Chromosome 1 in crested and marbled newts (Triturus)

The heteromorphic chromosomes 1 of Triturus cristatus carnifex and T. marmoratus were studied in mitotic metaphase after staining with the Giemsa C-banding technique and with the fluorochromes, DAPI (AT-specific) and mithramycin (GC-specific). They were also examined in the lampbrush form under phase-contrast before fixation and after fixation and staining with Giemsa. Chromosomes 1 of T.c. carnifex are asynaptic and achiasmatic throughout most of their long arms. They are also heteromorphic in most of their long arms for the patterns of Giemsa and fluorochrome staining and the distribution of distinctive lampbrush loops. The heteromorphic regions correspond to the regions that are asynaptic and achiasmatic. They stain more strongly with mithramycin and more weakly with DAPI than the remainder of the chromosomes, signifying that their DNA is relatively rich in GC. The patterns of staining with Giemsa and fluorochromes and the distributions of distinctive lateral loops vary from one animal to another in the same species and even in the same population. The asynaptic and achiasmatic regions of chromosomes 1 in T. marmoratus extend throughout the whole of the long arms and well beyond the heterochromatic region. Chiasmata form only in the short arm and occasionally in the short euchromatic segment at the tip of the long arms. The staining patterns of chromosomes 1 in T. marmoratus differ from those in T.c. carnifex although, like carnifex, their DNA is relatively GC-rich. The chromosomes 1 of T. marmoratus are more submetacentric than those of T.c. carnifex. In T. marmoratus chromosome 1B is about 12% shorter than 1A. There is a short paracentric inversion heterozygosity in the long arm of chromosome 1B in T. marmoratus which probably accounts for the lack of chiasmata in the euchromatin that separates the centromere from the start of the heterochromatin. In both carnifex and marmoratus, embryos that are homomorphic for chromosome 1 arrest and die at the late tailbud stage of development. The same applies to F₁ hybrid embryos T.c. carnifex x T. marmoratus, and this has permitted identification of chromosomes 1A and 1B in both species. There is no correspondence between patterns of Giemsa or fluorochrome staining of the heteromorphic regions of chromosome 1 and any feature of the lampbrush chromosomes. However, the short euchromatic ends of the long arms of chromosomes 1 in both species are distinguished in the lampbrush form by a series of uniformly small loops of fine texture associated with very small chromomeres. The Giemsa C-staining patterns of both chromosomes 1A and 1B are different in each of the four subspecies of T. cristatus. T.c. karelinii stands out by having unusually large masses of Giemsa C-staining centromeric heterochromatin on all but 1 of its 12 chromosomes. A scheme is proposed for the evolution of chromosome 1 in T. cristatus and T. marmoratus, based on all available cytological and molecular data.     

In situ hybridization of ribosomal DNA labelled with 125iodine to metaphase and lampbrush chromosomes from newts

Methods are described for in situ hybridization of ribosomal DNA from Xenopus laevis, labelled in vitro with ¹²⁵iodine, to mitotic and lampbrush chromosomes from Triturus cristatus carnifex. The hybridization reaction was carried out in a mixture containing 50% formamide, 4 x SSC, 0.1 M KI, at 37° C, or in 2 x SSC, 0.1 M KI at 65° C. Autoradiographs of mitotic metaphases from 2 males showed labelling over the middle of the short arm of one chromosome IX in each metaphase. In some cases, a region near the end of a longer chromosome was also labelled. In lampbrush preparations, labelling was confined to a region identified as about 53 units, near the middle of the short arm of both halves of bivalent IX. The usefulness of the technique and the significance of the labelling of only 1 of the 2 chromosomes IX in mitotic preparations are discussed.     

Lampbrush W and Z heterochromosome characterization with a monoclonal antibody and heat-induced chromosomal markers in the newtPleurodeles waltl: W chromosome plays a role in female sex determination

Two subsets of lateral loops scattered on lampbrush chromosomes of the newtPleurodeles waltl were characterized. One group was identified by labelling with a monoclonal antibody (A1). The second group was identified by the ability of the loops to be induced by heat treatment. Three loops of each subset were mapped on a short region of the two homologues of lampbrush bivalent IV. These regions appear to be heteromorphic because the six loops are always heterozygous. Five loops are found on one homologue and the sixth on the partner. The distribution of these markers in phenotypic females corresponding to the three sexual genotypes ZW, WW and ZZ shows an absolute correlation of the five loop group with the W chromosome and of the other loop with the Z chromosome. Therefore the heteromorphic regions of the homologues correspond to the differential segments of the heterochromosomes. The identification of a trisomic ZZW female suggests that the W chromosome bears female sex determinants. Furthermore the results show that heat induces loop development and that under normal conditions giant loop development is influenced by the sexual genotype.     

Lampbrush chromosomes and chiasmata of sex-reversed crested newts

Triturus cristatus carnifex provides a particularly clear example of sexual dimorphism for chiasma frequency and localisation. Oocytes from normal XX females routinely carry one proximal chiasma on each arm of their lampbrush bivalents. Spermatocytes from normal XY males have more numerous and relatively distal chiasmata. Lampbrush chromosomes from the oocytes of sex-reversed XY neofemales are found to resemble those from normal oocytes in having one proximal chiasma on each bivalent arm. A comparison of particular markers on the heteromorphic long arm of chromosome 1 provides evidence to equate the lampbrush 1A to somatic 1A, and confirms previous reports that lampbrush chromosome 1A is slightly longer than 1B. The XY sex bivalent of neofemales does not show any obvious heteromorphy of recognised marker loops. Received: 9 September 1997 / Accepted: 16 October 1997     

Identification of the lampbrush chromosome loops which transcribe 5S ribosomal RNA in Notophthalmus (Triturus) viridescens

The loops which transcribe 5S ribosomal RNA in lampbrush chromosomes of the newt, Notophthalmus (Triturus) viridescens, were identified by hybridizing purified 5S DNA to nascent 5S RNA in situ. The genes which code for 5S RNA were found near the centromeres of chromosomes 1, 2, 6, and 7 by hybridizing iodinated 5S RNA to denatured lampbrush and mitotic chromosomes in situ. These genes and their intervening spacer DNA were isolated from Xenopus laevis using sequential silver-cesium sulfate equilibrium centrifugations. This purified 5S DNA was iodinated and hybridized to non-denatured lampbrush chromosomes in situ, where it bound to nascent 5S RNA on loops at the base of the centromeres of chromosomes 1, 2, 6, and 7. The number of 5S genes present in the haploid chromosome complement of N. viridescens was determined. — The 5S loops were chosen for study, since (1) the synthesis of 5S RNA has been demonstrated during the lampbrush stage, (2) both 5S RNA and 5S DNA could be isolated in pure form, and (3) the localization of the repetitive 5S genes could be verified by conventional in situ hybridization procedures. These methods may be applicable to the identification of other loops, leading to a better understanding of lampbrush chromosome function.     

Heterochromatin regions of the chromosomes of the hen and Japanese quail in mitosis and at the lampbrush stage

The mitotic and lampbrush chromosomes of the domestic fowl and Japanese quail were analysed by fluorochrome staining technique. The lampbrush chromosomes of both the subjects displayed a typical "loop-chromomere" structure. Three distinct kinds of loops were distinguished in Gallus g. domesticus--normal, telomeric bows, and lumps. The former are distributed along the whole chromosome length. The latter and the bows were observed in subtelomeric and telomeric regions. By DNA/RNA specific acridine orange staining it was shown that each loop (especially, "lumpy" loops) contained a rich RNP matrix. A comparative analysis of the chromomycin A3/distamycin A banding pattern of mitotic and lampbrush chromosomes shows that the telomeric "bows" and "lumps" are special loops developed in telomeric heterochromatic bands. In Coturnix c. japonica, the CMA/DA-positive bands were not observed in telomeres of mitotic macrochromosomes, except a smallest band in the 2p-arm telomere. The absence of telomeric heterochromatic bands which can be visualized in the quail mitotic chromosomes coincides with the absence of "bow"-like loops. Only small lump-like structures were seen in some telomeres of macroautosomes. The biological significance of loop formation and RNA synthesis in heterochromatic band loops in growing oocytes is briefly discussed.     

Evidence for two successive pericentric inversions in sex lampbrush chromosomes of Rana rugosa (Anura: Ranidae)

The objective of this study was to clarify the course of inversions by which a ZW sex chromosome dimorphism has become established in Rana rugosa. Fortunately, R. rugosa preserves three different forms of sex chromosomes in the several isolated populations. In both males and females, the homomorphic sex chromosomes from Hiroshima were closely similar to Z, while those from Isehara were slightly different from the Z. Females from Hirosaki demonstrated heteromorphic sex chromosomes. In this study, the configuration and pairing behavior of sex lampbrush chromosomes were examined in the female offspring produced from a cross between a female from Hiroshima and a male from Isehara, as well as the female offspring of a female from Hirosaki and the male from Isehara. For the sex lampbrush chromosomes from Hiroshima and Isehara, chiasmata were exclusively formed between the distal regions of the long arms of one sex chromosome and the terminal regions of the short arms of the other. As a result, landmarks arranged in reverse order were observed in the achiasmatic regions of these chromosomes. For the sex lampbrush chromosomes from Isehara and Hirosaki, on the other hand, chiasma formation was mainly confined to the lower half of the chromosomes corresponding to the long arms, and the landmarks in the achiasmatic regions of these chromosomes were disposed in the opposite direction to each other. These results seem to indicate that in the primitive sex chromosomes of the Hiroshima type two pericentric inversions occurred, leading to the differentiation of the W chromosomes. This is the first report to substantiate the process of sex chromosome differentiation experimentally. Received: 10 November 1996; in revised form: 22 April 1997 / Accepted: 24 April 1997     

The nucleolar organizer of Plethodon cinereus cinereus (Green)

The 7th longest lampbrush bivalent in oocytes of Plethodon cinereus cinereus has a region of attached oocyte nucleoli near to the centromere on the shorter arm of each half bivalent. When squash preparations of P. c. cinereus spermatocytes are treated with NaOH to denature chromosomal DNA, and subsequently incubated in a solution of (³H) ribosomal RNA from Xenopus cell cultures, the ribosomal RNA binds specifically to a region near the centromeres on the shorter arms of the 7th longest bivalent, and to a region near the end of the shorter arm of the 14th bivalent. The amount of ribosomal RNA bound to the 7th bivalent at diplotene and 1st meiotic metaphase is regularly different on the 2 halves of the bivalent. Each half of the 14th bivalent is usually labelled more heavily than the less heavily labelled half of the 7th bivalent. These observations are discussed in relation to the involvement of nucleolar organizers in gene amplification and rectification.     

Comparative study of human chromosome replication in primary cultures of embryonic fibroblasts and in cultures of peripheral blood leucocytes

By autoradiography with ³H-thymidine and ³H-deoxycytidine it is shown that chromosomes 1 and 16 in cultures of embryonic fibroblasts at the termination of the S period synthesise AT- and GC-rich DNA at different rats: in both chromosomes the labelling of AT-bases is more intensive. In leucocyte cultures both nucleotide pairs label equally in these chromosomes. Chromosomes 2, 3, 4–5 and 21–22 are labelled equally in both cultures with respect to AT-and GC-pairs. Fibroblasts and leucocytes differ in the relative intensity of DNA synthesis at the end of the S period: chromosomes 1,16 and 21–22 contain more label in the case of fibroblasts (chromosome 1 solely due to AT-pairs) and chromosome 4–5 in the case of leucocytes. Analysis of distribution of late label along chromosome 1 showed that in fibroblast cultures the pericentromeric regions of both arms are labelled more intensively in respect to both nucleotide pairs than in leucocyte cultures. Both in fibroblast and leucocyte cultures no significant distinctions in the distribution of AT-and GC-pairs along chromosome 2 were established. In fibroblast cultures the pericentromeric regions of both arms of chromosome 3 are labelled more intensively than other regions. In leucocyte cultures the pericentromeric region of the short arm of this chromosome is labelled with the same intensively as in fibroblasts, whereas in the pericentromeric region of the long arm the intensity of incorporation of labelled synthesis precursors decreases. — Analysis of results obtained in the present study together with data of previous studied (Slesinger et al., 1974; Lozovskaya et al., 1976; Lozovskaya et al., 1977) shows that differences between the two types of cells in the intensity of late ³H-thymidine labelling in the C-heterochromatin regions of chromosomes 1 and 16 may be explained both by variation of replication time in leucocytes as compared with fibroblasts and by variation of the content of AT- rich DNA. Differences observed in other chromosomes are probably due to different times of replication of these chromosomes in leucocytes and fibroblasts. — Thus, the process of cell system differentiation involves not only differential activity of the genome (the main mechanism) that is connected with differences in the replication time of chromosomes and of their regions but also variation of the quantity of genetic material.     

Molecular cloning of microdissected lampbrush loop DNA sequences of Drosophila hydei

We microdissected a Y chromosomal lampbrush loop pair from primary spermatocyte nuclei of Drosophila hydei and cloned the DNA directly at the microscale. Four of the 12 recombinant DNA clones recovered display in situ hybridization to mitotic metaphase Y chromosomes, preferentially in the chromosomal region identified as the origin of the lampbrush loop pair. All clones, however, also hybridize to autosomal and X chromosomal loci in polytene chromosomes. Y chromosomal DNA sequences of D. hydei again prove to be members of different families of repeated sequences distributed throughout the genome. These microcloning experiments, which were carried out under very unfavourable experimental conditions (low DNA content of the lampbrush loops in the presence of large amounts of RNA) prove that almost any chromosomal structure detected by light microscopy is directly accessible to molecular cloning experiments by micromethods.     

Characterization of the lampbrush chromosomes of the marbled newt Triturus marmoratus (Latreille, 1800)

The maps of the lampbrush chromosomes of Triturus marmoratus oocytes were constructed on the basis of their lengths and major morphological characters such as giant fusing loops, dense matrix loops, lumpy objects, axial granules, lateral globules and reflected fusions; a nucleolus organizing region occurs subterminally on the right side of chromosome X. — Bivalent I appears morphologically asymmetrical, its two partners being of different lengths and bearing heteromorphic loops and other heterozygous structures: this heteromorphism may indicate that the two partners of bivalent I represent the ZW heterochromosomes of the species. Finally, an autoradiographic study has been performed in order to ascertain the pattern of ³H-uridine incorporation shown by the most typical landmarks and nucleoli.This work was financially supported by C.N.R., Roma.