Heterochromatic Regions Of Chromosomes Research Articles

<i>Otu</i> and <i>Rif<sup>1</sup></i> double mutant enables analysis of satellite DNA in polytene chromosomes of ovarian germ cells in <i>Drosophila melanogaster</i>

Polytene chromosomes in Drosophila serve as a classical model for cytogenetic studies. However, heterochromatic regions of chromosomes are typically under-replicated, hindering their analysis. Mutations in the Rif1 gene lead to additional replication of heterochromatic sequences, including satellite DNA, in salivary gland cells. Here, we investigated the impact of the Rif1 mutation on heterochromatin in polytene chromosomes formed in ovarian germ cells due to the otu gene mutation. By the analysis of otu11; Rif11 double mutants, we found that, in the presence of the Rif1 mutation, ovarian cells undergo additional polytenization of pericentromeric regions. This includes the formation of large chromatin blocks composed of satellite DNA. Thus, the effects of the Rif1 mutation were similar in salivary gland and germ cells. The otu11; Rif11 system opens new possibilities for studying factors associated with heterochromatin during oogenesis.

Otu and Rif1 Double Mutant Enables Analysis of Satellite DNA in Polytene Chromosomes of Ovarian Germ Cells in Drosophila melanogaster.

Polytene chromosomes in Drosophila serve as a classical model for cytogenetic studies. However, heterochromatic regions of chromosomes are typically under-replicated, hindering their analysis. Mutations in the Rif1 gene lead to additional replication of heterochromatic sequences, including satellite DNA, in salivary gland cells. Here, we investigated the impact of the Rif1 mutation on heterochromatin in polytene chromosomes formed in ovarian germ cells due to the otu gene mutation. By the analysis of otu11; Rif11 double mutants, we found that, in the presence of the Rif1 mutation, ovarian cells undergo additional polytenization of pericentromeric regions. This includes the formation of large chromatin blocks composed of satellite DNA. Thus, the effects of the Rif1 mutation are similar in salivary gland and germ cells. The otu11; Rif11 system opens new possibilities for studying factors associated with heterochromatin during oogenesis.

Supernumerary Marker Chromosome Identified in Asian Elephant (Elephas maximus).

We identified a small, supernumerary marker chromosome (sSMC) in two phenotypically normal Asian elephants (Elephas maximus): a female (2n = 57,XX,+mar) and her male offspring (2n = 57,XY,+mar). sSMCs are defined as structurally abnormal chromosomes that cannot be identified by conventional banding analysis since they are usually small and often lack distinct banding patterns. Although current molecular techniques can reveal their origin, the mechanism of their formation is not yet fully understood. We determined the origin of the marker using a suite of conventional and molecular cytogenetic approaches that included (a) G- and C-banding, (b) AgNOR staining, (c) preparation of a DNA clone using laser microdissection of the marker chromosome, (d) FISH with commercially available human painting and telomeric probes, and (e) FISH with centromeric DNA derived from the centromeric regions of a marker-free Asian elephant. Moreover, we present new information on the location and number of NORs in Asian and savanna elephants. We show that the metacentric marker was composed of heterochromatin with NORs at the terminal ends, originating most likely from the heterochromatic region of chromosome 27. In this context, we discuss the possible mechanism of marker formation. We also discuss the similarities between sSMCs and B chromosomes and whether the marker chromosome presented here could evolve into a B chromosome in the future.

Genome organization of major tandem repeats and their specificity for heterochromatin of macro- and microchromosomes in Japanese quail.

Tandemly repeated DNAs form heterochromatic regions of chromosomes, including the vital centromeric chromatin. Despite the progress in new genomic technologies, tandem repeats remain poorly deciphered and need targeted analysis in the species of interest. The Japanese quail is one of the highest-producing poultry species as well as a model organism. Its genome differs by a noticeable accumulation of heterochromatin, which led to an increase by 1/7 compared to the chicken genome size. Prominent heterochromatin blocks occupy the short arms of acrocentric macrochromosomes and of microchromosomes. We have applied de novo repeat finder approach to unassembled raw reads of the Japanese quail genome. We identified the 20 most common tandem repeats with the abundance >1Mb, which represent about 4.8% of the genome. We found that tandem repeat CjapSAT primarily contributes to the centromeric regions of the macrochromosomes CJA1-8. Cjap31B together with previously characterized BglII makes up centromere regions of microchromosomes and W chromosome. Other repeats populate heterochromatin of microchromosomal short arms in unequal proportions, as revealed by fluorescence in situ hybridization. The Cjap84A, Cjap408A, and CjapSAT repeat sequences show similarities to retrotransposon motifs. This suggests that retroelements may have played a crucial role in the distribution of repeats throughout the Japanese quail genome.

Loss of chromatin remodeler DDM1 causes segregation distortion in Arabidopsis thaliana.

In ddm1 mutants, the DNA methylation is primarily affected in the heterochromatic region of the chromosomes, which is associated with the segregation distortion of SNPs in the F2 progenies. Segregation distortion (SD) is common in most genetic mapping experiments and a valuable resource to determine how gene loci induce deviation. Meiotic DNA crossing over and SD are under the control of several types of epigenetic modifications. DNA methylation is an important regulatory epigenetic modification that is inherited across generations. In the present study, we investigated the relationship between SD and DNA methylation. The ecotypes Col-0/C24 and chromatin remodeler mutants ddm1-10/Col and ddm1-15/C24 were reciprocally crossed to obtain F2 generations. A total of 300 plants for each reciprocally crossed plant in the F2 generations were subjected to next-generation sequencing to detect the single-nucleotide polymorphisms (SNPs) as DNA markers. All SNPs were analyzed using the Chi-square test method to determine their segregation ratio in F2 generations. Through the segregation ratio, whole-genome SNPs were classified into 16 classes. In class 10, the SNPs in the reciprocal crosses of wild type showed the expected Mendelian ratio of 1:2:1, while those in the reciprocal crosses of ddm1 mutants showed distortion. In contrast, all SNPs in class 16 displayed a normal 1:2:1 ratio, and class 1 showed SD, regardless of wild type or mutants, as assessed using CAPS (cleaved amplified polymorphic sequences) marker analysis to confirm the next-generation sequencing. In ddm1 mutants, the DNA methylation is highly reduced throughout the whole genome and more significantly in the heterochromatic regions of chromosomes. Our results showed that the ddm1 mutants exhibit low levels of DNA methylation, which facilitates the SD of SNPs primarily located in the heterochromatic region of chromosomes by reducing the heterozygous ratio. The present study will provide a strong base for future research focusing on the impact of DNA methylation on trait segregation and plant evolution.

Genome evolution during bread wheat formation unveiled by the distribution dynamics of SSR sequences on chromosomes using FISH

BackgroundDuring the bread wheat speciation by polyploidization, a series of genome rearrangement and sequence recombination occurred. Simple sequence repeat (SSR) sequences, predominately located in heterochromatic regions of chromosomes, are the effective marker for tracing the genomic DNA sequence variations. However, to date the distribution dynamics of SSRs on chromosomes of bread wheat and its donors, including diploid and tetraploid Triticum urartu, Aegilops speltoides, Aegilops tauschii, Triticum turgidum ssp. dicocoides, reflecting the genome evolution events during bread wheat formation had not been comprehensively investigated.ResultsThe genome evolution was studied by comprehensively comparing the distribution patterns of (AAC)n, (AAG)n, (AGC)n and (AG)n in bread wheat Triticum aestivum var. Chinese Spring and its progenitors T. urartu, A. speltoides, Ae. tauschii, wild tetroploid emmer wheat T. dicocoides, and cultivated emmer wheat T. dicoccum. Results indicated that there are specific distribution patterns in different chromosomes from different species for each SSRs. They provided efficient visible markers for identification of some individual chromosomes and SSR sequence evolution tracing from the diploid progenitors to hexaploid wheat. During wheat speciation, the SSR sequence expansion occurred predominately in the centromeric and pericentromeric regions of B genome chromosomes accompanied by little expansion and elimination on other chromosomes. This result indicated that the B genome might be more sensitive to the “genome shock” and more changeable during wheat polyplodization.ConclusionsDuring the bread wheat evolution, SSRs including (AAC)n, (AAG)n, (AGC)n and (AG)n in B genome displayed the greatest changes (sequence expansion) especially in centromeric and pericentromeric regions during the polyploidization from Ae. speltoides S genome, the most likely donor of B genome. This work would enable a better understanding of the wheat genome formation and evolution and reinforce the viewpoint that B genome was originated from S genome.

Structural variations of subterminal satellite blocks and their source mechanisms as inferred from the meiotic configurations of chimpanzee chromosome termini

African great apes have large constitutive heterochromatin (C-band) blocks in subtelomeric regions of the majority of their chromosomes, but humans lack these. Additionally, the chimpanzee meiotic cell division process demonstrates unique partial terminal associations in the first meiotic prophase (pachytene). These are likely formed as a result of interaction among subtelomeric C-band blocks. We thus conducted an extensive study to define the features in the subtelomeric heterochromatic regions of chimpanzee chromosomes undergoing mitotic metaphase and meiotic cell division. Molecular cytogenetic analyses with probes of both subterminal satellite DNA (a main component of C-band) and rDNA demonstrated principles of interaction among DNA arrays. The results suggest that homologous and ectopic recombination through persistent subtelomeric associations (post-bouquet association observed in 32% of spermatocytes in the pachytene stage) appears to create variability in heterochromatin patterns and simultaneously restrain subtelomeric genome polymorphisms. That is, the meeting of non-homologous chromosome termini sets the stage for ectopic pairing which, in turn, is the mechanism for generating variability and genomic dispersion of subtelomeric C-band blocks through a system of concerted evolution. Comparison between the present study and previous reports indicated that the chromosomal distribution rate of sutelomeric regions seems to have antagonistic correlation with arm numbers holding subterminal satellite blocks in humans, chimpanzees, and gorillas. That is, the increase of subterminal satellite blocks probably reduces genomic diversity in the subtelomeric regions. The acquisition vs. loss of the subtelomeric C-band blocks is postulated as the underlying engine of this chromosomal differentiation yielded by meiotic chromosomal interaction.

Genetic and Molecular Analysis of Essential Genes in Centromeric Heterochromatin of the Left Arm of Chromosome 3 in Drosophila melanogaster.

A large portion of the Drosophila melanogaster genome is contained within heterochromatic regions of chromosomes, predominantly at centromeres and telomeres. The remaining euchromatic portions of the genome have been extensively characterized with respect to gene organization, function and regulation. However, it has been difficult to derive similar data for sequences within centromeric (centric) heterochromatin because these regions have not been as amenable to analysis by standard genetic and molecular tools. Here we present an updated genetic and molecular analysis of chromosome 3L centric heterochromatin (3L Het). We have generated and characterized a number of new, overlapping deficiencies (Dfs) which remove regions of 3L Het. These Dfs were critically important reagents in our subsequent genetic analysis for the isolation and characterization of lethal point mutations in the region. The assignment of these mutations to genetically-defined essential loci was followed by matching them to gene models derived from genome sequence data: this was done by using molecular mapping plus sequence analysis of mutant alleles, thereby aligning genetic and physical maps of the region. We also identified putative essential gene sequences in 3L Het by using RNA interference to target candidate gene sequences. We report that at least 25, or just under 2/3 of loci in 3L Het, are essential for viability and/or fertility. This work contributes to the functional annotation of centric heterochromatin in Drosophila, and the genetic and molecular tools generated should help to provide important insights into the organization and functions of gene sequences in 3L Het.

Heterochromatic regions in Japanese quail chromosomes: comprehensive molecular-cytogenetic characterization and 3D mapping in interphase nucleus.

Chromosomes of Japanese quail (Coturnix coturnix japonica, 2n=78), a galliform domestic species closely related to chicken, possess multiple heterochromatic segments. Due to the difficulties in careful analysis of such heterochromatic regions, there is a lack of data on their DNA composition, epigenetic status, as well as spatial distribution in interphase nucleus. In the present study, we applied giant lampbrush chromosome (LBC) microdissection for high-resolution analysis of quail centromeric regions of macrochromosomes and polymorphic short arms of submetacentric microchromosomes. FISH with the dissected material on mitotic and meiotic chromosomes indicated that in contrast to centromeres of chicken macrochromosomes, which are known to harbor chromosome-specific and, in some cases, tandem repeat-free sequences, centromeres of quail macroautosomes (CCO1-CCO11) have canonical organization. CCO1-CCO11 centromeres possess massive blocks of common DNA repeats demonstrating transcriptional activity at LBC stage. These repeats seem to have been subjected to chromosome size-correlated homogenization previously described primarily for avian microchromosomes. In addition, comparative FISH on chicken chromosomes supported the previous data on centromere repositioning events during galliform karyotype evolution. In interphase nucleus of different cell types, repetitive elements specific for microchromosome short arms constitute the material of prominent centrally located chromocenters enriched with markers of constitutive heterochromatin and rimmed with clusters of microchromosomal centromeric BglII-repeat. Thus, clustering of such repeats is responsible for the peculiar architecture of quail interphase nucleus. In contrast, centromere repeats of the largest macrochromosomes (CCO1 and CCO2) are predominantly localized in perinuclear heterochromatin. The possible involvement of the isolated repeats in radial genome organization is discussed.

Peculiarities of Meiosis in Drosophila: A Classical Object of Genetics Has Nonstandard Meiosis

Meiosis in Drosophila differs from the canonical type. Males lack synaptonemal complexes, chiasmata, and crossing-over. Only females have these classical traits of meiosis. However, during meiosis prophase I, female Drosophila lack the bouquet-like chromosome arrangement, an accessory mechanism for homologous chromosomes synapsis that is typical for the majority of eukaryotes. Instead, the pericentromeric heterochromatic regions of chromosomes are fused into the chromocenter. This leads to peculiarities in the pairing, synapsis, and segregation of chromosomes and to the so-called interchromosomal phenomena (effects). During late prophase I in females, chromosomes are packed in a karyosome, which is also characteristic of females in other animals with the nutrimental type of egg nutrition. The dissimilarities of meiosis in Drosophila from the classical scheme do not affect significantly its genetic consequences.

Distinct 'safe zones' at the nuclear envelope ensure robust replication of heterochromatic chromosome regions.

Chromosome replication and transcription occur within a complex nuclear milieu whose functional subdomains are beginning to be mapped out. Here we delineate distinct domains of the fission yeast nuclear envelope (NE), focusing on regions enriched for the inner NE protein, Bqt4, or the lamin interacting domain protein, Lem2. Bqt4 is relatively mobile around the NE and acts in two capacities. First, Bqt4 tethers chromosome termini and the mat locus to the NE specifically while these regions are replicating. This positioning is required for accurate heterochromatin replication. Second, Bqt4 mobilizes a subset of Lem2 molecules around the NE to promote pericentric heterochromatin maintenance. Opposing Bqt4-dependent Lem2 mobility are factors that stabilize Lem2 beneath the centrosome, where Lem2 plays a crucial role in kinetochore maintenance. Our data prompt a model in which Bqt4-rich nuclear subdomains are 'safe zones' in which collisions between transcription and replication are averted and heterochromatin is reassembled faithfully.

Immunodeficiency, centromeric heterochromatin instability of chromosomes 1, 9, and 16, and facial anomalies: the ICF syndrome

Instability of the heterochromatic centromeric regions of chromosomes 1 associated with immunodeficiency was found in a 3 and half months old girl. The case was referred to Department of Genetics, Global Reference Laboratory, Metropolis Healthcare Ltd, Mumbai with the suspicion of Downs Syndrome for chromosomal karyotyping. This patient had facial anomalies in addition to combined immunodeficiency and chromosomal instability. Stretching of the heterochromatic centromeric regions of chromosomes 1 and homologous and non-homologous associations of these regions were the most common cytogenetic findings in this patient. Multi-branched configurations and whole arm deletions of chromosomes 1 were also found. Comparing clinical and chromosomal data we conclude that the patient was suffering from immunodeficiency, centromeric heterochromatin instability and facial syndrome. The chromosomal karyotyping report was showing instability around vicinity of chromosome 1 and various abnormalities around vicinity of both chromosomes 1 were found in form of random breakages of chromosome 1, fragile sites, deletions/duplications of small and long arm, extra copies of chromosome 1 with rosette formations, exchange of arms and partial aneuploidies of chromosome 1. Further, the investigations regarding the immune status revealed that the level of IgM (5.98 mg/dl), IgA (<6.16mg/dl) and IgG (92.10 mg/dl) subgroup of immunoglobulin was very low. The results were consistent with The Immunodeficiency, Centromeric region instability, Facial anomalies (ICF) syndrome. Second sample from the patient for molecular studies could not be collected and performed since the patient failed to survive after 3 and half months.

IDENTIFICATION OF CDNA FRAGMENT TIGHTLY LINKED TO NV AND TM-2 LOCI IN TOMATO

Tm-2 is a resistance gene in tomato to Tomato Mosaic Virus (ToMV), located in heterochromatic region of chromosome nine. Since map based cloning difficult to perform for identify the gene on that region, we apply differential display approach by using two near-isogenic tomato lines (NILs), one without Tm-2 and the other with Tm-2 to identify cDNAs of the transcripts from the region surrounding the Tm-2 locus. Among the 150 combinations of three anchor primers and fifty arbitrary primers, 10 combinations generated cDNA polymorphic bands. Out of them, only one combination of CA6, exhibited polymorphic band under southern blot analysis, subsequently a genetic experiment showed that the CA6 locus tightly linked to the Tm-2 locus. The CA6 fragment also hybridized to genomic DNA fragments from a tomato line carrying Tm-2a, a line of L. peruvianum from which Tm-2a originated, and a tomato line carrying another Tm-2-like gene. A northern hybridization blotting result suggested that the gene corresponding to CA6 fragment was constitutively transcribed.

The puzzling character of repetitive DNA in Phodopus genomes (Cricetidae, Rodentia).

Three novel repetitive DNA sequences are described, presenting a similar heterochromatic chromosomal location in two hamster species: Phodopus roborovskii and Phodopus sungorus (Cricetidae, Rodentia). Namely, two species-specific repetitive sequences (PROsat from P. roborovskii and PSUchr1sat from P. sungorus) surrounding a third one (PsatDNA), that is shared by both hamster genomes. Fiber-FISH analyses revealed that PROsat intermingles with PsatDNA in P. roborovskii and PSUchr1sat intermingles with PsatDNA in P. sungorus. A model explaining the evolution of this intricate chromosomal distribution is proposed, which can explain better the evolution of these very derivative genomes (in comparison to the ancestral Muroidea). The most plausible evolutionary scenario seems to be the expansion of a number of repeats into other's domain, most probably resulting in its intermingling, followed by the subsequent spread of these complex repeats from a single chromosomal location to other chromosomes. Evidences of an association between repetitive sequences and the chromosome evolution process were observed, namely for PROsat. Most probably, the evolutionary breakpoints that shaped PRO and PSU chromosomes (pericentric inversions and fusions) occurred within the boundaries of PROsat blocks in the ancestor. The repeats high diversity at the heterochromatic regions of Phodopus chromosomes, together with its complex organization, suggests that these species are important models for evolutionary studies, namely in the investigation of a possible relationship between repetitive sequences and the occurrence of chromosomal rearrangements and consequently, in genome evolution.

Comparative Genomic Analysis of Euchromatic and Heterochromatic Chromosomal regions of two species of Drosophila

Comparative genomic analyses can yield important information about the structure and function of genomes. The public availability of DNA sequence data from genome sequencing projects provides opportunities for undergraduate and high school students to do genomics research. The Genomics Education Partnership (GEP, see www.gep.wustl.edu) is a scientific and educational collaboration centered at Washington University in St. Louis (WUSTL), which provides a variety of tools for comparative genome analysis of several Drosophila species. The goal of the current GEP project is to compare sequences of chromosome four (also called the ‘dot' chromosome) from D. melanogaster with homologous regions from other species. The dot chromosome has interesting features of heterochromatin and euchromatin, and is therefore a good choice for studying the evolution of these two types of sequences. Here we describe the analysis of a euchromatic region from D. biarmipes that is homologous to chromosome 3L of D. melanogaster. This analysis serves as an important control comparison in our larger project. We analyzed 40,000 base pairs of DNA from contig 6 of the D. biarmipes genome. Initial analysis suggested there are nine predicted genes in this region. We used several analysis tools available from the GEP and other sources to generate precise gene models for these genes. Our results will contribute to the completion of the full genomic map of D. biarmipes and will be compiled along with other student data to analyze the evolution of the structure and function of heterochromatin as compared to euchromatin. *The Genomics Education Partnership is funded by HHMI (Professors grant #52007051 to SCR Elgin) and by Washington University in St. Louis (WUSTL).

Simple Method for Fluorescence DNA <em>In Situ</em> Hybridization to Squashed Chromosomes

DNA in situ hybridization (DNA ISH) is a commonly used method for mapping sequences to specific chromosome regions. This approach is particularly effective at mapping highly repetitive sequences to heterochromatic regions, where computational approaches face prohibitive challenges. Here we describe a streamlined protocol for DNA ISH that circumvents formamide washes that are standard steps in other DNA ISH protocols. Our protocol is optimized for hybridization with short single strand DNA probes that carry fluorescent dyes, which effectively mark repetitive DNA sequences within heterochromatic chromosomal regions across a number of different insect tissue types. However, applications may be extended to use with larger probes and visualization of single copy (non-repetitive) DNA sequences. We demonstrate this method by mapping several different repetitive sequences to squashed chromosomes from Drosophila melanogaster neural cells and Nasonia vitripennis spermatocytes. We show hybridization patterns for both small, commercially synthesized probes and for a larger probe for comparison. This procedure uses simple laboratory supplies and reagents, and is ideal for investigators who have little experience with performing DNA ISH.

Topoisomerase II is required for the proper separation of heterochromatic regions during Drosophila melanogaster female meiosis.

Heterochromatic homology ensures the segregation of achiasmate chromosomes during meiosis I in Drosophila melanogaster females, perhaps as a consequence of the heterochromatic threads that connect achiasmate homologs during prometaphase I. Here, we ask how these threads, and other possible heterochromatic entanglements, are resolved prior to anaphase I. We show that the knockdown of Topoisomerase II (Top2) by RNAi in the later stages of meiosis results in a specific defect in the separation of heterochromatic regions after spindle assembly. In Top2 RNAi-expressing oocytes, heterochromatic regions of both achiasmate and chiasmate chromosomes often failed to separate during prometaphase I and metaphase I. Heterochromatic regions were stretched into long, abnormal projections with centromeres localizing near the tips of the projections in some oocytes. Despite these anomalies, we observed bipolar spindles in most Top2 RNAi-expressing oocytes, although the obligately achiasmate 4th chromosomes exhibited a near complete failure to move toward the spindle poles during prometaphase I. Both achiasmate and chiasmate chromosomes displayed defects in biorientation. Given that euchromatic regions separate much earlier in prophase, no defects were expected or observed in the ability of euchromatic regions to separate during late prophase upon knockdown of Top2 at mid-prophase. Finally, embryos from Top2 RNAi-expressing females frequently failed to initiate mitotic divisions. These data suggest both that Topoisomerase II is involved in the resolution of heterochromatic DNA entanglements during meiosis I and that these entanglements must be resolved in order to complete meiosis.

Is pericentromeric inversion of the heterochromatic region of chromosome 9 involved in couple infertility?

Searchable abstracts of presentations at key conferences in endocrinology ISSN 1470-3947 (print) | ISSN 1479-6848 (online)

Molecular analysis and genomic organization of major DNA satellites in banana (Musa spp.).

Satellite DNA sequences consist of tandemly arranged repetitive units up to thousands nucleotides long in head-to-tail orientation. The evolutionary processes by which satellites arise and evolve include unequal crossing over, gene conversion, transposition and extra chromosomal circular DNA formation. Large blocks of satellite DNA are often observed in heterochromatic regions of chromosomes and are a typical component of centromeric and telomeric regions. Satellite-rich loci may show specific banding patterns and facilitate chromosome identification and analysis of structural chromosome changes. Unlike many other genomes, nuclear genomes of banana (Musa spp.) are poor in satellite DNA and the information on this class of DNA remains limited. The banana cultivars are seed sterile clones originating mostly from natural intra-specific crosses within M. acuminata (A genome) and inter-specific crosses between M. acuminata and M. balbisiana (B genome). Previous studies revealed the closely related nature of the A and B genomes, including similarities in repetitive DNA. In this study we focused on two main banana DNA satellites, which were previously identified in silico. Their genomic organization and molecular diversity was analyzed in a set of nineteen Musa accessions, including representatives of A, B and S (M. schizocarpa) genomes and their inter-specific hybrids. The two DNA satellites showed a high level of sequence conservation within, and a high homology between Musa species. FISH with probes for the satellite DNA sequences, rRNA genes and a single-copy BAC clone 2G17 resulted in characteristic chromosome banding patterns in M. acuminata and M. balbisiana which may aid in determining genomic constitution in interspecific hybrids. In addition to improving the knowledge on Musa satellite DNA, our study increases the number of cytogenetic markers and the number of individual chromosomes, which can be identified in Musa.

Ogre retrotransposons in Lathyrus species

A repeated DNA element (pLsat10) 225 bp in length, whose nucleotide sequence was partly identical to that of the PBS of Ogre retrotransposons in Pisum sativum and in part 78.3% similar to that of the adjoining portion of the 5′ LTR of these retroelements, was isolated from a partial genomic library of Lathyrus sativus. By using this DNA sequence in dot-blot and Southern blot hybridizations, Ogre retrotransposons were traced and studied in four Lathyrus species (L. latifolius, L. odoratus, L. sativus, and L. sylvestris). The copy number per ng of DNA of pLsat-related sequences in L. sativus turned out to be 1.5×107, and an upper limit estimate of the proportion of the genome made up by Ogre may be 10–16%. The results of Southern blot hybridization of pLsat10 to genomic DNAs indicated the occurrence, in each Lathyrus genome, of distinct subfamilies of Ogre and suggested a higher activity of these retrotransposons in annual than in perennial species. Fluorescent in situ hybridization of pLsat10 showed Ogre to be widely dispersed in all chromosomes, but poorly represented or absent in heterochromatic chromosome regions.