Chromosomal radiosensitivity as associated with chromatin diminution in cyclops (Crustacea,Copepoda)

Chromosomal radiosensitivity inferred from the yield of chromosome aberrations (CAs) was for the first time studied in Cyclops (Crustacea, Copepoda) before and after chromatin diminution (CD). A comparison was made for C. kolensis, in which CD denudes somatic embryo cells of the greatest (94%) DNA amount known for multicellular organisms, and C. insignis, which lacks CD. The two species have similar genome sizes, 4.6 and 4.3 pg. respectively. Radiosensitivity of C. kolensis chromosomes proved to be extremely high during prediminution cleavage divisions. This was attributed to membrane damage in granules that contain enzymes (topoisomerases) normally involved in cleavage and ligation of chromosomal DNA during CD.     

Cytophotometric determination of genome size in two species of Cyclops of Lake Baikal (Crustacea: Copepoda, Cyclopoida) in ontogenetic development

The genome size of Cyclops in cells at early stages of cleavage (up to the fifth division) and in somatic cells was estimated by static digital Feulgen cytophotometry in order to study quantitative changes in DNA content during chromatin diminution. Described here cytophotometric method was approbated on five different digital-imaging systems in blood cells of four vertebrate species. In all cases, we observed a direct correlation between the data obtained with known from the literature on genome size and high reproducibility, which will allow these systems to be used in future work. We also optimized the conditions for DNA hydrolysis of both blood smears and for two species of Cyclops from the Moscow population as 30 min in 5 N HCl at 24°C. Here, we first revealed chromatin diminution in two endemic Baikal species of Cyclopoida: Acanthocyclops incolotaenia and Diacyclops galbinus. We estimated the extent of chromatin diminution in Diacyclops galbinus as 95.5–96.2%. Cytometric analysis of the third species, Mesocyclops leuckarti, did not reveal obvious chromatin diminution.     

Organization and dynamics of satellite and telomere DNAs in Ascaris: implications for formation and programmed breakdown of compound chromosomes

In the nematode genus Ascaris the germline genome contains considerable amounts of extra DNA, which is discarded from the somatic founder blastomeres during early cleavage. In Parascaris univalens the haploid germline genome is contained in one large compound chromosome, which consists of a euchromatic region containing the somatic genome flanked by large blocks of heterochromatin. Fluorescence in situ hybridization of fractions of the germline-limited satellite DNA revealed two highly repeated sequence families establishing the entire heterochromatin (HET blocks). The repeats, a pentanucleotide, TTGCA, and a decanucleotide, TTTGTGCGTG, constitute separate segments of the HET blocks. The blocks are polymorphic in length and, hence, in copy number of the repeats, and the arrangement of the segments. The numerous sequence variants of both repeats display a disperse distribution. The type and rate of base substitutions within both repeat units depend on position. Prior to the elimination process in presomatic cells, termed chromatin diminution, the chromosomes undergo differential mitotic condensation. Interstitial 'chromatin linkers' flanking the prospective numerous somatic chromosomes remain entirely decondensed. The somatic chromosomes are released from the plurivalent chromosomes via excision of the linkers at onset of anaphase, followed by exclusion of the akinetic linker chromatin and HET blocks from the daughter nuclei. In Ascaris suum, the germline-limited satellite, which consists of one 123 bp repeat, is scattered throughout the numerous chromosomes in small heterochromatic knobs of variable sizes, residing at chromosomal ends and/or intercalary positions. The programmed breakage, which appears to proceed in a similar manner to that in P. univalens, results in the loss of all heterochromatic knobs, accompanied by an increase in chromosome number. In both species, all germline chromosomes are capped by tracts of TTAGGC repeats. In P. univalens, such telomeric tracts also occur at the termini of the euchromatic intercalary regions. Upon diminution all telomeric tracts are discarded. De novo telomere addition occurs in all somatic cell lineages of both species. The presented data shed light on the evolutionary history of chromosome aggregation and satellite DNA formation, and putative mechanisms involved in the process of site-directed breakage to reestablish stable somatic chromosomes.     

Changes in nuclear morphology associated with elevated DNA levels during gametogenesis in cyclopoid copepods with chromatin diminution

Abstract. Most species of freshwater cyclopoid copepods follow a conventional course of DNA replication during gametogenesis, but certain species regularly undergo chromatin diminution during early embryogenesis, a process that is accompanied by the exclusion of large amounts of heterochromatic DNA from progenitor somatic cells and selective retention of this DNA by primordial germ cells after their segregation from the soma. We have used scanning microdensitometry and image analysis cytometry of individual Feulgen-stained nuclei to determine the DNA levels of individual somatic cell nuclei, oocytes, spermatocytes, and sperm for seven species, including Acanthocyclops brevispinosus, Acanthocyclops vernalis, Ectocyclops phaleratus, Eucyclops agilis, Eucyclops ensifer, Macrocyclops albidus , and Thermocyclops decipiens . The oocyte nuclei of these species have twice the DNA content of their diploid somatic cell nuclei. In specimens of Cyclops strenuus, Mesocyclops edax, Mesocyclops longisetus, Mesocyclops longisetus curvatus , and Metacyclops mendocinus , marked increases in DNA levels were noted in both female and male germ cells before meiosis. The appearance of enlarged nuclei with densely stained chromocenters is a distinguishing feature of oocytes and spermatocytes of cyclopoid species that exhibit excessive accumulations of DNA during gametogenesis and subsequently undergo chromatin diminution. The net increase in DNA content of the prediminution nuclei is 6–10 times the DNA level of their somatic cell nuclei and is largely attributable to increases in the amount of DNA associated with their heterochromatic chromocenters. The identification of a morphologically distinctive type of germ cell and its dramatic accumulation of large amounts of DNA before meiosis are discussed in terms of the selective elimination of heterochromatin during early cleavage stages in these cyclopoid species.     

Chromosomal Radiosensitivity as Associated with Chromatin Diminution in Cyclops (Crustacea, Copepoda)

Chromosomal radiosensitivity inferred from the yield of chromosome aberrations (CAs) was for the first time studied in Cyclops (Crustacea, Copepoda) before and after chromatin diminution (CD). A comparison was made for C. kolensis, in which CD denudes somatic embryo cells of the greatest (94%) DNA amount known for multicellular organisms, and C. insignis, which lacks CD. The two species have similar genome sizes, 4.6 and 4.3 pg, respectively. Radiosensitivity of C. kolensis chromosomes proved to be extremely high during prediminution cleavage divisions. This was attributed to membrane damage in granules that contain enzymes (topoisomerases) normally involved in cleavage and ligation of chromosomal DNA during CD.     

Cell cycle regulation of the licensing activity of Cdt1 in Xenopus laevis

Cdt1 is a conserved replication factor required in licensing the chromosome for a single round of DNA synthesis. The activity of Cdt1 is inhibited by geminin. The mechanism by which geminin interferes with Cdt1 activity is unknown. It is thought that geminin binds to and sequestrate Cdt1. We show that geminin does not interfere with the chromatin association of Cdt1 and that inhibition of DNA synthesis by geminin is observed following its accumulation on chromatin. The binding of geminin to chromatin has been investigated during S phase. We demonstrate that loading of geminin onto chromatin requires Cdt1, suggesting that geminin is targeted at replication origins. We also show that geminin binds chromatin at the transition from the pre-replication to pre-initiation complexes, which overlaps with the release of Cdt1. This regulation is strikingly different from that observed in somatic cells where the chromatin binding of these proteins is mutually exclusive. In contrast to somatic cells, we further show that geminin is stable during the early embryonic cell cycles. These results suggest a specific regulation of origin firing adapted to the rapid cell cycles of Xenopus and indicate that periodic degradation of geminin is not relevant to licensing during embryonic development.     

Chromatin diminution in the copepod Mesocyclops edax: diminution of tandemly repeated DNA families from somatic cells.

Chromatin diminution, i.e., the loss of selected chromosomal regions during the differentiation of early embryonic cells into somatic cells, has been described in taxa as varied as ciliates, copepods, insects, nematodes, and hagfish. The nature of the eliminated DNA has been extensively studied in ciliate, nematode, and hagfish species. However, the small size of copepods, which makes it difficult to obtain enough DNA from early embryonic cells for cloning and sequencing, has limited such studies. Here, to identify the sequences eliminated from the somatic cells of a copepod species that undergoes chromatin diminution, we randomly amplified DNA fragments from germ line and somatic line cells of Mesocyclops edax, a freshwater cyclopoid copepod. Of 47 randomly amplified germ line clones, 45 (96%) contained short, tandemly repeated sequences composed of either 2 bp CA-repeats, 8 bp CAAATAGA-repeats, or 9 bp CAAATTAAA-repeats. In contrast, of 83 randomly amplified somatic line clones, only 47 (57%) contained such short, tandemly repeated sequences. As previously observed in some nematode species, our results therefore show that there is partial elimination of chromosomal regions containing (CAAATAGA and CAAATTAAA) repeated sequences during the chromatin diminution observed in the somatic cells of M. edax. We speculate that chromatin diminution might have evolved repeatedly by recruitment of RNAi-related mechanisms to eliminate nonfunctional tandemly repeated DNA sequences from the somatic genome of some species.     

Evidence for endoreduplication: germ cell DNA levels prior to chromatin diminution in Mesocyclops edax.

We studied the functional significance of marked differences in the DNA content of somatic cells and germ line nuclei by static Feulgen-DNA cytophotometry for several species of microcrustaceans that exhibit chromatin diminution during very early stages of embryogenesis. Mature females and males showed many gonadal nuclei with elevated amounts of DNA that persist until dispersal of this "extra" DNA throughout the cytoplasm as fragments and coalescing droplets of chromatin during anaphase of the diminution division.     

p48 Activates a UV-Damaged-DNA Binding Factor and Is Defective in Xeroderma Pigmentosum Group E Cells That Lack Binding Activity

A subset of xeroderma pigmentosum (XP) group E cells lack a factor that binds to DNA damaged by UV radiation. This factor can be purified to homogeneity as p125, a 125-kDa polypeptide. However, when cDNA encoding p125 is translated in vitro, only a small fraction binds to UV-damaged DNA, suggesting that a second factor is required for the activation of p125. We discovered that most hamster cell lines expressed inactive p125, which was activated in somatic cell hybrids containing human chromosome region 11p11.2-11cen. This region excluded p125 but included p48, which encodes a 48-kDa polypeptide known to copurify with p125 under some conditions. Expression of human p48 activated p125 binding in hamster cells and increased p125 binding in human cells. No such effects were observed from expression of p48 containing single amino acid substitutions from XP group E cells that lacked binding activity, demonstrating that the p48 gene is defective in those cells. Activation of p125 occurred by a “hit-and-run” mechanism, since the presence of p48 was not required for subsequent binding. Nevertheless, p48 was capable of forming a complex with p125 either bound to UV-damaged DNA or in free solution. It is notable that hamster cells fail to efficiently repair cyclobutane pyrimidine dimers in nontranscribed DNA and fail to express p48, which contains a WD motif with homology to proteins that reorganize chromatin. We propose that p48 plays a role in repairing lesions that would otherwise remain inaccessible in nontranscribed chromatin.     

UV irradiation of pig metaphase chromosomes: maturation-promoting factor degradation, nuclear cytology and cell cycle progression

Experiments were designed to test two hypotheses. The first was that irradiation of pig metaphase chromosomes would block the normal sequence of cytological and molecular events associated with activation; the second postulated that damaged DNA would prevent eggs from progressing through the first mitotic cleavage cycle. The experimental protocol involved selectively irradiating the metaphase II plate of pig oocytes with highly focused 254 nm ultraviolet (UV) light, followed by activation using standard electroactivation procedures. The following assessments were made of different groups of eggs: (i) nuclear membrane reassembly; (ii) chromosomal cytology; (iii) changes in maturation-promoting factor kinase (MPF kinase) activity at 1 h intervals after activation; and (iv) mitotic progression of eggs containing damaged chromosomal fragments. UV irradiation neither prevented the reassembly of nuclear membranes required for pronuclear formation nor interfered with the normal pattern of MPF kinase degradation after egg activation. UV irradiation did induce a wide range of chromatin defects, including condensation and dispersal of DNA fragments which, in turn, resulted in the formation of micronuclei in the treated eggs and embryos. The presence of damaged DNA retarded, but did not inhibit, progression through the first mitotic cycle. No evidence was obtained that the subsequent mitotic cycle was adversely affected by the presence of UV-damaged DNA. Overall, these results indicate that early cleavage divisions in pig eggs are not blocked by the presence of damaged, hypercondensed chromatin. In this respect, pig eggs are similar to Xenopus eggs, but are different from bovine eggs. On the basis of these findings it is suggested that focused UV irradiation offers a simple and rapid technique for the non-invasive enucleation of pig oocytes provided that the residual hypercondensed chromatin does not affect later developmental stages.     

<Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis> Cmr1 protein preferentially binds to UV-damaged DNA <Emphasis Type="Italic">in vitro</Emphasis>

DNA metabolic processes such as DNA replication, recombination, and repair are fundamentally important for the maintenance of genome integrity and cell viability. Although a large number of proteins involved in these pathways have been extensively studied, many proteins still remain to be identified. In this study, we isolated DNA-binding proteins from Saccharomyces cerevisiae using DNA-cellulose columns. By analyzing the proteins using mass spectrometry, an uncharacterized protein, Cmr1/YDL156W, was identified. Cmr1 showed sequence homology to human Damaged-DNA binding protein 2 in its C-terminal WD40 repeats. Consistent with this finding, the purified recombinant Cmr1 protein was found to be intrinsically associated with DNA-binding activity and exhibited higher affinity to UV-damaged DNA substrates. Chromatin isolation experiments revealed that Cmr1 localized in both the chromatin and supernatant fractions, and the level of Cmr1 in the chromatin fraction increased when yeast cells were irradiated with UV. These results suggest that Cmr1 may be involved in DNA-damage responses in yeast.     

Chromatin diminution and early cleavage in Parascaris univalens (Nematoda)

Summary In Parascaris developmental commitment to the germ line and somatic lineages is indicated by the orientation of the mitotic spindle in blastomeres, the topology of cells in the embryo, and chromatin diminution in presomatic blastomeres. Using three different experimental techniques: transient pressure treatment, application of cytochalasin B, and isolation of blastomeres, we have succeeded in uncoupling several developmental processes during cleavage of P. univalens. The following results were obtained: (1) Following mitotic nondisjunction we observed identical behavior of all chromatids in each blastomere. Thus chromosome differentiation by differential replication does not occur. (2) Chromosome fragments obtained by pressure treatment of egg cells underwent chromatin diminution. Thus this process does not require an intact germ-line chromosome. However, chromosomes immobilized on a monopolar spindle did not undergo chromatin diminution. Thus diminution appears to require segregation of chromatids. (3) Blastomeres that completely lacked chromosomes as a result of mitotic nondisjunction underwent normal early cleavage divisions. (4) Pressure treatment or prolonged treatment with cytochalasin B caused egg cells or germ line blastomeres to lose their germ line quality, as deduced from the coincident occurrence of symmetrical (presomatic-like) cleavage and chromatin diminution. (5) Isolated blastomeres from 2-cell embryos, i.e. 1/2 blastomeres, usually cleaved according to their prospective fates in the whole embryo. However, in some partial embryos derived from such blastomeres, chromatin diminution was delayed for either one or two cleavage mitoses. An activation model as an alternative to a prelocalization model is presented, which can account for early blastomere topogenesis and chromatin diminution.     

Chromosome diminution in Ascaris suum. Two-fold increase of nucleosomal histone to DNA ratios during development

The swine intestinal nematode, Ascaris suum, eliminates chromatin material from its primordial somatic cells during early embryogenesis. A technique for isolation of nuclei from pre- and post-diminution stage embryos has been developed and these isolated nuclei were used in investigations of nuclear events during diminution. The amount of DNA per nucleus determined by diphenylamine assays and isotope dilutions was 0.66 pg and 0.29 pg in pre- and post-diminution nuclei, respectively. Thus, A. suum loses 56% of its nuclear DNA during diminution. The loss of nuclear DNA enabled in vivo examination of histone to DNA ratios as a function of changes in DNA quantities. Ascaris histones were identified by acid extractability and tryptic fingerprint comparison with rat liver histones. Measurement of histone quantities was accomplished using linearity of Coomassie blue binding to histones separated in dodecyl sulfate gels. Ascaris nucleosomal histones levels were relatively constant in pre- and post-diminution nuclei. However, nucleosomal histone to DNA ratios approximately doubled during diminution.     

Cell cycle-dependent regulation of the association between origin recognition proteins and somatic cell chromatin

Previous studies have suggested that cell cycle-dependent changes in the affinity of the origin recognition complex (ORC) for chromatin are involved in regulating initiation of DNA replication. To test this hypothesis, chromatin lacking functional ORCs was isolated from metaphase hamster cells and incubated in Xenopus egg extracts to initiate DNA replication. Intriguingly, Xenopus ORC rapidly bound to hamster somatic chromatin in a Cdc6-dependent manner and was then released, concomitant with initiation of DNA replication. Once pre-replication complexes (pre-RCs) were assembled either in vitro or in vivo, further binding of XlORC was inhibited. Neither binding nor release of XlORC was affected by inhibitors of either cyclin-dependent protein kinase activity or DNA synthesis. In contrast, inhibition of pre-RC assembly, either by addition of Xenopus geminin or by depletion of XlMcm proteins, augmented ORC binding by inhibiting ORC release. These results demonstrate a programmed release of XlORC from somatic cell chromatin as it enters S phase, consistent with the proposed role for ORC in preventing re-initiation of DNA replication during S phase.     

Some conclusions on the role of redundant DNA and the mechanisms of eukaryotic genome evolution inferred from studies of chromatin diminution in Cyclopoida

The absence of progress in understanding the problem of redundant eukaryotic DNA is stated. This is caused primarily by the attempts to solve this problem either in terms of the traditional approaches (the general phenotypic parameters such as developmental rate, body size, etc. depend on the genome size) or by introducing such vague terms as egoistic, parasitic, or junk DNA. Studying chromatin diminution (CD) in copepods yielded two important conclusions. First, part of the genome of a certain size (94% in Cyclops kolensis first described by the authors) is not needed for somatic functions as it is eliminated during the early (third to seventh) cleavage divisions from the presumptive somatic cells. Second, this DNA is not redundant, let alone selfish or junk, relative to the germline cells. In this sense, it can be regarded as invariant (monomorphic) trait that characterizes the species. Analysis of cloned and sequenced DNA regions eliminated from the somatic cell genome by CD (i.e., confined to the germline), which was first carried out for C. kolensis, showed that the molecular structure of this DNA has at least two features of regular organization: a mosaic structure of repetitive sequences and high (sometimes up to 100%) homology between different repeats and subrepeats. We have suggested that the germline-restricted DNA forms a unique molecular portrait of the species genome, thus acting as a significant factor of genetic isolation. Yet, the phenomenon of CD proper as it occurs in Cyclopoida without disintegration of the chromosome structure) may be regarded as a model of reductional genome evolution, which has repeatedly occurred in the history of eukaryotes.     

Chromatin diminution is a key process explaining the eukaryotic genome size paradox and some mechanisms of genetic isolation

The functions of redundant (junk, selfish, parasitic, etc.) DNA in eukaryotes can be reliably inferred from chromatin diminution (programmed elimination of up to 94% of the genome from somatic germ cells in Ascaris and Cyclops). These functions should be sought in germ cells, where this DNA is preserved during the entire life time of the species. A possible biological role of redundant DNA as a factor disrupting meiotic chromosome synapsis is suggested. At the same time, chromatin diminution itself can act as a mechanism of postzygotic isolation. All stage of the complex diminution mechanism could not be fixed in the genetic program of the species via gradual accumulation of mutations. The "program" of diminution must have appeared at once and in the completed form.     

Investigation of the mechanism of meiotic DNA cleavage by VMA1-derived endonuclease uncovers a meiotic alteration in chromatin structure around the target site

VMA1-derived endonuclease (VDE), a homing endonuclease in Saccharomyces cerevisiae, is encoded by the mobile intein-coding sequence within the nuclear VMA1 gene. VDE recognizes and cleaves DNA at the 31-bp VDE recognition sequence (VRS) in the VMA1 gene lacking the intein-coding sequence during meiosis to insert a copy of the intein-coding sequence at the cleaved site. The mechanism underlying the meiosis specificity of VMA1 intein-coding sequence homing remains unclear. We studied various factors that might influence the cleavage activity in vivo and found that VDE binding to the VRS can be detected only when DNA cleavage by VDE takes place, implying that meiosis-specific DNA cleavage is regulated by the accessibility of VDE to its target site. As a possible candidate for the determinant of this accessibility, we analyzed chromatin structure around the VRS and revealed that local chromatin structure near the VRS is altered during meiosis. Although the meiotic chromatin alteration exhibits correlations with DNA binding and cleavage by VDE at the VMA1 locus, such a chromatin alteration is not necessarily observed when the VRS is embedded in ectopic gene loci. This suggests that nucleosome positioning or occupancy around the VRS by itself is not the sole mechanism for the regulation of meiosis-specific DNA cleavage by VDE and that other mechanisms are involved in the regulation.