Application of mFISH for the analysis of chemically-induced chromosomal aberrations: a model for the formation of triradial chromosomes

Using a human lymphoblastoid cell line WTK-1, we applied multicolor fluorescence in situ hybridization (mFISH) technique to analyze mitomycin C (MMC)-induced chromatid exchanges, focusing especially on the triradial chromosomes. It was found that the triradial chromosomes were formed with a specific rearrangement, "recipient and donor" relationship. The exchange sites of the recipient chromosomes were on single chromatid breaks and distributed randomly throughout the interstitial, pericentromeric, and terminal regions. In counterpart, donor chromosomes exchanged on isochromatid breaks of their telomeric and/or subtelomeric regions with the single chromatid breaks of recipient chromosomes. More than 80% of the scored triradial chromosomes were formed with such rearrangements, and few acentric chromosome fragments derived from the donor chromosomes could be detected in the metaphases observed. We therefore suggest that biological mechanisms of breakages between the recipient and donor chromosomes are different: the former due to direct DNA-damage by MMC, but the latter due to indirect DNA-damage depending on telomeric specific structure/function.     

Why Genes Evolve Faster on Secondary Chromosomes in Bacteria

In bacterial genomes composed of more than one chromosome, one replicon is typically larger, harbors more essential genes than the others, and is considered primary. The greater variability of secondary chromosomes among related taxa has led to the theory that they serve as an accessory genome for specific niches or conditions. By this rationale, purifying selection should be weaker on genes on secondary chromosomes because of their reduced necessity or usage. To test this hypothesis we selected bacterial genomes composed of multiple chromosomes from two genera, Burkholderia and Vibrio, and quantified the evolutionary rates (dN and dS) of all orthologs within each genus. Both evolutionary rate parameters were faster among orthologs found on secondary chromosomes than those on the primary chromosome. Further, in every bacterial genome with multiple chromosomes that we studied, genes on secondary chromosomes exhibited significantly weaker codon usage bias than those on primary chromosomes. Faster evolution and reduced codon bias could in turn result from global effects of chromosome position, as genes on secondary chromosomes experience reduced dosage and expression due to their delayed replication, or selection on specific gene attributes. These alternatives were evaluated using orthologs common to genomes with multiple chromosomes and genomes with single chromosomes. Analysis of these ortholog sets suggested that inherently fast-evolving genes tend to be sorted to secondary chromosomes when they arise; however, prolonged evolution on a secondary chromosome further accelerated substitution rates. In summary, secondary chromosomes in bacteria are evolutionary test beds where genes are weakly preserved and evolve more rapidly, likely because they are used less frequently.     

Multi-step control of spindle pole body duplication by cyclin-dependent kinase

Organelles called centrosomes in metazoans or spindle pole bodies (SPBs) in yeast direct the assembly of a bipolar spindle that is essential for faithful segregation of chromosomes during mitosis. Abnormal accumulation of multiple centrosomes leads to genome instability, and has been observed in both tumour cells and cells with targeted mutations in tumour-suppressor genes. The defects that lead to centrosome amplification are not understood. We have recapitulated the multiple-centrosome phenotype in budding yeast by disrupting the activity of specific cyclin-dependent kinase (CDK) complexes. Our observations are reminiscent of mechanisms that govern DNA replication, and show that specific cyclin/CDK activities function both to promote SPB duplication and to prevent SPB reduplication.     

Bacterial genomics

Abstract: During the last decade, great advances have been made in the study of bacterial genomes which is perhaps better described by the term bacterial genomics. The application of powerful techniques, such as pulsed-field gel electrophoresis of macro-restriction fragments of genomic DNA, has freed the characterisation of the chromosomes of many bacteria from the constraints imposed by classical genetic analysis. It is now possible to analyse the genome of virtually every microorganism by direct molecular methods and to construct detailed physical and gene maps. In this review, the various practical approaches are compared and contrasted, and some of the emerging themes of bacterial genomics, such as the size, shape, number and organisation of chromosomes are discussed.     

Bacterial heme sources: the role of heme, hemoprotein receptors and hemophores

The major mechanisms by which Gram-negative bacteria acquire heme from host heme-carrier proteins involve either direct binding to specific outer membrane receptors or release of bacterial hemophores that take up heme from host heme carriers and shuttle it back to specific receptors. The ability to interact with and remove heme from carrier proteins distinguishes heme from conceptually similar siderophore and vitamin B12 receptors. Recent genetic, biochemical and crystallization studies have started to unravel the mechanism and molecular interactions between heme-carrier proteins and components of bacterial heme assimilation systems.     

Pairing of P1 plasmid partition sites by ParB

The mechanisms by which bacterial plasmids and chromosomes are partitioned are largely obscure, but it has long been assumed that the molecules to be separated are initially paired, as are sister chromatids in mitosis. We offer in vivo evidence that the partition protein ParB encoded by the bacterial plasmid P1 can pair cis-acting partition sites of P1 inserted in a small, multicopy plasmid. ParB was shown previously to be capable of extensive spreading along DNA flanking the partition sites. Experiments in which ParB spreading was constrained by physical roadblocks suggest that extensive spreading is not required for the pairing process.     

Does the parallel evolution pattern between the replication-segregation proteins and HU have a biological significance?

The bacterial chromosome is a highly compacted nucleoproteic structure. Its apparent disordered morphology is difficult to conciliate with newly discovered mechanisms governing the propagation of genetic information between mother and daughter cells. Recent experiments in bacterial genetics, biochemistry and cytology from a number of laboratories are beginning to unravel how at each cell division, DNA replication and segregation proteins interact spatially with specific DNA motifs to orchestrate replication and movement of replication forks and chromosomes. We propose here a method to confirm and perhaps extend these experiments by in silico protein sequence comparisons and phylogeny. This analysis showed a parallel evolution between the histone-like protein HU and key protein factors involved in DNA replication and chromosome segregation.     

Additional chromosomes in bacteria: properties and origin

The review considers papers published over the last 15 years that deal with the presence in cells of some bacterial genera and species of a second chromosome that is smaller than the major one (occasionally, of two additional chromosomes). These additional chromosomes differ from the major one in the set of genes and specific features of replication; however, they carry genes vitally important for the bacterium. The role of these chromosomes and their probable origin from megaplasmids are discussed.     

Additional chromosomes in bacteria: Properties and origin

The review considers papers published over the last 15 years that deal with the presence in cells of some bacterial genera and species of a second chromosome that is smaller than the main one (occasionally, of two additional chromosomes). These additional chromosomes differ from the main one in the set of genes and specific features of replication; however, they carry genes vitally important for the bacterium. The role of these chromosomes and their probable origin from megaplasmids are discussed.     

FtsY, the bacterial signal-recognition particle receptor, interacts functionally and physically with the SecYEG translocon

Co-translational membrane targeting of proteins by the bacterial signal-recognition particle (SRP) requires the specific interaction of the SRP-ribosome nascent chain complex with FtsY, the bacterial SRP receptor (SR). FtsY is homologous to the SRalpha-subunit of the eukaryotic SR, which is tethered to the endoplasmic-reticulum membrane by its interaction with the integral SRbeta-subunit. In contrast to SRalpha, FtsY is partly membrane associated and partly located in the cytosol. However, the mechanisms by which FtsY associates with the membrane are unclear. No gene encoding an SRbeta homologue has been found in bacterial genomes, and the presence of an FtsY-specific membrane receptor has not been shown so far. We now provide evidence for the direct interaction between FtsY and the SecY translocon. This interaction offers an explanation of how the bacterial SRP cycle is regulated in response to available translocation channels.     

Chromosome translocation and its consequence in the genome of Burkholderia cenocepacia AU-1054

Most bacterial genomes have one single chromosome. The species Burkholderia cenocepacia, a Gram-negative β-proteobacterium, is one of the exceptions. Genomes of four strains of the species have been sequenced and each has three circular chromosomes. In the genus Burkholderia, there are another seven sequenced strains that have three chromosomes. In this paper, the numbers of essential genes and tRNA genes among the 11 strains of the genus Burkholderia are compared. Interestingly, it is found that the shortest chromosome of B. cenocepacia AU-1054 has much (over three times) more essential genes and tRNA genes than the corresponding chromosomes in the other 10 strains. However, no significant difference has been found on the two longer chromosomes among the 11 strains. Non-homologous chromosomal translocation between chromosomes I and III in the species B. cenocepacia is found to be responsible for the unusual distribution of essential genes. The present work may contribute to the understanding of how the secondary chromosomes of multipartite bacterial genomes originate and evolve. The computer program, DEG_match, for comparatively identifying essential genes in any annotated bacterial genomes is freely available at http://cobi.uestc.edu.cn/resource/AU1054/.     

Chemical and biological mobilization of Fe(III) in marsh sediments

Iron reduction in marine sulfitic environments may occur via a mechanism involving direct bacterial reduction with the use of hydrogen as an electron donor, direct bacterial reduction involving carbon turnover, or by indirect reduction where sulfide acts to reduce iron. In the presented experiments, the relative importance of direct and indirect mechanisms of iron reduction, and the contribution of these two mechanisms to overall carbon turnover has been evaluated in two marsh environments. Sediments collected from two Northeastern US salt marshes each having different Fe (III) histories were incubated with the addition of reactive iron (as amorphous oxyhydroxide). These sediments were either incubated alone or in conjunction with sodium molybdate. Production of both inorganic and organic pore water constituents and a calculation of net carbon production were used as measures to compare the relative importance of direct bacterial reduction and indirect bacterial reduction. Results indicate that in the environments tested, the majority of the reduced iron found results from indirect reduction mediated by hydrogen sulfide, a result of dissolution and precipitation phenomena, or is a result of direct bacterial reduction using hydrogen as an electron donor. Direct iron reduction plays a minor role in carbon turnover in these environments.     

The nucleolus organizers of diploid wheats revealed by in situ hybridization

Summary Labelled RNA, transcribed in vitro from wheat ribosomal DNA cloned in a bacterial plasmid, has been hybridised to metaphase chromosomes of five diploid wheats. Autoradiography of the chromosomes has provided unequivocal evidence that these genotypes possess two pairs of nucleolus organizer chromosomes. The diploid wheat accessions used possess widely differing numbers of ribosomal RNA genes.     

Respiratory viral infection predisposing for bacterial disease: a concise review

Although bacterial superinfection in viral respiratory disease is a clinically well documented phenomenon, the pathogenic mechanisms are still poorly understood. Recent studies have revealed some of the mechanisms involved. Physical damage to respiratory cells as a result of viral infection may lead to opportunistic adherence of bacteria. Enhanced bacterial adherence by specific mechanisms has been documented for respiratory cells infected with influenza A virus, respiratory syncytial virus and adenovirus in both in vitro and in vivo models. To date, results of various experimental studies indicate that different mechanisms for increased bacterial adherence induced by viruses are operating for specific viral-bacterial combinations. In the present review, a number of key findings obtained during the past two decades is presented and discussed.     

New observations on the twisted arrangement of Dinoflagellate chromosomes

The Dinoflagellate Prorocentrum micans has been studied in classical and high voltage transmission electron microscopy, with the help of a goniometric stage. The general structure of the nucleus is analysed with special reference to the links observed between chromosomes and the nuclear envelope, the nucleoplasm and the nucleolus. The chromosomes present stacked series of nested arcs which are studied in detail. The sense of the arcs can be changed by a simple tilt of the section. These arcs do not correspond to DNA filaments with a genuine bend but to an illusion created by the overlap of layers of filaments whose orientation turns along the chromosome axis. — The transversal orientation of DNA and the examination of defects allow to rule out the polytenic hypothesis. It is clear that this hypothesis does not apply to bacterial nucleoids, which however can form series of nested arcs as in Dinoflagellate chromosomes. — The twisted arrangement of Dinoflagellate chromosomes is that of a liquid crystal of the cholesteric type. DNA is known to self assemble into cholesteric phases and this affords informations on the origin of the elongated shape of chromosomes and on the mechanisms of condensation and aggregation observed in this particular chromatin.     

The chromosomal basis of meiotic acentrosomal spindle assembly and function in oocytes

Several aspects of meiosis are impacted by the absence of centrosomes in oocytes. Here, we review four aspects of meiosis I that are significantly affected by the absence of centrosomes in oocyte spindles. One, microtubules tend to assemble around the chromosomes. Two, the organization of these microtubules into a bipolar spindle is directed by the chromosomes. Three, chromosome bi-orientation and attachment to microtubules from the correct pole require modification of the mechanisms used in mitotic cells. Four, chromosome movement to the poles at anaphase cannot rely on polar anchoring of spindle microtubules by centrosomes. Overall, the chromosomes are more active participants during acentrosomal spindle assembly in oocytes, compared to mitotic and male meiotic divisions where centrosomes are present. The chromosomes are endowed with information that can direct the meiotic divisions and dictate their own behavior in oocytes. Processes beyond those known from mitosis appear to be required for their bi-orientation at meiosis I. As mitosis occurs without centrosomes in many systems other than oocytes, including all plants, the concepts discussed here may not be limited to oocytes. The study of meiosis in oocytes has revealed mechanisms that are operating in mitosis and will probably continue to do so.     

The bacterial nucleoid: a highly organized and dynamic structure

Recent advances in bacterial cell biology have revealed unanticipated structural and functional complexity, reminiscent of eukaryotic cells. Particular progress has been made in understanding the structure, replication, and segregation of the bacterial chromosome. It emerged that multiple mechanisms cooperate to establish a dynamic assembly of supercoiled domains, which are stacked in consecutive order to adopt a defined higher-level organization. The position of genetic loci on the chromosome is thereby linearly correlated with their position in the cell. SMC complexes and histone-like proteins continuously remodel the nucleoid to reconcile chromatin compaction with DNA replication and gene regulation. Moreover, active transport processes ensure the efficient segregation of sister chromosomes and the faithful restoration of nucleoid organization while DNA replication and condensation are in progress.     

Identification of sex‐specific molecular markers using restriction site‐associated DNA sequencing

A major barrier to evolutionary studies of sex determination and sex chromosomes has been a lack of information on the types of sex‐determining mechanisms that occur among different species. This is particularly problematic in groups where most species lack visually heteromorphic sex chromosomes, such as fish, amphibians and reptiles, because cytogenetic analyses will fail to identify the sex chromosomes in these species. We describe the use of restriction site‐associated DNA (RAD) sequencing, or RAD‐seq, to identify sex‐specific molecular markers and subsequently determine whether a species has male or female heterogamety. To test the accuracy of this technique, we examined the lizard Anolis carolinensis. We performed RAD‐seq on seven male and ten female A. carolinensis and found one male‐specific molecular marker. Anolis carolinensis has previously been shown to possess male heterogamety and the recently published A. carolinensis genome facilitated the characterization of the sex‐specific RAD‐seq marker. We validated the male specificity of the new marker using PCR on additional individuals and also found that it is conserved in some other Anolis species. We discuss the utility of using RAD‐seq to identify sex‐determining mechanisms in other species with cryptic or homomorphic sex chromosomes and the implications for the evolution of male heterogamety in Anolis.     

Association of the folded chromosome with the cell envelope of E. coli: Characterization of the proteins at the DNA-membrane attachment site

Gentle lysis of E. coli cells in the presence of a DNA counterion (either 1.0 M NaCl or 5 mM spermidine) permits the isolation of the folded intact bacterial chromosome associated with membrane fragments. Most of the proteins in these chromosomes are also found in purified membrane preparations, and they can be identified as belonging to either the inner or the outer bacterial membrane.Ultraviolet irradiation of the membrane-attached chromosomes causes the formation of a stable complex between two inner membrane proteins (molecular weight 80,000 and 56,000 daltons) and 5-bromodeoxyuridine (BrdU)-substituted DNA. The photochemical attachment of BrdU-substituted DNA to specific membrane proteins suggests that these proteins may be bound to the DNA in vivo. Such DNA-membrane-binding proteins may have a role in the attachment of the folded chromosome to the bacterial envelope.