Mitotic and meiotic chromosomes in Somatochlora metallica (Cordulidae,Odonata). The absence of localized centromeres and inverted meiosis

Spermatogonial metaphase chromosomes were examined in two dragonfly species, Somatochlora metallica (Cordulidae) and Aeshna grandis (Aeshnidae), and the behaviour of male meiotic chromosomes was studied in S. metallica. Both in S. metallica and A. grandis the male mitotic metaphase chromosomes from cells treated with colchicine consisted of two equidistantly aligned chromatids, showing no primary constriction. In meiosis the chromosomes of S. metallica males showed telokinetic activity during the first meiotic division, and kinetic activity was restricted in the middle parts of chromosomes during the second division. The kinetic behaviour of the chromosomes both in mitosis and meiosis showed that they were holocentric. One chiasma arises interstitially in each bivalent in S. metallica male meiosis. The chiasmata retain their interstitial position at metaphase I and do not terminalize. At metaphase I bivalents co-orient with homologous telomere regions towards the opposite poles. Thus genuine dyads segregate at the first anaphase. Meiosis in these male dragonflies is thus pre-reductional or conventional, not post-reductional or inverted, as has been previously proposed.     

Metaphase I arrest upon activation of the Mad2-dependent spindle checkpoint in mouse oocytes

BACKGROUND: The importance of mitotic spindle checkpoint control has been well established during somatic cell divisions. The metaphase-to-anaphase transition takes place only when all sister chromatids have been properly attached to the bipolar spindle and are aligned at the metaphase plate. Failure of this checkpoint may lead to unequal separation of sister chromatids. On the contrary, the existence of such a checkpoint during the first meiotic division in mammalian oocytes when homologous chromosomes are segregated has remained controversial. RESULTS: Here, we show that mouse oocytes respond to spindle damage by a transient and reversible cell cycle arrest in metaphase I with high Maturation Promoting Factor (MPF) activity. Furthermore, the mitotic checkpoint protein Mad2 is present throughout meiotic maturation and is recruited to unattached kinetochores. Overexpression of Mad2 in meiosis I leads to a cell cycle arrest in metaphase I. Expression of a dominant-negative Mad2 protein interferes with proper spindle checkpoint arrest. CONCLUSIONS: Errors in meiosis I cause missegregation of chromosomes and can result in the generation of aneuploid embryos with severe birth defects. In human oocytes, failures in spindle checkpoint control may be responsible for the generation of trisomies (e.g., Down Syndrome) due to chromosome missegregation in meiosis I. Up to now, the mechanisms ensuring correct separation of chromosomes in meiosis I remained unknown. Our study shows for the first time that a functional Mad2-dependent spindle checkpoint exists during the first meiotic division in mammalian oocytes.     

Mitotic recombination and genetic changes in Saccharomyces cerevisiae during wine fermentation

Natural strains of Saccharomyces cerevisiae are prototrophic homothallic yeasts that sporulate poorly, are often heterozygous, and may be aneuploid. This genomic constitution may confer selective advantages in some environments. Different mechanisms of recombination, such as meiosis or mitotic rearrangement of chromosomes, have been proposed for wine strains. We studied the stability of the URA3 locus of a URA3/ura3 wine yeast in consecutive grape must fermentations. ura3/ura3 homozygotes were detected at a rate of 1 x 10(-5) to 3 x 10(-5) per generation, and mitotic rearrangements for chromosomes VIII and XII appeared after 30 mitotic divisions. We used the karyotype as a meiotic marker and determined that sporulation was not involved in this process. Thus, we propose a hypothesis for the genome changes in wine yeasts during vinification. This putative mechanism involves mitotic recombination between homologous sequences and does not necessarily imply meiosis.     

Un ménage à quatre: the molecular biology of chromosome segregation in meiosis

Sexually reproducing organisms rely on the precise reduction of chromosome number during a specialized cell division called meiosis. Whereas mitosis produces diploid daughter cells from diploid cells, meiosis generates haploid gametes from diploid precursors. The molecular mechanisms controlling chromosome transmission during both divisions have started to be delineated. This review focuses on the four fundamental differences between mitotic and meiotic chromosome segregation that allow the ordered reduction of chromosome number in meiosis: (1) reciprocal recombination and formation of chiasmata between homologous chromosomes, (2) suppression of sister kinetochore biorientation, (3) protection of centromeric cohesion, and (4) inhibition of DNA replication between the two meiotic divisions.     

Meiotic recombination intermediates are resolved with minimal crossover formation during return-to-growth, an analogue of the mitotic cell cycle

Accurate segregation of homologous chromosomes of different parental origin (homologs) during the first division of meiosis (meiosis I) requires inter-homolog crossovers (COs). These are produced at the end of meiosis I prophase, when recombination intermediates that contain Holliday junctions (joint molecules, JMs) are resolved, predominantly as COs. JM resolution during the mitotic cell cycle is less well understood, mainly due to low levels of inter-homolog JMs. To compare JM resolution during meiosis and the mitotic cell cycle, we used a unique feature of Saccharomyces cerevisiae, return to growth (RTG), where cells undergoing meiosis can be returned to the mitotic cell cycle by a nutritional shift. By performing RTG with ndt80 mutants, which arrest in meiosis I prophase with high levels of interhomolog JMs, we could readily monitor JM resolution during the first cell division of RTG genetically and, for the first time, at the molecular level. In contrast to meiosis, where most JMs resolve as COs, most JMs were resolved during the first 1.5-2 hr after RTG without producing COs. Subsequent resolution of the remaining JMs produced COs, and this CO production required the Mus81/Mms4 structure-selective endonuclease. RTG in sgs1-ΔC795 mutants, which lack the helicase and Holliday junction-binding domains of this BLM homolog, led to a substantial delay in JM resolution; and subsequent JM resolution produced both COs and NCOs. Based on these findings, we suggest that most JMs are resolved during the mitotic cell cycle by dissolution, an Sgs1 helicase-dependent process that produces only NCOs. JMs that escape dissolution are mostly resolved by Mus81/Mms4-dependent cleavage that produces both COs and NCOs in a relatively unbiased manner. Thus, in contrast to meiosis, where JM resolution is heavily biased towards COs, JM resolution during RTG minimizes CO formation, thus maintaining genome integrity and minimizing loss of heterozygosity.     

Meiosis-specific arrest revealed in DNA topoisomerase II mutants.

Although the processes of mitosis and meiosis are similar, there is evidence for fundamental regulatory differences between the two. To examine these differences, we have compared the meiotic phenotype of DNA topoisomerase II mutants with their previously described mitotic phenotype (C. Holm, T. Goto, J. Wang, and D. Botstein, Cell 41:553-563, 1985). top2 mutants in meiosis show no defects in the latest detectable stages of recombination, yet they arrest prior to spindle establishment at meiosis I. Fluorescence and electron microscopy reveal that top2 mutants exhibit wild-type levels of meiotic chromosome condensation and form morphologically normal synaptonemal complex but are delayed in the exit from pachytene. Arrested cells retain viability and form colonies if transferred to mitotic medium. Our results suggest that the top2 meiotic arrest is regulatory in nature. This arrest may have evolved to ensure the resolution of fortuitous tangles between nonhomologous chromosomes.     

Flow cytometric analyses of intraplant nuclear DNA content variation induced by sticky chromosomes

BACKGROUND: In several plant species, sticky chromosomes are a consequence of genetic mutations or environmental effects on mitosis and meiosis. Sticky chromosomes result in an unequal distribution of genetic material in daughter cells. This unequal distribution is hypothesized to result in an increase in the coefficient of variation (CV) of the G1 peak of dividing cells. METHODS: The st1 mutant and a nonmutant line in the same genetic background of maize (Zea mays L.) were planted in a soilless mix. A wheat (Triticum aestivum L. em thell.) line was grown in both low and high aluminum-saturated soil. Both plant species were assessed for sticky chromosomes by Feulgen-stained mitotic analysis and flow cytometric analysis of propidium iodide (PI)-stained G1 nuclei. RESULTS: In the st1 mutant, a significant increase in the number of abnormal anaphase figures was observed. An increase in abnormal mitotic figures was observed in wheat plants grown in aluminum soil. Using flow cytometry, an increase in the CV of the G1/G0 peak was seen in the maize mutant and in wheat grown at high levels of aluminum saturation. This increase correlated with the number of abnormal anaphase cells observed. CONCLUSIONS: Flow cytometry was sensitive enough to detect the intraplant nuclear DNA variation associated with sticky chromosomes within a plant.     

Chromosome mal-orientation and reorientation during mitosis.

We argue that mal-orientation of mitotic chromosomes is not as rare as once believed. However, unlike bivalents during meiosis I, the reorientation of a mal-oriented mitotic chromosome has yet to be observed. This appears to be due, in part, to the difficulty in differentiating mal-oriented chromosomes from mono-oriented ones which are common during spindle formation in living mitotic cells. We assume that mitotic cells possess mechanisms for correcting chromosome mal-orientations that are similar to those operating during meiosis. However, unlike meiosis, where reorientation appears to be triggered when tension on a K-fiber is relieved or reduced, other factors related to the close proximity of sister kinetochores may also induce reorientation in mal-oriented mitotic chromosomes. We favor a model in which the reorientation of a mitotic kinetochore depends on, and is initiated by, the kinetochore capturing MTs from the pole to which it is reorienting.     

Spindles and centrosomes during male meiosis in Drosophila melanogaster

We have studied the spatial distribution of chromosomes, spindle fibers and centrosomes throughout the first meiotic division in males of Drosophila melanogaster. There seem to be two different types of spindle fibers: those which connect the poles to the chromosomes, and others arranged as cup-shaped hemispheres that reach from the poles to an unstained area on the equator of the cell. These pole-equator fibers could be responsible for positioning the nucleus and distributing cytoplasmic organelles around the nucleus during prophase, so that after meiosis, the daughter cells are provided with equal amounts of preorganized cytoplasmic organelles. These fibers remain until after the daughter nuclei have formed during telophase. An antigen associated with the centrosomes of mitotic spindles appears during meiosis as dispersed particles surrounding the nucleus; these particles might provide the developing spermatids with microtubule-organizing centers.     

Disruption of a Conserved CAP-D3 Threonine Alters Condensin Loading on Mitotic Chromosomes Leading to Chromosome Hypercondensation

The condensin complex plays a key role in organizing mitotic chromosomes. In vertebrates, there are two condensin complexes that have independent and cooperative roles in folding mitotic chromosomes. In this study, we dissect the role of a putative Cdk1 site on the condensin II subunit CAP-D3 in chicken DT40 cells. This conserved site has been shown to activate condensin II during prophase in human cells, and facilitate further phosphorylation by polo-like kinase I. We examined the functional significance of this phosphorylation mark by mutating the orthologous site of CAP-D3 (CAP-D3^T1403A) in chicken DT40 cells. We show that this mutation is a gain of function mutant in chicken cells; it disrupts prophase, results in a dramatic shortening of the mitotic chromosome axis, and leads to abnormal INCENP localization. Our results imply phosphorylation of CAP-D3 acts to limit condensin II binding onto mitotic chromosomes. We present the first in vivo example that alters the ratio of condensin I:II on mitotic chromosomes. Our results demonstrate this ratio is a critical determinant in shaping mitotic chromosomes.     

丽纹攀蜥精巢染色体和减数分裂研究

本文用精巢细胞制片法,在国内首次报道了丽纹攀蜥(Japalura splendida)的精巢染色体组型和减数分裂过程,其精巢染色体n=17,含6个大型染色体和儿个微小染色体。除微小染色体呈点状外,大型染色体均为中间着丝粒染色体。同时我们观察了丽纹攀蜥减数分裂各个时期,并对各时期的特征进行了描述。     

Positive role of the mammalian TBPIP/HOP2 protein in DMC1-mediated homologous pairing

In meiosis, homologous recombination preferentially occurs between homologous chromosomes rather than between sister chromatids, which is opposite to the bias of mitotic recombinational repair. The TBPIP/HOP2 protein is a factor that ensures the proper pairing of homologous chromosomes during meiosis. In the present study, we found that the purified mouse TBPIP/HOP2 protein stimulated homologous pairing catalyzed by the meiotic DMC1 recombinase in vitro. In contrast, TBPIP/HOP2 did not stimulate homologous pairing by RAD51, which is another homologous pairing protein acting in both meiotic and mitotic recombination. The positive effect of TBPIP/HOP2 in the DMC1-mediated homologous pairing was only observed when TBPIP/HOP2 first binds to double-stranded DNA, not to single-stranded DNA, before the initiation of the homologous pairing reaction. Deletion analyses revealed that the C-terminal basic region of TBPIP/HOP2 is required for efficient DNA binding and is also essential for its homologous pairing stimulation activity. Therefore, these results suggest that TBPIP/HOP2 directly binds to DNA and functions as an activator for DMC1 during the homologous pairing step in meiosis.     

Immunocytochemical visualization of the centromeres during male and female meiosis in Lilium longiflorum

Immunofluorescence staining with an antiserum raised against a presumptive meiotic histone, which has been shown to appear prior to male meiosis in liliaceous plants, preferentially stained the centromere (kinetochore) region of meiotic chromosomes in microsporocytes and megasporocytes. Using this antiserum, we were able clearly to visualize the centromeres at all important meiotic stages in microsporocytes, namely, the association and fusion of centromeres of homologous chromosomes at zygotene-pachytene in prophase I, the disjunction of the homologous centromeres at diplotene, the doubling of each centromere at metaphase I and nonseparation of the sister centromeres at anaphase I, by confocal laser scanning microscopy. Thus, this report provides a complete picture of the behavior of centromeres during meiosis in a eukaryote for the first time. This antiserum also decorated centromeres during female meiosis in cryo-sectioned megasporocytes, but did not stain the centromeres of mitotic chromosomes in root-tip meristem. From these observations, it is suggested that a meiosis-specific centromere protein is required for the meiosis-specific behavior of the centromere. Received: 12 May 1997; in revised form: 20 August 1997 / Accepted: 25 August 1997     

Human BUBR1 is a mitotic checkpoint kinase that monitors CENP-E functions at kinetochores and binds the cyclosome/APC.

Human cells express two kinases that are related to the yeast mitotic checkpoint kinase BUB1. hBUB1 and hBUBR1 bind to kinetochores where they are postulated to be components of the mitotic checkpoint that monitors kinetochore activities to determine if chromosomes have achieved alignment at the spindle equator (Jablonski, S.A., G.K.T. Chan, C.A. Cooke, W.C. Earnshaw, and T.J. Yen. 1998. Chromosoma. 107:386-396). In support of this, hBUB1 and the homologous mouse BUB1 have been shown to be important for the mitotic checkpoint (Cahill, D.P., C. Lengauer, J. Yu, G.J. Riggins, J.K. Willson, S.D. Markowitz, K.W. Kinzler, and B. Vogelstein. 1998. Nature. 392:300-303; Taylor, S.S., and F. McKeon. 1997. Cell. 89:727-735). We now demonstrate that hBUBR1 is also an essential component of the mitotic checkpoint. hBUBR1 is required by cells that are exposed to microtubule inhibitors to arrest in mitosis. Additionally, hBUBR1 is essential for normal mitotic progression as it prevents cells from prematurely entering anaphase. We establish that one of hBUBR1's checkpoint functions is to monitor kinetochore activities that depend on the kinetochore motor CENP-E. hBUBR1 is expressed throughout the cell cycle, but its kinase activity is detected after cells have entered mitosis. hBUBR1 kinase activity was rapidly stimulated when the spindle was disrupted in mitotic cells. Finally, hBUBR1 was associated with the cyclosome/anaphase-promoting complex (APC) in mitotically arrested cells but not in interphase cells. The combined data indicate that hBUBR1 can potentially provide two checkpoint functions by monitoring CENP-E-dependent activities at the kinetochore and regulating cyclosome/APC activity.     

来自山羊草的杀配子染色体(Aegilops cylindryca 2C)对小黑麦减数分裂及花粉粒有丝分裂过程的影响

用来自柱穗山羊草的杀配子染色体2C,诱导六倍体、八倍体小黑麦染色体的断裂,观察杂种F1的减数分裂行为,在PMCI及PMCII后期观察到了大量的落后染色体、染色体断片、环状染色体及桥,在二分了解子及四分孢子中有为数甚多的、大小不一的微核,有的还形成多分孢子。在对F1花粉粒的有丝分裂观察中,未见分裂异常。由此推断杀配子染以体诱导染色体断裂可能不发生在配子形成的有丝分裂过程。这与巳有的报道不同。     

Inheritance of allozymes and hybridization in two European Tilia species

Inheritance analysis of seven enzyme systems in hexaploid Tilia cordata Mill. was performed utilizing single trees and their open-pollinated progenies. Genetic analyses of 12 polymorphic gene loci showed that T. cordata had disomic inheritance despite being an allopolyploid. T. platyphyllos Scop. was also used in the investigations although no genetic inheritance analysis was carried out. In comparison with T. cordata, zymograms of 10 spontaneous T. cordata x T. platyphyllos hybrids showed markedly different banding patterns with species-specific alleles at 13 of the 14 described gene loci. Hence, differentiation between both species and their naturally occurring hybrid (T. x europaea) is easily feasible with allozyme studies.     

Localisation of phosphorylated MAP kinase during the transition from meiosis I to meiosis II in pig oocytes

Mitogen-activated protein kinase (MAPK) has been reported to be involved in oocyte maturation in all animals so far examined. In the present study we investigate the expression and localisation of active phosphorylated MAPKs (p44ERK1/p42ERK2) during maturation of pig oocytes. In immunoblot analysis using anti-p44ERK1 antibody which recognised both active and inactive forms of p44ERK1 and p42ERK2, we confirmed that MAPKs were phosphorylated around the time of germinal vesicle breakdown (GVBD) and the active phosphorylated MAPKs (pMAKs) were maintained until metaphase II, as has been reported. On immunofluorescent confocal microscopy using anti-pMAPK antibody which recognised only phosphorylated forms of MAPKs, pMAPK was localised at the spindle poles in pig mitotic cells. On the other hand, in pig oocytes, no signal was detected during GV stage. After GVBD, the area around condensed chromosomes was preferentially stained at metaphase I although whole cytoplasm was faintly stained. At early anaphase I, the polar regions of the meiotic spindle were prominently stained. However, during the progression of anaphase I and telophase I pMAPK was detected at the mid-zone of the elongated spindle, gradually becoming concentrated at the centre. Finally, at the time of emission of the first polar body, pMAPK was detected as a ring-like structure between the condensed chromosomes and the first polar body, and the staining was maintained even after the metaphase II spindle was formed. The inhibition of MAPK activity with the MAPK kinase inhibitor U0126 during the meiosis I/meiosis II transition suppressed chromosome separation, first polar body emission and formation of the metaphase II spindle. From these results, we propose that the spindle-associated pMAPKs play an important role in the events occurring during the meiosis I/meiosis II transition, such as chromosome separation, spindle elongation and cleavage furrow formation in pig oocytes.     

Differential timing of S phases, X chromosome replication, and meiotic prophase in the C. elegans germ line

The replication of chromosomes in meiosis is an important first step for subsequent chromosomal interactions that promote accurate disjunction in the first of two segregation events to generate haploid gametes. We have developed an assay to monitor DNA replication in vivo in mitotic and meiotic germline nuclei of the nematode Caenorhabditis elegans. Using mutants that affect the mitosis/meiosis switch, we show that meiotic S phase is at least twice as long as mitotic S phase in C. elegans germ cell nuclei. Furthermore, our assay reveals that different regions of the genome replicate at different times, with the heterochromatic-like X chromosomes replicating at a distinct time from the autosomes. Finally, we have exploited S-phase labeling to monitor the timing of progression through meiotic prophase. Meiotic prophase for oocyte production in hermaphrodites lasts 54-60 h. Further, we find that the duration of the pachytene sub-stage is modulated by the presence of sperm. On the other hand, meiotic prophase for sperm production in males is completed by 20-24 h. Possible sources for the sex-specific differences in meiotic prophase kinetics are discussed.     

Origin of acrocentric trisomies in spontaneous abortuses

Summary A total of 33 spontaneous abortuses with various acrocentric trisomies were studied for the origin of the extra chromosomes using Q- and R-band polymorphisms as markers. Eleven trisomic abortuses were informative: nine trisomic abortuses (one with trisomy 13, three with trisomy 21, and five with trisomy 22 including one with a 46,XX/47,XX,+22 mosaicism) originated at maternal first meiosis; a 21-trisomic abortus resulted from an error at maternal second meiosis (or first mitosis); and a 13-trisomic abortus was of maternal first or second meiotic origin. The abortus with mosaic trisomy 22 started as a 22-trisomic zygote resulting from an error at maternal first meiosis, followed by a mitotic (in vivo or in vitro) loss of the paternally derived chromosome 22.