DNA fingerprinting of Vibrio cholerae strains with a novel insertion sequence element: a tool to identify epidemic strains.

A novel Vibrio cholerae insertion sequence element, designated IS1004, was characterized and used for DNA fingerprinting of Vibrio spp. IS1004 comprises 628 bp and contains an open reading frame whose product shows a large degree of sequence identity with the IS200-encoded transposase. IS1004 was present in one to eight copies in most of the V. cholerae strains analyzed. The IS1004-generated fingerprints of epidemic V. cholerae strains with serotype O1 were closely related, although it was possible to distinguish between the two biotypes, classical and El Tor. Non-O1 serotype strains generally showed heterogeneous patterns unrelated to those of the epidemic O1 strains. Several strains were observed with identical or related fingerprint patterns but expressed different serotypes. Conversely, strains with different fingerprint patterns but identical serotypes were also found. These observations indicate that the gene clusters coding for distinct O antigens may be transferred horizontally between V. cholerae strains. Two examples of non-O1 strains with a fingerprint resembling that of epidemic O1 strains were found; they were the O139 Bengal strain and an O37 strain. The O139 Bengal strain is closely related to the El Tor biotype. The O37 strain was responsible for a large cholera outbreak in Sudan in 1968 and was classified as a noncholera vibrio. Our study, however, shows that the O37 Sudan strain is genetically closely related to classical O1 strains. Similar to O139 Bengal, O37 Sudan lacked most of the O1 antigen cluster but did contain flanking genes. Thus, O37 Sudan represents a second example of an epidemic V. cholerae strain carrying non-O1 antigens. This study underlines the importance of genotypic methods for the differentiation of V. cholerae strains and for recognition of strains with epidemic potential.

Genesis of the novel epidemic Vibrio cholerae O139 strain: evidence for horizontal transfer of genes involved in polysaccharide synthesis.

Only Vibrio cholerae strains of serotype O1 are known to cause epidemics, while non-O1 strains are associated with sporadic cases of cholera. It was therefore unexpected that the recent cholera epidemic in Asia was caused by a non-O1 strain with the serotype O139. We provide evidence that O139 arose from a strain closely related to the causative agent of the present cholera pandemic, V. cholerae O1 El Tor, by acquisition of novel DNA which was inserted into, and replaced part of, the O antigen gene cluster of the recipient strain. Part of the novel DNA was sequenced and two open reading frames (otnA and otnB) were observed, the products of which showed homology to proteins involved in capsule and O antigen synthesis, respectively. This suggests that the otnAB DNA determines the distinct antigenic properties of the O139 cell surface. The otnAB DNA was not detected in O1 strains, but was present in two non-O1 V. cholerae strains with serotypes O69 and O141. In the O69 and O139 strains the otnAB genes were located proximate to the putative insertion sequence (IS) element rfbQRS, which is associated with O antigen synthesis genes in O1 strains, and may have played a role in the insertion of the otnAB DNA in the recipient chromosome. Our results suggest that the O139 strain arose by horizontal gene transfer between a non-O1 and an O1 strain. The acquired DNA has altered the antigenic properties of the recipient O1 strain, providing a selective advantage in a region where a large part of the population is immune to O1 strains.(ABSTRACT TRUNCATED AT 250 WORDS)