Barbara J. Froehlich

CooC and CooD are required for assembly of CS1 pili

Many strains of enterotoxigenic Escherichia coli (ETEC) isolated from patients with diarrhoeal disease exhibit CS1 pili on their surfaces. These appendages, which are thought to be important for colonization of the upper intestine, are composed largely of multiple Identical protein subunits encoded by cooA. We have sequenced the DNA directly downstream of cooA and identified two open reading frames, cooC and cooD, transcribed in the same direction as cooB and cooA. Following cooD Is DNA homologous to an insertion sequence, so cooB, A, C and D appear to encode all the information needed for E. coli K‐12 to synthesize CS1 pili. Complementation analysis of mutants cloned in E. coli K‐12 and constructed in an ETEC‐derived strain indicates that cooC and cooD are not required for stability of the major CS1 pilin protein or for its transport to the periplasm, but, like cooB, both are needed for assembly of cooA into pili.

The pCoo Plasmid of Enterotoxigenic Escherichia coli Is a Mosaic Cointegrate

CS1 is the prototype of a class of pili of enterotoxigenic Escherichia coli (ETEC) associated with diarrheal disease in humans. The genes encoding this pilus are carried on a large plasmid, pCoo. We report the sequence of the complete 98,396-bp plasmid. Like many other virulence plasmids, pCoo is a mosaic consisting of regions derived from multiple sources. Complete and fragmented insertion sequences (IS) make up 24% of the total DNA and are scattered throughout the plasmid. The pCoo DNA between these IS elements has a wide range of G+C content (35 to 57%), suggesting that these regions have different ancestries. We find that the pCoo plasmid is a cointegrate of two functional replicons, related to R64 and R100, which are joined at a 1,953-bp direct repeat of IS100. Recombination between these repeats in the cointegrate generates the two smaller replicons which coexist with the cointegrate in the culture. Both of the smaller replicons have plasmid stability genes as well as genes that may be important in pathogenesis. Examination by PCR of 17 other unrelated CS1 ETEC strains with a variety of serotypes demonstrated that all contained at least parts of both replicons of pCoo and that strains of the O6 genotype appear to contain a cointegrate very similar to pCoo. The results suggest that this family of CS1-encoding plasmids is evolving rapidly.

Streptococcus pyogenes CovRS mediates growth in iron starvation and in the presence of the human cationic antimicrobial peptide LL-37.

We found that the global regulatory two-component signal transduction system CovRS mediates the ability of group A streptococcus (GAS) to grow under two stresses encountered during infection: iron starvation and the presence of LL-37. We also showed that CovRS regulates transcription of the multimetal transporter operon that is important for GAS growth in a low concentration of iron.

CooB is required for assembly but not transport of CS1 pilin

CS1 pili are filamentous proteinaceous appendages found on many enterotoxigenic Escherichia coli (ETEC) strains isolated from human diarrhoeal disease. They are thought to effect colonization of the upper intestine by facilitating binding to human ileal epithelial cells. We have identified a gene, cooB, which lies directly upstream of cooA, the gene that encodes the major structural CS1 protein. When translated in vitro, the protein product of cooB migrates in sodium dodecyl sulphate/polyacrylamide gel with an apparent molecular mass of 26 kDa, which is consistent with that predicted from its DNA sequence. We constructed a mutant allele (cooB‐1) by insertion of the omega fragment, which inhibits transcription and translation, into the cooB gene in vitro. In a derivative of an ETEC strain with the cooB‐1 mutation (JEF100) and a plasmid that encodes Rns (pEU2030), the positive regulator required for CS1 expression, no cooB and a greatly reduced level of cooA product was detectable in total cell extracts. The reduction of cooA in this strain appears to result from polarity of the cooB mutation because introduction of the wild‐type cooA gene in trans causes production of CooA protein, which is found in cell pellet extracts, in extracts containing only surface proteins and in the culture supernatant. Therefore, in the absence of CooB, CooA is stable and it is transported through both inner and outer membranes. However, the cooB‐1 strain with cooA in trans does not cause haemagglutination of bovine erythrocytes (the model system used to assay adherence mediated by coli surface antigen 1 (CS1) pili). Electron microscopy reveals that there are no pili present on the cell surface or in the culture medium in which this strain was grown. Thus, although it is not required for stability or transport of the major CS1 pilin protein, CooB is needed for assembly of CooA into pili. The relationship of these gene products to those of other pili is discussed.

Serine/Threonine Protein Kinase Stk Is Required for Virulence, Stress Response, and Penicillin Tolerance in Streptococcus pyogenes▿

ABSTRACT Genes encoding one or more Ser/Thr protein kinases have been identified recently in many bacteria, including one (stk) in the human pathogen Streptococcus pyogenes (group A streptococcus [GAS]). We report that in GAS, stk is required to produce disease in a murine myositis model of infection. Using microarray and quantitative reverse transcription-PCR (qRT-PCR) studies, we found that Stk activates genes for virulence factors, osmoregulation, metabolism of α-glucans, and fatty acid biosynthesis, as well as genes affecting cell wall synthesis. Confirming these transcription studies, we determined that the stk deletion mutant is more sensitive to osmotic stress and to penicillin than the wild type. We discuss several possible Stk phosphorylation targets that might explain Stk regulation of expression of specific operons and the possible role of Stk in resuscitation from quiescence.

A single-copy promoter-cloning vector for use in Escherichia coli

We have constructed and tested a single-copy-plasmid vector (pEU720) based on the IncFII-group plasmid, R100, that is useful for cloning promoters in front of lacZ. The vector is 15 kb long and contains a unique XhoI site in front of lacZ.

The Histone-Like Protein Hlp Is Essential for Growth of Streptococcus pyogenes: Comparison of Genetic Approaches To Study Essential Genes

ABSTRACT Selection of possible targets for vaccine and drug development requires an understanding of the physiology of bacterial pathogens, for which the ability to manipulate expression of essential genes is critical. For Streptococcus pyogenes (the group A streptococcus [GAS]), an important human pathogen, the lack of genetic tools for such studies has seriously hampered research. To address this problem, we characterized variants of the inducible Ptet cassette, in both sense and antisense contexts, as tools to regulate transcription from GAS genes. We found that although the three-operator Ptet construct [Ptet(O)3] had low uninduced expression, its induction level was low, while the two-operator construct [Ptet(O)2] was inducible to a high level but showed significant constitutive expression. Use of Ptet(O)3 in the chromosome allowed us to demonstrate previously that RNases J1 and J2 are required for growth of GAS. Here we report that the uninduced level from the chromosomally inserted Ptet(O)2 construct was too high for us to observe differential growth. For the highly expressed histone-like protein (Hlp) of GAS, neither chromosomal insertion of Ptet(O)2 or Ptet(O)3 nor their use on a high-copy-number plasmid to produce antisense RNA specific to hlp resulted in adequate differential expression. However, by replacing the ribosome binding site of hlp with an engineered riboswitch to control translation of Hlp, we demonstrated for the first time that this protein is essential for GAS growth.

Horizontal Transfer of CS1 Pilin Genes of Enterotoxigenic Escherichia coli

CS1 is one of a limited number of serologically distinct pili found in enterotoxigenic Escherichia coli (ETEC) strains associated with disease in people. The genes for the CS1 pilus are on a large plasmid, pCoo. We show that pCoo is not self-transmissible, although our sequence determination for part of pCoo shows regions almost identical to those in the conjugative drug resistance plasmid R64. When we introduced R64 into a strain containing pCoo, we found that pCoo was transferred to a recipient strain in mating. Most of the transconjugant pCoo plasmids result from recombination with R64, leading to acquisition of functional copies of all of the R64 transfer genes. Temporary coresidence of the drug resistance plasmid R64 with pCoo leads to a permanent change in pCoo so that it is now self-transmissible. We conclude that when R64-like plasmids are transmitted to an ETEC strain containing pCoo, their recombination may allow for spread of the pCoo plasmid to other enteric bacteria.

A single amino acid difference between Rep proteins of P1 and P7 affects plasmid copy number

P1 and P7 are closely related plasmid prophages which are members of the same incompatibility group. We report the complete DNA sequence of the replication region of P7 and compare it to that of P1. The sequence predicts a single amino acid difference between the RepA proteins of these two plasmids, no differences in methylation sites or regions where dnaA protein is expected to bind, and no difference in the spacing of the major features of the two replicons. A P1 replicon with a mutation in repA, the gene that encodes an essential replication protein, is complemented for replication by providing either the P1 RepA protein (RepA1) or the P7 RepA protein (RepA7) in trans. Furthermore, when either of these proteins is supplied in trans, the plasmid copy number of P1 cop mutants drops to that of P1 cop+. However, when RepA7 is supplied, the copy number of P1 cop and P1 cop+ is higher than that when RepA1 is supplied. This indicates that the single amino acid difference between the two versions of the RepA protein plays an important role in determining the plasmid copy number.

CS1 pili of enterotoxigenic E. coli

In the establishment of bacterial infections, the first step is attachment to host tissue. For most Gram-negative bacteria, this is accomplished by surface appendages called pili. Different strains of enterotoxigenic E. coli (ETEC), which are a major cause of intestinal disease in humans, utilize a limited number of serologically different pili for attachment to the human gut. We are investigating one of these, CS1, whose morphogenesis appears to be totally unrelated to that of the better-studied pili of E. coli associated with urinary tract infections. The CS1 pilin operon, which is located on a large plasmid, requires rns, a trans-acting positive regulator encoded on a different plasmid, for its expression. Although the G + C content of E. coli DNA is about 50%, rns has a G + C content of only 28%. The major CS1 pilin subunit, encoded by coo A, has no cysteines and therefore can have no disulfide loop. Upstream of coo A we have identified cooB, which is not required for stability or transport of the major pilin subunit, but is required for its assembly into pili. CooB is not structurally similar to chaperonins or other proteins in the GENBANK database except its counterpart in another ETEC pilus, CFA/I. Although there is no detectable DNA hybridization, rns, coo A and cooB are closely related at the amino acid sequence level to their counterparts in the operon of the serologically different ETEC pilus CFA/I. We suspect that the CS1 locus will serve as the prototype for a new type of pilus which is common among ETEC strains.