Three dimensional reconstruction of the X-Y pair during pachytene in the rat (Rattus norvegicus)

The ultrastructure of the X-Y pair from rat spermatocytes has been reconstructed sterically by the study of serial sections. The X-Y pair of the rat at early pachytene contains two dense cores, a long and a short one, which form a synaptonemal complex 1.7 long at their common end. The long core (10.6 ) and the short core (4.5 ) correspond to X and Y, respectively. There is no RNA histochemically detectable in the X-Y pair. Nucleoli are independent of the X-Y pair. A low number of cells show nucleoli very near the X-Y pair but no continuity exists between these structures.     

Cytological dissection of sex chromosome heterochromatin of Drosophila hydei

Prophase chromosomes of Drosophila hydei were stained with 0.5 g/ml Hoechst 33258 and examined under a fluorescence microscope. While autosomal and X chromosome heterochromatin are homogeneously fluorescent, the entirely heterochromatic Y chromosome exhibits an extremely fine longitudinal differentiation, being subdivided into 18 different regions defined by the degree of fluorescence and the presence of constrictions. Thus high resolution Hoechst banding of prophase chromosomes provides a tool comparable to polytene chromosomes for the cytogenetic analysis of the Y chromosome of D. hydei. — D. hydei heterochromatin was further characterized by Hoechst staining of chromosomes exposed to 5-bromodeoxyuridine for one round of DNA replication. After this treatment the pericentromeric autosomal heterochromatin, the X heterochromatin and the Y chromosome exhibit numerous regions of lateral asymmetry. Moreover, while the heterochromatic short arms of the major autosomes show simple lateral asymmetry, the X and the Y heterochromatin exhibit complex patterns of contralateral asymmetry. These observations, coupled with the data on the molecular content of D. hydei heterochromatin, give some insight into the chromosomal organization of highly and moderately repetitive heterochromatic DNA.     

The meiotic structure and behavior of the strongly heteromorphic X/Y sex chromosomes of neotropical plethodontid salamanders of the genus Oedipina

Plethodontid salamanders in the genus Oedipina are characterized by a strongly heteromorphic sex-determining pair of X/Y chromosomes. The telocentric X chromosome and the subtelocentric Y chromosome are clearly distinguished from the autosomes and their behavior during meiosis can be sequentially followed in squash preparations of spermatocytes. In Oedipina the sex chromosomes are not obscured by an opaque sex vesicle during early meiotic stages, making it possible to observe details of sex bivalent structure and behavior not directly visible in other vertebrate groups. The sex chromosomes can first be distinguished from autosomal bivalents at the conclusion of zygotene, with X and Y synapsed only along a short segment at their non-centromeric ends, forming a bivalent that contrasts sharply with the completely synapsed autosomes. During pachytene, the XY bivalent becomes progressively shortened and more compact, disappearing as a visible structure when pachytene progresses into the diffuse stage of male meiosis. Diplotene bivalents gradually emerge from the diffuse nuclei, presumably by the return of the loops of chromatin into their respective chromomeres. During early diplotene, the X/Y bivalent is clearly visible with a single chiasma within the synapsed segment. This chiasma is terminalized by first meiotic metaphase with the X and Y appearing either in end-to-end synaptic contact or as univalents separated at opposite poles relative to the equatorially distributed autosomal bivalents. In C-banded preparations, the Y is entirely heterochromatic while the X contains a large centromeric C-band and another block of heterochromatin located at the telomeric end, in the region of synapsis with the Y. We find no cytological evidence of dosage compensation, such as differential staining of the X chromosomes or Barr bodies, in mitotic or interphase cells from female animals.     

Sex chromosome pairing patterns in male mice of novel Sxr genotypes

The influence of the sex-reversal factor (Sxr) on X and Y chromosome pairing was examined by comparing males with novel and standard Sxr genotypes. The novel Sxr males were exceptional in carrying Sxr on their X rather than their Y chromosome, or homozygously on both their X and Y chromosomes, or on a Y chromosome of different origin to that on which the factor arose. Regardless of its chromosomal location, Sxr was found to elevate the frequency of X-Y separation. Univalent X and Y chromosomes were observed to undergo self-association in a variable proportion of spermatocytes of all Sxr-carrying males. There was a suggestion that chromosomal location of the factor could influence the frequency of univalent self-association. Our observations do not support the published hypothesis of Y self-pairing as the cause of the elevated rate of X-Y separation at pachytene in Sxr-carrying males. Rather, they suggest that heterozygosity due to the presence of Sxr in the XY pairing region may be sufficient to disrupt pairing and cause univalence, or alternatively, that Sxr is an inefficient promoter of X-Y pairing initiation.     

Meiosis in the male mouse. An autoradiographic investigation

Meiosis in the male mouse has been studied autoradiographically in air-dried preparations. Information has been obtained on the relative rates of DNA synthesis and the lengths of the S-periods in spermatogonia and spermatocytes. The average rate of synthesis in the spermatocyte is lower, and the S-period is of longer duration than the preceding spermatogonial generations. The labelling pattern of the sex-chromosomes and autosomes observed at diakinesis and metaphase II in cells labelled at the spermatocyte S-period appears to be similar to that found in cells labelled during the spermatogonial S-periods. Replication in the autosomes commences before the sex-chromosomes. Late replicating autosomal centric regions show a marked degree of asynchrony in labelling both between and within bivalents. The Y chromosome starts and finishes replication later than the X. There is a short, late-replicating, segment of the X in the vicinity of the centromere. There is a short, early-replicating segment of the Y in the vicinity of the centromere which may represent the euchromatic short arm. The X and Y appear to associate at diakinesis by the distal ends of their long arms.     

Radiation induced deletions in spermatids and spermatocytes ofDrosophila

Summary Males of the composition X^C2/B ^S Yy ⁺ were collected as prepupae, aged an additional 48 hours, then irradiated with 1000 r and brooded individually for eight days with three virginy w f females each day. Analysis suggests that brood days 1–3 represent the recovery of cells which were predominantly spermatids at the time of treatment, those from brood days 4–6 predominantly spermatocytes, and those from brood days 7–8 predominantly spermatogonia. The highest frequency of loss of individual Y markers and X0 males, as well as the smallest F₁ population size was found in broods 5 and 6, and especially in brood 6. Further analysis suggests that the vast majority of individual Y-marker losses recovered from diploid cells (spermatocytes, spermatogonia) arose independent of inter-Y arm exchange and Y-autosome translocations. In general, the data confirm the suggestive results of other investigators that deletions are recovered most readily from spermatocytes than from any other stage in spermatogenesis.     

Chromosome banding in Amphibia

The chromosomes of the South American marsupial frogs Gastrotheca fissipes, G. ovifera, G. walkeri and Flectonotus pygmaeus were analyzed by means of conventional and various banding techniques. The karyotypes of G. ovifera and G. walkeri are characterized by highly differentiated XY/XX sex chromosomes. Whereas the X chromosomes and autosomes contain large amounts of constitutive heterochromatin, extremely little heterochromatin is located in the Y chromosomes. This is in contrast to all previously known amphibian Y chromosomes and the Y chromosomes of most other vertebrates. In the male meiosis of G. walkeri, the euchromatic segments of the heteromorphic XY chromosomes show the same pairing configuration as the autosomal bivalents. The karyotype of F. pygmaeus is remarkable for the unique presence of telocentric chromosomes and the high frequency of interstitially located chiasmata in the meiotic bivalents. The evolution of the karyotypes and sex chromosomes, the structure of the various classes of heterochromatin and the data obtained from meiotic analyses of the marsupial hylids are discussed.     

Karyotype differences in the crenaticeps-group of Atractomorpha (orthoptera,acridoidea, pyrgomorphidae)

The four known species of the crenaticeps-group of the genus Atractomorpha have 2n ()=18+X0. All members of the complement are rod-chromosomes and the smallest autosome (no. 9) is megameric. The four species have similar amounts of euchromatin but differ markedly in the amount of heterochromatin present in their genomes. In A. similis, A. crenaticeps and the unnamed species, Species-1, there are distinct proximal segments of heterochromatin in the eight large autosomes. In A. similis these chromosomes also have prominent distal segments of heterochromatin. The fourth species, A. australis, has no visible heterochromatin in its eight large autosomes except for a small segment at the proximal end of autosome 4. In all four species, the heterochromatic segments influence chiasma frequency and chiasma position. Moreover the overall chiasma frequency is lowest in A. similis with most heterochromatin and highest in A. australis with least heterochromatin.     

Karyotypic analysis of the cotton boll weevil, Anthonomus grandis Boheman

The diploid chromosome number of the cotton boll weevil, Anthonomus grandis Boheman, is 44. Both C‐ and N‐banding techniques of mitotic cells demonstrated constitutive heterochromatin in the p arm of the eight largest chromosomes, the p arm of the X chromosome, and the centromeric region of autosomal groups A–D. Neither the y nor the group E autosomes appeared to contain constitutive heterochromatin. Supernumerary chromosomes were not found in the boll weevil. Restriction endonuclease banding of primary spermatocytes revealed a rod‐shaped Xy tetrad in which the X and y were terminally associated. The p arm of the large, submetacentric X was C‐band positive. While two of the autosomal tetrads were typically ring‐shaped in primary spermatocytes, the remaining 19 autosomal tetrads were rod‐shaped. This revised version was published online in July 2006 with corrections to the Cover Date.     

Chromosome banding in Amphibia. XV. Two types of Y chromosomes and heterochromatin hypervariabilty inGastrotheca pseustes (Anura,Hylidae)

The chromosomes of the newly discovered South American marsupial frogGastrotheca pseustes were analyzed by conventional methods and by various banding techniques. This species is characterized by XY/XX sex chromosomes and the existence of two different morphs of Y chromosomes. Whereas in type A males the XY^A chromosomes are still homomorphic, in type B males the Y^B chromosome displays a large heterochromatic region at the long arm telomere which is absent in the X. In male meiosis, the homomorphic XY^A chromosomes exhibit the same pairing configuration as the autosomal bivalents. On the other hand, the heteromorphic XY^B chromosomes form a sex bivalent by pairing their short arm telomeres in a characteristic end-to-end arrangement. Analysis of the karyotypes by C-banding and DNA base pair-specific fluorochromes reveals enormous interindividual size variability of the autosomal heterochromatin.     

Analysis of nuclear proteins in primary spermatocytes of Drosophila hydei: the correlation of nuclear proteins with the function of the Y chromosomal loops

The protein content of spermatocyte nuclei from X/Y males and mutants of D. hydei which lack different Y chromosomal loop forming sites, was compared with that of X/0 males in ¹⁴C/³H double labelling experiments. Proteins of 45,000, 52,000, 54,000, 66,000, 80,000, 84,000, and 170,000 Dalton are found to be enriched in nuclei containing two or more active Y chromosomal loop forming sites. These proteins are also present in the nuclei of X0 males. In the complete absence of the Y-chromosomal loops proteins of 35,000, 46,000, 58,000 and 110,000 Dalton become enriched in the spermatocyte nuclei. — Analysis of the nuclear RNP of spermatocytes led to the isolation of an hnRNP-containing fraction with an S-value of >900S (RNP-PP). — In the RNP-PP of XY males labelled protein material associated with hnRNA is enriched by a factor of 3 in respect to the X0 genotype. The nuclear RNP has a heterogenous buoyant density in CsCl of p = 1.33 to 1.43 g/cm³. RNase T₁ treatment of the crude nuclear RNP from XY males prior to sucrose gradient analysis shows that the 66,000 Dalton protein which is also strongly enriched in the nuclei in the presence of active Y chromosomal loop forming sites, is the main protein associated with protected RNA-sequences of 80–120 and 200–300 nucleotides in length. Competitive nitrocellulose filter binding assays reveal that the 66,000 Dalton protein predominantly forms in 2 M NaCl stable RNA/protein complexes with the poly A ⁺hnRNA of the RNP-PP. These RNP complexes have a buoyant density of p = 1.43 g/cm³ in CsCl. The results are discussed in relation to the nuclear structure and the function of the Y chromosomal loops during spermatogenesis in Drosophila hydei.     

Chromosomes and DNA of Mus

Using C-banded preparations of Mus dunni it is possible to study the behavior of constitutive heterochromatin in early stages of meiotic prophase. The X and the Y chromosomes, both of which contain a large amount of heterochromatin, lie apart in leptotene but move toward each other during zygotene. They then form the sex vesicle at late zygotene. In autosomes zygotene pairing appears to start from the telomeric ends. The centromere of the Y chromosome associates end-to-end with the terminal end of the long arm of the X chromosome. The autosomal heterochromatic short arms show forked morphology in certain bivalents at pachytene, suggesting probable incomplete synapsis.     

Eubacteria have 3 growth modes keyed to nutrient flow

Aerobic growth of Escherichia coli and Paracoccus denitrificans has been studied in chemostat, fed batch, and recycling fermentor modes under carbon and energy limitation. Two abrupt drops or discontinuities in molar growth yield, Y, have been found that occur over relatively short ranges in the value of specific growth rate.Before the first discontinuity, Y is constant and maximal. After the first discontinuity, at a doubling time of 33 h, Y becomes constant again and independent of until the second discontinuity appears at a doubling time of about 50 h, corresponding to a of about 0.014. At this point, Y drops to a lower value that is constant at doubling times longer than 100 h, corresponding to a of about 0.007.The second discontinuity is associated in Paracoccus with elevated levels of guanosine tetraphosphate (ppGpp) that impose stringent regulation as has been found previously with Bacillus and Escherichia species. It is thus likely that the stringent response generally occurs in bacteria in vivo at a doubling time of about 50 h. The cause of the first discontinuity is unknown. All experiments indicate that Pirt-type calculations relating , Y, and maintenance energy demand are no longer valid. In chemostat experiments, the intercept of the relationship between specific substrate utilization and specific growth rate is defined as maintenance. However, this intercept most probably is caused by stringent regulation at low dilution rates. Three regions of bacterial growth rates are defined by this study, corresponding to doubling times of 0.5 to 15 h, 33 to 50 h, and >100 h. Some growth behavior in each region is unique to that region.Abbreviations ppGpp guanosine 5 diP 3 diP - pppGpp guanosine 5 triP 3 diP - SPR substrate provision rate (mol/l h)     

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.     

Susceptibility of heterochromatin to aphidicolin-induced chromosomal breakage

The distribution of aphidicolin-induced chromosomal lesions was analyzed to determine the relative breakage susceptibility of euchromatin and heterochromatin in the cactus mouse, Peromyscus eremicus. The observed breakage was tested against expected distributions corresponding to the karyotypic proportions of autosomal euchromatin, autosomal heterochromatin, X-chromosomal euchromatin, and X-chromosomal heterochromatin. The distribution of induced breakage was independent of sex but dependent on the individual. In all individuals, there was a highly significant (P0.0001) deficiency in the number of breaks observed as compared to expected in autosomal heterochromatin. Sparse observations in the X chromosome and the absence of breaks in the Y chromosome precluded valid statistical tests of the sex-chromosomal distribution of induced breakage. These data indicate that the autosomal heterochromatin of Peromyscus is resistant to aphidicolin-induced chromosomal breakage and argue against a simple relationship between late replication and a general mechanism for chromosomal fragility.     

The proton-translocating nicotinamide adenine dinucleotide transhydrogenase

H⁺-transhydrogenase couples the reversible transfer of hydride ion equivalents between NAD(H) and NADP(H) to the translocation of protons across a membrane. There are separate sites on the enzyme for the binding of NAD(H) and of NADP(H). There are some indications of the position of the binding sites in the primary sequence of the enzymes from mitochondria andEscherichia coli. Transfer of hydride ion equivalents only proceeds when a reduced and an oxidized nucleotide are simultaneously bound to the enzyme. When p=0 the rate of interconversion of the ternary complexes of enzyme and nucleotide substrates is probably limiting. An increase in p accelerates the rate of interconversion in the direction of NADH NADP⁺ until another kinetic component, possibly product release, becomes limiting. The available data are consistent with either direct or indirect mechanisms of energy coupling.Abbreviations DCCD N N¹-dicyclohexylcarbodiimide - FSBA 5¹-[p-(fluorosulfonyl)benzoyl] adenosine - FCCP carbonylcyanide-p-fluoromethoxyphenylhydrazone - H⁺-Thase H⁺-transhydrogenase - thio-NADP⁺ thionicotinamide adenine dinucleotide phosphate - AcPdAd⁺ 3-acetylpyridine adenine dinucleotide - p proton electrochemical gradient - membane potential - pH pH difference across the membrane     

Genomic organization in the flesh fly Sarcophaga bullata

The genome of the flesh fly Sarcophaga bullata has been characterized both cytologically and biochemically. S. bullata has a haploid DNA level of 0.61 picograms which is five times larger than the haploid genome size of Drosophila melanogaster. Reassociation kinetics of Sarcophaga DNA shows that its sequence organization is very similar to that of D. melanogaster in having a very large proportion of single copy DNA (81%) and only small amounts of highly and moderately repetitive DNA (9% and 6%, respectively). cRNAs from all three sequence classes were prepared and their cytological distributions on diploid and polytene cells determined by in situ hybridization. The cytological distribution of the highly repetitive probe was found to be restricted to the centromeric heterochromatin of two of the five autosomes and this sequence class was also found to be markedly underreplicated in polytene foot-pad cells. No highly repetitive DNA was localized on either of the sex chromosomes, but only on the two large centromeric regions of chromosomes C and E. Moderately repetitive DNA was found uniformly distributed on all of the autosomes in both testis and polytene foot-pad squashes. As in the case of the highly repetitive sequence probe, no moderately repetitive DNA was detected on either the X or Y chromosomes. Moderately repetitive DNA in Sarcophaga was also shown to have the Drosophila type pattern of sequence interspersion with a moderately repetitive element of 5,000 nucleotides adjacent to a unique element of greater than 10,000 nucleotides. The Sarcophaga genome is the largest for which this type of interspersion has so far been demonstrated.     

Structure,regulation and evolution of the crystal-Stellate system of Drosophila

The crystal–Stellate system is one of the most known example of interaction between heterochromatin and euchromatin: a heterochromatic locus on the Y chromosome (crystal) 'represses a euchromatic locus (Stellate) on the X chromosome in Drosophila melanogaster. The molecular mechanism regulating this interaction is not completely understood. It is becoming clear that an RNA interference (RNAi) mechanism could be responsible for the silencing carried out by crystal on the Stellate sequences. Here, a detailed structural analysis of all the sequences involved in the system is reported, demonstrating a their 'puzzling structure. In addition three autosomal mutations: sting, scratch and sirio are described that interfere with the system. All of them are male sterile mutations and exhibit crystals made by the STELLATE protein in their primary spermatocytes. They are requested during oogenesis and early in embryogenesis as well. Hypothesis on the involvement of these genes in activating the Stellate sequences are discussed.     

Sex Chromosome Meiotic Drive in DROSOPHILA MELANOGASTER Males

In Drosophila melanogaster males, deficiency for X heterochromatin causes high X-Y nondisjunction and skewed sex chromosome segregation ratios (meiotic drive). Y and XY classes are recovered poorly because of sperm dysfunction. In this study it was found that X heterochromatic deficiencies disrupt recovery not only of the Y chromosome but also of the X and autosomes, that both heterochromatic and euchromatic regions of chromosomes are affected and that the "sensitivity" of a chromosome to meiotic drive is a function of its length. Two models to explain these results are considered. One is a competitive model that proposes that all chromosomes must compete for a scarce chromosome-binding material in Xh(-) males. The failure to observe competitive interactions among chromosome recovery probabilities rules out this model. The second is a pairing model which holds that normal spermiogenesis requires X-Y pairing at special heterochromatic pairing sites. Unsaturated pairing sites become gametic lethals. This model fails to account for autosomal sensitivity to meiotic drive. It is also contradicted by evidence that saturation of Y-pairing sites fails to suppress meiotic drive in Xh(- ) males and that extra X-pairing sites in an otherwise normal male do not induce drive. It is argued that meiotic drive results from separation of X euchromatin from X heterochromatin.     

The effect of X-irradiation on male meiosis in Schistocerca gregaria (Forskål)

Symmetrical exchanges between non-homologous chromosomes were recovered following irradiation of germ-line cells of S. gregaria at different developmental stages. No X-Autosome exchanges were observed. It was found that the frequencies with which autosomes of the three size groups L, M and S participated in exchange agreed with the frequencies expected based on effective exchange lengths of polarized interphase chromosomes. All of the observed symmetrical exchanges were between euchromatic segments of the chromosomes and though many of the exchange points were close to the centromere, no exchanges were found with break points actually in the centric heterochromatin. None of the heterozygous symmetrical exchanges were seen to have an observable influence on the chiasma conditions of the cell.