S. pombe linear elements: the modest cousins of synaptonemal complexes

Synaptonemal complexes (SCs) are not formed during meiotic prophase in the fission yeast, Schizosaccharomyces pombe. Instead, so-called linear elements (LinEs) are formed at the corresponding stages. LinEs are remarkable in that their number does not correspond to the number of chromosomes or bivalents and that the changes in their organisation during prophase do not evidently reflect the pairing of chromosomes. Yet, LinEs are necessary for full meiotic pairing levels and for meiotic recombination. In this review, the composition of LinEs, their evolutionary relationship to SCs and their possible functions are discussed.     

Stage-specific damage to synaptonemal complexes and metaphase chromosomes induced by X rays in male mouse germ cells

Synaptonemal complexes reveal mutagen-induced effects in germ cell meiotic chromosomes. This study was aimed at characterizing relationships between damage to synaptonemal complexes and metaphase I chromosomes following radiation exposure at various stages of spermatogenesis. Male mice were irradiated with doses of 0, 2, or 4 Gy, and spermatocytes were harvested at times consistent with earlier exposures as spermatogonial stem cells, preleptotene cells (premeiotic DNA synthesis), or meiotic prophase cells. After stem-cell exposure, twice as many rearrangements were observed in synaptonemal complexes as in metaphase I chromosomes. Irradiation during premeiotic DNA synthesis resulted in dose-related increases in synaptonemal complex breakage and rearrangements (including novel forms) and in metaphase chromosomal aberrations. Following prophase exposure, various types and levels of damage to synaptonemal complexes and metaphase chromosomes were observed. Irradiation of zygotene cells led to high frequencies of chromosome multivalents in metaphase I without a correspondingly high level of damage in preceding prophase synaptonemal complexes. Thus irradiation of premeiotic and meiotic cells results in variable relationships between damage to synaptonemal complexes and metaphase chromosomes. Interpretations of these relationships are based upon what is known about both radiation clastogenesis and the structural/temporal relationships between synaptonemal complexes at prophase and chromosomes at metaphase I of meiosis.     

Silver staining of synaptonemal complexes in surface spreads for light and electron microscopy

Synaptonemal complexes (SCs), axes of the X and Y chromosomes, and nucleoli in surface-spread preparations of spermatocytes are selectively stained for both light and electron microscopy by ammoniacal silver. Combined with a simple technique for transferring material from glass slides to grids, sequential light and electron microscopic analysis of full SC complements is possible with no further preparation. This new method has potential for both basic and clinical cytogenetic research.     

Nucleolar structures in chromosome and SC preparations from human oocytes at first meiotic prophase

Summary We describe a comparative study of the behavior of nucleolar structures and their relationship with nucleolar chromosomes and synaptonemal complexes at first meiotic prophase of human oocytes in an attempt to elucidate the nature of this cellular organization and to learn more about maternal nondisjunction. The number of main nucleoli varies along the different stages of prophase I and is usually low. It shows an increase from leptotene to pachytene and a decrease from pachytene to diplotene related to a decrease and an increase of main nucleoli volume, respectively. The methodology employed has enabled us to analyze in detail dark bodies, round bodies, dense bodies, and main nucleoli in chromosome or synaptonemal complex spreads. The relationship between nucleolar chromosomes or synaptonemal complexes and the nucleoli implies the existence, in a very reduced space, of chromosomal regions that contain homologous sequences and that are often unpaired. This situation may facilitate the production of heterologous pairing and chromosomal exchanges between nonhomologous chromosomes and finally result in aneuploidy. THus, the situation explained above together with the differences between the oocyte and spermatocyte NOR cycles could be one of the reasons for the higher incidence of aneuploidies of maternal origin at meiosis I.     

Presence of abnormal synaptonemal complexes in heterothallic species of Neurospora

Synaptonemal complex abnormalities are frequent in reconstructed meiotic prophase nuclei of Neurospora crassa and Neurospora intermedia. Three kinds of synaptonemal complex anomalies were seen: lateral component splits, lateral component junctions, and multiple complexes. The anomalies apparently are formed during or after the pairing process, as they were not seen in the largely unpaired early zygotene chromosomes. Their presence at all the other substages from mid-zygotene to late pachytene indicates that they are not eliminated before the synaptonemal complex decomposes at diplotene. Abnormal synaptonemal complexes were seen in all 19 crosses of N. crassa and N. intermedia that were examined, including matings between standard laboratory strains, inversions, Spore killers, and strains collected from nature. The frequency of affected nuclei and degree of abnormality within a nucleus varied in different matings. No abnormalities were present in the homothallic species Neurospora africana and Neurospora terricola. Structural chromosome aberrations, introgression, and heterozygosity have been eliminated as causes for pairing disorder. The abnormal synaptonemal complexes seemingly do not interfere with normal ascus development and ascospore formation. The affected nuclei are not aborted during meiotic prophase, nor are they eliminated by abortion of mature asci. The abnormal meiocytes do not lead to aneuploidy, as judged by the low frequency of white ascospores in crosses between wild type strains that have many abnormalities. Thus, the abnormal synatonemal complexes do not appear to prevent chiasma formation between homologues.     

Human Synaptonemal Complex Protein 1 (SCP1): Isolation and Characterization of the cDNA and Chromosomal Localization of the Gene

Synaptonemal complexes (SCs) are structures that are formed between homologous chromosomes (homologs) during meiotic prophase. They consist of two proteinaceous axes, one along each homolog, that are connected along their length by numerous transverse filaments (TFs). The cDNA encoding one major component of TFs of SCs of the rat, rnSCP1, has recently been isolated and characterized. In this paper we describe the isolation and characterization of the cDNA encoding the human protein homologous to rnSCP1, hsSCP1. hsSCP1 and rnSCP1 have 75% amino acid identity. The most prominent structural features and amino acid sequence motifs of rnSCP1 have been conserved in hsSCP1. Most probably, hsSCP1 is functionally homologous to rnSCP1. The hsSCP1 gene was assigned to human chromosome 1p12–p13 by fluorescencein situhybridization.     

Nucleolar meiotic cycle in orthoptera

The evolution of nucleolar material was analyzed during spermatogenesis of two grasshopper species by using “in vivo” visualization and the silver staining method. Both nucleoli and nucleolar remnants are detectable during prophase I and absent from metaphase I until telophase I. During telophase I a great number of small silver positive masses which correspond to prenucleolar bodies (PBs) are observed covering the chromatin surface. At interkinesis these PBs coalesce to form nucleoli, which are dispersed at prophase II. Silver dots at NOR position were observed on metaphase II chromosomes. PBs reappear at telophase II and give rise to the nucleoli detected in early spermatids.This cycle is compared with those reported in plants and in some other animal species.     

Mammalian protein SCP1 forms synaptonemal complex-like structures in the absence of meiotic chromosomes

Synaptonemal complexes (SCs) are evolutionary conserved, meiosis-specific structures that play a central role in synapsis of homologous chromosomes, chiasmata distribution, and chromosome segregation. However, it is still for the most part unclear how SCs do assemble during meiotic prophase. Major components of mammalian SCs are the meiosis-specific proteins SCP1, 2, and 3. To investigate the role of SCP1 in SC assembly, we expressed SCP1 in a heterologous system, i.e., in COS-7 cells that normally do not express SC proteins. Notably, under these experimental conditions SCP1 is able to form structures that closely resemble SCs (i.e., polycomplexes). Moreover, we show that mutations that modify the length of the central alpha-helical domain of SCP1 influence the width of polycomplexes. Finally, we demonstrate that deletions of the nonhelical N- or C-termini both affect polycomplex assembly, although in a different manner. We conclude that SCP1 is a primary determinant of SC assembly that plays a key role in synapsis of homologous chromosomes.     

Synaptonemal complexes and meiosis in myxomycetes

Synaptonemal complexes (SC) have been observed in spores 18–24 hr past cleavage in natural fruitings of Physarum cinereum, P. bogoriense, Hemitrichia stipitata, Tubifera ferruginosa, and Arcyria incarnata. Laboratory fruitings of Arcyria cinerea, Stemonitis herbatica, and a homothallic isolate of Physarum pusillum also have SC's present in spores during the same postcleavage period. The presence of these paired chromosomes of meiotic prophase in spores of species collected in nature and in a diversity of taxa suggests that the usual position of meiosis in Myxomycetes is inside the postcleavage spore. Criteria are proposed for evaluating the validity of the SC as an indicator of meiosis.     

Identification of a structural protein component of rat synaptonemal complexes

Synaptonemal complexes (SCs) are evolutionarily conserved nuclear structures of meiotic cells which form during the zygotene stage of the first meiotic prophase and are responsible for the pairing of homologous chromosomes. Their formation appears to be a prerequisite for crossing-over events and proper chromosome segregation during the first meiotic division. Despite knowledge of their central role in genetic recombination processes very little is known about the molecular composition and the mechanisms governing the assembly of the SCs. In the present study we report on the characterization of a monoclonal antibody (SC14f10) which enabled us to identify a novel SC protein termed SC48. Protein SC48 has a Mr of 48,000 and migrates in two-dimensional gels with a pH value of 6.9. By means of immunogold EM we localized this protein to the central region of the SC. In cell fractionation experiments we recovered protein SC48 together with SC-residual structures in a karyoskeletal fraction of pachytene spermatocytes. Our results indicate that SC48 is a meiosis-specific structural protein component of the SC probably involved in the pairing of homologous chromosomes.     

SYP-3 restricts synaptonemal complex assembly to bridge paired chromosome axes during meiosis in Caenorhabditis elegans

Synaptonemal complex (SC) formation must be regulated to occur only between aligned pairs of homologous chromosomes, ultimately ensuring proper chromosome segregation in meiosis. Here we identify SYP-3, a coiled-coil protein that is required for assembly of the central region of the SC and for restricting its loading to occur only in an appropriate context, forming structures that bridge the axes of paired meiotic chromosomes in Caenorhabditis elegans. We find that inappropriate loading of central region proteins interferes with homolog pairing, likely by triggering a premature change in chromosome configuration during early prophase that terminates the search for homologs. As a result, syp-3 mutants lack chiasmata and exhibit increased chromosome mis-segregation. Altogether, our studies lead us to propose that SYP-3 regulates synapsis along chromosomes, contributing to meiotic progression in early prophase.     

Structure of chromatin and chromosomes in preparations of interphase nucleus derivatives, prepared by removal of the nucleuar envelopes. II. Structure of chromatin and associations of chromosomes in stretched amembranous nuclei and mitotic figures]

Preparations of surface stretched amembranous nuclei and mitotic figures were used for revealing the high order nuclear and chromosomal structures. The preparations were obtained by dropping amembraneous nuclei and mitotic figures suspension in methanol-glacial acetic acid mixture (3:1) on wetted superclean slides. Amembraneous nuclei and mitotic figures were isolated from intact murine and human cells (lines L1210, SK-UT-1B, PHA-stimulated lymphocytes) by means of their 1-5 min prefixational capillary pipetting with freshly prepared 0.018-0.06% Triton X-100 solution in the conditional cultural medium. Stretched amembraneous nuclei and mitotic figures had no features of induced chromatin dispersion and compaction. Stretched interphase amembraneous nuclei showed spatially separated individual structures (thin chromatin fibres, nucleoli, intranuclear bodies), polymorphous pattern of perinucleolar chromatin aggregation and episodically expressed beaded thick chromatin fibres and a chromocenter. The chromomeric pattern of the spread chromosomes of mitotic figures was quite similar but hardly identical with that of G-banding. The stretched prometaphase mitotic figures in all tested cell types always contained loose "residual" nucleoli looking like typical prophase nucleoli as concerns their shape and number per cell (mitotic figure). The majority of chromosomes of stretched mitotic figures and of prophase amembraneous nuclei were attached to the nucleolar material. All tested cell lines showed almost the same variation in number of nucleolus-attached chromosomes, per both prophase amembraneous nucleus and prometaphase mitotic figure. Some chromosomes of stretched mitotic figures were colocated with "residual" nucleoli and looked shortened and strongly condensed. Other chromosomes, locally associated with "residual" nucleoli, were straight and oriented radially to these. Mutual chromosomal arrangements in mitotic cells on smears and in stretched mitotic figures were analogous. Equatorial plates from PBS-washed SK-UT-1B cells displayed a better stretching capacity than those from untreated cells. In the former case metaphase chromosomes were seen more uniformly stretched and well identified after GTG-banding procedure. The number of interchromosomal (mainly telomere-telomeric and telomere-centromeric) connections per stretched mitotic figure (or per stretched prophase amembraneous nucleus) was minimum in late prometaphase, maximum in prophase and early prometaphase, and intermediate in metaphase. The obtained data are discussed in terms of topology and longitudinal heterogeneity of mitotic chromosomes.     

Ultrastructure of mitosis inAmoeba proteus

Summary The fine structure ofAmoeba proteus nuclei has been studied during interphase and mitosis. The interphase nucleus is discoidal, the nuclear envelope is provided with a honeycomb layer on the inside. There are numerous nucleoli at the periphery and many chromatin filaments and nuclear helices in the central part of nucleus.In prophase the nucleus becomes spherical, the numerous chromosomes are condensed, and the number of nucleoli decreases. The mitotic apparatus forms inside the nucleus in form of an acentric spindle. In metaphase the nuclear envelope loses its pore complexes and transforms into a system of rough endoplasmic reticulum cisternae (ERC) which separates the mitotic apparatus from the surrounding cytoplasm; the nucleoli and the honeycomb layer disappear completely. In anaphase the half-spindles become conical, and the system of ERC around the mitotic spindle persists. Electron dense material (possibly microtubule organizing centers—MTOCs) appears at the spindle pole regions during this stage. The spindle includes kinetochore microtubules attached to the chromosomes, and non-kinetochore ones which pierce the anaphase plate. In telophase the spindle disappears, the chromosomes decondense, and the nuclear envelope becomes reconstructed from the ERC. At this stage, nucleoli can already be revealed with the light microscope by silver staining; they are visible in ultrathin sections as numerous electron dense bodies at the periphery of the nucleus.The mitotic chromosomes consist of 10 nm fibers and have threelayered kinetochores. Single nuclear helices still occur at early stages of mitosis in the spindle region.     

Distribution of calcium during interphase and mitosis as observed by ion microscopy

The ion microscope, based on secondary ion mass spectrometry, has been used to demonstrate the distribution of calcium in the root tip cells of two plant species, Allium cepa and Vicia faba. Interphase nuclei showed higher intensities of calcium than cytoplasm, while nucleoli exhibited higher calcium intensities than the rest of the nucleoplasm. The chromosomes showed high intensities of calcium at all stages of mitosis. Calcium was also detected in the cell plate and phragmoplast region of dividing cells. It appears that during prophase calcium concentrates in the condensing chromosomes, and during telophase it is transferred to nucleoli. These observations suggest that chromosomes may serve as a reservoir of calcium during mitosis.     

Assembly of ovarian follicles in the caecilians Ichthyophis tricolor and Gegeneophis ramaswamii: light and transmission electron microscopic study

Though much is known about various aspects of reproductive biology of amphibia, there is little information on the cellular and mechanistic basis of assembly of ovarian follicles in this group. This is especially true of the caecilians. Therefore, taking advantage of the abundant distribution of caecilians in the Western Ghats of India, two species of caecilians, Ichthyophis tricolor and Gegeneophis ramaswamii, were subjected to light and transmission electron microscopic analysis to trace the sequential changes during the assembly of ovarian follicles. The paired ovaries of these caecilians are elongated sac-like structures each including numerous vitellogenic follicles. The follicles are connected by a connective tissue stroma. This stroma contains nests of oogonia, primary oocytes and pregranulosa cells as spatially separated nests. During assembly of follicles the oocytes increase in size and enter the meiotic prophase when the number of nucleoli in the nucleus increases. The mitochondrial cloud or Balbiani vitelline body, initially localized at one pole of the nucleus, disperses through out the cytoplasm subsequently. Synaptonemal complexes are prominent in the pachytene stage oocytes. The pregranulosa cells migrate through the connective tissue fibrils of the stroma and arrive at the vicinity of the meiotic prophase oocytes. On contacting the oocyte, the pregranulosa cells become cuboidal in shape, wrap the diplotene stage oocyte as a discontinuous layer and increase the content of cytoplasmic organelles and inclusions. The oocytes increase in size and are arrested in diplotene when the granulosa cells become flat and form a continuous layer. Soon a perivitelline space appears between the oolemma and granulosa cells, completing the process of assembly of follicles. Thus, the events in the establishment of follicles in the caecilian ovary are described.     

Mitotic reversion in prophase of PTK1 cells induced by argon laser microirradiation

In this paper, we report the effects of laser microirradiation of prophase nucleoli and mitotic chromosomes in cells of female rat kangaroo kidney epithelial cell line PTK1. When the laser power delivered to sample surface was 90-190 mW, irradiation of one of the two nucleoli in the prophase cell did not inhibit the mitotic progress, but resulted in the loss of the irradiated nucleolus in daughter cells. When the laser power was increased to 360-420 mW, either irradiation of the nucleolus or chromosome in midprophase caused a blockage of mitosis at terminal midprophase. The irradiated cells returned morphologically to early prophase. No mitotic reversion occurred in the case of irradiation of chromosomes at late prophase, prometaphase, metaphase, and anaphase. Irradiation of the cytoplasm in prophase cells caused a 50-70 min mitotic delay at prophase. However, the irradiated cells underwent successive mitotic divisions. The mechanism of laser-induced mitotic prophase reversion is discussed.     

OBSERVATIONS ON SYNAPTONEMAL COMPLEXES IN PREMEIOTIC INTERPHASE OF WHEAT

Synaptonemal complexes (SCs) were found in stage 3, premeiotic (S phase) pollen mother cell (PMC) nuclei of wheat which were labeled with ³H-thymidine. Three nucleoli are present in PMC nuclei at the beginning of stage 3, premeiotic interphase (S3). During S3, nucleoli move toward the nuclear envelope and fuse to form one nucleolus near the end of the stage. PMC nuclei labeled with ³H-thymidine were serially sectioned to show that more than one nucleolus was present and that SCs were also present in these DNA synthetic nuclei. Entire S3 PMC nuclei were serially sectioned to show the presence of SCs and all three nucleoli. Entire leptotene nuclei were also serially sectioned and segments of SCs were found. It is concluded that the association of homologous chromosomes in S3 of wheat is an early step in SC formation which proceeds through leptotene and is completed in zygotene and pachytene. Thus there is evidence that the continuum of chromosome pairing in wheat starts much earlier than was once thought.     

Mitotic reversion in prophase of PTK1 cells induced by argon laser microirradiation

In this paper, we report the effects of laser microirradiation of prophase nucleoli and mitotic chromosomes in cells of female rat kangaroo kidney epithelial cell line PTK₁. When the laser power delivered to sample surface was 90–190 mW, irradiation of one of the two nucleoli in the prophase cell did not inhibit the mitotic progress, but resulted in the loss of the irradiated nucleolus in daughter cells. When the laser power was increased to 360–420 mW, either irradiation of the nucleolus or chromosome in midprophase caused a blockage of mitosis at terminal midprophase. The irradiated cells returned morphologically to early prophase. No mitotic reversion occurred in the case of irradiation of chromosomes at late prophase, prometaphase, metaphase, and anaphase. Irradiation of the cytoplasm in prophase cells caused a 50–70 min mitotic delay at prophase. However, the irradiated cells underwent successive mitotic divisions. The mechanism of laser-induced mitotic prophase reversion is discussed.     

Laser microbeam irradiation of the juxtanucleolar region of prophase nucleolar chromosomes

To further understand the function of the nucleolus organizer (NO), especially as it relates to the mitotic cycle, we extended our previous irradiation studies to prophase chromosomes and nucleoli. The juxtanucleolar region of nucleolar chromosomes was irradiated with the argon laser microbeam, and cells were observed for several days. Nuclei with two nucleoli were generally chosen for irradiation because of their two clear secondary constrictions. Summarized results are as follows: (1) When either one or several juxtanucleolar sites of both or all nucleoli are irradiated, the mitotic process is blocked and the cells return to interphase. (2) When only the chromosomes associated with the largest nucleolus are irradiated, mitosis is also blocked. (3) When the juxtanucleolar regions of the smallest nucleolus are irradiated, the cells generally go into metaphase and complete division, but with a reduction in the number of resulting nucleoli. (4) When the nucleoli themselves are irradiated, mitosis proceeds and daughter nuclei show no reduction in nucleolar number. (5) When chromosomes are randomly irradiated at non-juxtanucleolar regions, the nucleus divides and produces the same number of nucleoli in each daughter nucleus as were present in the mother cell.