Joseph J. Ferretti

Complete genome sequence of an M1 strain of Streptococcus pyogenes

The 1,852,442-bp sequence of an M1 strain of Streptococcus pyogenes, a Gram-positive pathogen, has been determined and contains 1,752 predicted protein-encoding genes. Approximately one-third of these genes have no identifiable function, with the remainder falling into previously characterized categories of known microbial function. Consistent with the observation that S. pyogenes is responsible for a wider variety of human disease than any other bacterial species, more than 40 putative virulence-associated genes have been identified. Additional genes have been identified that encode proteins likely associated with microbial “molecular mimicry” of host characteristics and involved in rheumatic fever or acute glomerulonephritis. The complete or partial sequence of four different bacteriophage genomes is also present, with each containing genes for one or more previously undiscovered superantigen-like proteins. These prophage-associated genes encode at least six potential virulence factors, emphasizing the importance of bacteriophages in horizontal gene transfer and a possible mechanism for generating new strains with increased pathogenic potential.

Genome sequence of Streptococcus mutans UA159, a cariogenic dental pathogen

Streptococcus mutans is the leading cause of dental caries (tooth decay) worldwide and is considered to be the most cariogenic of all of the oral streptococci. The genome of S. mutans UA159, a serotype c strain, has been completely sequenced and is composed of 2,030,936 base pairs. It contains 1,963 ORFs, 63% of which have been assigned putative functions. The genome analysis provides further insight into how S. mutans has adapted to surviving the oral environment through resource acquisition, defense against host factors, and use of gene products that maintain its niche against microbial competitors. S. mutans metabolizes a wide variety of carbohydrates via nonoxidative pathways, and all of these pathways have been identified, along with the associated transport systems whose genes account for almost 15% of the genome. Virulence genes associated with extracellular adherent glucan production, adhesins, acid tolerance, proteases, and putative hemolysins have been identified. Strain UA159 is naturally competent and contains all of the genes essential for competence and quorum sensing. Mobile genetic elements in the form of IS elements and transposons are prominent in the genome and include a previously uncharacterized conjugative transposon and a composite transposon containing genes for the synthesis of antibiotics of the gramicidin/bacitracin family; however, no bacteriophage genomes are present.

Genome Sequence of a Nephritogenic and Highly Transformable M49 Strain of Streptococcus pyogenes

The 1,815,783-bp genome of a serotype M49 strain of Streptococcus pyogenes (group A streptococcus [GAS]), strain NZ131, has been determined. This GAS strain (FCT type 3; emm pattern E), originally isolated from a case of acute post-streptococcal glomerulonephritis, is unusually competent for electrotransformation and has been used extensively as a model organism for both basic genetic and pathogenesis investigations. As with the previously sequenced S. pyogenes genomes, three unique prophages are a major source of genetic diversity. Two clustered regularly interspaced short palindromic repeat (CRISPR) regions were present in the genome, providing genetic information on previous prophage encounters. A unique cluster of genes was found in the pathogenicity island-like emm region that included a novel Nudix hydrolase, and, further, this cluster appears to be specific for serotype M49 and M82 strains. Nudix hydrolases eliminate potentially hazardous materials or prevent the unbalanced accumulation of normal metabolites; in bacteria, these enzymes may play a role in host cell invasion. Since M49 S. pyogenes strains have been known to be associated with skin infections, the Nudix hydrolase and its associated genes may have a role in facilitating survival in an environment that is more variable and unpredictable than the uniform warmth and moisture of the throat. The genome of NZ131 continues to shed light upon the evolutionary history of this human pathogen. Apparent horizontal transfer of genetic material has led to the existence of highly variable virulence-associated regions that are marked by multiple rearrangements and genetic diversification while other regions, even those associated with virulence, vary little between genomes. The genome regions that encode surface gene products that will interact with host targets or aid in immune avoidance are the ones that display the most sequence diversity. Thus, while natural selection favors stability in much of the genome, it favors diversity in these regions.

Nucleotide sequence of the streptokinase gene from Streptococcus equisimilis H46A

The entire nucleotide sequence of a cloned 2568-bp PstI fragment from the genome of Streptococcus equisimilis H46A encoding the streptokinase gene (skc) has been determined. The longest open reading frame comprises 1320 bp which code for streptokinase. The protein is synthesized with a 26-amino acid residue N-terminal extension having properties characteristic of a signal peptide. Comparison of the deduced amino acid sequence with the available amino acid sequence of a commercial streptokinase reveals minor primary structure differences. The nucleotide sequencing of skc does not support the hypothesis that the gene has evolved by duplication and fusion, as suggested by internal twofold amino acid homologies of its product. Furthermore, the skc gene sequence shows no extended regions homologous to the staphylokinase gene. Upstream from the skc gene, the putative skc promoter and the ribosome-binding site sequence have been identified; downstream from the coding region, inverted repeat sequences thought to function as transcription terminators have been detected.

Bacteriophage T12 of Streptococcus pyogenes integrates into the gene encoding a serine tRNA

The region of temperate bacteriophage T12 responsible for integration into the chromosome of Streptococcus pyogenes has been identified. The integrase gene (int) and the phage attachment site (attP) are found immediately upstream of the gene for speA, the latter of which is known to be responsible for the production of erythrogenic toxin A (also known as pyrogenic exotoxin A). The integrase gene has a coding capacity for a protein of 41 457 Da, and the C‐terminus of the deduced protein is similar to other conserved C‐terminal regions typical of phage integrases. Upstream of int is a second open reading frame, which is capable of encoding an acidic protein of 72 amino acids (8744 Da); the position of this region in relation to int suggests it to be the phage excisionase gene (xis). The arms flanking the integrated prophage (attL and attR) were identified, allowing determination of the sequences of the phage (attP) and bacterial (attB) attachment sites. A fragment containing the integrase gene and attP was cloned into a streptococcal suicide vector; when introduced into S. pyogenes by electrotransformation, this plasmid stably integrated into the bacterial chromosome at attB. The insertion site for the phage into the S. pyogenes chromosome was found to be in the anticodon loop of a putative type II gene for a serine tRNA. attP and attB share a region of identity that is 96 bp in length; this region of identity corresponds to the 3′ end of the tRNA gene such that the coding sequence remains intact after integration of the prophage. The symmetry of the core region of att may set this region apart from previously described phage attachment sites (Campbell, 1992), and may play a role in the biology of this medically important bacteriophage.

Sequence analysis of the wall-associated protein precursor of Streptococcus mutans antigen A.

The nucleotide sequence has been determined for the Streptococcus mutans wall‐associated protein A (wapA) gene from serotype c strains Ingbritt and GS5. The nucleotide sequence for each wapA gene was virtually identical, although the gene from strain GS5 contained a 24 base pair deletion. A 29 amino acid signal peptide was specified by each wapA gene with a mature protein of 424 amino acids (Mr, 45276) for strain Ingbritt and 416 amino acids (Mr, 44846) for strain GS5. In the C‐terminal region of the wall‐associated protein A, considerable sequence similarity was found with the membrane anchor region of proteins from other Gram‐positive organisms such as the group A streptococcal M protein and the group G streptococcal IgG binding protein. Adjacent to the proposed membrane anchor is a highly hydrophilic region which may span the cell wall; both sequence data and experimental evidence indicate the existence of a region immediately outside the wall at which proteolytic cleavage occurs to release antigen A of Mr 29000 into the culture supernatant. Thus, the wall‐associated protein A is a precursor of the 29000 Mr antigen A.

PCR amplification of streptococcal DNA using crude cell lysates

Gram-positive organisms such as streptococci and enterococci are often difficult to lyse. Obtaining DNA for procedures such as PCR amplification usually requires a large scale isolation for each strain under investigation. We describe a simple procedure for small volumes of whole cells, involving pretreatment with detergent and proteinase that allows for efficient release of DNA for PCR amplification. This procedure is fast, reproducible, can be used with a large number of samples, and has been successfully applied to a variety of streptococcal and enterococcal strains.

Plasmid pGB301, a new multiple resistance streptococcal cloning vehicle and its use in cloning of a gentamicin/kanamycin resistance determinant

SummaryStreptococcal plasmid pGB301 is an in vivo rearranged plasmid with interesting properties and potential for the molecular cloning of genes in streptococci. Transformation of S. sanguis (Challis) with the group B streptococcal plasmid pIP501 (29.7 kb) gave rise to the deletion derivative pGB301 (9.8 kb, copy number 10) which retained the multiple resistance phenotype of its ancestor (inducible MLS-resistance, chloramphenicol resistance). Among the eight restriction endonucleases used to physically map pGB301 were four that cleaved the plasmid at single sites yielding either sticky (HpaII, KpnI) or bluntends (HpaI, HaeIII/BspRI). Passenger DNA derived from larger streptococcal plasmids (pSF351C61, 69.5 kb; pIP800, 71 kb) was successfully inserted into the HpaII site and, by blunt-end cloning, into the HaeIII/BspRI site. The gentamicin/kanamycin resistance gene of pIP800 was expressed by recombinant plasmids carrying the insert in either orientation. Insertion of passenger DNA into the HaeIII/BspRI site (but not the HpaII site) caused instability of adjacent pGB301 sequences which were frequently deleted, thereby removing the chloramphenicol resistance phenotype. The vector pGB301 has a remarkable capacity for passenger DNA (inserts up to 7 kb) and the property of instability and loss of a resistance phenotype following insertion of passenger DNA into the HaeIII/BspRI site should facilitate the identification of cloned segments of DNA when using this plasmid in molecular cloning experiments.

The streptokinase gene of group A streptococci: cloning, expression in Escherichia coli, and sequence analysis

The gene specifying the group A streptokinase (ska) gene was cloned from an M type 49 strain of Streptococcus pyogenes and shown to express in Escherichia coli. The nucleotide sequence of the DNA fragment carrying ska was determined and compared to that of the group C streptokinase gene (skc). There is 90% sequence identity between the two genes, with highly conserved transcription and translation control regions. The deduced amino acid sequence of the group A streptokinase (SKA) contains the same number of amino acids as that of group C streptokinase, with 85% sequence identity between the two proteins. Among 440 amino acid residues specified by the coding sequence, there are 62 non‐identical residues with 45 conserved and 17 non‐conserved residues. The non‐identical residues are located in two major regions, spanning residues 174 to 244 and 270 to 290, with 40 and 10 amino acid changes, respectively. The sequence differences provide an explanation at the molecular level for the previous findings of immunological and chemical heterogeneity among streptokinases produced by pathogenic streptococci.

Transport of Sugars, Including Sucrose, by the msm Transport System of Streptococcus mutans:

The range of substrates transported by the sugar-binding protein-dependent msm (multiple sugar metabolism) system of S. mutans was investigated. By determining the ability of unlabeled sugar to compete with radiolabeled melibiose transport, we have demonstrated that the transported sugars included a number of carbohydrates structurally related to raffinose. A model accommodating these results has been devised which accounts for the sugars transported by the msm transport system. Competition with radiolabeled melibiose transport indicated sucrose to be an msm substrate. This was confirmed by examination of uptake of radiolabeled sucrose in scrAB mutants lacking the sucrose-specific phosphotransferase system.