Satellite DNA-correlated nucleosomal proteins in Drosophila virilis

Three major satellite DNAs comprise 40–45% of the genome of Drosophila virilis. Since these satellites are not substrates for most restriction enzymes, we were able to digest D. virilis nuclei with HaeIII and micrococcal nuclease and isolate chromatin fractions containing variable levels of satellite DNA. Electrophoretic analysis of these chromatin fractions revealed that the level of the acid-soluble chromosomal protein, cp17.3, was directly related to the percentage of satellite DNA in chromatin. The correlation between cp17.3 and satellite DNA abundance suggests that cp17.3 is involved in the heterochromatic condensation of satellite DNAs. cp17.3 occurs at a frequency of one molecule per 10–20 nucleosomes. It is detected in an electrophoretically distinguishable class of mononucleosomes, provisionally identified as MN1uH2A, which contains ubiquitinated histone H2A (uH2a) but lacks histone H1. It is not detected in MN1, a second class of mononucleosomes, which lacks uH2A and H1. Since cp17.3 is correlated with satellite DNAs and present in nucleosome cores, it might be a histone variant specifically associated with satellite DNAs.This work was supported by Grant GM22138 from the National Institutes of Health. G.A.V. was a predoctoral trainee supported by Grant GM07094 from the National Institutes of Health.     

Denaturation of mouse satellite and ribosomal DNA during hydroxyapatite thermal chromatography of chromatin

Mouse DNA and chromatin were melted on hydroxyapatite and the denaturation profiles of ribosomal and satellite DNAs were followed by hybridization with their complementary RNAs. Neither ribosomal nor bulk DNA had significantly different melting profiles in chromatin as compared to DNA. However, most of satellite DNA eluted at higher temperature from chromatin than from purified DNA. One explanation for the higher melting temperature of mouse satellite DNA in chromatin suggests that the complex between this particular DNA component and at least some proteins in chromatin is more stable than the average DNA-protein interaction.     

The revolution of the biology of the genome

Sequence data of entire eukaryotic genomes and their detailed comparison have provided new evidence on genome evolution. The major mechanisms involved in the increase of genome sizes are polyploidization and gene duplication.Subsequent gene silencing or mutations, preferentially in regulatory sequences of genes, modify the genome and permit the development of genes with new properties. Mechanisms such as lateral gene transfer, exon shuffling or the creation of new genes by transposition contribute to the evolution of a genome, but remain of relatively restricted relevance.Mechanisms to decrease genome sizes and, in particular, to remove specific DNA sequences, such as blocks of satellite DNAs, appear to involve the action of RNA interference (RNAi). RNAi mechanisms have been proven to be involved in chromatin packaging related with gene inactivation as well as in DNA excision during the macronucleus development in ciliates.     

Chromosomal localisation of DNA sequences in condensed and dispersed human chromatin.

The DNAs purified from condensed and dispersed human chromatin were used as templates for the in vitro synthesis of ³H-labelled complementary RNAs (cRNAs). These cRNAs were hybridised in situ to preparations of fixed human metaphase chromosomes which had previously been stained with quinacrine and photographed with fluorescent (UV) light. Autoradiographs of the hybridised chromosomes were stained and photographed and the results analysed by comparison of the fluorescence photographs with the autoradiographs. This method allowed positive identification of every chromosomal site of hybridisation and quantitative analysis of grain distribution over a number of metaphase spreads. The cRNA transcribed from condensed chromatin DNA (cRNA_C) hybridised mainly to a limited number of sites close to or including centromeric heterochromatin (C-bands) and also to the brightly fluorescent regions of the Y chromosome. Many of these C-band regions are known to contain satellite DNAs, indicating that the repeated DNA in the condensed chromatin fraction consists largely, if not entirely, of satellite sequences. The cRNA transcribed from dispersed chromatin DNA (cRNA_D) does not contain satellite DNAs and hybridised more generally over the chromosome arms. However, the main sites of hybridisation with cRNA_D included the C-bands in the Y chromosome and autosomes, i.e. those regions which bound cRNA_C. This suggests that nonsatellite repeated DNA sequences may be associated with satellite DNAs in the chromosomes. No general correlation between the distribution of either kind of cRNA and the overall level of quinacrine fluorescence in chromosomes or chromosome arms was detectable, nor could the dispersed fraction be equated with cytological euchromatin, since it hybridised in many sites which appear heterochromatic. However, there was a suggestion that some non-fluorescing Q-bands bound cRNA_D preferentially. The differences which were found between the distribution of the cRNAs from the two chromatin fractions may be associated with differences in genetic activity.     

Variation in satellite DNA profiles--causes and effects

Heterochromatic regions of the eukaryotic genome harbour DNA sequences that are repeated many times in tandem, collectively known as satellite DNAs. Different satellite sequences co-exist in the genome, thus forming a set called a satellite DNA library. Within a library, satellite DNAs represent independent evolutionary units. Their evolution can be explained as a result of change in two parameters: copy number and nucleotide sequence, both of them ruled by the same mechanisms of concerted evolution. Individual change in either of these two parameters as well as their simultaneous evolution can lead to the genesis of species-specific satellite profiles. In some cases, changes in satellite DNA profiles can be correlated with chromosomal evolution and could possibly influence the evolution of species.     

植物功能着丝粒DNA研究进展

着丝粒（centromere）是真核生物染色体的重要功能结构。在细胞有丝分裂和减数分裂过程中,着丝粒通过招募动粒蛋白行使功能,保障染色体正确分离和传递。真核生物中,含有着丝粒特异组蛋白的CenH3区域被定义为功能着丝粒区,即真正意义上的着丝粒。近年来,借助染色质免疫沉淀技术,人们对功能着丝粒DNA开展了深入研究,揭示其组成、结构及演化特征,并发现功能着丝粒区存在具有转录活性的基因,且部分基因具有重要生物学功能。由于存在大量重复DNA,着丝粒演化之谜一直未能完全揭示。对植物功能着丝粒DNA序列研究进展进行了概述,并重点阐述了着丝粒重复DNA研究的新方法和新进展,以期为深入开展相关研究提供借鉴。     

Chromatin diminution in Ascaris suum: nucleotide sequence of the eliminated satellite DNA.

We have determined the prototype sequence of the DNA which is eliminated in the course of chromatin diminution in Ascaris suum. This DNA which is virtually absent from somatic cells but retained in the germ line consists predominantly of highly repetitive sequences which are variants of an AT rich 123 base pair repeat unit. Both major and minor variants have been sequenced. The overall structure of this germ line limited DNA corresponds to the segmental organization characteristic of satellite DNAs. Possible correlations between the mechanism of chromatin diminution and some properties of the satellite sequence are discussed.     

Effect of cis-located human satellite DNA on the electroporation efficiency of neo and HSV-1 tk containing plasmids.

Highly repetitive satellite DNAs comprise a significant portion of higher eukaryotic genomes and have been implicated in a variety of chromosome processes, such as centromere structure and function, that are related to their presence in heterochromatin. In addition, heterochromatin can induce metastable expression of adjacent genes. However, the role of highly repetitive satellite DNAs in these effects remains to be elucidated. In an effort to address this question, plasmids containing a human 1797-bp EcoRI satellite II DNA, plus the neo and the HSV-1 tk genes, were electroporated into a TK-/NEO- human cell line. The presence of the satellite DNA sequences within the electroporated plasmids was found to interfere with the generation of stable TK+, but not NEO+, transfectants depending on the location and/or orientation of the cloned satellite DNA.     

Longitudinal differentiation of the human Yq heterochromatin as revealed by the restriction enzyme TaqI

The restriction endonuclease TaqI cleaves DNA at TCGA sites which are very common in human satellite DNAs. However, this enzyme was not used successfully up to now to digest constitutive heterochromatin of human chromosomes, where those highly repetitive DNAs are preferentially located. In this work, we show that TaqI is able to cut and extract DNA from the major heterochromatic regions on chromosomes 1, 9, 15, and 16 which appear as unstained gaps. Yq heterochromatin displays moderate digestion along its entire length but a middle region can be distinguished which is usually more affected. Complete digestion of Yq heterochromatin can be achieved when this block has been previously undercondensed by treating cell cultures with the cytidine analog, 5-azacytidine. Thus, it may be deduced that some factors related to chromatin organization might be involved in the action of TaqI. These results come to reinforce previous data about heterogeneity of Yq heterochromatin, and allow us to subdivide it into three different regions according to their differential response to TaqI digestion.     

A tandemly repetitive centromeric DNA sequence of the fish Hoplias malabaricus (Characiformes: Erythrinidae) is derived from 5S rDNA

A substantial fraction of the eukaryotic genome consists of repetitive DNA sequences that include satellites, minisatellites, microsatellites, and transposable elements. Although extensively studied for the past three decades, the molecular forces that generate, propagate and maintain repetitive DNAs in the genomes are still discussed. To further understand the dynamics and the mechanisms of evolution of repetitive DNAs in vertebrate genome, we searched for repetitive sequences in the genome of the fish species Hoplias malabaricus. A satellite sequence, named 5SHindIII-DNA, which has a conspicuous similarity with 5S rRNA genes and spacers was identified. FISH experiments showed that the 5S rRNA bona fide gene repeats were clustered in the interstitial position of two chromosome pairs of H. malabaricus, while the satellite 5SHindIII-DNA sequences were clustered in the centromeric position in nine chromosome pairs of the species. The presence of the 5SHindIII-DNA sequences in the centromeres of several chromosomes indicates that this satellite family probably escaped from the selective pressure that maintains the structure and organization of the 5S rDNA repeats and become disperse into the genome. Although it is not feasible to explain how this sequence has been maintained in the centromeric regions, it is possible to hypothesize that it may be involved in some structural or functional role of the centromere organization.     

Phylogenetic footprinting of non-coding RNA: hammerhead ribozyme sequences in a satellite DNA family of <Emphasis Type="Italic">Dolichopoda</Emphasis>cave crickets (Orthoptera,Rhaphidophoridae)

Background  

The great variety in sequence, length, complexity, and abundance of satellite DNA has made it difficult to ascribe any function to this genome component. Recent studies have shown that satellite DNA can be transcribed and be involved in regulation of chromatin structure and gene expression. Some satellite DNAs, such as the pDo500 sequence family in Dolichopoda cave crickets, have a catalytic hammerhead (HH) ribozyme structure and activity embedded within each repeat.