Autosomal control of lampbrush-loop formation during spermatogenesis in Drosophila hydei by a gene also affecting somatic sex determination

Summary The Y chromosome of Drosophila hydei carries information that is necessary for the development of the spermatozoa. In primary spermatocytes Y chromosomal genes become active: five of the male fertility factors form giant lampbrush loops. Our prior work indicated interactions between the Y chromosomal genes and autosomal loci. It is of interest to identify loci regulating the activity of the Y chromosomal genes. We, therefore, screened a total of about 14,000 chromosomes (X, 2, 3 and 4) for mutations that interfere with the expression of the lampbrush loops. Two mutations with substantial effects on the loop morphology were recovered. One of them, a recessive male sterile mutation (ms (3) 5) on chromosome 3, is described in this paper. Its homozygous state results in a complete absence of all Y chromosomal lampbrush loops at 26° C; at 18° C the loops are formed. Temperature shifts with homozygous males indicate that the function early during the spermatogonial stage is crucial for the development of lampbrush loops in the primary spermatocyte. Meiosis is entirely absent in the male, but normal in females. Females homozygous for ms (3) 5 display a maternal effect, which reduces the viability and fertility of homozygous daughters and produces sons with signs of intersexuality. Linkage studies indicated that the effect on the male germ line and the maternal effects cannot be separated and may hence be induced by a single gene.     

Temperatursensitive Mutanten im Y-chromosom von Drosophila hydei

Mutations were induced in the Y chromosomal fertility genes of Drosophila hydei by EMS treatment of adult males. Four types of mutants were observed: 1. Sterile mutants without detectable cytological changes in Y chromosomal lampbrush loops. 2. Sterile males with morphologically changed loops. 3. Sterile males where one or several Y chromosomal loops are missing in the spermatocytes. 4. Mutants which are temperature-sensitive for sterility, development of loops or altered loop morphology. In this paper four Y mutants are described which are temperature-sensitive as regards fertility but which show unchanged lampbrush loops. They can be mapped in four different complementation groups. Two of those occur probably in regions of the Y chromosome without cytologically detectable lampbrush loops. All mutations are found in the distal half of the long arm. The temperature-sensitive period occurs during the primary spermatocyte stage and in early spermatid development while the manifestation of the effect occurs postmeiotically. The mutants are further characterized with respect to changes in the ultrastructure of the sperm at the restrictive temperature.     

Molecular cloning of microdissected lampbrush loop DNA sequences of Drosophila hydei

We microdissected a Y chromosomal lampbrush loop pair from primary spermatocyte nuclei of Drosophila hydei and cloned the DNA directly at the microscale. Four of the 12 recombinant DNA clones recovered display in situ hybridization to mitotic metaphase Y chromosomes, preferentially in the chromosomal region identified as the origin of the lampbrush loop pair. All clones, however, also hybridize to autosomal and X chromosomal loci in polytene chromosomes. Y chromosomal DNA sequences of D. hydei again prove to be members of different families of repeated sequences distributed throughout the genome. These microcloning experiments, which were carried out under very unfavourable experimental conditions (low DNA content of the lampbrush loops in the presence of large amounts of RNA) prove that almost any chromosomal structure detected by light microscopy is directly accessible to molecular cloning experiments by micromethods.     

Architecture of the Chinese hamster metaphase chromosome

The development of procedures for the isolation of unfixed metaphase chromosomes has made feasible a direct analysis of their morphology. Wholemount stereo electron microscopy was used to examine intact and partially disrupted chromosomes produced by physical shearing and extraction with salt and urea solutions. A model of chromosome architecture was developed to accommodate evidence from studies using both light and electron microscopy. In the proposed model the chromatid (anaphase chromosome) consists of two half-chromatids; each half-chromatid contains two deoxyribonucleoprotein ribbons wound into a single fiber (termed the core), with many loops of chromatin (termed epichromatin) attached along its length. The core ribbons are each about 50 Å thick by 4000 Å wide and are composed of many parallel deoxyribonucleoprotein strands. The epichromatin loops appear to be 250 Å supercoiled fibers containing about 75 per cent of the chromosomal DNA. The epichromatin can be selectively removed from the core fibers by extraction with 2.0 M NaCl or 6.0 M urea solutions.     

Bidirectional chromosome replication in Bacillus subtilis

We have examined autoradiographically the pattern of DNA replication following the germination of Bacillus subtilis spores in [³H]thymidine. Thymine-requiring spores were germinated in low specific activity medium and diluted into higher specific activity medium soon after the first round of replication was expected to start. After a further short period, replication was stopped and the chromosomal structures examined by autoradiography. From the pattern of labelling within individual replicating loops it is clear that the majority (≥75%) expand by growth at two positions that are opposite, i.e. expand bidirectionally. The loops continue to expand at approximately equal rates in both directions until at least 20% of the chromosome has been replicated.From a consideration of the other structural forms that become visible, it seems likely that most chromosomes replicate bidirectionally.     

Evolution of Y chromosomal lampbrush loop DNA sequences of Drosophila

The evolutionary conservation of Y chromosomal DNA sequences of Drosophila hydei in different species of the genus Drosophila was studied by in situ hybridization and on genomic DNA blots of restriction enzyme digested DNA. We demonstrated that Y specific DNA sequences, which form major parts of lampbrush loops related to the male fertility genes, are only retained in a few closely related species during evolution. Other Y chromosomal DNA sequences, also present in lampbrush loops but with homology to autosomal and X chromosomal locations, were found in distant species. We propose a model for the evolution of the Y chromosomal lampbrush loops.     

THE BASE COMPOSITION OF RIBONUCLEIC ACID IN LAMPBRUSH CHROMOSOMES, NUCLEOLI, NUCLEAR SAP, AND CYTOPLASM OF TRITURUS OOCYTES

The base composition of RNA's extracted from chromosomes, nucleoli, nuclear sap, and cytoplasm of Triturus oocytes has been determined by microelectrophoresis. The chromosomal RNA has a content of guanine+cytosine equal to that of DNA, but there is no complementarity in the composition as for DNA. Nuclear sap contains a highly variable RNA with a tendency towards high uracil values. Nucleolar and cytoplasmic RNA's are similar in composition and both are of the guanine-cytosine rich type. The chromosomes and nucleoli contain roughly equivalent amounts of RNA, somewhat less than is present in the nuclear sap. The RNA/DNA ratio of the whole chromosomes is about 10. However, the ratio in the synthetically active regions, the loops, is much higher, since the loops contain all the chromosomal RNA but only a small fraction of the DNA.     

Cytogenetic studies in six species of Scinax (Anura,Hylidae) clade Scinax ruber from northern and northeastern Brazil

Scinax species are still underrepresented in cytogenetic studies, mainly with respect to populations from northeastern and northern Brazil. In this study, we provide new chromosomal information on Scinax boesemani, S. camposseabrai, S. garbei, S. pachycrus, S. trilineatus and S. x-signatus, all belonging to clade S. ruber. They were collected at two locations in the Caatinga biome (northeastern Brazil) and at one in the Amazon (northern Brazil) biomes. Chromosomes were analyzed by conventional staining, C-banding, Ag-NOR staining, and fluorochrome staining. All species shared a modal diploid value of 2n = 24 and fundamental arm number (FN) of 48. Moreover, both chromosomal size and morphology were similar to other species in this Scinaxclade. C-banding revealed centromeric heterochromatin in all species, along with terminal species-specific C-bands in some species. Active nucleolar organizer regions (Ag-NORs) were identified at 11q in most species, except for S. boesemani and S. garbei (Ag-NORs at interstitial region of 8q). Differing from most anurans, GC-rich regions were not restricted to NORs, but also coincident with some centromeric and terminal C-bands. These data contribute to the cytotaxonomy of Scinax by providing chromosomal markers and demonstrating the occurrence of microstructural rearrangements and inversions on chromosomal evolution of Scinax.     

Evolutionary trends in the chromosome numbers of swarm-founding social wasps

Chromosome number and morphology are relevant aspects of genomic organization of eukaryotes and are considered key components to comprehend evolutionary mechanisms and karyotypic differentiation. Social wasps belonging to the tribe Epiponini show complex social characteristics that make these insects interesting models for genetic and evolutionary studies. However, there is a paucity of genetic information in social wasps as a whole. Aiming to investigate the process of chromosomal evolution of the social Epiponini wasps, chromosomes of ten species of this group were analyzed using Giemsa and fluorochrome staining techniques and fluorescence in situ hybridization in two species. In this study a high variation in the chromosome number and morphology was found and the previous range of chromosome number of Epiponini was broadened from n = 8–32 to n = 5–33. We also suggest that chromosomal segments with high GC content must have had a key role in the karyotype diversification of these wasps. Moreover, based on a phylogenetic background we find evidence of a main role of chromosomal fusion in the occurrence of gradual decrease of chromosome number in Epiponini during its chromosomal evolutionary history.     

Geographic variation in the greater Japanese shrew-mole,Urotrichus talpoides: Combining morphological and chromosomal patterns

Although much information on the species dynamics of small mammals may be gleaned from the integration of morphological and molecular data sets, the two are not routinely combined when species boundaries and definitions are investigated. The greater Japanese shrew-mole (Urotrichus talpoides) presents a rare example of intraspecific and geographical euchromatic chromosomal variation. In this study a combination of 2D landmark-based and outline-based geometric morphometric methods were used to provide the first quantitative examination of variation in skull morphology occurring between populations of U. talpoides. Geographic variation was found to be most conspicuous in ventral and dorsal cranial morphology, and less evident for outline-based analyses of the dentary, thereby indicating differing magnitudes of skeletal plasticity associated with geographic variation in each system. Both ventral and dorsal cranial morphology differed significantly between shrew-moles from western and eastern Honshu, in agreement with previously identified chromosomal variation boundaries. Inclusion of other island populations revealed shape differences between shrew-moles in Kyushu, Tsushima and North Honshu. These results lend general support for the unification of morphological and chromosomal data when assessing species boundaries.     

Effect of petroleum-destructing microorganisms (of the genus Acinetobacter) on the cytogenetic structures of human lymphocytes in cell cultures

The capability of the petroleum-destructing bacteria Acinetobacter calcoaceticus and A. valentis isolated from petroleum to induce karyopathological changes and chromosomal aberrations in human lymphocyte cultures was studied. It was shown that, in contrast to A. valentis, A. calcoaceticus provoked a significant increase in different cytogenetic and chromosomal abnormalities. The majority of the observed chromosomal aberrations (predominantly of the chromatid type) were localized in chromosomes 1 and 2. Meanwhile, abnormalities were found in specific chromosomal regions. Disturbances of the cell division process and changes in the nuclear morphology were observed in the cultures affected by A. calcoaceticus. The most frequent ones were cells displaying micronuclei, nuclear protrusions, lagging of chromosomes and their fragments in mitotic metaphase and anaphase, and multigroup mitoses and C-mitoses. Therefore, in contrast to A. valentis, the petroleum-destructing bacterium A. cacoaceticus has an evident genotoxic effect on human cells in vitro.     

Interplay between Structure-Specific Endonucleases for Crossover Control during Caenorhabditis elegans Meiosis

The number and distribution of crossover events are tightly regulated at prophase of meiosis I. The resolution of Holliday junctions by structure-specific endonucleases, including MUS-81, SLX-1, XPF-1 and GEN-1, is one of the main mechanisms proposed for crossover formation. However, how these nucleases coordinately resolve Holliday junctions is still unclear. Here we identify both the functional overlap and differences between these four nucleases regarding their roles in crossover formation and control in the Caenorhabditis elegans germline. We show that MUS-81, XPF-1 and SLX-1, but not GEN-1, can bind to HIM-18/SLX4, a key scaffold for nucleases. Analysis of synthetic mitotic defects revealed that MUS-81 and SLX-1, but not XPF-1 and GEN-1, have overlapping roles with the Bloom syndrome helicase ortholog, HIM-6, supporting their in vivo roles in processing recombination intermediates. Taking advantage of the ease of genetic analysis and high-resolution imaging afforded by C. elegans, we examined crossover designation, frequency, distribution and chromosomal morphology in single, double, triple and quadruple mutants of the structure-specific endonucleases. This revealed that XPF-1 functions redundantly with MUS-81 and SLX-1 in executing crossover formation during meiotic double-strand break repair. Analysis of crossover distribution revealed that SLX-1 is required for crossover suppression at the center region of the autosomes. Finally, analysis of chromosome morphology in oocytes at late meiosis I stages uncovered that SLX-1 and XPF-1 promote meiotic chromosomal stability by preventing formation of chromosomal abnormalities. We propose a model in which coordinate action between structure-specific nucleases at different chromosome domains, namely MUS-81, SLX-1 and XPF-1 at the arms and SLX-1 at the center region, exerts positive and negative regulatory roles, respectively, for crossover control during C. elegans meiosis.     

Chromosome evolution in marginal populations of Aegilops speltoides: causes and consequences

Background

Genome restructuring is an ongoing process in natural plant populations. The influence of environmental changes on the genome is crucial, especially during periods of extreme climatic fluctuations. Interactions between the environment and the organism manifest to the greatest extent at the limits of the species'' ecological niche. Thus, marginal populations are expected to exhibit lower genetic diversity and higher genetic differentiation than central populations, and some models assume that marginal populations play an important role in the maintenance and generation of biological diversity.

Scope

In this review, long-term data on the cytogenetic characteristics of diploid Aegilops speltoides Tauch populations are summarized and discussed. This species is distributed in and around the Fertile Crescent and is proposed to be the wild progenitor of a number of diploid and polyploid wheat species. In marginal populations of Ae. speltoides, numerical chromosomal aberrations, spontaneous aneuploidy, B-chromosomes, rDNA cluster repatterning and reduction in the species-specific and tribe-specific tandem repeats have been detected. Significant changes were observed and occurred in parallel with changes in plant morphology and physiology.

Conclusions

Considerable genomic variation at the chromosomal level was found in the marginal populations of Ae. speltoides. It is likely that a specific combination of gene mutations and chromosomal repatterning has produced the evolutionary trend in each specific case, i.e. for a particular species or group of related species in a given period of time and in a certain habitat. The appearance of a new chromosomal pattern is considered an important factor in promoting the emergence of interbreeding barriers.     

Identification of Meloidogyne Species on the Basis of Head Shape and,Stylet Morphology of the Male

Head shape and stylet morphology of males of 90 populations of M. arenaria, M. hapla, M. incognita, and M. javanica from geographic regions of the world were compared by light microscopy (LM). In addition, stylets of one population each of M. arenaria, M. incognita, and M. javanica and three different chromosomal forms of M. hapla race A and two of race B were excised and examined with a scanning electron microscope (SEM). Differences among species occurred in both head and stylet morphology. Head morphology differed in size and shape of the head cap, annulation of the head region, and width of the head region relative to the first body annule. Differences in stylets occurred in size and shape of the cone, shaft, and knobs. All populations of M. hapla, except one, had similar head morphology, but stylet morphology was different between cytological races A and B. Populations of M. javanica varied with respect to the presence of head annulations. Head shape and stylet morphology of males are recommended as additional characters useful in the identification of root-knot nematodes.     

Further Comparison of Temperature Effects on Growth and Survival of Clostridium perfringens Type A Isolates Carrying a Chromosomal or Plasmid-Borne Enterotoxin Gene

Clostridium perfringens type A isolates can carry the enterotoxin gene (cpe) on either their chromosome or a plasmid, but food poisoning isolates usually have a chromosomal cpe gene. This linkage between chromosomal cpe isolates and food poisoning has previously been attributed, at least in part, to better high-temperature survival of chromosomal cpe isolates than of plasmid cpe isolates. In the current study we assessed whether vegetative cells and spores of chromosomal cpe isolates also survive better than vegetative cells and spores of plasmid cpe isolates survive when the vegetative cells and spores are subjected to low temperatures. Vegetative cells of chromosomal cpe isolates exhibited about eightfold-higher decimal reduction values (D values) at 4°C and threefold-higher D values at −20°C than vegetative cells of plasmid cpe isolates exhibited. After 6 months of incubation at 4°C and −20°C, the average log reductions in viability for spores of plasmid cpe isolates were about fourfold and about threefold greater, respectively, than the average log reductions in viability for spores from chromosomal cpe isolates. C. perfringens type A isolates carrying a chromosomal cpe gene also grew significantly faster than plasmid cpe isolates grew at 25°C, 37°C, or 43°C. In addition, chromosomal cpe isolates grew at higher maximum and lower minimum temperatures than plasmid cpe isolates grew. Collectively, these results suggest that chromosomal cpe isolates are commonly involved in food poisoning because of their greater resistance to low (as well as high) temperatures for both survival and growth. They also indicate the importance of proper low-temperature storage conditions, as well as heating, for prevention of C. perfringens type A food poisoning.