IS200: a Salmonella-specific insertion sequence

A new IS element (IS200) has been identified in Salmonella. The sequence was identified as an IS element by the following criteria: its insertion caused the mutation hisD984; six copies of the sequence are present in strain LT2 of S. typhimurium; and transposition of the sequence has been observed on several occasions. IS200 is found in almost all Salmonella species examined but is absent from most other enteric bacteria. The specificity of this element for Salmonella (and the absence of IS1-IS4 from Salmonella) suggest that transfer of insertion sequences between bacterial groups may be less extensive than is commonly believed. Alternatively, the distribution may suggest that these elements play a selectively important role in bacteria.     

Genetic Mapping of Is200 Copies in SALMONELLA TYPHIMURIM Strain Lt2

The wild-type Salmonella typhimurium strain LT2 contains six copies of the insertion sequence element IS200 which is unique to Salmonella. We have determined the chromosomal locations of all six copies of IS200 in strain LT2. This was done by mapping the positions of Tn10 elements inserted near each copy of IS200. Such Tn10 insertions were detected by Southern hybridization as IS200-containing restriction fragments with altered electrophoretic mobility. The copies are located at quite evenly spaced sites in the chromosome. Some are found in regions with many known genes; others are in regions with few known functions. There is no indication of a possible function for IS200. The method described here should be applicable to the mapping of IS elements in general.     

Recombination between Chromosomal Is200 Elements Supports Frequent Duplication Formation in Salmonella Typhimurium

Spontaneous tandem chromosomal duplications are common in populations of Escherichia coli and Salmonella typhimurium. They range in frequency for a given locus from 10(-2) to 10(-4) and probably form by RecA-dependent unequal sister strand exchanges between repetitive sequences in direct order. Certain duplications have been observed previously to confer a growth advantage under specific selective conditions. Tandem chromosomal duplications are unstable and are lost at high frequencies, representing a readily reversible source of genomic variation. Six copies of a small mobile genetic element IS200 are evenly distributed around the chromosome of S. typhimurium strain LT2. A survey of 120 independent chromosomal duplications (20 for each of six loci) revealed that recombination between IS200 elements accounted for the majority of the duplications isolated for three of the loci tested. Duplications of the his operon were almost exclusively due to recombination between repeated IS200 elements. These data add further support to the idea that mobile genetic elements provide sequence repeats that play an important role in recombinational chromosome rearrangements, which may contribute to adaptation of bacteria to stressful conditions.     

Absence of insertions among spontaneous mutants of Salmonella typhimurium

Summary While insertion sequences (IS) in Escherichia coli transpose frequently to generate spontaneous insertion mutants, such mutations are rare in Salmonella typhimurium: the only documented insertion mutation is a hisD mutation caused by the Salmonella-specific IS element IS200. To obtain more examples of IS200 insertion mutations and to seek additional types of IS elements in Salmonella, we selected and characterized 422 independent, spontaneous His^– mutants and some 2100 additional mutants that are not necessarily independent. None of the mutants showed the absolute polar effect characteristic of insertion mutations or the reversion properties characteristic of insertions (low spontaneous reversion frequency and no reversion induction by chemical mutagens). A few mutants, showing a high spontaneous reversion frequency, were screened physically. No insertion mutations were found. Thus insertion mutations appear to be rare in S. typhimurium, in strong contrast to E. coli and despite the possession in Salmonella of at least one type of insertion element (IS200). These results suggest that in Salmonella transposition of the endogenous elements has been controlled. The transposition ability of the elements may have been reduced or favored target sites removed from the host genome.     

Characterization of Salmonella virchow phage types by plasmid profile and IS200 distribution

The type strains of the 57 phage types of Salmonella virchow have been characterized by plasmid profile and by distribution of the insertion sequence IS 200 . Thirty-two strains carried plasmids and 21 profile types were identified; 17 strains were resistant to antimicrobial agents. In contrast only six of the type strains carried IS 200 elements and three patterns were identified. Within Salm. virchow phage type 31, five of 10 wild-type isolates carried plasmids and two plasmid profiles were identified; in contrast, an IS 200 element was identified in the genome of only one of these strains. It is concluded that for Salm. virchow , IS 200 is unlikely to significantly extend the degree of discrimination achieved by phage typing which may be supplemented when appropriate by plasmid profile typing.     

Identification and characterization of novel salmonella mobile elements involved in the dissemination of genes linked to virulence and transmission

The genetic diversity represented by >2,500 different Salmonella serovars provides a yet largely uncharacterized reservoir of mobile elements that can contribute to the frequent emergence of new pathogenic strains of this important zoonotic pathogen. Currently, our understanding of Salmonella mobile elements is skewed by the fact that most studies have focused on highly virulent or common serovars. To gain a more global picture of mobile elements in Salmonella, we used prediction algorithms to screen for mobile elements in 16 sequenced Salmonella genomes representing serovars for which no prior genome scale mobile element data were available. From these results, selected mobile elements underwent further analyses in the form of validation studies, comparative analyses, and PCR-based population screens. Through this analysis we identified a novel plasmid that has two cointegrated replicons (IncI1-IncFIB); this plasmid type was found in four genomes representing different Salmonella serovars and contained a virulence gene array that had not been previously identified. A Salmonella Montevideo isolate contained an IncHI and an IncN2 plasmid, which both encoded antimicrobial resistance genes. We also identified two novel genomic islands (SGI2 and SGI3), and 42 prophages with mosaic architecture, seven of them harboring known virulence genes. Finally, we identified a novel integrative conjugative element (ICE) encoding a type IVb pilus operon in three non-typhoidal Salmonella serovars. Our analyses not only identified a considerable number of mobile elements that have not been previously reported in Salmonella, but also found evidence that these elements facilitate transfer of genes that were previously thought to be limited in their distribution among Salmonella serovars. The abundance of mobile elements encoding pathogenic properties may facilitate the emergence of strains with novel combinations of pathogenic traits.     

Tris-dependent site-specific cleavage of Streptomyces lividans DNA

The copy number and location of the insertion sequence IS200, a mobile DNA element, was established across a collection of Salmonella berta. All strains contained one common site, assumed to be present in the evolutionary ancestor of this serovar. With one exception, all strains, including recent outbreak isolates from the UK and sporadic isolates of world-wide distribution, were representatives of a single genotypic clone which carried three common IS200 insertion sites. This clone has acquired diverse combinations of plasmids, reflecting its actual or recent distribution and host. A single isolate, belonging to a second, minor genotypic clone was characterised by two IS200 insertion sites.     

Evolutionary lines among Salmonella enteritidis phage types are identified by insertion sequence IS200 distribution

A survey was made of the presence, copy number and location of the Salmonella-specific DNA insertion element IS200, within the genomes of the 27 phage type strains of Salmonella enteritidis. All the phage type strains contained copies of IS200 revealed by genomic Southern blot hybridizations with a 300-bp DNA probe internal to the element. Restriction site variation around IS200 insertion sites was examined. Three fundamental patterns of hybridization corresponding to chromosomal IS200 loci were found. In terms of population genetics, these 'IS200 profiles' correspond to clonal lineages of recent evolutionary origin, and underline the phage-typing scheme for epidemiological subdivision of S. enteritidis. The molecular analysis is consistent with genetic selection pressures which are apparent in the observed epidemiological distribution of S. enteritidis, since each clonal lineage contained one of the phage types of major clinical importance in the U.K.     

Identification of Salmonella abortusovis by PCR amplification of a serovar-specific IS200 element.

Field and collection isolates of Salmonella abortusovis carry one IS200 element in a distinct chromosome location. IS200 is not found in the corresponding region of the chromosome of other Salmonella serovars. Sequencing of the boundaries of the S. abortusovis-specific IS200 insertion permitted the design of primers for the amplification of this IS200 element by PCR. Isolates of S. abortusovis are identified by the amplification of a DNA fragment of about 900 bp or larger. PCR amplification of DNA from salmonellae other than S. abortusovis yields either a fragment of about 200 bp or no product. The high specificity of the assay is confirmed by the absence of cross-reactivity with the following templates: (i) sheep DNA, (ii) DNAs from abortion-causing agents other than S. abortusovis, and (iii) DNAs from microorganisms that do not cause abortion but are common in flocks.     

Natural Populations of Escherichia Coli and Salmonella Typhimurium Harbor the Same Classes of Insertion Sequences

Despite their close phylogenetic relationship, Escherichia coli and Salmonella typhimurium were long considered as having distinct classes of transposable elements maintained by either host-related factors or very restricted gene exchange. In this study, genetically diverse collections of E. coli and S. typhimurium (subgroup I) were surveyed for the presence of several classes of insertion sequences by Southern blot analysis and the polymerase chain reaction. A majority of salmonellae contained IS1 or IS3, elements originally recovered from E. coli, while IS200, a Salmonella-specific element, was present in about 20% of the tested strains of E. coli. Based on restriction mapping, the extent of sequence divergence between copies of IS200 from E. coli and S. typhimurium is on the order of that observed in comparisons of chromosomally encoded genes from these taxa. This suggests that copies of IS200 have not been recently transferred between E. coli and S. typhimurium and that the element was present in the common ancestor to both species. IS200 is polymorphic within E. coli but homogeneous among isolates of S. typhimurium, providing evidence that these species might differ in their rates of transfer and turnover of insertion sequences.     

IS1397 is active for transposition into the chromosome of Escherichia coli K-12 and inserts specifically into palindromic units of bacterial interspersed mosaic elements

We demonstrate that IS1397, a putative mobile genetic element discovered in natural isolates of Escherichia coli, is active for transposition into the chromosome of E. coli K-12 and inserts specifically into palindromic units, also called repetitive extragenic palindromes, the basic element of bacterial interspersed mosaic elements (BIMEs), which are found in intergenic regions of enterobacteria closely related to E. coli and Salmonella. We could not detect transposition onto a plasmid carrying BIMEs. This unprecedented specificity of insertion into a well-characterized chromosomal intergenic repeated element and its evolutionary implications are discussed.     

Spontaneous transposition in the bacteriophage lambda cro gene residing on a plasmid.

A new mutagenesis assay system based on the phage lambda cro repressor gene residing on a plasmid was developed. The assay detects mutations in cro that decrease the binding of the repressor to the OR operator in an OR PR-lacZ fusion present in a lambda prophage. Mutations arose spontaneously during growth of E. coli cells harboring cro plasmids at a frequency of 3-6 x 10(-6). Analysis of some 200 cro mutants from several 'wild-type' strains revealed a substantial fraction of 25-70% insertion events caused by transposition of IS elements. Most of the insertions were caused by IS1, but IS5 insertions were observed too. In strains harboring Tn10, IS10 was responsible for most insertions. Restriction nuclease digestion analysis revealed a preference for insertion of IS10 into the C-terminal half of cro, despite the absence of sequences which are known hot spots for Tn10 insertions. The frequency of IS1 insertions into cro decreased 25-60-fold and that of IS10 insertions decreased 200-fold in cells carrying the recA56 mutation, suggesting that RecA is involved in transposition of these elements. During the logarithmic phase of growth, the mutation frequency was constant for at least 22 generations; however, upon continuous incubation at the stationary phase, the mutation frequency gradually increased, yielding a 3-fold increase in the frequency of insertion and a 4-5-fold increase in point mutation. Genomic Southern analysis of chromosomal IS elements in cells which underwent a transposition from the chromosome into the cro plasmid revealed that the number and distribution of IS1 and IS5 were usually unaltered compared to cells which did not undergo a transposition event. In contrast, essentially each IS10 transposition was accompanied by multiple events which led to changes in the number and distribution of chromosomal IS10 elements.     

Y1转座酶关联转座子在大肠杆菌和沙门氏菌基因组中的分布和结构特征

Y1转座酶关联转座子(Y1ATs)的活性催化位点为一个酪氨酸,能够切割和连接单链DNA,在原核生物分布广泛。为探究Y1转座酶关联转座子在大肠杆菌(Escherichia coli, E. coli)与沙门氏菌(Salmonella enterica, S. ente)基因组中系统进化特性,通过Hmmsearch程序对Y1转座酶关联转座子进行了挖掘分析。结果表明,Y1转座酶关联转座子广泛分布于96.84%大肠杆菌基因组和80.4%沙门氏菌基因组。根据序列比对和蛋白结构域预测将Y1转座酶关联转座子分为10类,均隶属于IS200/IS605超家族,其中11 645个属于IS200家族,4 811个属于IS605家族。IS200家族广泛分布于S. ente基因组中(72.24%),而IS605家族广泛分布于E. coli基因组中(89.38%)。IS200拷贝数以及完整拷贝数显著高于IS605。IS200家族仅含有一个Y1转座酶编码区,而IS605家族含两个开放阅读框,分别编码Y1转座酶和TnpB蛋白。IS200家族的Y1氨基酸序列高度保守(95.3%),而IS605家族的Y1和TnpB具有较高遗传多样性,为研究转座子在原核生物的遗传进化模式提供重要参考。IS200家族具有高度保守的Y1转座酶,且完整拷贝数比例较高,提示该类转座子可能具有转座活性,对其活性的挖掘有利于研制转座子介导的新型高效基因编辑工具。     

Conventional and molecular approaches to isolates of Salmonella hadar from sporadic and epidemic cases

In September 1994 an outbreak of gastroenteritis occurred in 437 people who had consumed lunch in the canteen of a factory in Central Italy. Salmonella sp. was isolated from stools of 99 patients and in 73 of them Salmonella hadar was identified. This is the first outbreak caused by this serotype described in Italy. In order to examine the genotypic basis of the epidemic strains, molecular typing was applied to sporadic strains isolated before and after the outbreak episode. For this purpose phage type, resistance to antibiotics, DNA plasmid profile and sites of insertion of the mobile element of IS200 were determined. The epidemic strains were genetically distinct from the non-epidemic isolates; they were shown to be phage type 26, harbouring four small plasmids, were resistant to nalidixic acid and showed a unique characteristic IS200 fingerprint. The typing methods used in this study allowed the identification and discrimination of the outbreak strains from related isolates. They can thus be considered as a tool for epidemiological purposes. In addition we should point out the emerging resistance to nalidixic acid, largely used in veterinary medicine, in Salm . hadar .     

Mutational Analysis of the Open Reading Frames in the Transposable Element Is1

IS1 is one of the smallest transposable elements found in bacteria (768 bp). It contains eight overlapping open-reading-frames (ORFs) greater than 50 codons, designated insA to insG and insB'. To determine which of the ORFs actually code for proteins involved in transposition, we have introduced amber codons into each ORF by site-directed mutagenesis which make neutral changes in the overlapping ORFs. Each mutant IS1 was then tested for its ability to mediate cointegrate formation in Su+ and Su- backgrounds. The mutant elements were also tested for trans-complementation in an IS1-free Salmonella background. Our results show that the products of the insA and insB genes are the only ones essential for cointegrate formation. We suggest that other ORFs may, however, encode accessory proteins.