Relationship between plasmid and chromosomal hemolysin determinants of Escherichia coli

Plasmid hemolysin (hly) determinants have been shown previously to comprise three cistrons (hlyA, hlyB, hlyC), coding for the synthesis and transport of hemolysin. Using recombinant plasmids as specific probes for these cistrons, we were able to analyze the chromosomal hly determinants of nine Escherichia coli strains which belonged to serotypes O4, O6, O18, and O75 and were isolated from urinary tract infections and fecal flora. The chromosomal hly genes shared extensive sequence homology with the cloned plasmid hly determinant. Nevertheless, small differences were observed, and these were found to lie mainly within cistron A (hlyA), which has been shown to determine the hemolysin protein itself. These fine variations were not specific for the O-serotype.     

Multiple copies of hemolysin genes and associated sequences in the chromosomes of uropathogenic Escherichia coli strains.

The O6 serogroup Escherichia coli strain 536 carries two hemolysin (hly) determinants integrated into the chromosome. The two hly determinants are not completely identical, either functionally or structurally, as demonstrated by spontaneous deletion mutants carrying only one of them and by cloning each of the two determinants separately into cosmid vectors. Each hly determinant is independently deleted at a frequency of 10(-4), leading to variants which exhibit similar levels of internal hemolysin but different amounts of secreted hemolysin. The two hly determinants were also identified in the O4 E. coli strain 519. The three E. coli strains 251, 764, and 768, which belong to the serogroup O18, and the O4 strain 367 harbor a single chromosomal hly determinant, as demonstrated by hybridization with hly-gene-specific probes. However, a hybridization probe derived from a sequence adjacent to the hlyC-proximal end of the plasmid pHly 152-encoded hly determinant hybridizes with several additional chromosomal bands in hemolytic O18 and O6 E. coli strains and even in E. coli K-12. The size of the probe causing the multiple hybridization suggests a 1,500- to 1,800-base pair sequence directly flanking hlyC. Spontaneous hemolysin-negative mutants were isolated from strains 764 and 768, which had lost the entire hly determinant but retained all copies of the hlyC-associated sequence.2+.     

Spontaneous deletions and flanking regions of the chromosomally inherited hemolysin determinant of an Escherichia coli O6 strain.

The hemolytic Escherichia coli strain 536 (O6) propagates spontaneous hemolysin-negative mutants at relatively high rates (10(-3) to 10(-4)). One type of mutant (type I) lacks both secreted (external) and periplasmic (internal) hemolysin activity (Hlyex-/Hlyin-) and in addition shows no mannose-resistant hemagglutination (Mrh-), whereas the other type (type II) is Hlyex-/Hlyin+ and Mrh+. The genetic determinants for hemolysin production (hly) and for mannose-resistant hemagglutination (mrh) of this strain are located on the chromosome. Hybridization experiments with DNA probes specific for various parts of the hly determinant reveal that mutants of type I have lost the total hly determinant, whereas those of type II lack only part of the hlyB that is essential for transport of hemolysin across the outer membrane. Using a probe that contains the end sequence of the plasmid pHly152-encoded hly determinant (adjacent to hlyB), we determined that a related sequence flanks also the hlyB-distal end of the chromosomal hly determinant of E. coli 536. In addition several other similar or even identical sequences are found in the vicinity of the hlyC- and the hlyB-distal ends of both the chromosomal and the plasmid hly determinants.     

Synthesis, inactivation, and localization of extracellular and intracellular Escherichia coli hemolysins.

Extra- and intracellular Escherichia coli hemolysin expressed by two cloned hly determinants, both under the control of the activator element hlyR, were analyzed. One determinant carried all four hly genes (hlyC, hlyA, hlyB, and hlyD), whereas the other carried only the two genes (hlyC and hlyA) required for synthesis of active hemolysin but not those essential for its secretion. It was shown that the total amounts of HlyA protein and of hemolytic activity are similar in both cases in logarithmically growing cultures. The E. coli strain carrying the complete hly determinant released most hemolysin into the media and accumulated very little HlyA intracellularly. The active extracellular hemolysin (HlyA*) was inactivated in the stationary phase without degradation of the HlyA protein. In contrast, the hemolysin which accumulated intracellularly in the E. coli strain carrying hlyA and hlyC only was proteolytically degraded at the end of the logarithmic growth phase. Immunogold labeling indicates that active intracellular HlyA bound preferentially to the inner membrane, whereas that part of the extracellular HlyA which remained cell-bound was located exclusively at the cell surface. It was shown by fluorescence-activated cell sorter analysis that active extra- and intracellular HlyA* bound with similar efficiency to erythrocytes, whereas hemolytically inactive HlyA protein did not bind to these target cells.     

Cloning of the chromosomal determinants encoding hemolysin production and mannose-resistant hemagglutination in Escherichia coli.

We have cloned the chromosomal hemolysin determinants from Escherichia coli strains belonging to the four O-serotypes O4, O6, O18, and O75. The hemolysin-producing clones were isolated from gene banks of these strains which were constructed by inserting partial Sau3A fragments of chromosomal DNA into the cosmid pJC74. The hemolytic cosmid clones were relatively stable. The inserts were further subcloned either as SalI fragments in pACYC184 or as BamHI-SalI fragments in a recombinant plasmid (pANN202) containing cistron C (hlyC) of the plasmid-encoded hemolysin determinant. Detailed restriction maps of each of these determinants were constructed, and it was found that, despite sharing overall homology, the determinants exhibited minor specific differences in their structure. These appeared to be restricted to cistron A (hlyA), which is the structural gene for hemolysin. In the gene banks of two of these hemolytic strains, we could also identify clones which carried the genetic determinants for the mannose-resistant hemagglutination antigens Vb and VIc. Both of these fimbrial antigens were expressed in the E. coli K-12 clones to an extent similar to that observed in the wild-type strains. These recombinant cosmids were rather unstable, and, in the absence of selection, segregated at a high frequency.     

Molecular cloning of the hemolysin determinant from Vibrio cholerae El Tor

Vibrio cholerae El Tor RV79 is phenotypically nonhemolytic; however, strongly hemolytic convertants are occasionally observed on blood agar plates. We have cloned DNA sequences corresponding to the hemolysin determinant from RV79 (Hly+) in the lambda L47.1 and pBR322 vectors. A 2.3-kilobase fragment of V. cholerae DNA was found to be necessary for hemolytic activity. This cloned DNA sequence was used as a probe in Southern blot hybridization analysis of chromosomal restriction digests of a variety of El Tor and classical biotype V. cholerae strains. In all cases, DNA fragments with the same electrophoretic mobilities hybridized to the Hly probe. The results presented demonstrate that the cloned hemolysin determinant is the hly locus. By using mutator vibriophage VcA-3 insertion to promote high-frequency transfer, the hly locus was mapped between arg and ilv on the V. cholerae RV79 chromosome.     

Characterization of the α-haemolysin determinant from the human enteropathogenic Escherichia coli O26 plasmid pEO5

The 157-kb conjugative plasmid pEO5 encoding α-haemolysin in strains of human enteropathogenic Escherichia coli (EPEC) O26 was investigated for its relationship with EHEC-haemolysin-encoding plasmids of enterohaemorrhagic E. coli (EHEC) O26 and O157 strains. Plasmid pEO5 was found to be compatible with EHEC-virulence plasmids and did not hybridize in Southern blots with plasmid pO157 from the EHEC O157:H7 strain EDL933, indicating that both plasmids were unrelated. A 9227-bp stretch of pEO5 DNA encompassing the entire α- hly CABD operon was sequenced and compared for similarity to plasmid and chromosomally inherited α- hly determinants. The α- hly determinant of pEO5 (7252 bp) and its upstream region was most similar to corresponding sequences of the murine E. coli α-hly plasmid pHly152, in particular, the structural α- hly CABD genes (99.2% identity) and the regulatory hly R regions (98.8% identity). pEO5 and α-hly plasmids of EPEC O26 strains from humans and cattle were very similar for the regions encompassing the structural α- hly CABD genes. The major difference found between the hly regions of pHly152 and pEO5 is caused by the insertion of an IS 2 element upstream of the hly C gene in pHly152. The presence of transposon-like structures at both ends of the α- hly sequence indicates that this pEO5 virulence factor was probably acquired by horizontal gene transfer.     

More pieces in the promoter jigsaw: recognition of −10 regions by alternative sigma factors

Two papers in this issue of Molecular Microbiology from Carol Gross and colleagues describe experiments that investigate how two alternative Escherichia coli σ proteins recognize target promoter −10 regions. A combination of genetics, biochemistry and bioinformatics is used to show that determinants in two adjacent domains of the σ proteins contact discrete sequence elements in the −10 regions.     

Cloning in Bacillus subtilis of temperature-dependent promoter fragments from Bacillus stearothermophilus and Bacillus subtilis

Abstract Using promoter-probe plasmids, more than 200 promoter-containing fragments from Bacillus stearothermophilus and Bacillus subtilis were cloned in B. subtilis . Among these, 15 promoter fragments were highly temperature-dependent in activity compared to the promoter sequence (TTGAAA for the −35 region, TATAAT for the −10 region) of the amylase gene, amyT , from B. stearothermophilus . Some fragments exhibited higher promoter activities at elevated temperature (48°C), others showed higher activities at lower temperature (30°C). Active promoter fragments at higher and lower temperatures were obtained mainly from the thermophile ( B. stearothermophilus ) and the mesophile ( B. subtilis ), respectively. A promoter fragment active at high temperature was sequenced, and the feature of the putative promoter region was discussed.