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.     

Asymmetrically heteropycnotic X chromosomes in the grasshopper Melanoplus femur-rubrum

In short-horned grasshoppers the X chromosome is negatively heteropycnotic in at least some of the spermatogonia but is positively heteropycnotic (heterochromatic) during prophase I of spermatogenesis. In tetraploid (4n) spermatocytes in prophase I the two Xs present have so far been reported always to be heterochromatic and unpaired. In several males of the grasshopper Melanoplus femur-rubrum (Acrididae), however, some of the 4n primary spermatocytes contained one heterochromatic X (X_h) and one euchromatic X (X_e). This asymmetry of heteropycnosis (AH) was first observed in grasshoppers by M.J.D. White who observed it, however, only in 4n spermatogonia in which one X was negatively heteropycnotic and the other was isopycnotic (euchromatic). In M. femur-rubrum the AH involved both positive and negative heteropycnosis. In some of the 4n cells both Xs were heterochromatic and these cells were usually present in small groups but sometimes comprised whole cysts. The 4n cells with X_e+X_h always comprised several whole cysts in a follicle or whole follicles. The origin of the two cell types may be explained by assuming that heteropycnosis originated prior to the origin of the cysts, that when, as a result of polyploidization, two Xs were present in a 4n cell only one became heteropycnotic, and that the state of the X (X_h vs. X_e) usually persisted into meiosis. The 4n primary spermatocytes exhibiting AH divided regularly during the first meiotic division but following telophase I they usually failed to undergo cytokinesis and to enter the second meiotic division. The available evidence suggests that the arrest of these cells is the result of the genetic activity of the X_e in those stages in which the X is usually heterochromatic and genetically inactive. The relationship between AH and facultative heterochromatinization is discussed and it is concluded that the present observations put into question the validity of previous models attempting to explain facultative heterochromatinization (including that of the X in the mammalian female).     

The human inactivated X chromosome folds in early metaphase,prometaphase, and prophase

Summary The inactivated X chromosome has a site of unusually frequent folding in region Xq1, whereas a fold in Xq1 is uncommon on the active X. We investigated the pattern of X chromosome folding in high-resolution GTG- and RBG-stained preparations from four women. In early metaphase cells, slightly more than 50% of late-replicating Xs folded at Xq1Xq21, compared with about 6% of early replicating Xs. The late-replicating X folded in about 80% of prometaphase cells; the early, in only about 14% of these cells. And the latereplicating X folded in 19 of 20 prophase cells. Occasionally, one X had an omega-shaped loop or apparent physical connection between Xq13 and Xq21.1. It is possible that a segment of Xq1 never completely uncoils and may help to provide continuity for the Barr body from one interphase to the next.     

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.     

Meiotic chromosomes and nucleolar behavior in testicular cells of the grassland spittlebugs Deois flavopicta, Mahanarva fimbriolata and Notozulia entreriana (Hemiptera, Auchenorrhyncha)

Spittlebugs annually infest pastures and cause severe damage, representing a serious problem for the tropical American beef cattle industry. Spittlebugs are an important biotic constraint to forage production and there is a lack of cytogenetic data for this group of insects. For these reasons, we conducted this work, in which the spermatogenesis and nucleolar behavior of Deois flavopicta, Mahanarva fimbriolata and Notozulia entreriana were studied. The males possessed testes in the shape of a "bunch of grapes"; a variable number of testicular lobes per individual and polyploid nuclei composed of several heteropycnotic bodies. A heteropycnotic area was located in the periphery of the nucleus (prophase I); the chiasmata were terminal or interstitial; metaphases I were circular or linear and anaphase showed late migration of the sex chromosome. The chromosome complement had 2n = 19, except for N. entreriana (2n = 15); the spermatids were round with heteropycnotic material in the center and elongated with conspicuos chromatin. The analysis of testes after silver nitrate staining showed polyploid nuclei with three large and three smaller nucleolar bodies. Early prophase cells had an intensely stained nucleolar body located close to the chromatin and another less evident body located away from the chromatin. The nucleolar bodies disintegrated during diplotene. Silver staining occurred in two autosomes, in terminal and subterminal locations, the latter probably corresponding to the nucleolus organizer regions (NORs). The spermatids were round with a round nucleolar body and silver staining was observed in the medial and posterior region of the elongated part of the spermatid head.     

DNA amount of X and B chromosomes in the grasshoppers Eyprepocnemis plorans and Locusta migratoria

We analyzed the DNA amount in X and B chromosomes of 2 XX/X0 grasshopper species (Eyprepocnemis plorans and Locusta migratoria), by means of Feulgen image analysis densitometry (FIAD), using previous estimates in L. migratoria as standard (5.89 pg). We first analyzed spermatids of 0B males and found a bimodal distribution of integrated optical densities (IODs), suggesting that one peak corresponded to +X and the other to -X spermatids. The difference between the 2 peaks corresponded to the X chromosome DNA amount, which was 1.28 pg in E. plorans and 0.80 pg in L. migratoria. In addition, the +X peak in E. plorans gave an estimate of the C-value in this species (10.39 pg). We next analyzed diplotene cells from 1B males in E. plorans and +B males in L. migratoria (a species where Bs are mitotically unstable and no integer B number can be defined for an individual) and measured B chromosome IOD relative to X chromosome IOD, within the same cell, taking advantage of the similar degree of condensation for both positively heteropycnotic chromosomes at this meiotic stage. From this proportion, we estimated the DNA amount for 3 different B chromosome variants found in individuals from 3 E. plorans Spanish populations (0.54 pg for B1 from Saladares, 0.51 pg for B2 from Salobre?a and 0.64 for B24 from Torrox). Likewise, we estimated the DNA amount of the B chromosome in L. migratoria to be 0.15 pg. To automate measurements, we wrote a GPL3 licensed Python program (pyFIA). We discuss the utility of the present approach for estimating X and B chromosome DNA amount in a variety of situations, and the meaning of the DNA amount estimates for X and B chromosomes in these 2 species.     

The cytogenetic structure of Tasmanian populations of Phaulacridium vittatum

In 8 out of 20 Tasmanian populations of Phaulacridium vittatum from 0.3-11.0 percent of the males carried a single supernumerary chromosome. In such males the X and B univalents are both heteropycnotic at first prophase of male meiosis and associate with another in a non-homolgous manner in about two-thirds of the diplotene cells examined. In all 56 B-containing individuals studied, however, these associations lapse by first metaphase and the X and the B move at random with respect to one another at first anaphase. The supernumerary in this species is stable and only 5 of the 56 individuals with supernumeraries showed evidence of B-chromosome non-disjunction in the pre-meiotic mitoses. Since there was no other evidence for the loss or gain of supernumeraries in the male line it is clear that B-transmission is regular in the males of this species. There were significant differences between population with respect to mean cell chiasma frequency but there was no significant effect of the B-chromosome on this metric. Additionally a comparison of mean cell chiasma frequency in follicles with and without supernumeraries from a mosaic individual shows no significant difference.     

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.     

B-chromosome behaviour in Phaulacridium vittatum

Nine individuals of Phaulacridium vittatum in a single population sample of 1250 males collected at Crookwell, N. S.W. contained a single supernumerary chromosome. One further individual had two B-chromosomes. The supernumerary in question was larger than any of the standard set and was distinguishable from them at all stages of mitosis and meiosis. Like the X-univalent the B-chromosome was heteropycnotic at the onset of meiosis but differed from it in size, structure and behaviour. During first prophase single supernumeraries were frequently associated with the X in a non-homologous fashion as a consequence of their precocity. All such associations lapsed before first metaphase and the X and the B moved at random with respect to one another at first anaphase. In the one individual with two supernumeraries the two B-chromosomes showed regular pairing and segregated in a conventional manner. In all these respects the Crookwell supernumerary differed markedly from a morphologically identical B-chromosome present in a population of the same species from Hobart, Tasmania studied by Jackson and Cheung in 1967. Whether these differences in the behaviour of the B-chromosome in the two populations determines the higher frequency of the supernumerary in Hobart (11.3%) as compared with Crookwell (0.8%) remains to be resolved.     

Cytogenetics studies in thirteen brazilian species of Phaneropterinae (Orthoptera: Tettigonioidea: Tettigoniidae): main evolutive trends based on their karyological traits

The thirteen species of Phaneropterinae here studied can be arranged in four different groups according to their basic karyological traits. All of them share the same kind of chromosomal sex determining mechanism with X0 (male sign) and XX(female sign). The X chromosome differs among species and always appears heteropycnotic during prophase I, it is the largest in the set and segregates precociously during anaphase I. Among the species, the karyotypes varies in fundamental number between 31 to 21. The meaning of these significant changes in the karyotypes in relation to the phylogeny within some large taxonomic group of species is discussed.     

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.     

Replication of autosomal heterochromatin in man

Summary In interphase nuclei of leukocytes and oral mucosa cells of normal human males and f males, two types of heterochromatin can he distinguished according to their location in the nucleus. Firstly, nucleolus-associated heterochromatin which consists of one large mass of autosomal segments surrounding the nucleolus, or several large masses if there appears to be more than one nucleolus in the same nucleus. Secondly, scattered heterochromatin composed of a large number of positively heteropycnotic bodies scattered throughout the nucleus and not directly associated with the nucleolus. The correspondence of this type of heterochromatin with chromosome segments is obtained at late prophase where several positively heteropycnotic regions belonging to the autosomes are found scattered throughout the nucleus.In human females sex-chromatin is present in addition to these two types. In leukocytes the sex-chromatin cannot be easily identified due to the large size and number of the scattered heterochromatic bodies, but in oral mucosa cells such a distinction is more easily achieved due to the smaller amount of autosomal heterochromatin.Nucleolus-associated and scattered heterochromatin from leukocytes of both sexes synthesized their DNA at a different period of time from the euchromatin. The asynchrony of replication observed in the heterochromatin at interphase is in agreement with the asynchrony between autosomes and within autosomes described by many authors at metaphase. This does not mean, however, that every segment or chromosome found replicating asynchronously at metaphase contains necessarily heterochromatin.Dedicated to Professor H. Bauer on the occasion of his 60th birthday. — This investigation was supported by a research grant to A. Lima-de-Faria from the Swedish Natural Science Research Council.     

Cytological evidence that the Sxr fragment of XY,Sxr mice pairs homologously at meiotic prophase with the proximal testis-determining region

Self-pairing of the Y chromosome at prophase of meiosis in XY,Sxr male mice appears to take place in many cells to the exclusion of pairing between the Y and the X. This phenomenon offers an explanation for the high level of X-Y separation seen in these males at prophase of meiosis, additional separations being evident, however, when metaphase I (MI) cells are examined. A minority of prophase cells show the Y paired both autologously and with a sub-terminal region of the X which could be the normal pairing region. The balloon-like configurations observed when self-pairing occurs suggest that the distal Sxr fragment is inverted on the Y chromosome of Sxr carrier males in relation to the normal proximal testis-determining (Td)-containing region.     

Chromosome systems in the eriococcidae (Coccoidea Homoptera)

Spermatogenesis is described in two eriococcid species and the observations are compared to those previously reported. In Gossyparia spuria the diploid chromosome number is 28 in both males and females. In the female all the chromosomes are euchromatic. In most male tissues 14 of the chromosomes are euchromatic (E) and 14 are heterochromatic (H). Prior to the first meiotic division in males the number of H chromosomes was reduced. During prophase I all the cells showed 14 E chromosomes and from 1 to over 9 H chromosomes. The range of chromosome numbers in metaphase I was similar to that in prophase I. All the chromosomes divided in anaphase I, and, following differential uncoiling at interkinesis, the E and H groups of chromosomes segregated from each other at anaphase II. Only the E groups formed sperm. The presence of a variable number of H chromosomes and a haploid number of E chromosomes in spermatogenesis suggested the presence of the multiple-D variant of the Comstockiella chromosome system. In this system some of the H chromosomes become euchromatic prior to prophase I of spermatogenesis and pair with their E homologues. All the remaining H chromosomes are thus univalents, while among the E elements, some are univalents and the rest are bivalents. The observed reduction in the number of H chromosomes in the first meiotic division which was previously attributed to pairing among the H chromosomes, is now interpreted to be the result of the return of some of the H chromosomes to a euchromatic state and to their subsequent pairing with their E homologues. Spermatogenesis in Eriococcus araucariae was similar to that of G. spuria except that the reduction in the number of H chromosomes was not as extensive. The chromosome systems of the two species are compared to those of other eriococcids and the differences are briefly discussed.Supported by grant GB1585 from the National Science Foundation, Washington, D. C.     

Destruction of specific heterochromatic chromosomes during spermatogenesis in the Comstockiella chromosome system (Coccoidea: Homoptera)

In male coccids with the Comstockiella chromosome system, the set of chromosomes of paternal orgin becomes heterochromatic (H) during early cleavage. Just prior to prophase I of spermatogenesis, some of the H chromosomes are destroyed; the rest are eliminated following meiosis. In this report a Comstockiella sequence is described from Dactylopius opuntiae (2n=10) in which one chromosome pair is about three times longer than the others. During prophase I the number of small H chromosomes present varied from cyst to cyst, but the long H chromosome was present in every cyst. These observations provide the best evidence to date that in the Comstockiella system a particular chromosome may always escape destruction. An analysis of Kitchin's (1975) data about the frequency of prophase I cysts with 1–4 H chromosomes in three species of Parlatoria with 2n = 8 suggested that in these species chromosomes of similar size may have very different probabilities of being destroyed. Evidence that in other species with the Comstockiella system a particular H chromosome is always retained is reviewed, and the possibility that in Ancepaspis tridentata the variation in the length of the H chromosome retained is due to the partial destruction of the longest chromosome is discussed.     

First evidence of sex chromosome pre-reduction in male meiosis in the Miridae bugs (Heteroptera)

The karyotype and male meiosis of Macrolophus costalis Fieber (Insecta, Heteroptera, Miridae) were studied using C-banding, AgNOR-banding and DNA sequence specific fluorochrome staining. The chromosome formula of the species is 2n = 28(24+X1X2X3Y). Male meiotic prophase is characterized by a prominent condensation stage. At this stage, two sex chromosomes, "X" and Y are positively heteropycnotic and always appeared together, while in autosomal bivalents homologous chromosomes were aligned side by side along their entire length, that is, meiosis is achiasmatic. At metaphase I, "X" and Y form a pseudobivalent and orient to the opposite poles. At early anaphase I, the "X" chromosome disintegrates into three separate small chromosomes, X1, X2, and X3. Hence both the autosomes and sex chromosomes segregate reductionally in the first anaphase, and separate equationally in the second anaphase. This is the first evidence of sex chromosome pre-reduction in the family Miridae. Data on C-heterochromatin distribution and its composition in the chromosomes of this species are discussed.     

Meiotic silencing and fragmentation of the male germline restricted chromosome in zebra finch

During male meiotic prophase in mammals, X and Y are in a largely unsynapsed configuration, which is thought to trigger meiotic sex chromosome inactivation (MSCI). In avian species, females are ZW, and males ZZ. Although Z and W in chicken oocytes show complete, largely heterologous synapsis, they too undergo MSCI, albeit only transiently. The W chromosome is already inactive in early meiotic prophase, and inactive chromatin marks may spread on to the Z upon synapsis. Mammalian MSCI is considered as a specialised form of the general meiotic silencing mechanism, named meiotic silencing of unsynapsed chromatin (MSUC). Herein, we studied the avian form of MSUC, by analysing the behaviour of the peculiar germline restricted chromosome (GRC) that is present as a single copy in zebra finch spermatocytes. In the female germline, this chromosome is present in two copies, which normally synapse and recombine. In contrast, during male meiosis, the single GRC is always eliminated. We found that the GRC in the male germline is silenced from early leptotene onwards, similar to the W chromosome in avian oocytes. The GRC remains largely unsynapsed throughout meiotic prophase I, although patches of SYCP1 staining indicate that part of the GRC may self-synapse. In addition, the GRC is largely devoid of meiotic double strand breaks. We observed a lack of the inner centromere protein INCENP on the GRC and elimination of the GRC following metaphase I. Subsequently, the GRC forms a micronucleus in which the DNA is fragmented. We conclude that in contrast to MSUC in mammals, meiotic silencing of this single chromosome in the avian germline occurs prior to, and independent of DNA double strand breaks and chromosome pairing, hence we have named this phenomenon meiotic silencing prior to synapsis (MSPS).     

The behaviour of a multiple sex chromosome system in Dundocoris flavilineatus (Heteroptera: Aradidae: Carventinae) that originated by autosome-sex chromosome fusion

The nominate subspecies of Dundocoris flavilineatus Jacobs occurs in indigenous evergreen forests over a wide area in KwaZulu-Natal and the Eastern Cape Province of South Africa. It has a chromosome number of 2n male = 28XY, which is the ancestral number for the genus. D. flavilineatus ndabeniensis, which comprises an isolated sibling population at Ndabeni forest in northern KwaZulu-Natal, possesses a multiple sex chromosome system, presumably a X1X2Y system and has a chromosome number of 2n male = 27X1X2Y. The system probably originated when an autosome and the Y-chromosome of the 28XY karyotype fused. In contrast to the situation previously described in the XY1Y2 system of D. nodulicarinus the autosomal and original Y-chromosome parts of the neo-Y chromosome seem to have a reciprocal influence on each other in terms of structure and staining intensity during prophase 1. The autosomal part of the neo-Y adopts a granulate, heteropycnotic, linear structure while the original Y part is less globular than usual in structure. The neo-X chromosome (= X2) behaves like, and stays isopycnotic with the autosomes. It is connected to the neo-Y by terminal association--probably a terminal chiasma. The sex chromosome system is post-reductional and a sex chromosome trivalent is present in all metaphase II cells. The origin and behaviour of the neo-X1X2Y sex chromosome system in D. flavilineatus ndabeniensis are described, discussed, illustrated with photomicrographs and compared to the XY1Y2 system in D. nodulicarinus. Idiograms of the karyotypes of the two subspecies of D. flavilineatus are also presented.     

Is late replication of the inactive X chromosome irreversible in all cells of mammals?

The X chromosomes of the female bandicoot rat (Nesokia indica) were 3H-thymidine labeled during two consecutive cell divisions to determine if all of the same segments of the "triplicate-type" X chromosome of these animals always replicated late. In 87% of metaphases examined the findings were as expected. One entire X chromosome (X1) and the long arm of the other X (X2) synthesized DNA late in the S phase in both divisions. However, in the other 13% of the metaphases, the late-replicating and presumably genetically inactive short-arm segments of the X1 chromosome had completed DNA synthesis by the time it entered the late-S phase of the second cycle. Thus, in this species, some cells appear to have an X chromosome of which the facultative heteropycnotic segment condenses in one cell cycle but becomes euchromatic in the subsequent cell cycle. Although this appears at first to be inconsistent with the generally accepted pattern of X-chromosome condensation and genetic inactivation, it may represent an instance of evolutionary specialization for an as yet unexplained reason. It is also possible that closer analysis of other mammalian species with composite sex chromosomes or methods equally suitable for this type of analysis will reveal other instances where a minority of the somatic cells of females do not follow the predictions of the Lyons hypothesis completely.     

The influence of the Robertsonian translocation Rb(X.2)2Ad on anaphase I non-disjunction in male laboratory mice

A Robertsonian translocation in the mouse between the X chromosome and chromosome 2 is described. The male and female carriers of the Rb(X.2)2Ad were fertile. A homozygous/hemizygous line was maintained. The influence of the X-autosomal Robertsonian translocation on anaphase I non-disjunction in male mice was studied by chromosome counts in cells at metaphase II of meiosis and by assessment of aneuploid progeny. The results conclusively show that the inclusion of Rb2Ad in the male genome induces non-disjunction at the first meoitic division. In second metaphase cells the frequency of sex-chromosomal aneuploidy was 10.8%, and secondary spermatocytes containing two or no sex chromosome were equally frequent. The Rb2Ad males sired 3.9% sex-chromosome aneuploid progeny. The difference in aneuploidy frequencies in the germ cells and among the progeny suggests that the viability of XO and XXY individuals is reduced. The pairing configurations of chromosomes 2, Rb2Ad and Y were studied during meiotic prophase by light and electron microscopy. Trivalent pairing was seen in all well spread nuclei. Complete pairing of the acrocentric autosome 2 with the corresponding segment of the Rb2Ad chromosome was only seen in 3.2% of the cells analysed in the electron microscope. The pairing between the X and Y chromosome in the Rb2Ad males corresponded to that in males with normal karyotype. Reasons for sex-chromosomal non-disjunction despite the normal pairing pattern between the sex chromosomes may be seen in the terminal chiasma location coupled with the asynchronous separation of the sex chromosomes and the autosomes.(ABSTRACT TRUNCATED AT 250 WORDS)