Replication of euchromatin and heterochromatin in a mealybug

Asynchronous DNA replication of euchromatic (E) and heterochromatic (H) chromosomes and heterochromatic B chromosomes (B) were studied in the mealybug, Pseudococcus obscurus Essig (Homoptera: Coccoidea). The study was carried out on mycetocytes of adult females and on spermatocytes of mid-second instar males by employing tritiated thymidine labeling and autoradiography. In the mycetocytes the incorporation of the labeled thymidine began and ended later in the B's than in the E chromosomes. The S period was found to be about 21 hours. The DNA replication of the E chromosomes occupied about 86% of the S period and that of the B's 33%; during 18% of the mid-S period the replication of the two types of chromosomes overlapped. In the meiotic S period of the spermatocytes, the DNA of the E chromosomes started to replicate earlier than that of the H chromosomes and the B's, but the replication of the E chromosomes, the H chromosomes, and the B's overlapped. The H chromosomes completed their replication much later than the E chromosomes and slightly later than the B's.Supported by grants GB 1585 and GB 6745 to Dr. Uzi Nur from the National Science Foundation, Washington, D. C.Part of a thesis submitted to the University of Rochester in partial fulfillment of the requirements for the degree of Doctor of Philosophy.     

Nonreplication of heterochromatic chromosomes in a mealy bug,Planococcus citri (Coccoidea: Homoptera)

In males of mealy bugs with the lecanoid chromosome system, the paternal set of chromosomes becomes heterochromatic in early embryogeny. In males of the mealy bug, Planococcus citri, the heterochromatic (H) set in testis sheath cells and in most of the oenocytes apparently did not replicate while the euchromatic (E) set was undergoing several cycles of endoreplication. In third instar males, testis sheath cells in endoanaphase and endotelophase exhibited 5H and either 40 or 80E chromosomes. The increase in the number of E chromosomes was attributed to the replication of only the E chromosomes. Oenocytes of third instar males had 0, 5, or 10H chromosomes and from 10 to 240E chromosomes. The oenocytes with 5H chromosomes had a mean of 50.8E chromosomes, and those with 10H chromosomes had a mean of 155.6E chromosomes. Nuclear and cell fusion was considered as a means of producing the various numbers of H and E chromosomes in oenocytes, and it was concluded that although nuclear fusion probably took place, the differences between the number of H and E chromosomes was at least in part due to replication of only the E chromosomes. The size of the H chromosomes was about the same in all the testis sheath cells and the oenocytes irrespective of the level of endopolyploidy for the E set. These H chromosomes apparently did not increase in polyteny, because they were only about half the size of the H chromosomes in prophase I of spermatogenesis. The significance of the nonreplication of the H set and the control of nonreplication are briefly discussed.This study was aided by a grant (GB-1585) from the National Science Foundation, Washington, D.C.     

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.     

Histone H3 lysine 9 acetylation pattern suggests that X and B chromosomes are silenced during entire male meiosis in a grasshopper

The facultative heterochromatic X chromosome in leptotene spermatocytes of the grasshopper Eyprepocnemis plorans showed marked hypoacetylation for lysine 9 in the H3 histone (H3-K9) with no sign of histone H2AX phosphorylation. Since H3-K9 hypoacetylation precedes the meiotic appearance of phosphorylated H2AX (gamma-H2AX), which marks the beginning of recombinational DNA double-strand breaks (DSBs), it seems that meiotic sex-chromosome inactivation (MSCI) in this grasshopper occurs prior to the beginning of recombination and hence synapsis (which in this species begins later than recombination). In addition, all constitutively heterochromatic chromosome regions harbouring a 180-bp tandem-repeat DNA and rDNA (B chromosomes and pericentromeric regions of A chromosomes) were H3-K9 hypoacetylated at early leptotene even though they will synapse at subsequent stages. This also suggests that meiotic silencing in this grasshopper might be independent of synapsis. The H3-K9 hypoacetylated state of facultative and constitutive heterochromatin persisted during subsequent meiotic stages and was even apparent in round spermatids. Finally, the fact that B chromosomes are differentially hypoacetylated in testis and embryo interphase cells suggests that they might be silenced early in development and remain this way for most (or all) life-cycle stages.     

Non-random segregation during anaphase II in an individual of Arcyptera tornosi (Bol.) (Orthoptera) heterozygous for three supernumerary heterochromatic segments

An individual of Arcyptera tornosi heterozygous for distal heterochromatic segments affecting M₆, S₁₀ and S₁₁ chromosomes has been analyzed during all the meiotic stages in order to establish the pattern of meiotic segregation in anaphase I and II. S-bivalents invariably show an equational separation during anaphase I and the anaphase II separation is non-random, both chromatids with heterochromatic segments often segregating to the same pole. Differences are significant if compared with the expected segregation. Some aspects of this particular chromosome behaviour are briefly discussed.     

Differential DNA synthesis in heterochromatic and euchromatic chromosome sets of Planococcus citri

In males of the mealy bug Planococcus citri, Nur (1966) counted five heterochromatic (H) and about 5, 10, 20, 40, or 80 euchromatic (E) chromosomes in testis sheath nuclei which were undergoing endomitosis. He suggested that the H chromosomes were not replicating and that the nuclei were becoming polyploid as a result of successive cycles of replication of only the E chromosomes. This hypothesis was tested using autoradiography with H³-thymidine to detect DNA synthesis and microspectrophotometric measurements of the Feulgen reaction in nuclei to detect quantitative changes in DNA. — The integrated absorbance of the whole nucleus and of the isolated clump of heterochromatic chromosomes (H body) in polyploid testis sheath nuclei were measured using the mechanical scanner of the CYDAC system. The absorbance of the H body was similar in all testis sheath nuclei examined and was not significantly different from the absorbance of a haploid set of H chromosomes measured after meiosis. The absorbance of the euchromatic component varied in different sheath nuclei, the values closely corresponding to the terms of the series 2c, 4c, 8c. This series is expected if the DNA in the E chromosomes is exactly doubled at each cycle of replication. — Autoradiographs showed that most labeled sheath nuclei had silver grains localized exclusively over euchromatin. With one exception, the remainder of the labeled nuclei had silver grains over both euchromatin and the H body. The observation that euchromatin was much more heavily labeled than the H body and that labeled H bodies occurred at a low frequency and only in the presence of labeled euchromatin suggests that the H body did not incorporate the label and that the silver grains over the H body were the result of -particles which originated in proximal euchromatin.     

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.     

What are the spermatocyte's requirements for successful meiotic division?

The consequences of error during meiotic division in spermatogenesis can be serious: aneuploid spermatozoa, embryonic lethality, and developmental abnormalities. Recombination between homologs is essential to ensure normal segregation; thus the spermatocyte must time division precisely so that it occurs after recombination between chromosomes and accumulation of the cell-cycle machinery necessary to ensure an accurate segregation of chromosomes. We use two systems to investigate meiotic division during spermatogenesis in the mouse: pharmacological induction of meiotic metaphase in cultured spermatocytes and transillumination-mediated dissection of stage XII seminiferous tubule segments to monitor progress through the division phase. By these approaches we can assess timing of acquisition of competence for the meiotic division phase and the temporal order of events as division proceeds. Competence for the meiotic division arises in the mid-pachytene stage of meiotic prophase, after chromosomes have synapsed and coincident with the accumulation of the cell-cycle regulatory protein CDC25C. The activity of both MPF and topoisomerase II are required. The earliest hallmarks of the division phase are nuclear envelope breakdown, followed by phosphorylation of histone H3 and chromosome condensation. These events are likely to be monitored by checkpoint mechanisms since checkpoint proteins can be localized in nuclei and DNA-damaging agents delay entry into the meiotic division phase. Understanding how the spermatocyte regulates its entry into the meiotic division phase can help clarify the natural mechanisms ensuring accurate chromosome segregation and preventing aneuploidy. J. Exp. Zool. (Mol. Dev. Evol.) 285:243-250, 1999.     

Histone modifications related to chromosome silencing and elimination during male meiosis in Bengalese finch

We report here that a germline-restricted chromosome (GRC) is regularly present in males and females of the Bengalese finch (Lonchura domestica). While the GRC is euchromatic in oocytes, in spermatocytes this chromosome is cytologically seen as entirely heterochromatic and presumably inactive. The GRC is observed in the cytoplasm of secondary spermatocytes, indicating that its elimination from the nucleus occurs during the first meiotic division. By immunofluorescence on microspreads, we investigated the presence of histone H3 modifications throughout male meiosis, as well as in postmeiotic stages. We found that the GRC is highly enriched in di- and trimethylated histone H3 at lysine 9 during prophase I, in agreement with the presumed inactive state of this chromosome. At metaphase I, dimethylated histone H3 is no longer detectable on the GRC and its chromatin is more faintly stained with DAPI. The condensed GRC is underphosphorylated at serine 10 compared to the regular chromosomes during metaphase I, being phosphorylated later at this site after the first meiotic division. From these results, we proposed that trimethylation of histone H3 at lysine 9 on the GRC chromatin increases during metaphase I. This hypermethylated state at lysine 9 may preclude the phosphorylation of the adjacent serine 10 residue, providing an example of cross-talk of histone H3 modifications as described in experimental systems. The differential underphosphorylation of the GRC chromatin before elimination is interpreted as a cytologically detectable byproduct of deficient activity of Aurora B kinase, which is responsible for the phosphorylation of H3 at serine 10 during mitosis and meiosis.     

Polymorphism involving heterochromatic segments in Metrioptera brachyptera

A complex pattern of polymorphism involving terminal heterochromatic segments on L₃ and L₄ chromosomes has been uncovered in eight populations of Metrioptera brachyptera. There are individuals in every population which carry reduced segments on one or both L₄'s. In six populations, enlarged heterochromatic segments have been encountered on the L₃ chromosomes in some individuals. The L₄ system is almost certainly stable although the frequency of L₄ karyotypes does not conform to a Hardy-Weinberg distribution in all populations. Stability of the L₃ polymorphism could not be ascertained. A reduction of L₄ heterochromatin leads to a significant rise both in mean cell chiasma frequency and between cell variance. The effect on chiasma frequency is transchromosomal. The normal pattern of strict chiasma localisation tends to be disrupted in germ lines which include modified L₄ chromosomes. There is a reduction in the number of proximal and distal chiasmata and an increase in the frequency of interstitial ones. It is proposed that the standard L₄ heterochromatin may function in conserving heterozygosity and promoting uniformity between parent and offspring. Partial removal may lead to an effective increase in recombination and produce a greater diversity of genotypes for selection to act upon.     

Genotypes affecting the condensation and transmission of heterochromtic B chromosomes in the mealybug Pseudococcus affinis

In male mealybugs (Pseudococcide: Homoptera) the set of chromosomes of paternal origin becomes heterochromatic (H) and genetically inactive in early embryogenesis. During spermatogenesis the two sets segregate and only the meiotic products with the euchromatic (E) set form sperm. Individuals of Pseudococcus affinis (Maskell) may carry a B chromosome (B) which is usually heterochromatic. During prophase I of spermatogenesis, however, the B becomes even less condensed than the E set and usually segregates with the E set. We have previously shown that natural populations of P. affinis contain genotypes that can reduce the rate of transmission (k) of Bs from more than 0.9 to less than 0.1. We now demonstrate that these genotypes suppress k either by enhancing or by preventing the decondensation of the B, which in turn affects the position of the B on the metaphase plate and its segregation. We also demonstrate that radiation-induced fragment of the B, and a piece of a B which has been translocated onto a piece of an H chromosome, retain their characteristic pattern of condensation and thus that the condensation of the B is not controlled by one or a few cis-acting centers or loci.     

C-banding and non-homologous associations

A chromosome complement formed by 16 autosomes and an Xy_p sex chromosome system was found in Epilachna paenulata Germar (Coleoptera: Coccinellidae). All autosomes were metacentric except pair 1 which was submetacentric. The X and the Y chromosomes were also submetacentric but the Y was minute. The whole chromosome set carried large paracentric heterochromatic C-segments representing about 15% of the haploid complement length. Heterochromatic segments associated progressively during early meiotic stages forming a large single chromocenter. After C-banding, chromocenters revealed an inner networklike filamentous structure. Starlike chromosome configurations resulted from the attachment of bivalents to the chromocenters. These associations were followed until early diakinesis. Thin remnant filaments were also observed connecting metaphase I chromosomes. Evidence is presented that, in this species, the Xy_p bivalent resulted from an end-to-end association of the long arms of the sex chromosomes. The parachute Xy_p bivalent appeared to be composed of three distinct segments: two intensely heterochromatic C-banded corpuscles formed the canopy and a V-shaped euchromatic filament connecting them represented the parachutist component. The triple constitution of the sex bivalent was interpreted as follows: each heterochromatic corpuscle corresponded to the paracentric C-segment of the X and Y chromosomes; the euchromatic filament represented mainly the long arm of the X chromosome terminally associated with the long arm of the Y chromosome. The complete sequence of the formation of the Xy_p bivalent starting from nonassociated sex chromosomes in early meiotic stages, and progressing through pairing of heterochromatic segments, coiling of the euchromatic filament, and movement of the heterochromatic corpuscles to opposite poles is described. These findings suggest that in E. paenulata the Xy_p sex bivalent formation is different than in other coleopteran species and that constitutive heterochromatic segments play an important role not only in chromosome associations but also in the Xy_p formation.     

Male and female segregation distortion for heterochromatic supernumerary segments on the S8 chromosome of the grasshopper Chorthippus jacobsi

The mode of inheritance of supernumerary segments located on three different chromosome pairs was investigated in controlled crosses with specimens of the grasshopper Chorthippus jacobsi. While extra segments located on chromosomes M₅ and M₆ showed Mendelian inheritance, that on S₈ did not. Thus, the two supernumerary heterochromatic chromosome segments located distally on the S₈ chromosome accumulated through non-Mendelian transmission through both sexes. The observed transmission patterns may be explained by gametic selection for spermatozoa carrying segmented S₈ chromosomes, in addition to meiotic drive for segmented S₈ chromosomes in heterozygous females. The significance of these findings for the maintenance of these polymorphisms in natural populations is discussed.by S.A. Gerbi     

Inverted meiosis and meiotic drive in mealybugs

In the males of lecanoid coccids, or mealybugs, an entire, paternally derived, haploid chromosome set becomes heterochromatic after the seventh embryonic mitotic cycle. In females, both haploid sets are euchromatic throughout the life cycle. In mealybugs, as in all homopteran species, chromosomes are holocentric. Holocentric chromosomes are characterized by the lack of a localized centromere and consequently of a localized kinetic activity. In monocentric species, sister chromatid cohesion and monopolar attachment play a pivotal role in regulating chromosome behavior during the two meiotic divisions. Both these processes rely upon the presence of a single, localized centromere and as such cannot be properly executed by holocentric chromosomes. Here we furnish further evidence that meiosis is inverted in both sexes of mealybugs and we suggest how this might represent an adaptation to chromosome holocentrism. Moreover, we reveal that at the second meiotic division in males a monopolar spindle is formed, to which only euchromatic chromosomes become attached. By this mechanism the paternally derived, heterochromatic, haploid chromosome set strictly segregates from the euchromatic one, and it is then excluded from the genetic continuum as a result of meiotic drive.Communicated by E.A. Nigg     

Molecular cytogenetic analysis of supernumerary heterochromatic segments in Rumex acetosa.

The dioecious plant Rumex acetosa shows intraspecific karyotype variation, caused by supernumerary heterochromatic segments or DAPI (4',6-diamidino-2 phenylindole)-bands at the ends of the short arms of three pairs of autosomes. A DNA sequence (RAE730) specific to the supernumerary heterochromatic segments was cloned and sequenced. RAE730 was about 730 bp and AT-rich (71% AT-content). Using fluorescence in situ hybridization (FISH), RAE730 was localized in the supernumerary DAPI-positive heterochromatic segments on several mitotic chromosomes and chromocenters in interphase nuclei, but not in the DAPI-bands of Y or B chromosomes. RAE730 was tandemly arranged in the genome, and the copy number varied between plants from 40000 to 304000 copies per 2C, corresponding to the relative amount of supernumerary heterochromatic segments per genome. These results indicate that the karyotype variation caused by the supernumerary heterochromatic segment was generated by amplification or reduction of the tandem repeats of RAE730.     

Pseudoterminalisation,terminalisation, and non-chiasmate modes of terminal association

Terminal associations occur commonly between meiotic homologues of the two smallest (S10, S11) chromosomes in the northern race of Cryptobothrus chrysophorus when they are either heterozygous or homozygous for distal supernumerary heterochromatic segments. A detailed examination of the origin and behaviour of these associations provides convincing evidence that they are non-chiasmate in character and so cannot be explained by either pseudoterminalisation or terminalisation. The same is true of the terminal associations involved in the persistent pseudomultiples that develop between non-homologues of Heteropternis obscurella when one or both of these carry distal heterochromatic segments. In both situations the C-bands involved in such terminal associations are entire and are never interrupted by non-banded material. In Cryptobothrus, similar associations can also develop between centromere regions when these are heterozygous or homozygous for proximal supernumerary heterochromatic segments.     

Chiasma frequency and position in male and female mice of chromosomes involved in homozygous and heterozygous translocations and tertiary trisomy

Chiasma frequency and position were analyzed at a predominantly late diplotene-diakinesis stage of the first meiotic division in oocytes and spermatocytes from T(1;13)70H homozygotes and heterozygotes, T(2;8)26H heterozygotes and from Ts(I¹³)70H tertiary trisomics of the mouse, Mus musculus. For T70H/T70H, the 13¹ long marker bivalent was studied and for the other karyotypes, analysis was confined to the multivalent configurations adopted by the rearranged chromosomes and their homologues. For the 13¹ bivalent, the chiasma frequency tended to be increased in the female. For the T26H and the T70H multivalents, the chiasma frequencies were higher in the female, largely due to the much higher values in the short interstitial segments. This observed enhancement has been attributed to pairing differences rather than to differences in chiasma forming capability. Both in the telomeric region of the 13¹ bivalent and in the short translocated segments of the reciprocal translocation and tertiary trisomic multivalents, females showed fewer chiasmata than males. The determinations of chiasma position in the 13¹ bivalent indicated chiasma interference with respect to position, leading to clustering of chiasmata somewhat beyond the centromere and towards the telomere of this chromosome.     

Color differential staining of NOR-associated heterochromatic segments using acridine orange

A new staining technique has been evaluated for detecting heterochromatic segments accompanying nucleolus organizing regions (NORs). This technique essentially consists of C-banding followed by acridine orange staining. When the technique was applied to five species of plants, the NOR-associated heterochromatic segments (NOR H-segments) were differentiated from other segments of the chromosomes as regions emitting yellowish green fluorescence. An incubation of at least 30 min in hot 2 x SSC was required to make the NOR H-segments emit yellowish green fluorescence in Nothoscordum fragrans. Fluorescence on other heterochromatic segments varied from reddish orange to bright yellow; euchromatic segments emitted orange or yellowish orange fluorescence. The technique permits identification of NOR H-segments throughout mitosis based on the characteristic fluorescent color.     

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).