bp repeats separated by one of three 5-bp spacers, and bpm encodes a DNA adenine methylase with unusual site specificity and a homopolymer tract that functions as a hotspot for frameshift mutations. Morphological and sequence analysis suggests that these Bordetella phage are genetic hybrids of P22 and T7 family genomes, lending further support to the idea that regions encoding protein domains, single genes, or blocks of genes are readily exchanged between bacterial and phage genomes. Bordetella bacteriophages are capable of transducing genetic markers in vitro, and by using animal models, we demonstrated that lysogenic conversion can take place in the mouse respiratory tract during infection.Parasite adaptation to dynamic host characteristics is a common theme in biology. We recently identified a unique mechanism of adaptation that governs the interactions between a group of bacterial pathogens belonging to the Bordetella genus and a family of bacteriophages that infect them (21). As pathogens of numerous mammalian species, Bordetella spp. undergo major changes in gene expression as they transition through their infectious cycles (9). As part of their adaptive strategy, Bordetella phages use a novel mechanism to evolve new ligands that allow the use of alternative surface receptors for host cell entry.Bordetella pertussis, Bordetella parapertussis, and Bordetella bronchiseptica are highly related, gram-negative coccobacilli that infect respiratory epithelial surfaces in humans and other mammals (25). In response to a variety of environmental signals, these subspecies modulate virulence gene expression through the BvgAS signal transduction system, which controls a spectrum of gene expression states. BvgAS signaling occurs through a multistep phosphorelay involving the BvgS transmembrane sensor kinase and the BvgA response regulator (41,42). When the system is active (Bvg ϩ phase), expression of virulence factors such as adhesins, toxins, and a type III secretion system is induced. When BvgAS is inactive (Bvg Ϫ phase), an alternative set of genes are expressed, including motility and urease genes in B. bronchiseptica and virulence-repressed g...
Studies are presented of the biliproteins of Anabaena sp. This filamentous cyanobacterium contains three major biliproteins. Whereas two of these, C-phycocyanin and allophycocyanin, are common to all cyanobacteria, the third, phycoerythrocyanin (gammamax approximately 568 nm) has hitherto not been described and its distribution among cyanobacteria appears to be limited. Anabaena variabilis and Anabaena sp. 6411 allophycocyanin, C-phycocyanin, and phycoerythrocyanin were purified to homogeneity and characterized with respect to molecular weight, isoelectric point, absorption spectrum and amino acid composition. The alpha and beta subunits of each of these proteins were also purified to homogeneity and characterized in the same manner. The tetrapyrrole chromophore content was determined for each of the proteins and subunits. The alpha subunit of phycoerythrocyanin carries a novel phycobiliviolin-like chromophore. This chromophore has not previously been detected in cyanobacterial biliproteins, but has been noted as a prosthetic group of a cryptophytan phycocyanin. Sedimentation equilibrium studies show that at pH 7.0, at protein concentrations of 0.2-0.6 mg/ml, allophycocyanin, C-phycocyanin and phycoerythrocyanin, each exists as a trimeric aggregate, (alphabeta)3, of molecular weight of approximately 105000. Structrual studies of microcrystals of these three biliproteins by electron microscopy and X-ray diffraction reveal a common plan for the construction of higher assembly forms. The major building block appears to be the trimer (alphabeta)3. It is proposed that this is a disc-like structure about 3.0 X 12.0 nm. The individual alpha or beta subunits are roughly spherical, 3 nm in diameter. Allophycocyanin trimers stack to form bundles of rods which form long needles. Both phycocyanin and phycoerythrocyanin form double discs (alphabeta)6 which are visible as ring-shaped structures by electron microscopy. The mode of assembly of the biliprotein structures in the phycobilisome is, as yet, unknown.
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