Heterochromatic differentiation in barley chromosomes revealed by C- and N-banding techniques

Summary Heterochromatin distribution in barley chromosomes was investigated by analyzing the C- and N-banding patterns of four cultivars. Enzymatic maceration and air drying were employed for the preparation of the chromosome slides. Although the two banding patterns were generally similar to each other, a clear difference was observed between them at the centromeric sites on all chromosomes. Every centromeric site consisted of N-banding positive and C-banding negative (N⁺ C^–) heterochromatin in every cultivar examined. An intervarietal polymorphism of heterochromatin distribution was confirmed in each of the banding techniques. The appearance frequencies of some bands were different between the two banding techniques and among the cultivars. The heterochromatic differentiation observed is discussed with respect to cause.     

Cytogenetic Analysis of a Segment of the Y Chromosome of DROSOPHILA MELANOGASTER

Males carrying a large deficiency in the long arm of the Y chromosome known to delete the fertility gene kl-2 are sterile and exhibit a complex phenotype: (1) First metaphase chromosomes are irregular in outline and appear sticky; (2) spermatids contain micronuclei; (3) the nebenkerns of the spermatids are nonuniform in size; (4) a high molecular weight protein ordinarily present in sperm is absent; and (5) crystals appear in the nucleus and cytoplasm of spermatocytes and spermatids. In such males that carry Ste⁺ on their X chromosome the crystals appear long and needle shaped; in Ste males the needles are much shorter and assemble into star-shaped aggregates. The large deficiency may be subdivided into two shorter component deficiencies. The more distal is male sterile and lacks the high molecular weight polypeptide; the more proximal is responsible for the remainder of the phenotype. Ste males carrying the more proximal component deficiency are sterile, but Ste ⁺ males are fertile. Genetic studies of chromosome segregation in such males reveal that (1) both the sex chromosomes and the large autosomes undergo nondisjunction, (2) the fourth chromosomes disjoin regularly, (3) sex chromosome nondisjunction is more frequent in cells in which the second or third chromosomes nondisjoin than in cells in which autosomal disjunction is regular, (4) in doubly exceptional cells, the sex chromosomes tend to segregate to the opposite pole from the autosomes and (5) there is meiotic drive; i.e., reciprocal meiotic products are not recovered with equal frequencies, complements with fewer chromosomes being recovered more frequently than those with more chromosomes. The proximal component deficiency can itself be further subdivided into two smaller component deficiencies, both of which have nearly normal spermatogenic phenotypes as observed in the light microscope. Meiosis in Ste ⁺ males carrying either of these small Y deficiencies is normal; Ste males, however, exhibit low levels of sex chromosome nondisjunction with either deficient Y. The meiotic phenotype is apparently sensitive to the amount of Y chromosome missing and to the Ste constitution of the X chromosome.     

A cytogenetic analysis of X- ray induced male steriles on the Y chromosome of Drosophila melanogaster

A total of 1020 B ^s Yy ⁺chromosomes was screened for the induction of male sterile mutations by X irradiation. The 29 recovered mutations were analyzed by genetic complementation and the metaphase chromosomes stained with Hoechst 33258 and observed with fluorescence microscopy. The cytological and genetic maps derived from this analysis were compared to similar maps of the Y chromosome mutations isolated in an earlier study (Brosseau, 1960). Unlike the previous work we have identified only 6 male fertility loci (2 on the short arm, 4 on the long arm) on the Y chromosome. These loci are distributed along the length of the long arm and are likely to reside at two separate sites on the short arm. There is no apparent clustering of these fertility factors in this heterochromatic chromosome. The deletions obtained in this study were observed to be unstable and the nature of this instability was investigated. The original Y chromosome was marked at both telomeres with normally X-linked genes. The loss of one or the other of these markers was accompanied in many cases by the concomitant loss of large segments of Y chromosome material. The possible mechanism of this loss is discussed.Author to whom correspondence should be sent     

Male-Sterilizing Interactions between Duplications and Deficiencies for Proximal X-Chromosome Material in DROSOPHILA MELANOGASTER

The genetic limits of sixty-four deficiencies in the vicinity of the euchromatic-heterochromatic junction of the X chromosome were mapped with respect to a number of proximal recessive lethal mutations. They were also tested for male fertility in combination with three Y chromosomes carrying different amounts of proximal X-chromosome-derived material (B^SYy⁺, y⁺Ymal¹²⁶ and y⁺Ymal⁺). All deficiencies that did not include the locus of bb and a few that did were male-fertile in all male-viable Df(1)/Dp(1;Y) combinations. Nineteen bb deficiencies fell into six different classes by virtue of their male-fertility phenotypes when combined with the duplicated Y chromosomes. The six categories of deficiencies are consistent with a formalism that invokes three factors or regions at the base of the X, one distal and two proximal to bb, which bind a substance critical for precocious inactivation of the X chromosome in the primary spermatocyte. Free duplications carrying these regions or factors compete for the substance in such a way that, in the presence of such duplications, proximally deficient X chromosomes are unable to command sufficient substance for proper control of X-chromosome gene activity preparatory to spermatogenesis. We conclude that there is no single factor at the base of the X that is required for the fertility of males whose genotype is otherwise normal.     

Fine Mapping of Satellite DNA Sequences along the Y Chromosome of Drosophila Melanogaster: Relationships between Satellite Sequences and Fertility Factors

The entirely heterochromatic Y chromosome of Drosophila melanogaster contains a series of simple sequence satellite DNAs which together account for about 80% of its length. Molecular cloning of the three simple sequence satellite DNAs of D. melanogaster (1.672, 1.686 and 1.705 g/ml) revealed that each satellite comprises several distinct repeat sequences. Together 11 related sequences were identified and 9 of them were shown to be located on the Y chromosome. In the present study we have finely mapped 8 of these sequences along the Y by in situ hybridization on mitotic chromosome preparations. The hybridization experiments were performed on a series of cytologically determined rearrangements involving the Y chromosome. The breakpoints of these rearrangements provided an array of landmarks along the Y which have been used to localize each sequence on the various heterochromatic blocks defined by Hoechst and N-banding techniques. The results of this analysis indicate a good correlation between the N-banded regions and 1.705 repeats and between the Hoechst-bright regions and the 1.672 repeats. However, the molecular basis for banding does not appear to depend exclusively on DNA content, since heterochromatic blocks showing identical banding patterns often contain different combinations of satellite repeats. The distribution of satellite repeats has also been analyzed with respect to the male fertility factors of the Y chromosome. Both loop-forming (kl-5, kl-3 and ks-1) and non-loop-forming (kl-2 and ks-2) fertility genes contain substantial amounts of satellite DNAs. Moreover, each fertility region is characterized by a specific combination of satellite sequences rather than by an homogeneous array of a single type of repeat.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recognition of Two Types of Positive Staining Chromosomal Material by Manipulation of Critical Steps in the N-Banding Technique

The nucleolar regions on chromosomes 1B and 6B of Triticum aestivum L. cv Chinese Spring wheat can reliably be observed after careful control of the Giemsa N-banding technique. Identification of rye (Secale cereaie) chromosomes using N-banding is demonstrated and compared to a simple C-banding method. The N-banding in rye chromosomes and the nucleolar sites on IB and 6B of wheat differ from the normal N-banding sites of wheat chromosomes. Further, the banding of these nucleolar regions and of the rye chromosomes does not reappear in preparations that have been retreated with hot acid buffer. These differences provide evidence for at least two types of chromatin that stain darkly (positively) using N-banding. The critical procedures in the N-banding technique and the use of alternatives to 1 M NaH₂PO₄ buffer are discussed along with the possible basis of N-band formation.     

The chromosomes of two Drosophila races: D. nasuta nasuta and D. n. albomicana

Heterochromatin distribution and differentiation in metaphase chromosomes of two morphologically identical Drosophila races, D. nasuta nasuta and D. n. albomicana, have been studied by C- and N-banding methods. — The total heterochromatin values differ only slightly between these races. However, homologous chromosomes of the two Drosophila forms show striking differences in the size of heterochromatin regions and there is an alternating pattern in D. n. nasuta and D. n. albomicana of chromosomes which contain more, or respectively less heterochromatin than their counterparts in the other race. — Three different N-banding patterns could be obtained depending on the conditions of the method employed: One banding pattern occurs which corresponds to the C-banding pattern. Another pattern is the reverse of the C-band pattern; the euchromatic chromosome regions and the centromeres are stained whereas the pericentric heterochromatin regions remain unstained. In the Y chromosomes of both races and in chromosome 4 of D. n. albomicana, however, the heterochromatin is further differentiated. In the third N-banding pattern only the centromeres are deeply stained. Furthermore, between the races, subtle staining differences in the pericentric heterochromatin regions can be observed as verified in F₁ hybrids. On the basis of C- and N-banding results specific aspects of chromosomal differences between D. n. nasuta and D. n. albomicana are discussed.Dedicated to Prof. W. Beermann on the occasion of his 60th birthday     

Temperature-sensitive mutations in Drosophila melanogaster. XI. Male sterile mutants of the Y chromosome

Eight temperature-sensitive (ts) male sterile mutations have been induced by ethyl methanesulfonate treatment of Y chromosomes derived from a selected temperature-resistant Amherst wild-type stock of Drosophila melanogaster. Males carrying such mutated Y chromosomes (Y^ts) are sterile when raised at 29°C but fertile when reared at 22°C. Complementation tests of the mutants with Y chromosome fragments, deletions, and inter se localized all eight to the long arm of the chromosome in four different complementation groups.When Y^ts-bearing males, reared to adulthood at 22°C, were subjected to a 48-hr regimen at 29°C and mated to fresh virgin females daily, a significant reduction in fertility resulted 5 days after initiation of 29°C treatments. This period of sterility was transient (48–72-hr duration) and corresponded to a temperature-sensitive period (TSP) of spermatogenesis during the primary spermatocyte stage. A more precise definition of the TSP utilized exposure of subadult males to 29°C at selected developmental periods during which only certain germ cell stages are present. Upon eclosion adult males were subjected to a similar schedule of consecutive matings of 12-hr duration in order to detect any delay in the appearance of fertility. Different ts males could be distinguished by the resultant pattern of sterility, and the TSP of different mutations thus localized to either primary spermatocyte or immediately post-meiotic stage.Associated with Y^ts-mediated sterility, spermiogenesis is defective at restrictive temperature as evidenced by the production of nonmotile sperm and a failure to transfer such sperm to the female during copulation. In addition, electron microscopy detected a variety of ultrastructural abnormalities, including defects of axoneme formation, irregularities of Nebenkern derivative development, and failures of separation from the syncitial state or mature cyst with subsequent degeneration.     

Locations of a Human Satellite DNA in Human Chromosomes

USING techniques for DNA/RNA or DNA/DNA hybridization in situ, Pardue and Gall¹ and Jones² made several significant discoveries on the chromosomal locations of the mouse satellite DNA: (1) this fraction of DNA is found in all chromosomes except the Y, (2) the cytological location of the satellite DNA is limited to the centromeric region of each chromosome and is probably absent in other regions and (3) the centromeric regions of all mouse chromosomes are hetero-chromatic.     

The Genetic and Cytological Organization of the Y Chromosome of DROSOPHILA MELANOGASTER

Cytological and genetic analyses of 121 translocations between the Y chromosome and the centric heterochromatin of the X chromosome have been used to define and localize six regions on the Y chromosome of Drosophila melanogaster necessary for male fertility. These regions are associated with nonfluorescent blocks of the Y chromosome, as revealed using Hoechst 33258 or quinacrine staining. Each region appears to contain but one functional unit, as defined by failure of complementation among translocations with breakpoints within the same block. The distribution of translocation breakpoints examined appears to be nonrandom, in that breaks occur preferentially in the nonfluorescent blocks and not in the large fluorescent blocks.     

Study on the Chromosome N-Banding in Plants

The present paper is dealing with the investigation of the chromosome N-banding technique and the N-banding patterns in Hordeum vulgare, Triticum aestivum, Secale cereale, Vicia faba and Allium eepa. Two N-banding techniques were applied. First, the chromosome slides were stained with Giemsa solution. Second, the slides were treated in 1 M NaH2PO4 solution at 92—94 ℃ for 3.5—8.5 min. After rinsing in tap water they were stained with Giemsa solution. The experiments have demonstrated that the N-banding technique is simple and rapid and the banding patterns are distinctive. The data of N-banding patterns indicated that the N bands did not display the nucleolus organisers exclusively. The comparison of the N-banding patterns of these plants with their C-banding patterns shows that in some of these plants although some regions of N-bands and C-bands correspond, there are a number of instances where regions show N-bands but no C-bands and vice-versa. Therefore, a combination of the N-banding and C-banding techniques should be valuable in the cytological identification of plant chromosome. Like the C-bands, the N-bands are also useful markers in cytogenetics.     

Distamycin A-DAPI banding of nonfluorescent Y (Ynf) chromosomes in 45,X/46,XYnf mosaicism

Summary The distamycin A-DAPI banding patterns of nonfluorescent, nonheterochromatic Y chromosomes (Y^nf) in two patients with 45,X/46,XY^nf mosaicism were investigated. In both cases moderately fluorescent bands were observed near the centromere and on the distal long arm of the Y^nf. These bands were similar to the centrometric band on normal Y chromosomes and support the hypothesis that the Y^nf is an isodicentric chromosome derived from the proximal portion of the Y chromosome.     

Mitotic Recombination in the Heterochromatin of the Sex Chromosomes of DROSOPHILA MELANOGASTER

The frequency of spontaneous and X-ray-induced mitotic recombination involving the Y chromosome has been studied in individuals with a marked Y chromosome arm and different XY compound chromosomes. The genotypes used include X chromosomes with different amounts of X heterochromatin and either or both arms of the Y chromosome attached to either side of the centromere. Individuals with two Y chromosomes have also been studied. The results show that the bulk of mitotic recombination takes place between homologous regions.     

N-banded karyotypes of wheat species

Nine of the twenty-one chromosome pairs of the hexaploid wheat Triticum aestivum var. Chinese Spring (genome constitution AABBDD) show distinctive N-banding patterns. These nine chromosomes are 4A, 7A and all of the B genome chromosomes. The remaining chromosomes show either faint bands or no bands at all. Tetraploid wheat, T. dicoccoides (AABB), showed banded chromosomes similar to those observed in the hexaploid. Of the diploid species T. monococcum, T. boeoticum, T. urartu and Aegilops sauarrosa showed little or no banding as would be expected of donors of the A and D genomes. Ae. speltoides had a number of N-banded chromosomes as would be expected of a candidate for the B genome donor. Since N-bands are not evident on some nucleolar organiser chromosomes, the staining specificity cannot be correlated with the presence of nucleolar organiser regions.     

Identification of wheat-barley addition lines with N-banding of chromosomes

The seven chromosomes of barley (Hordeum vulgare) have been identified individually by their distinctive N-banding pattern. Furthermore all of the barley chromosome N-banding patterns were found to be recognizably different from those exhibited by wheat chromosomes, making it possible to identify individual barley chromosomes when present in a wheat background. N-banding has therefore been used to identify the individual barley chromosomes present in (a) reciprocal wheat-barley F₁ hybrids, including some with abnormal chromosome constitution, and (b) a set of wheat-barley addition lines produced in this laboratory. The value of N-banding for detecting translocations between wheat and barley chromosomes and for isolating lines possessing a pair of barley chromosomes substituted for a particular pair of wheat chromosomes is also demonstrated.     

Cytogenetic Mapping of Enzyme Loci on Chromosomes J and U of DROSOPHILA SUBOBSCURA

Enzyme loci located on chromosome J and U were mapped cytologically by means of a Y translocation technique. A linkage map of the two chromosomes was established in a parallel experiment and the recombination frequency in different regions of the chromosomes determined. A comparison of the cytogenetic localization of the enzyme genes in D. subobscura and D. melanogaster indicates that many paracentric inversions must have taken place in the course of divergent evolution. However, no displacements of genes from one element to another due to pericentric inversions, reciprocal translocations or transposing elements can be observed. In spite of the large number of structural rearrangements that have occurred in the phylogeny of the genus Drosophila, gross similarities of banding pattern in homologous regions of the chromosomes of the two species become apparent.     

Chromosome banding in Triticum aestivum cv. chinese spring and Aegilops variabilis

N-banding has been used to identify each of the fourteen chromosomes of Aegilops variabilis Eig. These patterns differ from the patterns of the nine wheat chromosomes that band with this technique. The banding pattern of Aegilops variabilis chromosome G was the same when examined in the parent species and in the wheat-variabilis addition line. — Banding analysis can be reliably carried out on both mitotic and meiotic chromosomes of wheat. Nine pairs of wheat chromosomes can be identified at meiosis.     

X-Y Exchange and the Coevolution of the X and Y Rdna Arrays in Drosophila melanogaster

The nucleolus organizers on the X and Y chromosomes of Drosophila melanogaster are the sites of 200-250 tandemly repeated genes for ribosomal RNA. As there is no meiotic crossing over in male Drosophila, the X and Y chromosomal rDNA arrays should be evolutionarily independent, and therefore divergent. The rRNAs produced by X and Y are, however, very similar, if not identical. Molecular, genetic and cytological analyses of a series of X chromosome rDNA deletions (bb alleles) showed that they arose by unequal exchange through the nucleolus organizers of the X and Y chromosomes. Three separate exchange events generated compound X·Y ^L chromosomes carrying mainly Y-specific rDNA. This led to the hypothesis that X-Y exchange is responsible for the coevolution of X and Y chromosomal rDNA. We have tested and confirmed several of the predictions of this hypothesis: First, X· Y^L chromosomes must be found in wild populations. We have found such a chromosome. Second, the X·Y^L chromosome must lose the Y^L arm, and/or be at a selective disadvantage to normal X⁺ chromosomes, to retain the normal morphology of the X chromosome. Six of seventeen sublines founded from homozygous X·Y^Lbb stocks have become fixed for chromosomes with spontaneous loss of part or all of the appended Y^L. Third, rDNA variants on the X chromosome are expected to be clustered within the X⁺ nucleolus organizer, recently donated (" Y") forms being proximal, and X-specific forms distal. We present evidence for clustering of rRNA genes containing Type 1 insertions. Consequently, X-Y exchange is probably responsible for the coevolution of X and Y rDNA arrays.     

Polyploidy, B chromosomes, and heterochromatin characterization of Mimosa caesalpiniifolia Benth. (Fabaceae-Mimosoideae)

Eight populations of Mimosa caesalpiniifolia Benth. were investigated using a cytogenetic approach. Here, we describe for the first time details of the karyotype including chromosome morphology, physical mapping of chromomycin A3 (CMA) 4′,6-diamidino-2-phenylindole (DAPI) and silver staining of nucleolar organizer regions (Ag-NOR banding), as well as 45S rDNA sites. All populations studied showed karyotypes with 2n?=?2x?=?26 small metacentric and submetacentric chromosomes, although some individuals exhibited 2n?=?4x?=?52 chromosomes. Moreover, we observed putative additional B chromosomes in some populations. The CMA banding and fluorescent in situ hybridization techniques revealed NOR heteromorphism on the unique pair containing 45 rDNA site (chromosome 12) while the Ag-NOR banding indicated NORs on both cytotypes. Up to two and four nucleoli were observed, respectively, on individuals with 2n?=?2x?=?26 and 2n?=?4x?=?52 chromosomes and the differences in nucleolar size seems to be directly related to NOR heteromorphism in some individuals. The data present new and important information to understand karyotypic evolution of Mimosa and Fabaceae.     

Selective Recombination System in Bombyx mori. I. Chromosome Specificity of the Modification Effect

The effect of modifiers on recombination frequency between Ze and lem loci on chromosome 3 to elucidate the chromosome specificity of modification and the distribution of modifiers using Bombyx mori lines selected for high (H) and low (L) recombination rates between the p^S and Y loci in chromosome 2 was investigated. By crossing to the Z (Ze lem/++) line, the recombination rate between the p^S and Y loci in chromosome 2 was decreased from 28.18 to 23.33 in the H line and was increased from 4.92 to 16.05 in the L line. On the other hand, the recombination rate between the Ze and lem loci in chromosome 3 was increased from 16.21 to 20.21 in the Z line by crossing to the H line, but also increased to 19.02 by crossing to the L line. The significant correlation observed between the transformed recombination rates of chromosomes 2 and 3 in the (Z x L) x L backcross indicated that there were common factors modifying recombination frequency in chromosomes 2 and 3 or different factors linked to the same chromosomes. In the family of L x [(Z x L) x L] backcross, the distribution of transformed recombination rates indicated that there were several factors in the remaining chromosomes which were modifying recombination frequency in chromosome 2 but not in chromosome 3. It was also indicated that these factors were linked to different chromosomes than are the factors modifying recombination frequency in chromosome 3. In order to interpret these results, one genetic system model controlling recombination that consists of general and local recombination modifiers was proposed. The evolution of dynamic genetic systems that would effectively reduce recombinational load without reducing the advantage of recombination was discussed.