Transmission of the yeast mitochondrial genome to progeny: The impact of intergenic sequences

Summary In a previous publication it was shown that the output of yeast mitochondrial loci lacking nearby intergenic sequences (encompassing ori/rep elements) was reduced in crosses to strains with wild-type mtDNAs. In the present work, mitochondrial genomes carrying the intergenic deletions were marked at unlinked, loci by introducing specific antibiotic resistance mutations against erythromycin, oligomycin and paromomycin. These marked genomes were used to follow the output of unlinked regions of the genome from crosses between the intergenic deletion mutants and wild-type strains. Transmission of genetically unlinked markers in coding regions was substantially reduced when an intergenic deletion was present on the same genome. In general the transmission of the antibiotic markers was the same as or slightly higher than the corresponding intergenic marker. These results indicate that the presence of an intergenic deletion in the regions studied impairs the transmission to progeny of a mitochondrial genome as a whole. More specifically, the results suggest that ori/rep sequences, present in the regions that have been deleted, confer a competitive advantage over genomes lacking a full complement of such sequences. These results support the hypothesis that intergenic sequences, and specifically ori/rep elements, have a biological role in the mitochondrial genome. However, because of the exclusive presence of ori/rep sequences in the genus Saccharomyces, it may be that these sequences evolved in (or invaded) the mitochondrial genome relatively late in the evolution of the yeasts. Therefore, in a more general sense, variations in the amount and structure of intergenic sequences in various yeasts may reflect processes that have been of selective advantage in the metabolism of individual mitochondrial DNA in a particular environment and that have not drastically interrupted the respiratory phenotype.     

The distribution of the transposable elementBari-1 in theDrosophila melanogaster andDrosophila simulans genomes

The distribution of the transposable elementBari-1 inD. melanogaster andD. simulans was examined by Southern blot analysis and byin situ hybridization in a large number of strains of different geographical origins and established at different times.Bari-1 copies mostly homogeneous in size and physical map are detected in all strains tested. Both inD. melanogaster and inD. simulans a relatively high level of intraspecific insertion site polymorphism is detectable, suggesting that in both speciesBari-1 is or has been actively transposing. The main difference between the two sibling species is the presence of a large tadem array of the element in a well-defined heterochromatic location of theD. melanogaster genome, whereas such a cluster is absent inD. simulans. The presence ofBari-1 elements with apparently identical physical maps in allD. melanogaster andD. simulans strains examined suggests thatBari-1 is not a recent introduction in the genome of themelanogaster complex. Structural analysis reveals unusual features that distinguish it from other inverted repeat transposons, whereas many aspects are similar to the widely distributedTc1 element ofC. elegans.     

Retrotransposon <Emphasis Type="Italic">gtwin</Emphasis>: Structural analysis and distribution in <Emphasis Type="Italic">Drosophila</Emphasis> strains

A search for noncanonical variants of the gypsy retrotransposon ( MDG4 ) in the genome of the Drosophila melanogaster strain G32 led to the cloning of four copies of the poorly studied 7411-bp gtwin element. Sequence analysis showed that gtwin belongs to a family of endogeneous retroviruses, which are widespread in the Drosophila genome and have recently been termed insect erantiviruses. The gtwin retrotransposon is evolutionarily closest to MDG4, as evident from a good alignment of their nucleotide sequences including ORF2 (the pol gene) and ORF3 (the env gene), as well as the amino acid sequences of their protein products. These regions showed more than 75% homology. The distribution of gtwin was studied in several strains of the genus Drosophila. While strain G32 contained more than 20 copies of the element, ten other D. melanogaster strains carried gtwin in two to six copies per genome. The gtwin element was not detected in D. Hydei or D. Virilis. Comparison of the cloned gtwin sequences with the gtwin sequence available from the D. melanogaster genome database showed that the two variants of the mobile element differ by the presence or absence of a stop codon in the central region of ORF3. Its absence from the gtwin copies cloned from the strain G32 may indicate an association between the functional state of ORF3 and amplification of the element.Translated from Genetika, Vol. 41, No. 1, 2005, pp. 23–29.Original Russian Text Copyright © 2005 by Kotnova, Karpova, Feoktistova, Lyubomirskaya, Kim, Ilyin.     

Molecular domestication of mobile elements

Transposable elements are ubiquitous in all organisms and represent a dynamic component of their genomes, causing mutations and thereby genetic variation. Because of their independent and expansive replication strategy, these elements are called selfish and were thought to have no impact on the adaptive evolution of their host organisms. Although most TE-induced mutations seem to exert only negative effects on the fitness of their carrier, recent evidence indicates that in the course of evolution at least some TE-mediated changes have become established features of the host genome. For example, the insertion of TEs may provide novel cis-regulatory regions to preexisting host genes or TE-derived trans-acting factors may undergo a molecular transition into novel host genes through a process described as molecular domestication. The stationary P element related gene clusters of D. guanche, D. madeirensis and D. subobscura provide an excellent model system to study the evolutionary impact of TEs on genome evolution. Each cluster unit consists of a cis-regulating section composed of different insertion sequences followed by the first three exons of a P element that are coding for a 66 kDa ‘repressor-like’ protein. This revised version was published online in August 2006 with corrections to the Cover Date.     

INTROGRESSION IN THE DROSOPHILA SUBOBSCURA—D. MADEIRENSIS SISTER SPECIES: EVIDENCE OF GENE FLOW IN NUCLEAR GENES DESPITE MITOCHONDRIAL DIFFERENTIATION

Species hybridization, and thus the potential for gene flow, was once viewed as reproductive mistake. However, recent analysis based on large datasets and newly developed models suggest that gene exchange is not as rare as originally suspected. To investigate the history and speciation of the closely related species Drosophila subobscura, D. madeirensis, and D. guanche, we obtained polymorphism and divergence data for 26 regions throughout the genome, including the Y chromosome and mitochondrial DNA. We found that the D. subobscura X/autosome ratio of silent nucleotide diversity is significantly smaller than the 0.75 expected under neutrality. This pattern, if held genomewide, may reflect a faster accumulation of beneficial mutations on the X chromosome than on autosomes. We also detected evidence of gene flow in autosomal regions, while sex chromosomes remain distinct. This is consistent with the large X effect on hybrid male sterility seen in this system and the presence of two X chromosome inversions fixed between species. Overall, our data conform to chromosomal speciation models in which rearrangements are proposed to serve as gene flow barriers. Contrary to other observations in Drosophila, the mitochondrial genome appears resilient to gene flow in the presence of nuclear exchange.     

A Comparative Analysis of Stachybotrys chartarum Strains Isolated in Russia

This work deals with a comparative analysis of Stachybotrys chartarum strains isolated from various artificial cellulose-containing materials and natural substrates in geographically distant regions of Russia. The analysis included determination of the spore size; the strain toxicity to Paramecium caudatum; the strain resistance to the fungicides Benomil, Olilen, and Tilt; and the PCR study of the genome structure with the aid of a primer that was complementary to the core sequence of the SINE retrotransposon. It was found that some of the strains that were isolated from different areas and from different substrates differ in their toxicity, fungicide resistance, and genome structure. PCR analysis showed the absence of any correlation between the genome structure, the strain properties, the geographic area, and the substrates from which the strains were isolated. The pheno- and genotypic diversity of the strains and their different vegetative compatibility suggest the existence of an intraspecies diversity of the S. chartarum strains that were isolated in different geographic areas. The absence of any correlation between the pheno- and genotypic properties of the strains and the substrates from which they were isolated implies that the colonization of artificial substrates by S. chartarum occurred occasionally from natural habitats. The S. chartarum populations that live on artificial substrates are unlikely to have their own evolutionary history.     

Shared molecular characteristics of successfully transformed mitochondrial genomes in <Emphasis Type="Italic">Chlamydomonas</Emphasis><Emphasis Type="Italic">reinhardtii</Emphasis>

Three types of respiratory deficient mitochondrial strains have been reported in Chlamydomonas reinhardtii: a deficiency due to (i) two base substitutions causing an amino acid change in the apocytochrome b (COB) gene (i.e., strain named dum-15), (ii) one base deletion in the COXI gene (dum-19), or (iii) a large deletion extending from the left terminus of the genome to somewhere in the COB gene (dum-1, -14, and -16). We found that these respiratory deficient strains of C. reinhardtii can be divided into two groups: strains that are constantly transformable and those could not be transformed in our experiments. All transformable mitochondrial strains were limited to the type that has a large deletion in the left arm of the genome. For these mitochondria, transformation was successful not only with purified intact mitochondrial genomes but also with DNA-constructs containing the compensating regions. In comparison, mitochondria of all the non-transformable strains have both of their genome termini intact, leading us to speculate that mitochondria lacking their left genome terminus have unstable genomes and might have a higher potential for recombination. Analysis of mitochondrial gene organization in the resulting respiratory active transformants was performed by DNA sequencing and restriction enzyme digestion. Such analysis showed that homologous recombination occurred at various regions between the mitochondrial genome and the artificial DNA-constructs. Further analysis by Southern hybridization showed that the wild-type genome rapidly replaces the respiratory deficient monomer and dimer mitochondrial genomes, while the E. coli vector region of the artificial DNA-construct likely does not remain in the mitochondria.     

Histone H1 Genes and Histone Gene Clusters in the Genus Drosophila

Whereas the genomes of many organisms contain several nonallelic types of linker histone genes, one single histone H1 type is known in Drosophila melanogaster that occurs in about 100 copies per genome. Amplification of H1 gene sequences from genomic DNA of wild type strains of D. melanogaster from Oregon, Australia, and central Africa yielded numerous clones that all exhibited restriction patterns identical to each other and to those of the known H1 gene sequence. Nucleotide sequences encoding the evolutionarily variable domains of H1 were determined in two gene copies of strain Niamey from central Africa and were found to be identical to the known H1 sequence. Most likely therefore, the translated sequences of D. melanogaster H1 genes do not exhibit intragenomic or intergenomic variations. In contrast, three different histone H1 genes were isolated from D. virilis and found to encode proteins that differ remarkably from each other and from the H1 of D. melanogaster and D. hydei. About 40 copies of H1 genes are organized in the D. virilis genome with copies of core histone genes in gene quintets that were found to be located in band 25F of chromosome 2. Another type of histone gene cluster is present in about 15 copies per genome and contains a variable intergenic sequence instead of an H1 gene. The H1 heterogeneity in D. virilis may have arisen from higher recombination rates than occur near the H1 locus in D. melanogaster and might provide a basis for formation of different chromatin subtypes. Received: 2 March 2000 / Accepted: 1 June 2000     

Comparative Sequence Analysis of the <Emphasis Type="Italic">Phytochrome C</Emphasis> Gene and its Upstream Region in Allohexaploid Wheat Reveals New Data on the Evolution of its Three Constituent Genomes

Bread wheat is an allohexaploid with genome composition AABBDD. Phytochrome C is a gene involved in photomorphogenesis that has been used extensively for phylogenetic analyses. In wheat, the PhyC genes are single copy in each of the three homoeologous genomes and map to orthologous positions on the long arms of the group 5 chromosomes. Comparative sequence analysis of the three homoeologous copies of the wheat PhyC gene and of some 5 kb of upstream region has demonstrated a high level of conservation of PhyC, but frequent interruption of the upstream regions by the insertion of retroelements and other repeats. One of the repeats in the region under investigation appeared to have inserted before the divergence of the diploid wheat genomes, but was degraded to the extent that similarity between the A and D copies could only be observed at the amino acid level. Evidence was found for the differential presence of a foldback element and a miniature inverted-repeat transposable element (MITE) 5′ to PhyC in different wheat cultivars. The latter may represent the first example of an active MITE family in the wheat genome. Several conserved non-coding sequences were also identified that may represent functional regulatory elements. The level of sequence divergence (K_s) between the three wheat PhyC homoeologs suggests that the divergence of the diploid wheat ancestors occurred some 6.9 Mya, which is considerably earlier than the previously estimated 2.5–4.5 Mya. K_a/K_s ratios were <0.15 indicating that all three homoeologs are under purifying selection and presumably represent functional PhyC genes. RT-PCR confirmed expression of the A, B and D copies. The discrepancy in evolutionary age of the wheat genomes estimated using sequences from different parts of the genome may reflect a mosaic origin of some of the Triticeae genomes.     

酱香型白酒发酵中地衣芽孢杆菌前噬菌体的鉴别

【背景】噬菌体是微生物群落的重要组成部分,但传统白酒发酵中噬菌体的分类和存在尚不清楚。【目的】通过检测公共数据库和酱香型白酒发酵中地衣芽孢杆菌(Bacillus licheniformis)基因组中的前噬菌体整合区域,探究传统酱香型白酒发酵中关键功能菌株的前噬菌体分类和侵染情况。【方法】使用未培养(细菌全基因组分析)和可培养(菌株筛选和特异性PCR反应)技术对不同环境来源和来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体的分类和存在进行解析。【结果】细菌全基因组分析显示,30株来自不同环境的地衣芽孢杆菌基因组中共注释到165个前噬菌体,其中63.6%(105/165)为完整前噬菌体序列。97.1%感染地衣芽孢杆菌的噬菌体属于长尾噬菌体科(Siphoviridae),2.9%属于肌尾噬菌体科(Myoviridae),53.0%完整前噬菌体的基因功能未知。在来自酱香型白酒发酵的B. licheniformis MT-B06中检测到7个前噬菌体整合序列,其中57.1%(4/7)为完整前噬菌体序列,来自酱香型白酒发酵的地衣芽孢杆菌存在多种不同前噬菌体的共感染。来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体存在来自细菌基因组上相邻CotD孢子外壳蛋白(CotD family spore coat protein)基因的水平基因转移。在26株来自酱香型白酒发酵的地衣芽孢杆菌中,69.2%(18/26)存在噬菌体编码主要衣壳蛋白的基因,100.0%(26/26)存在噬菌体编码CotD孢子外壳蛋白的基因。【结论】来自不同环境的地衣芽孢杆菌和酱香型白酒发酵的地衣芽孢杆菌中存在高水平的前噬菌体整合,来自酱香型白酒发酵的地衣芽孢杆菌前噬菌体中广泛存在来源于宿主的CotD孢子外壳蛋白基因的水平基因转移。本研究为首次对传统发酵白酒中噬菌体的分类和存在进行探究,有助于对发酵微生物群落中噬菌体-细菌相互作用加深理解。     

Postmating Reproductive isolation between strains of Drosophila willistoni

Speciation can occur through the presence of reproductive isolation barriers that impede mating, restrict cross-fertilization, or render inviable/sterile hybrid progeny. The D. willistoni subgroup is ideally suited for studies of speciation, with examples of both allopatry and sympatry, a range of isolation barriers, and the availability of one species complete genome sequence to facilitate genetic studies of divergence. D. w. willistoni has the largest geographic distribution among members of the Drosophila willistoni subgroup, spanning from Argentina to the southern United States, including the Caribbean islands. A subspecies of D. w. willistoni, D. w. quechua, is geographically separated by the Andes mountain range and has evolved unidirectional sterility, in that only male offspring of D. w. quechua females × D. w. willistoni males are sterile. Whether D. w. willistoni flies residing east of the Andes belong to one or more D. willistoni subspecies remains unresolved. Here we perform fecundity assays and show that F1 hybrid males produced from crosses between different strains found in Central America, North America, and northern Caribbean islands are reproductively isolated from South American and southern Caribbean island strains as a result of unidirectional hybrid male sterility. Our results show the existence of a reproductive isolation barrier between the northern and southern strains and suggest a subdivision of the previously identified D. willistoni willistoni species into 2 new subspecies.     

Comparative hybridization reveals extensive genome variation in the AIDS-associated pathogen Cryptococcus neoformans

Background

Genome variability can have a profound influence on the virulence of pathogenic microbes. The availability of genome sequences for two strains of the AIDS-associated fungal pathogen Cryptococcus neoformans presented an opportunity to use comparative genome hybridization (CGH) to examine genome variability between strains of different mating type, molecular subtype, and ploidy.

Results

Initially, CGH was used to compare the approximately 100 kilobase MAT a and MATα mating-type regions in serotype A and D strains to establish the relationship between the Log2 ratios of hybridization signals and sequence identity. Subsequently, we compared the genomes of the environmental isolate NIH433 (MAT a) and the clinical isolate NIH12 (MATα) with a tiling array of the genome of the laboratory strain JEC21 derived from these strains. In this case, CGH identified putative recombination sites and the origins of specific segments of the JEC21 genome. Similarly, CGH analysis revealed marked variability in the genomes of strains representing the VNI, VNII, and VNB molecular subtypes of the A serotype, including disomy for chromosome 13 in two strains. Additionally, CGH identified differences in chromosome content between three strains with the hybrid AD serotype and revealed that chromosome 1 from the serotype A genome is preferentially retained in all three strains.

Conclusion

The genomes of serotypes A, D, and AD strains exhibit extensive variation that spans the range from small differences (such as regions of divergence, deletion, or amplification) to the unexpected disomy for chromosome 13 in haploid strains and preferential retention of specific chromosomes in naturally occurring diploids.     

Statistical analysis of the envelope gene and the prM region of Japanese encephalitis virus: Evidence suggestive of positive selection

The variation in nucleotide sequence observed in the envelope (E) gene and the prM (precursor of M protein) region of different strains of Japanese encephalitis virus (JEV) was analysed. Presence of selective forces acting on these regions was investigated by computing the relative rates of synonymous (K _s) and nonsynonymous (K _a) substitutions. The ratioK _s/K _a was used as an indicator of the overall selective constraints on the amino acid sequence of JEV proteins. The possibility that different regions of the gene may be subject to varying selective pressures was tested by dividing the gene into three regions and estimating theK _s/K _a ratio for each region. On the basis of analysis of a limited number (17) of strains of JEV, evidence suggestive of positive selection acting on certain regions of the E gene of the virus, and in some cases on the entire gene, was obtained. Analysis ofK _a diversity in the prM region of 46 JEV strains grouped into three genotypes revealed that strains included in genotype II were more heterogeneous than strains belonging to genotype I, while the differences between meanK _a values for genotypes I and III and genotypes II and III were not statistically significant. Analysis of host-specific heterogeneity in the prM region revealed that pig isolates were more X_a-diverse than human isolates.     

Development of a high-resolution molecular marker for tracking Pseudo-nitzschia pungens genetic diversity through comparative analysis of mitochondrial genomes

The harmful algal bloom (HAB) species Pseudo-nitzschia pungens is widely distributed in almost all continents. Accumulating evidence suggests that P. pungens has high genetic diversity and many strains can produce the toxin domoic acid (DA) that harms animals and humans. Nevertheless, different P. pungens strains cannot be distinguished using morphological features or using common molecular markers including 18S rDNA, 28S rDNA, ITS, cox1, and rbcL. As such, high-resolution molecular markers need to be developed to resolve P. pungens genetic diversity, facilitating accurate tracking of toxic P. pungens strains. We hypothesized that molecular markers with high resolution and high specificity can be designed through identifying regions with high genomic variations in the mitochondrial genome. Here, we describe the development of a new molecular marker Pseudo-nitzschia pungens mitochondrial 1 (ppmt1) with high resolution and high specificity through comparative analysis of mitochondrial genomes of nine P. pungens strains isolated from coastal regions of China. In conclusion, we have developed ppmt1 as a high-resolution and high-specificity molecular marker for tracking strains and genetic diversity of the HAB species P. pungens.

     

Genotypic diversity in Oenococcus oeni by high-density microarray comparative genome hybridization and whole genome sequencing

Many bacteria display substantial intra-specific genomic diversity that produces significant phenotypic variation between strains of the same species. Understanding the genetic basis of these strain-specific phenotypes is especially important for industrial microorganisms where these characters match individual strains to specific industrial processes. Oenococcus oeni, a bacterium used during winemaking, is one such industrial species where large numbers of strains show significant differences in commercially important industrial phenotypes. To ascertain the basis of these phenotypic differences, the genomic content of ten wine strains of O. oeni were mapped by array-based comparative genome hybridization (aCGH). These strains comprised a genomically diverse group in which large sections of the reference genome were often absent from individual strains. To place the aCGH results in context, whole genome sequence was obtained for one of these strains and compared with two previously sequenced, unrelated strains. While the three strains shared a core group of conserved ORFs, up to 10% of the coding potential of any one strain was specific to that isolate. The genome of O. oeni is therefore likely to be much larger than that present in any single strain and it is these strain-specific regions that are likely to be responsible for differences in industrial phenotypes.     

Mobilization of a Hobo-related Sequence in the Genome of Drosophila simulans

The hobo transposable element can occur under three forms in the Drosophila genome: as a complete element (also called canonical), as internally deleted copies, or as hobo-related sequences (relics). Some evidence indicated that canonical elements and internally deleted copies are recent acquisitions of Drosophila genomes, while the “relics” are old components, normally degenerated and immobile. Here we present the characterization of a hobo-related sequence, found in the genome of a hypermutable strain of D. simulans, which insertion into the white locus raised a de novo white mutation. It is a shorter hobo related element presenting, overall, roughly 18% of divergence at the DNA level from the canonical hobo, with many indels that make clear this element is defective. However, its ITRs and flanking regions are extremely conserved. This is the first hobo “relic” showed to be mobilizable. We suggest, and point up some evidences, toward the idea that this sequence could have been mobilized by the canonical element. The presence of a similar “relic” element in D. sechellia allows us to suggest that these elements have been maintained mobilizable since the time of divergence between these species.     

Strain variation in the katG region of Mycobacterium tuberculosis

Southern blot analysis of chromosomal DNA from clinical isolates of Mycobacterium tuberculosis using cosmid DNA probes revealed extensive strain variation in the katG region of the genome. In addition to deletion of the katG gene itself in some isoniazid-resistant strains, adjacent DNA fragments were missing or altered in a range of drug-sensitive and drug-resistant isolates. A species-specific 2 kb Kpnl fragment located 10 kb upstream of katG in M. tuberculosis H37Rv hybridized to fragments of differing size in different clinical isolates and was characterized in detail. Sequence analysis of this fragment showed that it comprised three tandem copies of a novel 75 bp repeat element flanked by multiple copies of the previously described 10 bp major polymorphic tandem repeat of M. tuberculosis (MPTR). The copy number of the 75 bp repeat was found to vary between strains, allowing application of a poly-merase chain reaction amplification strategy for strain differentiation. These results indicate that the katG region of the M. tuberculosis genome is highly variable and unstable. The presence of repetitive sequences may contribute to instability in this region of the genome.