Chromosomal localization of complex and simple repeated human DNAs

Complex repeating restriction multimers and a simple AT rich satellite isolated with Hoechst 33258 (<= 0.5% of the human genome) were localized by in situ hybridization to human chromosomes. The complex repeats were clustered at the centromeres, consonant with their integration in tandem arrays at these loci; these sequences were very prominent on chromosomes 7, 10 and 19, sites not previously identified with any specific human repeated sequence. The Hoechst simple satellite labelled predominantly the long arms of the Y chromosome. Although this simple satellite and the complex restriction multimers did not hybridize with each other, and did not contain detectable ribosomal sequences, both isolates additionally labelled the nucleolus organizing regions (NORs) of acrocentric chromosomes. —The possible relationship of complex and simple repeated DNAs, and their assignment to specific chromosomal domains, is discussed.     

A solitary human H3 histone gene on chromosome 1

A solitary histone H3 gene encoding a novel H3 protein sequence has been isolated. This H3 gene maps to chromosome 1 (1g42), whereas we have shown previously that the majority of the human histone genes form a large cluster on chromosome 6 (6p21.3). In addition, a small cluster has been described at 1q21. The clustered histone genes are expressed during the S-phase of the cell cycle, hence their definition as replication-dependent histone genes. In contrast, expression of replacement histone genes is essentially cell-cycle independent; they are solitary genes and map outside the major clusters. The newly described H3 gene maps outside all known histone gene clusters and varies by four amino acid residues from the consensus mammalian H3 structure. In contrast to other solitary histone genes, this human H3 gene shows the consensus promoter and 3 flanking portions that are typical for replication-dependent genes.     

Cytogenetic characterization and mapping of rDNAs,core histone genes and telomeric sequences in <Emphasis Type="Italic">Venerupis aurea</Emphasis> and <Emphasis Type="Italic">Tapes rhomboides</Emphasis> (Bivalvia: Veneridae)

We describe the chromosomal location of GC-rich regions, 28S and 5S rDNA, core histone genes, and telomeric sequences in the veneroid bivalve species Venerupis aurea and Tapes (Venerupis) rhomboides, using fluorochrome staining with propidium iodide, DAPI and chromomycin A3 (CMA) and fluorescent in situ hybridization (FISH). DAPI dull/CMA bright bands were coincident with the chromosomal location of 28S rDNA in both species. The major rDNA was interstitially clustered at a single locus on the short arms of the metacentric chromosome pair 5 in V. aurea, whereas in T. rhomboides it was subtelomerically clustered on the long arms of the subtelocentric chromosome pair 17. 5S rDNA also was a single subtelomeric cluster on the long arms of subtelocentric pair 17 in V. aurea and on the short arms of the metacentric pair 9 in T. rhomboides. Furthermore, V. aurea showed four telomeric histone gene clusters on three metacentric pairs, at both ends of chromosome 2 and on the long arms of chromosomes 3 and 8, whereas histone genes in T. rhomboides clustered interstitially on the long arms of the metacentric pair 5 and proximally on the long arms of the subtelocentric pair 12. Double and triple FISH experiments demonstrated that rDNA and H3 histone genes localized on different chromosome pairs in the two clam species. Telomeric signals were found at both ends of every single chromosome in both species. Chromosomal location of these three gene families in two species of Veneridae provides a clue to karyotype evolution in this commercially important bivalve family.     

The organization,localization and nucleotide sequence of the histone genes of the midge Chironomus thummi

Several histone gene repeating units containing the genes for histones H1, H2A, H2B, H3 and H4 were isolated by screening a genomic DNA library from the midge Chironomus thummi ssp. thummi. The nucleotide sequence of one complete histone gene repeating unit was determined. This repeating unit contains one copy of each of the five histone genes in the order and orientation H3 H4 H2A H2B H1. The overall length is 6262 bp. The orientation, nucleotide sequence and inferred amino acid sequence as well as the chromosomal arrangement and localization are different from those reported for Drosophila melanogaster. The codon usage also shows marked differences between Chironomus and Drosophila. Thus the histone gene structure reported for Drosophila is not typical of all insects.by H. Jäckle     

Polymorphism and stability in the histone gene cluster of Drosophila melanogaster

Histone genes in Drosophila melanogaster are organized into repeats of 4.8 and 5.0 kb (Lifton et al., 1978). We find these repeat sizes in every one of the more than 20 Drosophila strains we have examined. Strains differ in the relative amounts of the two repeat types, with ratios varying from 11 to 14, the 5.0 kb repeat always present in equal or greater amounts than the 4.8 kb repeat. Restriction enzyme digestion and blotting analysis reveals that the strains also differ in a number of far less abundant fragments containing histone DNA sequences. In the Amherst and Samarkand strains, there are, in addition, many copies of 4.0 and 5.5 kb repeat-like fragments respectively. A series of stocks were made isogenic for single second chromosomes from the Amherst strain. The hybridization patterns of the histone DNA from these stocks containing different Amherst chromosomes are very similar but a number of differences in the minor fragments were seen. The stability of the histone locus restriction pattern was tested by following the DNA derived from a single second chromosome of the b Adhn² pr cn strain over a two year period. The restriction pattern of major and minor bands remained identical. Finally, histone loci distinguishable by their restriction pattern on blots were recombined with visible markers. These chromosomes will be useful in tracing the fate of specific histone loci during genetic manipulations.     

Histone gene transposition in the phylogeny of the Drosophila obscura group

The chromosomal location of the histone genes was determined in seven species of the Drosophila obscura group by in situ hybridization. Histone genes occur on more than one site per genome and on non-homologous chromosome elements. In addition, the metaphase karyotypes and the banding pattern of the polytene chromosomes were compared. Based on chromosomal characters, the cladogenesis of the D. obscura group was established. From the distribution of histone sites in different species, analysed in this paper and in previous studies, the phylogenetic history of histone gene transposition was derived. The molecular mechanisms responsible for the generation of new histone sites are discussed.     

Sequence and evolution of the gene for the monomeric globin I and its linkage to genes coding for dimeric globins in the insect Chironomus thummi

We isolated genomic clones containing sequences encoding globins I and IA from a Chironomus thummi thummi genomic library. Three clones contain globin IA (ctt-1A) genes, while one contains a globin I (ctt-1) gene. The coding regions of the four genes are identical except for the single base substitution accounting for the globin I/IA polymorphism. The noncoding DNA flanking the coding region is more than 98% similar, confirming a previous hypothesis that the globin ctt-1 and ctt-1A genes are alleles. Hemoglobins I and IA are monomeric in the insect hemolymph. Earlier in situ hybridization studies suggested that monomeric and dimeric globin genes are clustered at different chromosomal loci. In situ hybridization of ctt-1 DNA to polytene salivary gland chromosomes places the ctt-1 gene on the same band as genes for the dimeric globins II and VIIB, forcing revision of the earlier hypothesis that genes for monomeric and dimeric globin genes are at different loci. The evolution of the ctt-1 and ctt-1A alleles and of the two globin gene loci are discussed. Correspondence to: G. Bergtrom     

Development and localization of microsatellite markers for the sibling species Chironomus riparius and Chironomus piger (Diptera: Chironomidae)

Five variable microsatellite loci are reported for the nonbiting midge species Chironomus riparius and Chironomus piger. All loci show considerable intraspecific variation and species‐specific alleles, which allow to discriminate among the two closely related species and their interspecific hybrids, and to estimate genetic diversity within and between populations. Additionally, the loci were localized on C. riparius polytene chromosomes to verify their single copy status and investigate possible chromosomal linkage. The described markers are used in different studies with regard to population and ecological genetics and evolutionary ecotoxicology of Chironomus.     

In situ localization of the evolutionary conserved Cpy/Cty gene in the subfamily Chironominae (Chironomidae, Diptera): establishment of chromosomal homologies

The homologous sites on the salivary gland chromosomes of 13 species from three genera: Chironomus, Glyptotendipes, Kiefferulus have been mapped by means of fluorescent in situ hybridization using the evolutionary conserved gene Cpy/Cty (clone Cla1.1). In all species of genus Chironomus and genus Kiefferulus , the Cty/Cpy gene is located on arm F of chromosome EF. The relocation of the gene among the species of genus Chironomus can be done by simple or complex homozygous inversions which occurred during the divergent evolution of the chromosome of the species. In the genus Glyptotendipes , the Cty/Cpy gene was localized in arm E of chromosome EF. Since the banding patterns of salivary gland chromosomes between genus Chironomus and genus Glyptotendipes cannot be compared directly, in situ hybridization with clone of conservative gene was performed to be established some homologous chromosomes. The results obtained indicate that the chromosome arm F of Chironomus and chromosome arm E of Glyptotendipes may be homologous.     

玉米抗甘蔗花叶病毒基因的比较定位

收集了玉米抗甘蔗花叶病毒基因/QTL定位信息, 借助玉米遗传图谱IBM2 2005 Neighbors进行了整合。在国内外研究中, 累计报道81个抗病毒基因位点, 分布在玉米7条染色体上, 比较定位发现这些位点集中分布于第3和6染色体。采用元分析技术, 确定3个“一致性”抗病毒QTL, 其中1个位于第3染色体, 在遗传图谱IBM2 2005 Neighbors上覆盖的范围为6.44 cM; 2个位于第6染色体, 覆盖范围分别为6.16 cM和27.48 cM。借助比较基因组学策略, 在第3染色体“一致性”QTL区间内筛选出4个抗病位置候选基因。该研究结果为确定和克隆抗病主效基因提供了基础。     

Electron microscopic study of reassociation of spectrin and actin with the human erythrocyte membrane

The distribution of accessible antigenic sites in the chromosomal protein high mobility group one (HMG-1) in Chironomus thummi polytene chromosomes is visualized by immunofluorescence. The results indicate that (a) HMG-1 is distributed in a distinct banding pattern along the entire length of the chromosomes; (b) the banding pattern obtained with fluorescent antibody does not strictly correspond to that observed by phase-contrast microscopy; and (c) the amount of HMG-1 increases, and the fluorescent banding pattern changes, during the development of the organism. Our findings suggest that the protein may be involved in the modulation of the structure of selected loci in the chromosome.     

Polymorphisms in bovine immune genes and their associations with somatic cell count and milk production in dairy cattle

Background

Chromosome rearrangements are an important part of the speciation process in many taxa. The study of chromosome evolution in bivalves is hampered by the absence of clear chromosomal banding patterns and the similarity in both chromosome size and morphology. For this reason, obtaining good chromosome markers is essential for reliable karyotypic comparisons. To begin this task, the chromosomes of the mussels Brachidontes puniceus and B. rodriguezi were studied by means of fluorochrome staining and fluorescent in situ hybridization (FISH).

Results

Brachidontes puniceus and B. rodriguezi both have 2n = 32 chromosomes but differing karyotype composition. Vertebrate-type telomeric sequences appear at both ends of every single chromosome. B. puniceus presents a single terminal major rRNA gene cluster on a chromosome pair while B. rodriguezi shows two. Both mussels present two 5S rDNA and two core histone gene clusters intercalary located on the long arms of two chromosome pairs. Double and triple-FISH experiments demonstrated that one of the 5S rDNA and one of the major rDNA clusters appear on the same chromosome pair in B. rodriguezi but not in B. puniceus. On the other hand, the second 5S rDNA cluster is located in one of the chromosome pairs also bearing one of the core histone gene clusters in the two mussel species.

Conclusion

Knowledge of the chromosomal distribution of these sequences in the two species of Brachidontes is a first step in the understanding of the role of chromosome changes on bivalve evolution.     

DNA replication of histone gene repeats in Drosophila melanogaster tissue culture cells: multiple initiation sites and replication pause sites.

We showed previously that DNA replication initiates at multiple sites in the 5-kb histone gene repeating unit in early embryos of Drosophila melanogaster. The present report shows evidence that replication in the same chromosomal region initiates at multiple sites in tissue culture cells as well. First, we analyzed replication intermediates by the two-dimensional gel electrophoretic replicon mapping method and detected bubble-form replication intermediates for all fragments restricted at different sites in the repeating unit. Second, we analyzed bromodeoxyuridine-labeled nascent strands amplified by the polymerase chain reaction method and detected little differences in the size distribution of nascent strands specific to six short segments located at different sites in the repeating unit. These results strongly suggest that DNA replication initiates at multiple sites located within the repeating unit. We also found several replication pause sites located at 5' upstream regions of some histone genes.     

Chromosome rearrangements in Pectinidae (Bivalvia: Pteriomorphia) implied based on chromosomal localization of histone H3 gene in four scallops

Chromosomal structural rearrangement in four scallops, Chlamys farreri (n = 19), Patinopecten yessoensis (n = 19), Chlamys nobilis (n = 16) and Argopecten irradians (n = 16), was studied by fluorescence in situ hybridization using histone H3 gene probes. The results show that histone H3 gene sites differ strikingly with regard to number, location, and intensity among, or even within these species. For example, two histone H3 gene loci were detected on the metaphase chromosomes of P. yessoensis, while one locus was found in the others. In P. yessoensis, differing intensities of hybridization signals were detected between homologues 5 and 11, and within homologue 11. These data suggest that the histone H3 gene is a qualified chromosome marker for the preliminary understanding of the historical chromosomal reconstructing of the Pectinidae family. The variable distribution patterns of the histone H3 gene suggest that gene duplication/diminution as well as chromosome rearrangements by inversion and translocation may have played important roles in the genomic evolution of Pectinidae. We also compiled our present results with former published data regarding the chromosome mapping of rDNAs in species of the Pectinidae family. Such comparative chromosomal mapping should improve our understanding of historical chromosomal reconstructions of modern-day scallops.     

The location of repeated DNA sequences in the chromosomes of Chironomus tentans

Polytene chromosomes of Chironomus tentans were hybridized in situ with in vivo labelled nuclear and chromosomal RNA. Nuclear RNA formed hybrids preferentially in five distinct regions considered to contain clustered, repeated DNA sequences. These are the two nucleolar organizer regions, Balbiani ring 1 and 2, and the 5 S RNA genes in region 2A of chromosome II, which together comprised almost 70% of the total number of grains over the complement. The remaining grains were diffusely distributed over the chromosomes. There was a significant difference in the distribution of grains when RNA from different chromosomes was used for hybridization. Chromosome I RNA hybridized preferentially with chromosome I, and chromosome II+III RNA preferentially with chromosome II+III. Some regions within the chromosomes hybridized significantly more chromosomal RNA than other regions. A considerable cross-hybridization of RNA from one particular type of chromosome with the other chromosomes was also found. It is concluded that repeated DNA sequences which hybridize with heterogeneous chromosomal RNA in C. tentans are widely dispersed in the genome. Some of these sequences have a delimited localization, others are dispersed, and some sequences which are transcribed in one particular chromosome are present also in the other chromosomes.     

Nature genetic basis and evolution of the haemoglobin polymorphism inChironomus

Chironomus larvae exhibit considerable haemoblobin polymorphism. Chironomus tnetans has 10 and C. pallidivittatus has 8 electrophoretically different Hb-chains. With the exception of one Hb-chain, all are species-specific. The hybrid which is fertile, shows the Hb-pattern of both parents. In the F2 and subsequent generations, considerable chromosome rearrangements occurs. Since the chromosomes of the parent species can be distinguished in the polytene state, Hb-patterns can be correlated with specific chromosomal constitutions. All the species-specific Hb-genes are located on one chromosome. This finding suggests that the Hb-genes have evolved through multiple gene duplications. Different mechanisms for gene duplication are discussed.     

Retrogenes Moved Out of the Z Chromosome in the Silkworm

Previous studies on organisms with well-differentiated X and Y chromosomes, such as Drosophila and mammals, consistently detected an excess of genes moving out of the X chromosome and gaining testis-biased expression. Several selective evolutionary mechanisms were shown to be associated with this nonrandom gene traffic, which contributed to the evolution of the X chromosome and autosomes. If selection drives gene traffic, such traffic should also exist in species with Z and W chromosomes, where the females are the heterogametic sex. However, no previous studies on gene traffic in species with female heterogamety have found any nonrandom chromosomal gene movement. Here, we report an excess of retrogenes moving out of the Z chromosome in an organism with the ZW sex determination system, Bombyx mori. In addition, we showed that those "out of Z" retrogenes tended to have ovary-biased expression, which is consistent with the pattern of non-retrogene traffic recently reported in birds and symmetrical to the retrogene movement in mammals and fruit flies out of the X chromosome evolving testis functions. These properties of gene traffic in the ZW system suggest a general role for the heterogamety of sex chromosomes in determining the chromosomal locations and the evolution of sex-biased genes.