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.     

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     

Evidence for specific RNA/protein interactions in the differential segment of the W sex chromosome in the amphibian Pleurodeles waltl

Pleurodeles exhibits a ZZ/ZW system of GSD (genotype sex determination). However, the Z and W sex chromosomes appear to be morphologically identical. A short RNA sequence is described that was specifically bound to lampbrush loops in the differential segment of the sexual bivalent IV. The distribution of these labeled loops in experimentally produced ZZ and WW females enabled us to demonstrate that such labeled loops were perfectly correlated with the W chromosome. Therefore, this RNA sequence constitutes an excellent marker for the W differential segment. Furthermore, analysis of the labeled loops under various experimental conditions suggested that their labeling is caused by specific interactions between this RNA sequence and lampbrush loop-associated proteins (RNA/protein interactions). North-western assays revealed that nuclear polypeptide(s) of 65 kDa could be responsible for such binding.     

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     

Genetic function correlated with unfolding of lampbrush loops by the Y chromosome in spermatocytes of Drosophila hydei

Summary Deficiencies of the Y chromosome of Drosophila hydei including sites which develop lampbrush loops invariably cause sterility of males. Suppression of loop unfolding in one or more sites equally results in similar morphogenetic defects of spermiogenesis. A variegated type repression of lampbrush loop unfolding observed during the spermatocyte stage results in varying morphogenetic effects on spermiogenesis. This demonstrates the existence of causal relationships between the active phase of Y chromosomal factors in spermatocytes and the differentiation processes in spermatids.In some translocated Y fragments the mode of unfolding of a particular pair of lampbrush loops may be permanently changed. As a result, lampbrush loops of a mutant phenotype are developed. Some alterations of this type are correlated with functional alterations resulting in defective spermiogenesis.Three different fragments of the Y chromosome in which lampbrush loop formation was repressed have been tested for possible reversions of loop suppression by means of X irradiations. In none of the three cases reversion has been detected among two thousand tested chromosomes.To the memory of Karl-Heinz Bier.     

Chromosome banding in amphibia

The distribution of constitutive heterochromatin on the chromosomes of Triturus a. alpestris, T. v. vulgaris and T. h. helveticus (Amphibia, Urodela) was investigated. Sex-specific chromosomes were determined in the karyotypes of T. a. alpestris (chromosomes 4) and T. v. vulgaris (chromosomes 5). The male animals have one heteromorphic chromosome pair, of which only one homologue displays heterochromatic telomeres in the long arms; the telomeres of the other homologue are euchromatic. This chromosome pair is always homomorphic and without telomeric heterochromatin in the female animals. There is a highly reduced crossing-over frequency between the heteromorphic chromosome arms in the male meiosis of T. a. alpestris; in T. v. vulgaris no crossing-over at all occurs between the heteromorphic chromosome arms. No heteromorphisms between the homologues exist on the corresponding lampbrush chromosomes of the female meiosis. In T. h. helveticus no sex-specific heteromorphism of the constitutive heterochromatin could be determined. The male animals of this species, however, already possess a chromosome pair with a greatly reduced frequency of chiasma-formation in the long arms. The C-band patterns and the pairing configurations of the sex-specific chromosomes in the male meiosis indicate an XX/XY-type of sex-determination for the three species. A revision of the literature about experimental interspecies hybridizations, gonadic structure of haploid and polyploid animals, and sex-linked genes yielded further evidence in favor of male heterogamety. The results moreover suggest that the heterochromatinization of the Y-chromosome was the primary step in the evolution of the sex chromosomes.     

Autosomal control of lampbrush-loop formation during spermatogenesis in Drosophila hydei by a gene also affecting somatic sex determination

Summary The Y chromosome of Drosophila hydei carries information that is necessary for the development of the spermatozoa. In primary spermatocytes Y chromosomal genes become active: five of the male fertility factors form giant lampbrush loops. Our prior work indicated interactions between the Y chromosomal genes and autosomal loci. It is of interest to identify loci regulating the activity of the Y chromosomal genes. We, therefore, screened a total of about 14,000 chromosomes (X, 2, 3 and 4) for mutations that interfere with the expression of the lampbrush loops. Two mutations with substantial effects on the loop morphology were recovered. One of them, a recessive male sterile mutation (ms (3) 5) on chromosome 3, is described in this paper. Its homozygous state results in a complete absence of all Y chromosomal lampbrush loops at 26° C; at 18° C the loops are formed. Temperature shifts with homozygous males indicate that the function early during the spermatogonial stage is crucial for the development of lampbrush loops in the primary spermatocyte. Meiosis is entirely absent in the male, but normal in females. Females homozygous for ms (3) 5 display a maternal effect, which reduces the viability and fertility of homozygous daughters and produces sons with signs of intersexuality. Linkage studies indicated that the effect on the male germ line and the maternal effects cannot be separated and may hence be induced by a single gene.     

Temperatursensitive Mutanten im Y-chromosom von Drosophila hydei

Mutations were induced in the Y chromosomal fertility genes of Drosophila hydei by EMS treatment of adult males. Four types of mutants were observed: 1. Sterile mutants without detectable cytological changes in Y chromosomal lampbrush loops. 2. Sterile males with morphologically changed loops. 3. Sterile males where one or several Y chromosomal loops are missing in the spermatocytes. 4. Mutants which are temperature-sensitive for sterility, development of loops or altered loop morphology. In this paper four Y mutants are described which are temperature-sensitive as regards fertility but which show unchanged lampbrush loops. They can be mapped in four different complementation groups. Two of those occur probably in regions of the Y chromosome without cytologically detectable lampbrush loops. All mutations are found in the distal half of the long arm. The temperature-sensitive period occurs during the primary spermatocyte stage and in early spermatid development while the manifestation of the effect occurs postmeiotically. The mutants are further characterized with respect to changes in the ultrastructure of the sperm at the restrictive temperature.     

The lampbrush chromosomes of Salamandra salamandra (L.) (Amphibia Urodela)

Lampbrush chromosomes isolated from the germinal vesicle of medium sized oocytes can be individually identified by differences in two characters: (1) chromosome regions rich in well developed loops, and (2) number and position of spheres. Actually the lateral loops are not all equally extended, but those which are inserted in a certain region of the axis of some chromosomes are more developed and sometimes are loaded with dense and copious matrix; chiasmata do not occur inside these regions. One or more spheres are present on eight chromosomes in the complement (chromosomes I–VI, VIII and X): the total number of spheres inserted on S. salamandra lampbrush chromosomes is the highest among the salamandrid species studied so far. These landmarks as well as the maximally developed normal loops are schematically drawn on the maps of the single lampbrush chromosomes. The length of the maps corresponds to the mean value of the lengths of each chromosome relative to that of chromosome XII, taken as 100 units long.Also bivalents from first metaphase spermatocytes have been analysed: they are generally ring-shaped with two terminal or subterminal chiasmata.     

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.     

Synaptonemal complexes with associated chromatin in a moth,Ephestia kuehniella Z.

Chromosome structure and pairing behaviour of the pachytene bivalents in the wildtype and in W chromosome mutants were studied using a microcentrifugation technique. The spread bivalents display a characteristic lampbrush structure with lateral loops having the typical appearance of nucleosomal fibers, in autosomes as well as in the W and Z chromosomes. While the autosomal loops are always completely dispersed by the spreading forces, the loops of the heterochromatic W chromosome frequently are found to be condensed in tangles. These tangles contain supranucleosomal globular particles of a diameter of 37.7±1.2 nm. — Pairing of the WZ can be complete or partial, probably depending on the stage of the pachytene. Incomplete pairing normally is interpreted as demonstrating non-homology. Pairing was weak, however, even between homologous segments of the W chromosome, which were introduced into the genome in homozygous form by a translocation chromosome.