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.     

Chromatin diminution in nematode development

Chromatin diminution in Parascaris and Ascaris represents the classical case of a developmentally programmed genome rearrangement. The process is very specific with respect to ontogenetic timing and chromosomal localization, and involves chromosomal breakage, new telomere formation and DNA degradation. Recent evidence from Ascaris lumbricoides var. suum suggests that chromatin diminution might have a function in gene regulation.     

New telomere formation during the process of chromatin diminution in Ascaris suum

Chromatin diminution in the parasitic nematode Ascaris suum represents an interesting case of developmentally programmed DNA rearrangement in higher eukaryotes. At the molecular level, it is a rather complex event including chromosome breakage, new telomere formation and DNA degradation. Analysis of a cloned somatic telomere (pTel1) revealed that it has been newly created during the process of chromatin diminution by the addition of telomeric repeats (TTAGGC)n to a chromosomal breakage site (Müller et al., 1991). However, telomere addition does not occur at a single chromosomal locus, but at many different sites within a short chromosomal region, termed CBR1 (chromosomal breakage region 1). Here we present the cloning and the analysis of 83 different PCR amplified telomere addition sites from the region of CBR1. The lack of any obvious sequence homology shared among them argues for a telomerase-mediated healing process, rather than for a recombinational event. This hypothesis is strongly supported by the existence of 1-6 nucleotides corresponding to and being in frame with the newly added telomeric repeats at almost all of the telomere addition sites. Furthermore, we show that telomeres are not only added to the ends of the retained chromosomal portions, but also to the eliminated part of the chromosomes, which later on become degraded in the cytoplasm. This result suggests that de novo telomere formation during the process of chromatin diminution represents a non-specific process which can heal any broken DNA end.     

Developmentally regulated telomerase activity is correlated with chromosomal healing during chromatin diminution in Ascaris suum

Telomerase is the ribonucleoprotein complex responsible for the maintenance of the physical ends, or telomeres, of most eukaryotic chromosomes. In this study, telomerase activity has been identified in cell extracts from the nematode Ascaris suum. This parasitic nematode is particularly suited as a model system for the study of telomerase, because it shows the phenomenon of chromatin diminution, consisting of developmentally programmed chromosomal breakage, DNA elimination, and new telomere formation. In vitro, the A. suum telomerase is capable of efficiently recognizing and elongating nontelomeric primers with nematode-specific telomere repeats by using limited homology at the 3' end of the DNA to anneal with the putative telomerase RNA template. The activity of this enzyme is developmentally regulated, and it correlates temporally with the phenomenon of chromatin diminution. It is up-regulated during the first two rounds of embryonic cell divisions, to reach a peak in 4-cell-stage embryos, when three presomatic blastomeres prepare for chromatin diminution. The activity remains high until the beginning of gastrulation, when the last of the presomatic cells undergoes chromatin diminution, and then constantly decreases during further development. In summary, our data strongly argue for a role of this enzyme in chromosome healing during the process of chromatin diminution.     

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.     

A novel UV-damaged DNA binding protein emerges during the chromatin-eliminating cleavage period in Ascaris suum.

During the early cleavage period of Ascaris suum , chromatin diminution takes place in the somatic founder cells. In the process of chromatin diminution numerous heterochromatic blocks, consisting predominantly of highly repeated DNA, are discarded during mitotic anaphase and are later on digested in the cytoplasm. Very little is known about proteins that are involved in chromatin diminution. We have detected a nuclear protein and purified it to near homogeneity by its preferential binding to UV-damaged DNA. We termed this protein chromatin diminution associated factor 1 (CDAF1), because maximum binding activity per nucleus was observed to develop in 4-8-cell stages, when chromatin diminution occurs for the first time. CDAF1 recognizes cyclobutane pyrimidine dimers in UV-damaged double-stranded DNA. Its binding properties identify CDAF1 as a novel kind of damaged-DNA binding protein. CDAF1 activity is almost not detectable in 1-celled embryos. It increases dramatically during formation of somatic founder cells and persists up to the first larval stage. However, CDAF1 is absent in tissues of adults. These findings led us to suggest that CDAF1 plays a dual role: during the early segregative cleavage period it might be involved in chromatin diminution as a transfactor and act in nucleotide excision repair as an accessory factor throughout embryogenesis.     

Neither a germ line-specific nor several somatically expressed genes are lost or rearranged during embryonic chromatin diminution in the nematode Ascaris lumbricoides var. suum

Ascaris lumbricoides var. suum is a parasitic nematode of pigs. Its embryos undergo chromatin diminution between the third and fifth cleavages, resulting in the loss of about 30% of the DNA from all somatic precursor cells while the germ line DNA stays intact. Most of the eliminated DNA has been shown to be satellite sequences. Theodor Boveri [(1910) In "Festschrift fur R. Hertwig, III," Vol. 3, pp. 131-214, Fischer] proposed that functions essential only to the germ line might be lost from the soma. We have examined this proposal by cloning a gene encoding the major sperm protein (MSP) using a cloned MSP gene from Caenorhabditis elegans as a probe. The MSP appears to be expressed only in the testis of Ascaris, as it is in Caenorhabditis. Actin and alpha tubulin were also cloned to serve as somatically expressed gene controls. By probing Southern blots of somatic and germ line DNA with these cloned genes, it was found that none of them was lost or rearranged during chromatin diminution. Thus at least one germ line-specific gene is neither lost nor rearranged during chromatin diminution. We also found that the two nematode species differ widely in their numbers of both MSP and actin genes. Caenorhabditis has greater than 30 MSP genes, but Ascaris has no more than three; whereas Ascaris has many more actin genes than Caenorhabditis.     

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.     

Chromatin diminution in nematodes

The process of chromatin diminution in Parascaris and Ascaris is a developmentally controlled genome rearrangement, which results in quantitative and qualitative differences in DNA content between germ line and somatic cells. Chromatin diminution involves chromosomal breakage, new telomere formation and DNA degradation. The programmed elimination of chromatin in presomatic cells might serve as an alternative way of gene regulation. We put forward a new hypothesis of how an ancient partial genome duplication and chromatin diminution may have served to maintain the genetic balance in somatic cells and simultaneously endowed the germ line cells with a selective advantage.     

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.     

New telomere formation after developmentally regulated chromosomal breakage during the process of chromatin diminution in Ascaris lumbricoides

During the process of chromatin diminution, which takes place in all presomatic cells of the early Ascaris embryo, the heterochromatic termini of the chromosomes are lost. Here we show that the newly formed ends of the reduced somatic chromosomes carry tandem repeats of the telomeric sequence TTAGGC. Comparison of a cloned somatic telomere with the corresponding germline chromosomal region revealed that these telomeric repeats are not present at or near the chromosomal breakage site. They are most likely added by a telomerase-mediated event. Chromosomal breakage, which precedes the telomere addition process, takes place within a short, specific chromosomal region (CBR); however, it does not occur at a single locus, but rather at many different sites. Altogether, our data show that chromatin diminution in Ascaris is a complex molecular process that includes site-specific chromosomal breakage, new telomere formation, and DNA degradation.     

The development of a large nucleolus during oogenesis in Acanthocyclops vernalis (Crustacea, Copepoda) and its possible relationship to chromatin diminution

The development of a single, very large (25-35 microns diameter) nucleolus during oogenesis in the crustacean Acanthocyclops vernalis is described. The nucleolus is the site of ribosomal RNA production in the egg, as shown by in situ hybridization, and apparently the only source, as accessory cells are not observed. Ribosomal DNA amplification, as manifested by the presence of multiple nucleoli, is also not observed. Silver staining and C-banding suggest that chromosomal regions other than the nucleolar organizer are involved with the elaboration of the nucleolus. These observations, along with what is known about the nature of the DNA lost during the developmental process of chromatin diminution in this organism, suggest a relationship between the large oocyte nucleolus and the DNA lost during diminution.     

Structure and genomic organization of proretrovirus-like elements partially eliminated from the somatic genome of Ascaris lumbricoides.

A clone containing a middle repetitive element next to satellite DNA has been isolated from a germ line genomic library of the chromatin eliminating nematode Ascaris lumbricoides var. suum. The structure of this element has been elucidated by comparison of several clones containing the element in different environments. It is flanked by 256-bp-long terminal repeats (LTRs) and has an internal region of approximately 7 kb. The nucleotide sequences of both the 5' and the 3' LTRs have been determined. The element has a strong structural similarity with retroviral proviruses and related mobile elements. It was therefore named 'Tas', for transposon-like element of Ascaris. Approximately 50 Tas copies are dispersed over approximately 20 different chromosomal sites. Their genomic distribution varies between individuals, indicating that Tas elements are mobile in the Ascaris genome. Two variant forms, Tas-1 and Tas-2, present in a ratio of approximately 2 to 1 in the germ line genome, have been characterized. They differ not only in their restriction pattern, but also in their elimination behaviour. While only about one-fourth of the Tas-1 elements are expelled from the somatic cell lineage, all Tas-2 copies are specifically eliminated and are thus confined to the germ line cells. We have demonstrated that a cloned representative of Tas-1 elements is expelled concomitantly with its flanking DNA sequences during the chromatin elimination process.     

Chromatin diminution at the border of the XX and XXI centuries

The size of genomes in eukaryotic organisms is one of the greatest mysteries of biology. As known from the middle of the XX century, the level of organization of a particular organism, does not depend on its genome size, i. e. on DNA amount in the nucleus. We believe that an actual function of non-coding DNA stands behind the phenomenon of chromatin diminution, known already for 100 years. Diminution of chromatin normally takes place in cells involved in body building and never occurs in developmental precursors of germ cells. Apparently, the former are cells, in which non-coding DNA is functionally significant. We cloned a fraction of DNA eliminated during chromatin diminution of Cyclops kolensis (Cyclopoida, Crustascea) and sequenced 90 clones totally making 32 kb. Taken together, the provided evidence has demonstrated a high organization ordering of DNA sequences restricted to the germ line. Chromatin diminution never takes place in human cells and in cells of the majority of animals. These cells may isolate non-coding DNA in other ways, making it unreactable for most enzymes and thus functionally cut off. Thus, a certain part of genome with a particular size and structure may serve for genetic isolation of species as shellfish or junk DNA are vital components rather than pieces of garbage.     

Molecular characterization of Ascaris suum DNA and of chromatin diminution

A technique for the extraction of pure somatic (post-diminution) and germ line (pre-diminution) DNA from the parasitic nematode Ascaris is described. Uncontaminated post- and pre-diminution DNAs were sheared and reassociated to different C₀t values. Computer analysis of the complete reassociation kinetics determined that 33% of the germ line genome is eliminated during the process of chromatin diminution. The eliminated DNA is comprised of repetitive and unique sequences in an approx. 1:1 ratio.     

Chromatin diminution in early embryogenesis of Ascaris lumbricoides L. var. suum

The occurrence of chromatin diminution in early Ascaris lumbricoides L. embryos has been studied in detail, and it is shown that it is possible to preselect three characteristic types of mitoses: pre-diminution, diminution, and post-diminution mitosis. The first three embryonic mitotic divisions are of the pre-diminution type. Chromatin diminution occurs after the third mitosis, but there is a variation from embryo to embryo as to whether or not chromosomal diminution occurs during the fourth, fifth, and six divisions. However, the seventh embryonic division, which gives rise to an eight-cell embryo, always exhibits chromatin diminution. Subsequent mitoses of somatic cells already in the diminished state are of the post-diminution type of mitosis.     

The diminution of heterochromatic chromosomal segments in Cyclops (Crustacea,Copepoda)

The chromosomes of Cyclops divulsus, C. furcifer, and C. strenuus, like those of several other Copepods, undergo a striking diminution of chromatin early in embryogenesis. The process is restricted to the presumptive soma cells and occurs at the 5th cleavage in C. divulsus, at the 6th and 7th in C. furcifer, and at the 4th in C. strenuus. The eliminated chromatin derives from the excision of heterochromatic chromosome segments (H-segments). Their chromosomal location is different in the three investigated species: Whereas in C. divulsus and C. furcifer the H-segments form large blocks — exclusively terminal in the former and terminal as well as kinetochoric in the latter — the germ line heterochromatin in C. strenuus is scattered all along the chromosomes. Extensive polymorphism exists with respect to the length of the terminal H-segments in C. furcifer, and with respect to the overall content of heterochromatin in the chromosomes of C. strenuus. In a local race of C. strenuus an extreme form of dimorphism has been found which is sex limited: females as a rule are heterozygous for an entire set of large (heterochromatin-rich), and a second set of small chromosomes in their germ line. Males are homozygous for the large set. In the first three cleavage divisions the H-polymorphism is solely expressed through differences of chromosome length. Following diminution the differences between homologous have disappeared. Feulgen cytophotometry demonstrates that in the three species the 1C DNA value for the germ line, as measured in sperm, is about twice that measured in somatic mitoses (germ line/soma C-values in picograms of DNA: C. strenuus 2.2/0.9, C. furcifer 2.9/1.44, C. divulsus 3.1/1.8). — The data imply that chromatin diminution is based on a mechanism which allows specific DNA segments, regardless of their location and size, to be cut out from the chromosomes without affecting the structural continuity of the remaining DNA. This mechanism may be analogous to that of prokaryotic DNA excision.     

The effects of chromatin diminution on the pattern of C-banding in the chromosomes of Acanthocyclops vernalis Fischer (Copepoda: Crustacea)

Chromatin diminution is the loss of selected regions of pre-somatic cell chromosomes during early development, resulting in the removal of a large amount of the genomic DNA from the pre-somatic cells. In copepods, diminution is characterized by the formation of heterochromatically staining regions, or H-segments, which contain the chromatin to be lost. The removal of H-segments during diminution also must represent a major restructuring of the chromosomes which contained them. In order to examine the effects of diminution on the morphology and structure of the chromosomes, the C-banding technique was used. This procedure revealed that most C-bands present in the pre-diminution complement were absent in the post-diminution set. Additionally, in order to explore further the possible composition of the DNA contained in H-segments, a comparison, based on the relationship of C-bands to highly-repetitive DNA in chromosomes, was made between pre-diminution C-bands and H-segments. This comparison showed that not all H-segments are at chromosomal locations which produce a C-band, indicating that H-segments are perhaps not entirely composed of genetically inert DNA, as is currently supposed.     

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.