Directed Synthesis of a Segmental Chromosomal Transposition: An Approach to the Study of Chromosomes Lethal to the Gametophyte Generation of Maize

Because of the haploid nature of the gametophyte generation of plants, most mutations that are lethal or detrimental to the gametophytes cannot be recovered. Our laboratory is currently developing several techniques to overcome this situation. In this paper, a procedure is described to generate directed segmental chromosomal transpositions. The method involves recovery of recombinants between reciprocal translocation overlaps such that one region of the genome is inserted into a nonhomologous chromosome in a predetermined and directed manner. This duplicated segment then could serve to cover deficiencies or mutations, lethal to the gametophytes, in the region from whence it originated. The manipulation of segmental chromosomal transpositions for analyzing mutants lethal or detrimental to the gametophyte generation is discussed. The procedure to generate transpositions, the translocations between normal A and supernumerary B chromosomes that generate deficiencies in the male gametes, the r-X1 chromosome that generates deficiencies in the female gametes and other techniques available in maize form a system to analyze gametophyte lethal mutations.     

Steady-state transposon mutagenesis in inbred maize

We implement a novel strategy for harnessing the power of high-copy transposons for functional analysis of the maize genome, and report behavioral features of the Mutator system in a uniform inbred background. The unique UniformMu population and database facilitate high-throughput molecular analysis of Mu-tagged mutants and gene knockouts. Key features of the population include: (i) high mutation frequencies (7% independent seed mutations) and moderation of copy number (approximately 57 total Mu elements; 1-2 MuDR copies per plant) were maintained by continuous back-crossing into a phenotypically uniform inbred background; (ii) a bz1-mum9 marker enabled selection of stable lines (loss of MuDR), inhibiting further transpositions in lines selected for molecular analysis; (iii) build-up of mutation load was prevented by screening Mu-active parents to exclude plants carrying pre-existing seed mutations. To create a database of genomic sequences flanking Mu insertions, selected mutant lines were analyzed by sequencing of MuTAIL PCR clone libraries. These sequences were annotated and clustered to facilitate bioinformatic subtraction of ancestral elements and identification of insertions unique to mutant lines. New insertions targeted low-copy, gene-rich sequences, and in silico mapping revealed a random distribution of insertions over the genome. Our results indicate that Mu populations differ markedly in the occurrence of Mu insertion hotspots and the frequency of suppressible mutations. We suggest that controlled MuDR copy number in UniformMu lines is a key determinant of these differences. The public database (http://uniformmu.org; http://endosperm.info) includes pedigree and phenotypic data for over 2000 independent seed mutants selected from a population of 31 548 F2 lines and integrated with analyses of 34 255 MuTAIL sequences.     

Transpositional bursts and chromosome rearrangements in unstable lines of Drosophila

The phenomenon of transpositional bursts-massive simultaneous transpositions of mobile elements belonging to different structural classes and accompanied by multiple mutagenesis were earlier described. Although the mechanisms of this phenomenon are still unclear, it is obvious now that it embraces total genome and includes not only transpositions of different mobile elements but also recombination processes--homologous recombination for LTR's and gene conversion. It is shown in this work that transpositional bursts may be accompanied by appearance of grass chromosomal rearrangements. The chain of closely related mutations which is characterized, as well as pedigrees described earlier, by coordinated mutational transitions and multiple transpositions of mdg1, mdg2 and retrotransposon jokey was analyzed. Spontaneous appearance of mutations in the loci yellow, white (deficiency for 462 kb) and cut (insertion of mdg4, together with jokey) correlates with appearance of inversion In(I), 14A-20B, and the reversions of these mutations to the wild type (y+w+ct+) or to other alleles (ctMR2--insertion of mdg4 without jokey) are accompanied by reversions of inversion. The relationship of all lines analyzed in this work as well as the lines from other pedigrees was proved using analysis of polymorphic restriction sites at the scute and cut loci (5 probes were used). All "y w ctpN"--type mutants are shown to have insertion of about 7 kb at the scute locus which causes no alteration of phenotype. This once again proves multiple and coordinated character of changes taking place during hybrid dysgenesis.     

Highly sensitive systems for experimental insertional mutagenesis in repair-deficient genetic environment in Drosophila melanogaster: new opportunities for studying postreplication repair of double-stranded DNA breaks and mechanisms of transposable element migration

Spontaneous mutations in Drosophila melanogaster are related mainly to transposable elements (TEs). They are caused by both migration of TEs over the genome (transpositions) and the ability of TEs to induce chromosomal mutations. Migration of DNA transposons is accompanied by formation of double-strand DNA breaks (DSBs), which are repaired by host repair systems encoded by genes for recombination repair. We relied on this notion to develop a combined approach to the investigation of the type of DNA breaks accompanying transpositions; investigation of systems involved in DSB repair; and detection of repair genes, whose products were involved in repair of DNA breaks induced by TE transposition. The approach is based on the combination of experimental insertional mutagenesis systems and genetic environment deficient for enzymes of the repair system in a single genome. The main advantages of this approach are versatility, wide applicability, and simple design.     

Low occurrence of gene transposition events during the evolution of the genus Drosophila

Abstract.— The role played by gene transpositions during the evolution of eukaryotic genomes is still poorly understood and indeed has been analyzed in detail only in nematodes. In Drosophila , a limited number of transpositions have been detected by comparing the chromosomal location of genes between different species. The relative importance of gene transposition versus other types of chromosomal rearrangements, for example, inversions, has not yet been evaluated. Here, we use physical mapping to perform an extensive search for long-distance gene transpositions and assess their impact during the evolution of the Drosophila genome. We compare the relative order of 297 molecular markers that cover 60% of the euchromatic fraction of the genome between two related Drosophila species and conclude that the frequency of gene transpositions is very low, namely one order of magnitude lower than that of nematodes. In addition, gene transpositions seem to be events almost exclusively associated with genes of repetitive nature such as the Histone gene complex ( HIS-C ).     

Genome sequencing of mouse induced pluripotent stem cells reveals retroelement stability and infrequent DNA rearrangement during reprogramming

The biomedical utility of induced pluripotent stem cells (iPSCs) will be diminished if most iPSC lines harbor deleterious genetic mutations. Recent microarray studies have shown that human iPSCs carry elevated levels of DNA copy number variation compared with those in embryonic stem cells, suggesting that these and other classes of genomic structural variation (SV), including inversions, smaller duplications and deletions, complex rearrangements, and retroelement transpositions, may frequently arise as a consequence of reprogramming. Here we employ whole-genome paired-end DNA sequencing and sensitive mapping algorithms to identify all classes of SV in three fully pluripotent mouse iPSC lines. Despite the improved scope and resolution of this study, we find few spontaneous mutations per line (one or two) and no evidence for?endogenous retroelement transposition. These results show that genome stability can persist throughout reprogramming, and argue that it is possible to generate iPSCs lacking gene-disrupting mutations using current reprogramming methods.     

Maximum likelihood and Bayesian methods for estimating the distribution of selective effects among classes of mutations using DNA polymorphism data

Maximum likelihood and Bayesian approaches are presented for analyzing hierarchical statistical models of natural selection operating on DNA polymorphism within a panmictic population. For analyzing Bayesian models, we present Markov chain Monte-Carlo (MCMC) methods for sampling from the joint posterior distribution of parameters. For frequentist analysis, an Expectation-Maximization (EM) algorithm is presented for finding the maximum likelihood estimate of the genome wide mean and variance in selection intensity among classes of mutations. The framework presented here provides an ideal setting for modeling mutations dispersed through the genome and, in particular, for the analysis of how natural selection operates on different classes of single nucleotide polymorphisms (SNPs).     

Highly sensitive systems for experimental insertional mutagenesis in repair-deficient genetic environment in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>: New opportunities for studying postreplication repair of double-stranded DNA breaks and mechanisms of transposable element migration

Spontaneous mutations in Drosophila melanogaster are related mainly to transposable elements (TEs). They are caused by both migration of TEs over the genome (transpositions) and the ability of TEs to induce chromosomal mutations. Migration of DNA transposons is accompanied by formation of double-strand DNA breaks (DSBs), which are repaired by host repair systems encoded by genes for recombination repair. We relied on this notion to develop a combined approach to the investigation of the type of DNA breaks accompanying transpositions; investigation of systems involved in DSB repair; and detection of repair genes, whose products were involved in repair of DNA breaks induced by TE transposition. The approach is based on the combination of experimental insertional mutagenesis systems and genetic environment deficient for enzymes of the repair system in a single genome. The main advantages of this approach are versatility, wide applicability, and simple design.     

GENESIS: genome evolution scenarios

Summary: We implemented a software tool called GENESIS for threedifferent genome rearrangement problems: Sorting a unichromosomalgenome by weighted reversals and transpositions (SwRT), sortinga multichromosomal genome by reversals, translocations, fusionsand fissions (SRTl), and sorting a multichromosomal genome byweighted reversals, translocations, fusions, fissions and transpositions(SwRTTl). Availability: Source code can be obtained by the authors, oruse the web interface http://www.uni-ulm.de/in/theo/research/genesis.html Contact: simon.gog{at}uni-ulm.de Associate Editor: Chris Stoeckert     

Bayesian estimation of concordance among gene trees

Multigene sequence data have great potential for elucidating important and interesting evolutionary processes, but statistical methods for extracting information from such data remain limited. Although various biological processes may cause different genes to have different genealogical histories (and hence different tree topologies), we also may expect that the number of distinct topologies among a set of genes is relatively small compared with the number of possible topologies. Therefore evidence about the tree topology for one gene should influence our inferences of the tree topology on a different gene, but to what extent? In this paper, we present a new approach for modeling and estimating concordance among a set of gene trees given aligned molecular sequence data. Our approach introduces a one-parameter probability distribution to describe the prior distribution of concordance among gene trees. We describe a novel 2-stage Markov chain Monte Carlo (MCMC) method that first obtains independent Bayesian posterior probability distributions for individual genes using standard methods. These posterior distributions are then used as input for a second MCMC procedure that estimates a posterior distribution of gene-to-tree maps (GTMs). The posterior distribution of GTMs can then be summarized to provide revised posterior probability distributions for each gene (taking account of concordance) and to allow estimation of the proportion of the sampled genes for which any given clade is true (the sample-wide concordance factor). Further, under the assumption that the sampled genes are drawn randomly from a genome of known size, we show how one can obtain an estimate, with credibility intervals, on the proportion of the entire genome for which a clade is true (the genome-wide concordance factor). We demonstrate the method on a set of 106 genes from 8 yeast species.     

Induction of unstable mutations in Drosophila melanogaster by microinjection of oncogenic virus DNA into the embryo polar plasma. Insertional nature of mutations]

We have demonstrated that mutations induced in Drosophila melanogaster by the microinjections of adenovirus Sa7 DNA in early embryos are of insertional nature. The role of insertional elements is played by the Drosophila transposons, but not by the virus DNA. The ability of oncoviral DNA to induce transpositions of mobile elements in recipient genome is the molecular basis of this system of genetic instability.     

Large and small rearrangements in the evolution of prokaryotic genomes

Relative frequencies of large and small genome rearrangements (inversions and transpositions) in the evolution of prokaryotic genomes can be evaluated using the ratio between the index S (the ratio of the number of identical pairs of neighboring genes in two genomes to the total number of genes in the sample of interest) and 1 - 6 x L/n, where L is the mean difference in intergenic distances and n is the number of genes in the sample. The S value uniformly decreases with the fixation of genome rearrangements, while the decrease rate of I - 6 x L/n is determined by the rearrangement size. Specifically, large inversions and transpositions lead to a dramatic decrease in the index value, while small rearrangements result in an insignificant decrease. The ratio between these indices was computed for twenty pairs of closely related species belonging to different groups of bacteria and archaea. The pairs examined strongly differed in the relative frequency of large and small rearrangements. However, computer simulation showed that the total variation can be reproduced with the same input parameters of the model. This means that the differences observed can be stochastic and can be interpreted without assuming different mechanisms and factors of genome rearrangements for different groups of prokaryotes. Relative frequencies of large and small rearrangements displayed no noticeable correlations with taxonomic position, total rate of rearrangement fixation, habitation conditions, and the abundance of transposons and repetitive sequences. It is suggested that, in some cases, phage activity increases the frequency of large genome rearrangements.     

An evolutionary model for the origin of non-randomness, long-range order and fractality in the genome.

We present a model for genome evolution, comprising biologically plausible events such as transpositions inside the genome and insertions of exogenous sequences. This model attempts to formulate a minimal proposition accounting for key statistical properties of genomes, avoiding, as far as possible, unsupportable hypotheses for the remote evolutionary past. The statistical properties that are observed in genomic sequences and are reproduced by the proposed model are: (i) deviations from randomness at different length scales, measured by suitable algorithms, (ii) a special form of size distribution (power law distribution) characterising different levels of genome organisation in the non-coding, and (iii) extensive resemblance in the alternation of coding and non-coding regions at several length scales (self-similarity) in long genomic sequences of higher eukaryotes.     

HuGeMap: a distributed and integrated Human Genome Map database.

The HuGeMap database stores the major genetic and physical maps of the human genome. It is also interconnected with the gene radiation hybrid mapping database RHdb. HuGeMap is accessible through a Web server for interactive browsing at URL http://www.infobiogen. fr/services/Hugemap , as well as through a CORBA server for effective programming. HuGeMap is intended as an attempt to build open, interconnected databases, that is databases that distribute their objects worldwide in compliance with a recognized standard of distribution. Maps can be displayed and compared with a java applet (http://babbage.infobiogen.fr:15000/Mappet/Show. html ) that queries the HuGeMap ORB server as well as the RHdb ORB server at the EBI.     

What makes transposable elements move in the Drosophila genome?

Transposable elements (TEs), by their capacity of moving and inducing mutations in the genome, are considered important drivers of species evolution. The successful invasions of TEs in genomes, despite their mutational properties, are an apparent paradox. TEs' transposition is usually strongly regulated to low value, but in some cases these elements can also show high transposition rates, which has been associated sometimes to changes in environmental conditions. It is evident that factors susceptible to induce transpositions in natural populations contribute to TE perpetuation. Different factors were proposed as causative agents of TE mobilization in a wide range of organisms: biotic and abiotic stresses, inter- and intraspecific crosses and populational factors. However, there is no clear evidence of the factors capable of inducing TE mobilization in Drosophila, and data on laboratory stocks show contradictory results. The aim of this review is to have an update critical revision about mechanisms promoting transposition of TEs in Drosophila, and to provide to the readers a global vision of the dynamics of these genomic elements in the Drosophila genome.     

Large and small rearrangements in the evolution of prokaryotic genomes

Relative frequencies of large and small genome rearrangements (inversions and transpositions) in the evolution of prokaryotic genomes can be evaluated using the ratio between the index S (the ratio of the number of identical pairs of neighboring genes in two genomes to the total number of genes in the sample of interest) and 1–6L/n, where L is the mean difference in intergenic distances and n is the number of genes in the sample. The S value uniformly decreases with the fixation of genome rearrangements, while the decrease rate of 1–6L/n is determined by the rearrangement size. Specifically, large inversions and transpositions lead to a dramatic decrease in the index value, while small rearrangements result in an insignificant decrease. The ratio between these indices was computed for twenty pairs of closely related species belonging to different groups of bacteria and archaea. The pairs examined strongly differed in the relative frequency of large and small rearrangements. However, computer simulation showed that the total variation can be reproduced with the same input parameters of the model. This means that the differences observed can be stochastic and can be interpreted without assuming different mechanisms and factors of genome rearrangements for different groups of prokaryotes. Relative frequencies of large and small rearrangements displayed no noticeable correlations with taxonomic position, total rate of rearrangement fixation, habitation conditions, and the abundance of transposons and repetitive sequences. It is suggested that, in some cases, phage activity increases the frequency of large genome rearrangements.     

The Metropolized Partial Importance Sampling MCMC mixes slowly on minimum reversal rearrangement paths

Markov chain Monte Carlo has been the standard technique for inferring the posterior distribution of genome rearrangement scenarios under a Bayesian approach. We present here a negative result on the rate of convergence of the generally used Markov chains. We prove that the relaxation time of the Markov chains walking on the optimal reversal sorting scenarios might grow exponentially with the size of the signed permutations, namely, with the number of syntheny blocks.     

Sorting by weighted reversals, transpositions, and inverted transpositions.

During evolution, genomes are subject to genome rearrangements that alter the ordering and orientation of genes on the chromosomes. If a genome consists of a single chromosome (like mitochondrial, chloroplast, or bacterial genomes), the biologically relevant genome rearrangements are (1) inversions--also called reversals--where a section of the genome is excised, reversed in orientation, and reinserted and (2) transpositions, where a section of the genome is excised and reinserted at a new position in the genome; if this also involves an inversion, one speaks of an inverted transposition. To reconstruct ancient events in the evolutionary history of organisms, one is interested in finding an optimal sequence of genome rearrangements that transforms a given genome into another genome. It is well known that this problem is equivalent to the problem of "sorting" a signed permutation into the identity permutation. In this paper, we provide a 1.5-approximation algorithm for sorting by weighted reversals, transpositions and inverted transpositions for biologically realistic weights.     

Variation of the mitochondrial genome in the evolution of Drosophila

The evidence on mitochondrial genome variation and its role in evolution of the genus Drosophila are reviewed. The mitochondrial genome is represented by a circular double-stranded DNA molecule 16 to 19 kb in length. The genome contains no introns involved in recombination. The entire mitochondrial genome can be arbitrarily divided into three parts: (1) protein-coding genes; (2) genes encoding rRNA and tRNA; and (3) the noncoding regulatory region (A + T region). The selective importance of mutations within different mtDNA regions is therefore unequal. In Drosophila, the content of the A + T pairs in mtDNA is extremely low and a pattern of nucleotide substitution is characterized by a low transition/transversion ratio (and a low threshold of mutation saturation). The deletions and duplications are of common occurrence in the mitochondrial genome. However, this genome lacks such characteristic for the nuclear genome aberrations as the inversions and transpositions. The phenomena of introgression and heteroplasmy provide an opportunity to study the adaptive role of the mitochondrial genome and its role in speciation. Analysis of evidence concerning mtDNA variation in different species of the genus Drosophila made it possible to ascertain data on phylogenetic relationships among species obtained by studying nuclear genome variation. In some species, mtDNA variation may serve as a reliable marker for population differentiation within a species, although evidence on the population dynamics of the mtDNA variation is very scarce.