Souichirou Kubota

Chromosomal Location and Nucleotide Sequences of 5S Ribosomal DNA of Two Cyprinid Species (Osteichthyes, Pisces)

Abstract5S ribosomal DNAs (rDNAs) from two cyprinid species, Acheilognathus tabira subsp. 1 and Cyprinus carpio, were isolated and sequenced. Tandemly arranged rDNAs were 179 bp in A. tabira and 204 bp in C. carpio. The non-transcribed spacer region elucidates the size difference of 5S rDNA between the two species. Fluorescence in-situ hybridization (FISH) localized 5S rDNAs to the short arms of two pairs of chromosomes in A. tabira and two to four pairs in C. carpio. Subsequent analysis demonstrated NORs in one pair of chromosomes in both species. Both the NOR and 5S rDNA are carried by a chromosome pair in A. tabira, but they are located on different chromosomes separately in C. carpio. Karyotype evolution by tetraploidy seems complex in cyprinid species.

Germ line-restricted, highly repeated DNA sequences and their chromosomal localization in a Japanese hagfish (Eptatretus okinoseanus)

The various species of Japanese hagfish, namely, Eptatretus okinoseanus (types A and B), Eptatretus burgeri and Myxine garmani, are known to eliminate a fraction of their chromosomes during early embryogenesis. High molecular weight DNA from germ line cells and somatic cells of these hagfish species was isolated and digested with different restriction enzymes. The DNA fragments were separated by agarose gel electrophoresis. Digestion with BamHI and DraI generated two weak bands and one weak band, respectively, that were estimated to be about 90, and 180 bp and about 90 bp long and were limited to the germ line DNA in both types of E. okinoseanus. DNA filter hybridization experiments showed that the two BamHI fragments and the one DraI fragment were present almost exclusively in the germ line DNA of E. okinoseanus. Thus, these DNA fragments appear to be eliminated during embryogenesis. Moreover, evidence was obtained that these fragments are highly and tandemly repeated. Molecular cloning and sequence analysis revealed that the BamHI fragments are mainly composed of a family of closely related sequences that are 95 bp long (EEEo1, for Eliminated Element of E. okinoseanus 1), and the DraI fragment is composed of another family of closely related sequences that are 85 bp long (EEEo2). The two DNA families account for about 19% of the total eliminated DNA in E. okinoseanus type A. Fluorescence in situ hybridization experiments demonstrated that the two families of DNA are located on several C-band-positive, small chromosomes that are limited to germ cells in both types of E. okinoseanus.

Molecular organization of 5S rDNA in bitterlings (Cyprinidae)

Molecular organization and nucleotide sequences of the 5S rRNA gene and NTS were investigated in freshwater fish, bitterlings (Acheilognathinae), including 10 species/subspecies of four genera, Acheilognathus, Pseudoperilampus, Rhodeus, and Tanakia, to understand the evolutionary trait of 5S rDNA arrays. Southern hybridization analysis revealed a general trend with tandem repeats of 5S rDNA in all the examined bitterlings. Sequence analysis demonstrated a conserved 120 bp sequence of the 5S rRNA gene and a short NTS of 56–67 bp with two distinct portions, a conserved (5′-flanking portion; at positions −1 to −38) and a variable part (3′-flanking portion), in 6 of 10 species/subspecies examined. The conserved NTS region was most likely an external promoter so far observed in various vertebrates, whereas the variable NTS region could be divided into two types due to its nucleotide polymorphisms. Molecular phylogeny using the 5S rRNA gene and NTS sequences suggested the occurrence of 5S rDNA duplication before speciation and a concerted evolution for the gene and conserved NTS regions, but a birth-and-death process to maintain the variable NTS region. Thus, the 5S rDNA in the examined bitterlings might have evolved under a mixed process of evolution.

Chromatin diminution and chromosome elimination in four Japanese hagfish species.

Cytogenetic examination of four Japanese hagfish species belonging to the order Myxinida (Eptatretus okinoseanus, E. burgeri. Paramyxine atami, and Myxine garmani) revealed differences in chromosome number between germ cells (spermatocytes and spermatogonia) and somatic cells (liver, blood, gill, and kidney). The differences in chromosome number between spermatogonia (54, 52, 48, and 16) and somatic cells (34, 36, 34, and 14) were 20, 16, 14, and 2 in E. okinoseanus, E. burgeri, P. atami, and M. garmani, respectively. The amount of DNA in a somatic cell (2C) relative to that in a germ cell (2C) averaged 54.6% (E. okinoseanus type A), 44.9% (E. okinoseanus type B), 79.1% (E. burgeri), 60.0% (P. atami), and 70.2% (M. garmani). These results clearly indicate that chromosome elimination takes place during early cleavage in the four hagfish species of Myxinida living in Japanese waters, except in the ancestral germline cells. C-banding of metaphase chromosome preparations of germline and somatic cells from each hagfish species revealed that the C-band-positive chromatin in the ancestral somatic cells had been almost completely eliminated. Three patterns of elimination of this chromatin are discussed.

Chromosome elimination in three Baltic, south Pacific and north-east Pacific hagfish species

We have confirmed that chromosome elimination occurs in the cells ofMyxine glutinosa, collected from the Baltic Sea off Sweden,Eptatretus cirrhatus from the south Pacific Ocean off the east coast of New Zealand, andE. stoutii from the north-east Pacific Ocean off Canada, similar to cells of four Japanese hagfish species. InM. Glutinosa, E. cirrhatus type A,E. cirrhatus type B andE. stoutii, the differences in chromosome number between spermatogonia (44, 72, 80 and 48) and somatic cells (28, 34, 34 and 34) were 16, 38, 46 and 14 respectively. The amount of DNA eliminated from presumptive somatic cells averaged 43.5%, 48.7%, 54.6% and 52.8% respectively. Euchromatic chromosomes and/or parts of chromosomes in addition to heterochromatic chromosomes were clearly eliminated inE. cirrhatus andE. stoutii. Adding our previous observations of four Japanese hagfish species, chromosome elimination occurs in all seven of the hagfish species. These results suggest that this phenomenon, chromosome elimination, generally occurs in the order Myxinida. In addition, B-chromosomes were observed in the germ cells ofE. cirrhatus andE. stoutii, similar to the cells ofE. okinoseanus, E. burgeri andParamyxine atami (E. atami). This fact suggests that B-chromosomes might exist generally in the family Eptatretidae.

A germline restricted, highly repetitive DNA sequence in Paramyxineatami: an interspecifically conserved, but somatically eliminated, element

Abstract In some species of hagfish, the phenomenon of chromosome elimination occurs during embryogenesis. However, only two repetitive DNA families are known to be represented in chromosomes that are eliminated from somatic cells of the Japanese hagfish Eptatretus okinoseanus. Using molecular analyses, another germ line-restricted, highly repetitive DNA family has been detected in another Japanese hagfish, Paramyxine atami. The repeat unit of this family, which is 83 bp long, has been designated “EEPa1”, for Eliminated Element of P. atami 1. DNA filter hybridization using EEPa1 as a probe revealed that this family is shared among several species and is conserved in the germline DNA. Although eliminated, repetitive DNA that is shared interspecifically has not been reported in hagfish species, cases of chromatin diminution and chromosome elimination processes have been described previously in other organisms.The patterns and intensities of hybridization signals suggest that members of the repetitive DNA family defined by EEPa1 have undergone concerted molecular evolution.

Highly repetitive DNA families restricted to germ cells in a Japanese hagfish (Eptatretus burgeri): a hierarchical and mosaic structure in eliminated chromosomes

It is known that in eight hagfishes chromosome elimination occurs during early embryogenesis. The eliminated chromosomes are mostly C-band positive, so that none of the somatic cells have any C-band-positive chromatin. Recently, some highly repetitive DNA sequences have been reported as eliminated elements in these hagfishes based on molecular biological methods. However, no germline-restricted repetitive DNA have been directly isolated from the Japanese hagfish Eptatretus burgeri, from which approximately 21% of the total DNA is eliminated from presumptive somatic cells. Through electrophoretic investigation after digestion with restriction endonucleases, two DNA families that are restricted to germline DNA were isolated. Molecular cloning and sequence analysis revealed that these families are composed of closely related sequences of 64 and 57 bp in length, respectively. Southern blot hybridization revealed that the two DNA families are restricted to germline DNA and were thus named EEEb1 and EEEb2, respectively. Moreover, these eliminated elements were highly and tandemly repeated, and it is predicted that they might amplify by saltatory replication and have evolved in a concerted manner. By densitometric scanning, EEEb1 and EEEb2 were found to amount to make up approximately 18.5 and 0.024% of the total germline genomic DNA, accounting for 88.6% of the total eliminated DNA. A fluorescence in situ hybridization experiment demonstrated that EEEb1 is located on all C-band-positive chromosomes that are limited to germ cells, suggesting that EEEb1 is the primary component of eliminated DNA of E. burgeri.

Highly repetitive DNA sequences that are restricted to the germ line in the hagfish Eptatretus cirrhatus: a mosaic of eliminated elements

Abstract. The New Zealand hagfish, Eptatretus cirrhatus, is known to eliminate parts of its chromosomes during embryogenesis from presumptive somatic cells. Electrophoresis of germ line and somatic DNAs of this species, after treatment with the restriction endonucleases DraI and EcoRI, revealed three fragments of DNA that were restricted to the germ line. DNA filter hybridization experiments demonstrated that these fragments were present almost exclusively in the germ line DNA of E. cirrhatus and that they were highly and tandemly repeated. Thus, these DNA fragments appeared to be eliminated during embryogenesis. Moreover, one fragment (a DraI fragment) cross-hybridized with the germ line DNA from other species of hagfish, namely, Eptatretus okinoseanus and Paramyxine atami. Molecular cloning and sequence analysis revealed that the DraI fragment was composed mainly of closely related sequences of 85 bp in length and that this sequence was about 75% homologous to the sequence of EEEo2 (eliminated element of E. okinoseanus 2) which is a germ line-restricted and highly repetitive sequence that was isolated previously from E. okinoseanus. The other two fragments were composed of three families of closely related sequences that were 172 bp long (designated EEEc1), 61 bp long (EEEc2) and 54 bp long (EEEc3). Fluorescence in situ hybridization experiments revealed that each eliminated element was distributed on several chromosomes that are limited to germ cells. EEEo2 was dispersed on 12 C-band-positive chromosomes. EEEc1 and EEEc3 were dispersed on all C-band-positive and several C-band-negative chromosomes. By contrast, EEEc2 was located to terminal regions of several C-band-negative chromosomes. These results suggest that the eliminated chromosomes in hagfish are mosaics of highly repeated, germ line-restricted families of DNA sequences.

Germ line-restricted supernumerary (B) chromosomes in Eptatretus okinoseanus

Cytogenetic studies were performed on two types of Japanese hagfish (Eptatretus okinoseanus) that eliminate about 45% (type A) and 55% (type B) of their DNA from presumptive somatic cells during the differentiation of somatic cells. The observations revealed inter- and intraindividual variations in the number of chromosomes in germ cells of both types of hagfishes. Although the modal number of chromosomes in the germ cells was 54 in both types, the percentage of cells with the modal number was rather low (38.6% [51/132] in five specimens of type A and 22.7% [25/110] in eight specimens of type B). In addition, one of seven type B specimens clearly had a modal number of 62 chromosomes. Another specimen of type B had a bimodal distribution of chromosome numbers, with peaks of 54 and 59 chromosomes. The observation of interindividual variations was supported by data on the amount of DNA in germ cells of type B specimens. However, these variations were rarely observed in somatic cells. These results suggest that supernumerary (B) chromosomes are maintained in germ cells and are eliminated together with some other chromosomes and/or chromatin from somatic cells.

Whole chromosome elimination and chromosome terminus elimination both contribute to somatic differentiation in Taiwanese hagfish Paramyxine sheni

Chromosome elimination is a process in which some chromatins are discarded from the presumptive somatic cells during early embryogenesis. Eliminated chromatins in hagfish generally consist of repetitive sequences, and they are highly heterochromatinized in germ cells. In this study, we characterized four novel eliminated DNA families, EEPs1–4, from the Taiwanese hagfish Paramyxine sheni. Sequences of these four elements occupied 20–27% of eliminated DNA in total, and each family was arranged mainly in tandem in the germline genome with high copy numbers. Although most of these elements were eliminated, a minor fraction remained in somatic cells. Some eliminated DNA families are shared as eliminated sequences between Eptatretidae and Myxinidae. Fluorescence in situ hybridization (FISH) of these elements showed that not only heterochromatic chromosomes but also both ends of euchromatic chromosomes in germ cells are absent in somatic cells of P. sheni. It strongly suggests that chromosome terminus elimination, in addition to whole chromosome elimination, contributes to somatic chromosome differentiation. Telomere-FISH further showed that chromosome fragmentation and the subsequent de novo addition of telomeric repeats are the likely mechanisms underlying chromosome terminus elimination. These characteristics make it indispensable to study the evolution and mechanisms underlying chromosome elimination in hagfish.