Localized euchromatinization of the X chromosome during spermatogenesis in the grasshopper Melanoplus femur-rubrum

In grasshoppers, as well as in most other animals, the X chromosome is heteropycnotic (heterochromatic) during prophase I and metaphase I of spermatogenesis. During the same stages, in some of the cells of three Melanoplus femur-rubrum males (out of several hundred males examined) part of the X appeared euchromatic (E). In one male, the E segment was observed in 90% of the cells of a single cyst in which all the cells lacked one of the smallest autosomes. In another cyst of the same follicle all the cells contained one additional small autosome, and none of the Xs exhibited an E segment. The size of the E segment suggested that it resulted from the failure of part of the X to become heteropycnotic prior to the formation of the cyst. In the other two males, many of the cells contained chromosome fragments and translocations. In many cells in which the X exhibited an E segment, however, there was no evidence of chromosome breakage. The E segments were sometimes terminal and sometimes interstitial in the same cyst. This variation suggested that they resulted from the euchromatinization of part of the X immediately prior to prophase I of meiosis. Because fragmentation and the presence of Xs with an E segment were each very rare, it was concluded that they were in some way causally related. It was also concluded that in this species the heterochromatinization of the X is not controlled by a single inactivation center.     

Undercondensation and localized euchromatinization of the X chromosome in the grasshopper Melanoplus femur-rubrum

In most animals, including grasshoppers, the X chromosome is heterochromatic (heteropycnotic) during prophase I and metaphase I of spermatogenesis. This report describes one grasshopper male in which at these states some of the X chromosomes contained an euchromatic (E) segment. In grasshoppers, the heteropycnotic state of the X is apparently established prior to the formation of the cysts. The spermatocytes containing the E segments, however, did not comprise whole cysts. It was concluded, therefore, that the E segments resulted from a localized euchromatinization rather than a failure to become heteropycnotic. The cytology of this male was unusual in two other respects. In most of the spermatocytes the chromosomes were longer and thinner than those of other males. In addition, in some of the cells undergoing meiosis, the cytoplasm failed to divide during both meiotic divisions and the resulting spermatids failed to differentiate into sperm. Because in this species both the presence of Xs with E segments and undercondensation are very rare and both involve condensation, it is likely that they are in some way related. Evidence for and against the possibility that the E segments were genetically active and that this activity led to the arrest of some of the spermatids is discussed.     

Selective staining of X chromosome segments in Schistocerca gregaria after denaturation and reassociation procedures

The DNA of fixed mitotic and meiotic chromosomes and of spermatides of Schistocerca gregaria males was heat denaturated and then differentially reassociated in a Giemsa buffer or in acridine orange buffer solution. After this procedure, two to three large, selectively stained regions are seen in the X chromosome of spermatocytes and spermatides. Denaturation and reassociation experiments have shown that after differential reassociation such a selective stainability of chromosome regions is characteristic for the presence of fast-reassociating, i.e., repetitive DNA (Stockert and Lisanti, 1972). The possible presence of repetitive DNA in the X chromosome regions concerned can not be the only reason for the occurrence of the heavily stained segments after reassociation because (1) these segments are obtained in positively heteropycnotic X chromosomes, but not in negatively heteropycnotic Xs and (2) they do not occur in positively heteropycnotic X chromosomes when the histones have been extracted before the denaturation and reassociation processes. Contrary to the latter statement, the heavily stained X chromosomal regions are preserved when the histones are removed after the denaturation and reassociation steps. — It is assumed that the heavily stained X chromosome segments represent DNA reassociation complexes which are only formed if histones are present. It is discussed whether the formation of the X chromosome complexes depends on a specific chromatin configuration within positively heteropycnotic X chromosomes.     

A Drosophila melanogaster cell line tested for the presence of active NORs by silver staining

Silver staining was used to detect active NORs in a Drosophila melanogaster cell line (C1 82) characterized by dimorphic X chromosomes (XX_L), one of the two Xs showing a marked increase in heterochromatin where the nucleolar organizer (NO) is located. The Q-banding technique was used to determine the karyotype characteristics of the line. Ag-positive NORs appeared only on structurally changed X chromosomes (X_L), both in diploid and tetraploid cells, indicating that rRNA genes of X_L are more active or numerous than those on normal homologues. A possible relationship between NOR stainability, the presence of an increased heterochromatic portion and the selective advantage of XX_L cells, recurrent in numerous Drosophila female lines, is discussed.     

Asymmetry of heteropycnosis in tetraploid cells of a grasshopper

In XO male grasshoppers (Acridoidea and Eumastacoidea) X-chromatin is negatively heteropycnotic in spermatogonial mitoses. In neo-XY species which have a fusion between the original X and an autosome it is usual for the former alone to show negative heteropycnosis. This is the case in the Australian Morabine grasshopper species P52a. In tetraploid spermatogonia of this species, however, which contain two neo-X's and two neo-Y's, only one of the neo-X's has a negatively heteropycnotic left limb, the other X having the same degree of condensation as the autosomes. This novel type of behavior is compared with the heteropycnosis of one of the two X's in the somatic cells of female mammals. It is concluded that the asymmetry of condensation of the two X's in tetraploid spermatogonia of P52a demonstrates the existence of a fundamental cellular mechanism which is inherent and only expressed under the abnormal condition of tetraploidy.Supported by Public Health Service Grant GM-07212 from the Division of General Medical Sciences, U.S. National Institutes of Health and by a grant from the Australian Research Grants Committee.     

A radiation analysis of a comstockiella chromosome system: destruction of heterochromatic chromosomes during spermatogenesis in Parlatoria oleae (Coccoidea: Diaspididae)

In the males of the olive scale insect, Parlatoria oleae (2n=8), the paternal set of chromosomes becomes heterochromatic during late cleavage or early blastula and remains so until spermatogenesis. Immediately before the onset of meiosis in the males one or more heterochromatic chromosomes disappear from each primary spermatocyte. At prophase four euchromatic and from one to three heterochromatic chromosomes are present in each cell. The disappearance of the heterochromatic chromosomes before meiosis could be due either to the dehetero-chromatization of the heterochromatic chromosomes and their subsequent pairing with their euchromatic homologues, or to the destruction of the heterochromatic chromosomes. — The alternative interpretations of spermatogenesis in P. oleae were tested by using chromosome aberrations, which had been induced in the heterochromatic set by paternal X-irradiation, as genetic markers in breeding tests of about 400 X₁ males. Meiosis was examined in X₁ males which showed conspicuous chromosomal rearrangements in their somatic cells. The absence of either heteromorphic chromosome pairs or multivalents at spermatogenesis and the failure of the X₁ males to transmit any form of chromosome aberration induced by paternal irradiation is strong evidence that the heterochromatic chromosomes are destroyed in P. oleae. — The evolutionary relationships of the chromosome systems in the coccids are considered. Models are outlined for the derivation of a Comstockiella system involving chromosome destruction either from a lecanoid sequence or from a hypothetical Comstockiella sequence involving chromosome pairing. Problems concerning the control of chromosome destruction are discussed.From a dissertation submitted in partial fulfillment of the requirements of Doctor of Philosophy in Genetics.This work was supported by grant GB 8196 from the National Science Foundation to Dr. Spencer W. Brown, and by a National Institutes of Health Fellowship 1 F02 CA 44173-01 to the author from the National Cancer Institute.Dedicated to Dr. Sally Hughes-Schrader on the occasion of her seventy-fifth birthday.     

The behavior and morphology of the X and Y chromosomes during prophase I in the Sitka deer mouse (Peromyscus sitkensis)

Surface-spread, silver-stained primary spermatocytes from individuals of the Sitka deer mouse (Peromyscus sitkensis) were analyzed by electron microscopy. Pairing of the X and Y chromosomes is initiated at early pachynema and is complete by mid pachynema. The pattern of sex chromosome pairing is unique in that it is initiated at an interstitial position, with subsequent synapsis proceeding in a unidirectional fashion towards the telomeres of the homologous segments. One-third the length of the X and two-thirds the length of the Y are involved in the synaptonemal complex of the sex bivalent. Various morphological complexities develop in the heteropycnotic (unpaired) segments as pachynema progresses, but desynapsis is not initiated until diplonema. Analysis of C-banded diakinetic nuclei indicated that sex chromosome pairing involves the heterochromatic short arm of the X and the long arm of the heterochromatic Y. An interstitial chiasma between the X and Y was observed in the majority of the diakinetic nuclei. The observation of a substantial pairing region and chiasma formation between the sex chromosomes of these deer mice is interpreted as indicating homology between the short arm of the X and the long arm of the Y.     

Karyotype,DNA replication and origin of sex chromosomes in Anopheles atroparvus

Anopheles atroparvus has two pairs of autosomes similar in length and morphology and two sex chromosomes with equal, heterochromatic, late replicating long arms with homologous C-, G-, and Q-bands. The short arm of the Y is shorter than that of the X and both are euchromatic. The mean number of chiasmata per cell in the male is 3.2. During mitosis there is a high grade of somatic pairing but X and Y, which form a heteropycnotic mass in the interphase nucleus, have a differential behaviour. The chronology of DNA replication was studied in spermatogonia and brain cells by autoradiography. It is hypothesized that the present sex chromosomes of A. atroparvus evolved by accumulation of sex determining factors and gene deterioration resulting in heterochromatinization of the long arms, followed by structural rearrangements.—The homology of the two sex chromosomes requires limited dosage compensation which is achieved either as in Drosophila by modifier genes or by accumulation on the short arm of the X, only of female determining factors which do not require dosage compensation.     

Insect sex chromosomes

The two X chromosomes in tetraploid spermatogonial cells from Gryllotalpa fossor respond differentially to the production of chromatid aberrations by ³H-uridine (³H-U). As in diploid female somatic cells, only the euchromatic arm of one X shows such aberrations. The equivalent arm of the other X and the constitutive arms of both Xs are not affected. This differential response of the homologous arms of the two Xs appears to be due to a facultative heterochromatinization of one of them. It is suggested that an imprinting process, which has been assumed to occur during fertilization in other cases of X-inactivation, may not be necessary for the differential regulation of two X chromosomes in this case.     

Stability of a multiple X chromosome system and associated B chromosomes in birch aphids (Euceraphis spp.; Homoptera: Aphididae)

Autosomal dissociations are a common feature of aphid karyotype evolution, but multiple X chromosome systems are rare. Birch-feeding aphids of the genus Euceraphis, however, have X₁X₂O males as a general rule, X₁ being always much larger than X₂. Only one species has XO males, and this condition appears to be secondary. Most Euceraphis karyotypes also have one or more, usually heterochromatic, elements that occur in the same numbers in both males and females, yet behave like X chromosomes at male and female meiosis I. They appear to be supernumerary, non-functional X chromosomes, although showing greater within-species stability in size and number than typical B chromosomes. Euceraphis gillettei forms a separate group within the genus and feeds on alders (Alnus species), yet has a similar system, and the two most closely related genera, Symydobius and Clethrobius, also have additional chromosomal elements possibly representing non-functional X chromosomes. Thus the multiple X chromosome system in these aphids seems to be a primitive condition.     

Selective differential staining of sister chromatids of the facultative heterochromatic X chromosome in the female mouse

Selective differential staining of sister chromatids for the facultative heterochromatic X chromosome in the female mouse has been achieved by the combination of two differential staining techniques; one for the heterochromatic X chromosome and the other for sister chromatids. Thermal hypotonic treatment moderately destroyed the chromosome structure except for the heterochromatic X in BrdU labelled metaphase cells, resulting in the selective sister chromatid differentiation of this X with Giemsa stain. This technique enables us to know the exact frequency of the spontaneous sister chromatid exchanges in the heterochromatic X without using ³H-TdR labelling for detecting the late DNA replication. The results indicate that the sister chromatid exchange frequency of the heterochromatic X chromosome is not affected by its late DNA replication during S phase, or by the genetic inactivation and the resulting heterochromatinization.     

A complex sex-chromosome system in the hare-wallaby Lagorchestes conspicillatus Gould

Among specimens of the spectacled hare-wallaby Lagorchestes conspicillatus Gould (Marsupialia, family Macropodidae) 4 males had 15 chromosomes and 2 females 16 chromosomes. The sex chromosomes are X₁X₁X₂X₂ in the female and X₁X₂Y in the male, the Y being metacentric and both X chromosomes are acrocentric. In about 96% of sperm mother cells at meiosis the sex chromosomes form a chain trivalent and in more than 99% of these this orients convergently so that the X₁ and X₂ move to the same pole. Evidence is presented that L. conspicillatus has evolved from a form with 22 chromosomes including a small X and a minute Y. Autoradiographic studies show that the proximal fifth of the X₁ chromosome replicates late. This is probably the ancestral X chromosome which has been translocated to an autosome. The fate of the original Y is obscure but an hypothesis is proposed that it forms the centromeric region of the Y. A single male had 14 chromosomes and was heterozygous for a translocation involving the centric fusion of two acrocentric autosomes. In about 30% of sperm mother cells the autosomal trivalent did not disjoin regularly but, despite this, all secondary spermatocytes observed at metaphase 2 had balanced complements of chromosomes. It is assumed that unbalanced secondary spermatocytes died before reaching metaphase.     

The cytogenetic systems of grasshoppers and locusts

The australian plague locust (2n=23 male, 24 female) is distinctive in possessing three pairs of two-armed, short autosomes (S₉, S₁₀ and S₁₁). In two of these pairs (S₉, S₁₀) these arms are a constant feature but in the shortest (S₉) pair most individuals are either heterozygous for them or else are homozygous telocentric. Coupled with this five of the heterozygous individuals give evidence of occasional short-arm detachment.—In all the S-pairs the shorter of the two arms is invariably heterochromatic in character and in the S₉ and S₁₁ shows a bi- or tri-partite sub-structure which suggests they may have originated by tandem duplication. — Three of the other autosomes (L₂, M₃ and M₆) also have small heterochromatin(het)-blocks associated with them. At first meiotic prophase these frequently associate with the univalent X chromosome which itself displays an unconventional pattern of allocycly, its centric end appearing negatively heteropycnotic from leptotene through diplotene.—At metaphase I the het-blocks on the telocentric autosomes sometimes transform into swollen, negatively heteropycnotic, segments equivalent in appearance to that shown by the entire X at this stage. It is suggested that these puff-like structures represent an inter-chromosomal position effect conditional upon prior X/A het-association at first prophase.     

The grasshopper X chromosome

The X chromosome can be identified with the light microscope throughout all stages of the gonial cell cycle (including interphase) in the grasshopper Brachystola magna. At gonial mitotic stages the X chromosome gives the appearance of being undercondensed or negatively heteropycnotic. At interphase the X projects out from the body of the nucleus. — Examination with the electron microscope reveals that the X is compartmentalized at least two gonial cell cycles prior to the entry of the cells into meiotic prophase. The membrane layers that envelope the X chromatin at interphase remain associated with the X chromosome throughout gonial mitotic stages providing the ultrastructural basis for the apparent negative heteropycnosis observed with the light microscope. — The X chromosome is inactive in RNA synthesis during gonial mitotic stages but is hyperactive in RNA synthesis when compared to autosomes at gonial interphase. — X chromosome condensation which reaches its maximum at premieotic interphase is initiated at or prior to the pre-pentultimate gonial division.     

Chromosomal segregational mechanisms in ant-lions (Myrmeleontidae,Neuroptera)

In a single male specimen of Myrmeleon mexicanum Banks the sex chromosomes, normally X and Y, were replaced by what appeared to be X¹X² and Y. These segregated as expected on that interpretation in only half of the spermatocytes — in the other half, one X and the Y segregated from the other X. This atypical segregation is explicable on the assumption that one of the supposed Xs is a supernumerary, not a sex chromosome, and the diploid complement of the male comprises six pairs of autosomes plus a supernumerary and the X and Y sex chromosomes. The orientation of the X chromosomes at first metaphase was variable: kinetochoric activity may be localized midway the length of the chromosome, as in gonial mitosis, or terminally. Comparative study of three congeneric species, seven of Brachynemurus, one of Psammoleon, and one of Vella showed normal segregation in all, and no evidence for secondary kinetochoric activity. In nine of the species studied one pair of autosomes was unconjoined at first metaphase in 0.3%–1.2% of primary spermatocytes. These autosomes segregated precociously with the sex chromosomes in the central unit of the spindle. In one exceptional male of Brachynemurus hubbardi Currie all first meiotic metaphases showed this behavior, and a compound X¹X²/Y¹Y² system was thus simulated. Bivalent formation replaced distance segregation of sex chromosomes in 0.4%–3.2% of the spermatocytes in seven of the thirteen species studied. These sex-bivalents frequently displayed partial or complete failure in congression.     

A developmental study of constitutive heterochromatin in Microtus agrestis

In the vole, Microtus agrestis, the constitutive heterochromatin is largely restricted to the giant sex chromosomes but varies in its degree of condensation in various cell types. In the cleavage embryos and fibroblasts it formed one or two long and extended heterochromatic fibers, in hepatocytes it formed two large and diffuse masses and in neurons, spermatogonia and oogonia it formed two large and compact masses. The basic patterns of all differentiated cells were essentially unchanged throughout development.—At all stages of development and in cells of all types, mitotic nuclei displayed two large heteropycnotic chromosomes in prophase and persistent condensation in telophase. Apposition and delayed separation of chromatids of the giant chromosomes was also observed in metaphase and anaphase, respectively. During the first meiotic prophase of spermatocytes and oocytes, the giant chromosomes were also heteropycnotic.—The results strongly suggest that constitutive heterochromatin is localized in the same chromosomes throughout development and represents a specific entity.     

A supernumerary chromosome with an accumulation mechanism in the lecanoid genetic system

Summary The supernumerary chromosomes of a mealy bug,Pseudococcus obscurus Essig are heterochromatic but show a variable heteropycnosis. In the female, they are weakly heteropyonotic in most tissues, but in a few tissues the individual supernumeraries form striking chromocenters. At oogenesis, they remain unassociated and divide equationally during the first division; during the second, they pair and disjoin. Pairing is usually accomplished by twos so that an unpaired supernumerary is found whenever an odd number, or only one, is present; the unpaired entity is twice as likely to go to the second polar body as to the egg.The normal spermatogenesis in the mealy bugs is a highly modified meiosis in which the paternal heterochromatic set is eliminated from the genetic continuum; during this sequence the supernumeraries are fully heterochromatic up until late prophase I. They then undergo a sharp change in pycnosis and become negatively heteropycnotic. In the second meiotic division they usually segregate with the maternal euchromatic set. Their behavior during spermatogenesis thus becomes an accumulation mechanism since an unreduced number, or nearly that, is transmitted by the males.The variable behavior of the supernumeraries affords further insight into the problem of heterochromatization in the mealy bugs.The supernumeraries may have originated from fragments followed by subsequent duplications. The accumulation mechanism may have been an important factor in their establishment.In genetic systems in which the supernumeraries have an accumulation mechanism, an elimination mechanism might evolve to stabilize the number of supernumeraries. Such elimination mechanisms are known for other genetic systems but have not yet been developed in this mealy bug.The material in this paper is part of a dissertation submitted to the graduate school of the University of California in partial satisfaction of the requirements for the degree of Doctor of Philosophy. This work was supported in part by a National Science Foundation Grant (G-9772) to ProfessorSpencer W. Brown.Predoctoral Trainee in Genetics, National Institutes of Health, 1960–1961.     

First report on C-banding,fluorochrome staining and NOR location in holocentric chromosomes of Elasmolomus (Aphanus) sordidus Fabricius, 1787 (Heteroptera,Rhyparochromidae)

In spite of various cytogenetic works on suborder Heteroptera, the chromosome organization, function and its evolution in this group is far from being fully understood. Cytologically, the family Rhyparochromidae constitutes a heterogeneous group differing in chromosome numbers. This family possesses XY sex mechanism in the majority of the species with few exceptions. In the present work, multiple banding techniques viz., C-banding, base-specific fluorochromes (DAPI/CMA₃) and silver nitrate staining have been used to cytologically characterize the chromosomes of the seed plant pest Elasmolomus (Aphanus) sordidus Fabricius, 1787 having 2n=12=8A+2m+XY. One pair of the autosomes was large while three others were of almost equal size. At diplotene, C-banding technique revealed, that three autosomal bivalents show terminal constitutive heterochromatic bands while one medium sized bivalent was euchromatic. Microchromosomes (m-chromosomes) were positively heteropycnotic. After DAPI and CMA₃ staining, all the autosomal bivalents showed equal fluorescence, except CMA₃ positive signals, observed at both telomeric heterochromatic regions of one medium sized autosomal bivalent. Silver nitrate staining further revealed that this chromosome pair carries Nucleolar Organizer Regions (NORs) at the location of CMA₃ positive signals. The X chromosome showed a thick C-band, positive to both DAPI /CMA₃ while Y, otherwise C-negative, was weakly positive to DAPI and negative to CMA₃, m-chromosomes were DAPI bright and CMA₃ dull.     

Meiotic differences between three triatomine species (Hemiptera,Reduviidae)

We have found the following differences in the male meiosis among three triatomine species: (1) The three largest autosomal bivalents ofTriatoma infestans are heterochromatic.Rhodnius prolixus has two autosomal bivalents with heterochromatic blocks.Triatoma rubrovaria does not show any heteropycnotic autosomes. (2) Sex chromosomes inT. infestans form a chromocenter. At early prophase terminal associations are seen between sex chromosomes inT. rubrovaria, and they maintain a close association until diakinesis. An intimate association between the X and Y chromosomes is observed during early prophase inR. prolixus, but a distant association is maintained by the sex chromosomes at diffuse and diplotene stages in this species. (3) Polyploid nuclei of the nutritive cells are quite distinct. Numerous chromocenters of different shapes and sized are seen in those ofT. infestans. InT. rubrovaria one chromocenter having two positively heteropycnotic elements is observed surrounded by homogeneous chromatin. Only one compact chromocenter is found amongst unevenly distributed chromatin, inR. prolixus.