Genomic organization of the yeast Yarrowia lipolytica

We produced electrophoretic karyotypes of the reference strain E150 and of seven other isolates from different geographical origins to study the genomic organization of the dimorphic yeast Yarrowia lipolytica. These karyotypes differed in the number and size of the chromosomal bands. The karyotype of the reference stain E150 consisted of five bands of between 2.6 and 4.9 Mb in size. This strain contained at least five rDNA clusters, from 190 to 620 kb in size, which were scattered over most of the chromosomes. The assignment of 43 markers, including rRNA genes and three centromeres, to the E150 bands defined five linkage groups. Hybridization to the karyotypes of other isolates with pools of markers of each linkage group showed that linkage groups I, II, IV and V were conserved in the strains tested whereas group III was not and was split between at least two chromosomes in most strains. Use of a meganuclease I-SceI site targeted to one locus of E150 linkage group III showed that two chromosomes actually comigrated in band III of this strain. Our results are compatible with six chromosomes defining the haploid complement of strains of Y. lipolytica and that, despite an unprecedented chromosome length polymorphism, the overall structure of the genome is conserved in different isolates. Received: 27 March 1997; in revised form: 8 July 1997 / Accepted: 9 July 1997     

Physical map and gene localization on sunflower (Helianthus annuus) chloroplast DNA: evidence for an inversion of a 23.5-kbp segment in the large single copy region

As a first step in the study of chloroplast genome variability in the genus Helianthus, a physical restriction map of sunflower (Helianthus annuus) chloroplast DNA (cpDNA) has been constructed using restriction endonucleases BamH I, Hind III, Pst I, Pvu II and Sac. I. Sunflower circular DNA contains an inverted repeat structure with the two copies (23 kbp each) separated by a large (86 kbp) and a small (20 kbp) single copy region. Its total length is therefore about 152 kbp. Sunflower cpDNA is essentially colinear with that of tobacco with the exception of an inversion of a 23.5-kbp segment in the large single copy region. Gene localization on the sunflower cpDNA and comparison of the gene map with that from tobacco chloroplasts have revealed that the endpoints of the inversion are located between the trnT and trnE genes on the one hand, and between the trnG and trnS genes on the other hand.Analysis of BamH I restriction fragment patterns of H. annuus, H. occidentalis ssp. plantagineus, H. grossesseratus, H. decapetalus, H. giganteus, H. maximiliani and H. tuberosus cpDNAs suggests that structural variations are present in the genus Helianthus.     

Chromosome of the enterohemorrhagic Escherichia coli O157:H7; comparative analysis with K-12 MG1655 revealed the acquisition of a large amount of foreign DNAs.

A complete Xba I and Bln I cleavage map was constructed for the chromosome of an enterohemorrhagic Escherichia coli (EHEC) O157:H7 strain isolated from an outbreak in Sakai City, Japan, in 1996. A comparative chromosome analysis with E. coli K-12 strain MG1655 was made. The EHEC chromosome was approximately 5600 kb in length, 1 Mb larger than that of MG1655. Despite the marked difference in chromosome length, the location and direction of seven rRNA operons of the EHEC strain were similar to those for MG1655. Overall organization of genes common in both strains is also highly conserved. Chromosome expansion was observed throughout the EHEC chromosome, albeit in an uneven manner. A large portion of the chromosome enlargement was observed in the region surrounding the replication terminus, particularly in a segment containing the terA locus. Sample sequencing of 3627 random shotgun clones suggested the presence of approximately 1550 kb strain-specific DNAs on the EHEC chromosome, most of which are likely to be of foreign origin.     

Restriction Enzyme Analysis of Mitochondrial DNA of Acanthamoeba Strains in Japan

ABSTRACT. Eight isolates, identified as either Acanthamoeba castellanii or A. polyphaga from human eye infections, contact lens containers, and soil in Japan, were characterized by restriction fragment length polymorphisms (RFLP) of mitochondrial DNA (mtDNA). Mitochondrial DNA was digested with either Bgl II, Eco R I, Hind III, Hpa I, Sca I or Xba I, electrophoresed in agarose gels, and stained with ethidium bromide. Four distinct RFLP phenotypes that refer to the collection of six fragment size patterns obtained for a single strain with six enzymes, were discovered among the eight strains used in this study. Three strains morphologically classified as A. polyphaga share a single RFLP phenotype with the Ma strain of A. castellanii. The interspecific sequence differences of 7.06–12.74% in DNA nucleotide were estimated from the proportion of DNA fragments shared by each pair of mtDNA.     

临床分离耐甲氧西林溶血性葡萄球菌的SCCmec分型及同源性分析

目的了解临床分离耐甲氧西林溶血性葡萄球菌（MRSH）的SCCmec基因型别及相同SCCmec型别菌株的同源性。方法多重PCR进行SCCmec分型,ERIC-PCR法对相同SCCmec型别菌株进行同源性分析。结果83株临床分离MRSH菌株中,SCCmecI型有23株（27．7％）,SCCmecⅡ型有10株（12．1％）,SCCmecm型有24株（28．9％）,SCCmecIV型有1株（1．2％）,I、Ⅱ混合型有8株（9．6％）,I、Ⅲ混合型有6株（7．2％）,Ⅱ、11混合型有5株（6．0％）,I、Ⅱ、Ⅲ混合型有3株（3．6％）,未分型3株（3．6％）。ERIC—PCR结果显示,23株SCCmecI型分为11型,其中A型5株,B型5株,C型3株,其余8株各为1型,2株未分型;10株SCCmecⅡ型分为6型,其中D型4株,E型2株,3株各为1型,1株未分型;24株SCCmecm型分为9型,其中F型11株,G型2株,H型2株,I型2株,5株各为1型,2株未分型。结论临床分离MRSH中,SCCmecI、Ⅲ型为多,部分菌株呈混合型别;相同SCCmec型别的部分菌株之间可能存在克隆传播。     

Integron-bearing methicillin-resistant coagulase-negative staphylococci in South China, 2001-2004.

A total of 53 methicillin-resistant coagulase-negative staphylococci strains isolated in a hospital in Guangzhou, China, were analyzed to detect class 1 integrons and SCCmec typing. Thirty strains had the class 1 integrase (intI1) gene and 26 strains possessed the 3' conserved region of qacEDelta1-sul1. Four different types of gene cassette arrays were found and a highly prevalent array of dfrA12-orfF-aadA2 gene cassettes was observed. Thirty class 1 integron-positive coagulase-negative staphylococci strains were subjected to Southern hybridization analysis; the result showed that class 1 integrons were located on chromosome, not plasmid. According to the results of SCCmec typing for 30 integron-bearing MRCNS strains, five, 15 and five strains belonged to type I, II and III SCCmec, respectively, and five strains were untypeable. For 23 non-integron-bearing methicillin-resistant coagulase-negative staphylococci strains, four, nine and seven strains belonged to type I, II and III SCCmec, respectively, and three strains were untypeable. None of the strains belonged to type IV or V. Twenty-three coagulase-negative staphylococci isolates of three Staphylococcal species that contained the dfrA12-orfF-aadA2 gene cassette array were phylogenetically unrelated to each other by randomly amplified polymorphic DNA, indicating that the gene cassettes might be disseminated in the clinical strains by a horizontal gene transfer.     

Alterations in the adenine-plus-thymine-rich region of CEN3 affect centromere function in Saccharomyces cerevisiae.

Centromere DNA from 11 of the 16 chromosomes of the yeast Saccharomyces cerevisiae have been analyzed and reveal three sequence elements common to each centromere, referred to as conserved centromere DNA elements (CDE). The adenine-plus-thymine (A + T)-rich central core element, CDE II, is flanked by two short conserved sequences, CDE I (8 base pairs [bp]) and CDE III (25 bp). Although no consensus sequence exists among the different CDE II regions, they do have three common features of sequence organization. First, the CDE II regions are similar in length, ranging from 78 to 86 bp measured from CDE I to the left boundary of CDE III. Second, the base composition is always greater than 90% A + T. Finally, the A and T residues in these segments are often arranged in runs of A and runs of T residues, sometimes with six or seven bases in a stretch. We constructed insertion, deletion, and replacement mutations in the CDE II region of the centromere from chromosome III, CEN3, designed to investigate the length and sequence requirements for function of the CDE II region of the centromere. We analyzed the effect of these altered centromeres on plasmid and chromosome segregation in S. cerevisiae. Our results show that increasing the length of CDE II from 84 to 154 bp causes a 100-fold increase in chromosome nondisjunction. Deletion mutations removing segments of the A + T-rich CDE II DNA also cause aberrant segregation. In some cases partial function could be restored by replacing the deleted DNA with fragments whose primary sequence or base composition is very different from that of the wild-type CDE II DNA. In addition, we found that identical mutations introduced into different positions in CDE II have very similar effects.     

Homology in capsular transformation reactions in Pneumococcus

Summary Experiments were carried out to determine the relative effect of homology inside or outside of the capsular genomes of donor and recipient strains of pneumococci on the frequency of transfer of capsular markers. In one series of experiments, 3 recipient strains were transformed to CapIII⁺ by DNA from 2 donor strains. Recipient strains (III)capIII D6 ¹, (II)capIII D15 P1 ¹, and (II)capII-1 ¹ were each transformed to CapIII⁺ at different absolute frequencies dependent upon the amount of genetic information that the strain had to acquire. The chromosomal background of the donor strain carrying the CapIII capsular genome had no influence on the results, however, for each strain was transformed at the same frequency by DNA from donor strain (II)CapIII⁺ or donor strain (III)CapIII⁺. In a second series of experiments, 2 (I)CapIII-strains, a (II)CapIII-strain and a (III)CapIII-strain were transformed to heterologous type I and binary type I-III with DNA from donor strains (I)CapI⁺, (II)CapI⁺, and (III)CapI⁺. Again, the chromosomal background of the donor strain was unimportant to the results. The origin of the recipient strain, however, markedly influenced the frequency of transformation. (I)CapIII-strains were transformed to CapI⁺ at about 10 times the frequency and to CapI-III at from 18–6000 times the frequency of the other CapIII-strains. Consideration of the results leads to the conclusion that transformation of CapIII-strains to CapI⁺ and transformation of CapI-strains to CapIII⁺ are not reciprocal reactions; CapI-strains lose less information in transformation to CapIII⁺ than CapIII-strains gain in transformation to CapI⁺. In (I)CapIII-recipient strains, the residual information from the CapI capsular genome is responsible for the higher frequency of transformation to both CapI⁺ and to CapI-III. It is suggested that addition of exogenous linear DNA to a recipient chromosome to give rise to binary strains occurs when sequence homology with the recipient is limited to one end of a piece of transforming DNA. Models to explain the results (Figs. 1 through 3) are consistent with the experimental findings and are amenable to further testing.     

Structural conservation and variation in the mitochondrial control region of fringilline finches (Fringilla spp.) and the greenfinch (Carduelis chloris)

We sequenced the entire control region and portions of flanking genes (tRNA(Phe), tRNA(Glu), and ND6) in the common chaffinch (Fringilla coelebs), blue chaffinch (F. teydea), brambling (F. montifringilla), and greenfinch (Carduelis chloris). In these finches the control region is similar in length (1,223-1,237 bp) and has the same flanking gene order as in other birds, and contains a putative TAS element and the highly conserved CSB-1 and F, D, and C boxes recognizable in most vertebrates. Cloverleaf-like structures associated with the TAS element at the 5' end and CSB-1 at the 3' end of the control region may be involved with the stop and start of D-loop synthesis, respectively. The pattern of nucleotide and substitution bias is similar to that in other vertebrates, and consequently the finch control region can be subdivided into a central, conserved G-rich domain (domain II) flanked by hypervariable 5'-C-rich (domain I) and 3'-AT-rich (domain III) segments. In pairwise comparisons among finch species, the central domain has unusually low transition/transversion ratios, which suggests that increased G + T content is a functional constraint, possibly for DNA primase efficiency. In finches the relative rates of evolution vary among domains according to a ratio of 4.2 (domain III) to 2.2 (domain I) to 1 (domain II), and extensively among sites within domains I and II. Domain I and III sequences are extremely useful in recovering intraspecific phylogeographic splits between populations in Africa and Europe, Madeira, and a basal lineage in Nefza, Tunisia. Domain II sequences are highly conserved, and are therefore only useful in conjunction with sequences from domains I and III in phylogenetic studies of closely related species.      

Genetic Analysis of Flagellar Mutants in Escherichia coli

Flagellar mutants in Escherichia coli were obtained by selection for resistance to the flagellotropic phage chi. F elements covering various regions of the E. coli genome were then constructed, and, on the basis of the ability of these elements to restore flagellar function, the mutations were assigned to three regions of the E. coli chromosome. Region I is between trp and gal; region II is between uvrC and aroD; and region III is between his and uvrC. F elements carrying flagellar mutations were constructed. Stable merodiploid strains with a flagellar defect on the exogenote and another on the endogenote were then prepared. These merodiploids yielded information on the complementation behavior of mutations in a given region. Region III was shown to include at least six cistrons, A, B, C, D, E, and F. Region II was shown to include at least four cistrons, G, H, I, and J. Examination of the phenotypes of the mutants revealed that those with lesions in cistron E of region III produce "polyhooks" and lesions in cistron F of region III result in loss of ability to produce flagellin. Mutants with lesions in cistron J of region II were entirely paralyzed (mot) mutants. Genetic analysis of flagellar mutations in region III suggested that the mutations located in cistrons A, B, C, and E are closely linked and mutations in cistrons D and F are closely linked.     

Mutational Analysis of Meiotic and Mitotic Centromere Function in Saccharomyces cerevisiae

A centromere (CEN) in Saccharomyces cerevisiae consists of approximately 150 bp of DNA and contains 3 conserved sequence elements: a high A + T region 78-86 bp in length (element II), flanked on the left by a conserved 8-bp element I sequence (PuTCACPuTG), and on the right by a conserved 25-bp element III sequence. We have carried out a structure-function analysis of the element I and II regions of CEN3 by constructing mutations in these sequences and subsequently determining their effect on mitotic and meiotic chromosome segregation. We have also examined the mitotic and meiotic segregation behavior of ARS plasmids containing the structurally altered CEN3 sequences. Replacing the periodic tracts of A residues within element II with random A + T sequences of equal length increases the frequency of mitotic chromosome nondisjunction only 4-fold; whereas, reducing the A + T content of element II while preserving the length results in a 40-fold increase in the frequence of chromosome nondisjunction. Structural alterations in the element II region that do not decrease the overall length have little effect on the meiotic segregation behavior of the altered chromosomes. Centromeres containing a deletion of element I or a portion of element II retain considerable mitotic activity, yet plasmids carrying these same mutations segregate randomly during meiosis I, indicating these sequences to be essential for maintaining attachment of the replicated sister chromatids during the first meiotic division. The presence of an intact element I sequence properly spaced from the element III region is absolutely essential for proper meiotic function of the centromere.     

Genetics of cytochrome P450 in two insecticide-resistant strains of the housefly,Musca domestica L.

A susceptible strain of Musca domestica containing visible mutant markers on chromosomes II, III, and V was crossed with multiresistant R-Fc and R-diazinon strains. F₁ flies were backcrossed to the mutant parent, resultant progenies were isolated according to phenotype, and substrains were established. The level of resistance to diazinon, aldrin epoxidase activity, and cytochrome P450 difference spectra of microsomes from each substrain were measured. Titers of cytochrome P450, measured as CO spectra, as well as type I, type II, and type III cytochrome P450 substrate difference spectra were compared in microsomal preparations obtained from phenotypes containing vatious resistant chromosome combinations. In both resistant strains, high levels of cytochrome P450 were controlled by a gene(s) on chromosome II. In R-diazinon, qualitative spectral changes were also controlled by chromosome II, whereas in R-Fc both chromosomes II and V contributed to qualitative changes in cytochrome P450. Both quantitative and qualitative characteristics were intermediate in heterozygous flies, suggesting incomplete dominance for their inheritance. Findings are discussed in relation to known genetics of microsomal resistance to insecticides.     

Localization of prophages of serological group B and F on restriction fragments defined in the restriction map of Staphylococcus aureus NCTC 8325

Abstract Several Staphylococcus aureus strains were lysogenized by the phages of serological group B (phages φ53, φ85) as well as by some of serological group F (phages φ77, φ84) and macrorestriction fragment patterns of genomic DNA were estimated in the lysogenized, non-lysogenic and delysogenized (cured of prophages) strains. It was shown that the integration of phage DNA into chromosome of S. aureus leads to specific changes in restriction fragment pattern in all the lysogenized strains. These changes correlate well with the Sma I restriction map of S. aureus NCTC 8325 since they concern the restriction fragments defined in this map. Phages φ53 and φ85 integrate into Sma I fragment B. On the other hand, phages φ77 and φ84 integrate into Smal fragment E of the S. aureus restriction map. The prophages of strain NCTC 8511 have their integration sites, as follows: the phage designated by us φM integrates in fragment A, whereas the integration site for phage φJ lies in fragment E. Phage φM was estimated to be genetically related to phages of serological group A and phage φJ to those of serological group F. Evidence was given that lysogenization of S. aureus strains by at least four prophages does not cast any doubt upon the estimation of their genetic relatedness based on their similarity in restriction pattern.     

Precocious Meiotic Centromere Separation of a Novel Yeast Chromosome

In Saccharomyces cerevisiae, a reciprocal translocation between chromosome II and a linear plasmid carrying a centromere (CEN6) has split chromosome II into two fragments: one, approximately 530 kilobase pairs (kbp) in size, has the left arm and part of the right arm of chromosome II; the other, a telocentric fragment approximately 350 kbp in size, has CEN6 and the rest of the right arm of chromosome II. A cross of this yeast strain with a strain containing a complete chromosome II exhibits a high frequency of precocious centromere separation (separation of sister chromatids during meiosis I) of the telocentric fragment. Precocious centromere separation is not due to the position of the centromere per se, since diploids that are homozygous for both fragments of chromosome II segregate the telocentric fragment with normal meiotic behavior. The precocious centromere separation described here differs from previously described examples in that pairing and synapsis of this telocentric chromosome seem to be normal. One model of how centromeres function in meiosis is that replication of the centromere is delayed until the second meiotic division. Data presented in this paper indicate that replication of the centromere is complete before the first meiotic division. The precocious separation of the centromere described here may be due to improper synapsis of sequences flanking the centromere.     

Identification of distinct Campylobacter lari genogroups by amplified fragment length polymorphism and protein electrophoretic profiles

Campylobacter lari is a phenotypically and genotypically diverse species that comprises the classical nalidixic acid-resistant thermophilic campylobacters (NARTC) and the biochemical C. lari variants, including the urease-positive campylobacters (UPTC), the nalidixic acid-susceptible campylobacters (NASC), and the urease-producing nalidixic acid-susceptible campylobacters. To study the taxonomic and epidemiological relationships among strains of the C. lari variants, amplified fragment length polymorphism (AFLP) profiling and whole-cell protein profile analysis were performed with 55 C. lari strains. Great genetic heterogeneity in AFLP and protein profiles was observed. Numerical analysis of AFLP profiles and of partial protein profiles allowed discrimination of four distinct genogroups. AFLP cluster I included nearly homogeneous patterns for C. lari NARTC strains (genogroup I). UPTC strains together with non-urease-producing NASC strains produced highly diverse patterns and were placed in genogroup II. The genogroup III strains had the NASC phenotype and produced more homogeneous patterns. Finally, genogroup IV strains had the classical NARTC phenotype and produced AFLP patterns that were very distinct from those of other genogroups. One UPTC strain had aberrant patterns and clustered separately, which may indicate that there is an additional genogroup. Preliminary DNA-DNA hybridization experiments suggested that genogroups I and III represent a single genomic species and that genogroup IV represents a distinct species. The detection of moderate levels of DNA-DNA hybridization between a genogroup II reference strain and genogroup I and III reference strains highlights the need for further DNA-DNA hybridization experiments to clarify the taxonomic status of the former group. No correlation of genogroups with different sources of strains was identified. These data show that UPTC strains are genetically diverse and distinct from NARTC strains. In addition, they indicate that the classical NARTC phenotype encompasses at least two genogroups.     

Drosophila-Host Genetic Control of Susceptibility to Drosophila C Virus

Interactions between Drosophila C virus (DCV) and its natural host, Drosophila melanogaster, were investigated using 15 geographical population samples infected by intraabdominal inoculation. These strains derived from natural populations of D. melanogaster differed in susceptibility to the DCV(C). One strain was ``partially tolerant'. Isofemale lines obtained from one susceptible and one partially tolerant strain were studied. The partially tolerant phenotype was dominant, and there was no difference between F(1) progeny of direct and reciprocal crosses. Analysis of F(2) progeny showed that neither sex-linked genes nor maternal effects are involved in susceptibility to DCV(C). The partially tolerant strain phenotype was dominant and segregated with chromosome III. Two nonexclusive hypotheses are proposed to explain chromosome III gene action.