Damage to synaptonemal complex structure and peculiarities of selection of mouse spermatocytes I at response to drug administration

Using immunocytochemistry methods, the structure of synaptonemal complexes (SC) of chromosomes in spread nuclei of primary spermatocytes of mice at 1, 10, and 36 days after the 10-day intraperitoneal administration of antibacterial preparations of three pharmacological groups: furacilin, an antiseptic derivative of nitrofuran; cifran, an antibiotic from the group of fluoroquinolones; and sextaphage, a polyvalent piobacteriophage was investigated. The maximal number of damages in the structure and behavior of synaptonemal complex was revealed on the first day after the end of preparation administration. On days 10 and 36, the total number of damages in SC structure decreased gradually. On the first day after the end of the administration of cifran and sextaphage in 41.8 and 25% of nuclei, respectively, the fragmentation of synaptonemal complexes was revealed and, in males to whom furacilin had been administered, the fragmentation of synaptonemal complexes was identified in 100% of nuclei. Multiple chromosome fragmentation is a meiotic catastrophe and results in the degeneration of cells without enabling the mechanism of pachytene arrest. The features of pachytene arrest were revealed in the nuclei of primary spermatocytes with the violation of chromosomes pairing. After the administration of sextaphage, circle structures released from the lateral elements of SC and are dyed with antibodies to SCP3 protein.     

The synaptonemal complex as part of the nuclear matrix of the flour moth, Ephestia kuehniella

A nuclear matrix fraction was prepared from ovaries of the achiasmatic flour moth, Ephestia kuehniella, by removal of the chromatin, using detergent treatment of homogenized ovaries or dissected ovary tips followed by DNase digestion and high salt extraction. Removal of DNA and histones from the nuclei was demonstrated by Feulgen staining and polyacrylamide gel electrophoresis (PAGE), respectively. By light microscopy, ribbon-like structures similar in dimension to the synaptonemal complex were observed in the oocyte after digestion of the chromosomes. Electron microscopic examination of matrix preparations of pachytene cells showed a defined synaptonemal complex structure with both lateral and central elements. Such structures were not found in either the fully differentiated nurse cells or in follicle cells which were exposed to the same preparative technique concurrently. However, in early post-pachytene nurse cells the typical polycomplex structures, formed in these cells from the synaptonemal complex, were found in nuclear matrix preparations. The results suggest an association of synaptonemal complexes with the nuclear matrix.     

SYNAPTONEMAL COMPLEXES IN RED ALGAE1,2

The presence of synaptonemal complexes in the nuclei of young tetraspore mother cells is described for the first time in the red algae. Synaptonemal complexes were found in Janczewskia gardneri Setchell, Levringiella gardneri Setchell, Gonimophyllum skottsbergii Setchell, and Polycoryne gardneri Setchell. The synaptonemal complexes consist of 2 lateral, dark-staining elements from which small fibrils extend to form a less densely staining central element. With minor variations, the dimensions and structure of these synaptonemal complexes correspond to those found in other organisms.     

Synaptonemal polycomplexes in spermatocytes of the gooseneck barnacle,Pollicipes polymerus Sowerby (Crustacea: Cirripedia)

Polycomplexes are described for the first time in spermatocytes of a cirripede crustacean, Pollicipes polymerus Sowerby. Synaptonemal complexes of regular tripartite construction are seen from zygotene to mid-pachytene. Although some of the synaptonemal complexes are disrupted at late pachytene and may degenerate at this stage, some persist and by diplotene may form polycomplexes by the bending and self-fusion of their lateral elements. These polycomplexes are still encompassed by chromosomes and consist of four dense plates and intercalated central elements and transverse fibers. Other polycomplexes with five or six dense plates, all of which are considerably wider than lateral elements of mid-pachytene synaptonemal complexes, are also seen in diplotene nuclei. These may be attached to a chromosome at only one end or may be in the nucleoplasm, free of chromosomal involvement except for fine fibrous connectives. No polycomplexes are seen in meiotic cells after diplotene and their fate is unknown. It is suggested that poly-complexes serve as sequestra for synaptonemal material which could prevent normal chromosomal disjunction.     

Synaptonemal complex proteins

Synaptonemal complexes were isolated from rate spermatocytes for the purpose of biochemical and morphological analysis. Several monoclonal antibodies were elicited against purified synaptonemal complexes to study the composition and assembly of these structures. Four classes of antibodies could be discriminated according to the polypeptides that they recognize on Western blots of purified synaptonemal complexes, namely antibodies recognizing (i) a 190-kDa polypeptide; (ii) a 30- and a 33-kDa polypeptide; (iii) two polypeptides with molecular weights of about 120 kDa; and (iv) polypeptides with molecular weights of 66-55 kDa. The localization of these antigens within spermatocytes was analyzed light microscopically, by means of the immunoperoxidase technique and ultrastructurally, by immunogold labelling of surface-spread spermatocytes. The 66- to 55-kDa polypeptides are not confined to synaptonemal complexes; rather, these polypeptides appear to be chromosomal components. The 190-, 30-, and 33-kDa polypeptides make part of the lateral elements of paired as well as unpaired segments of synaptonemal complexes. The 120-kDa polypeptides were localized on the inner edge of the lateral elements, specifically in paired segments of synaptonemal complexes. The distribution of the 190-, 120-, 30-, and 33-kDa polypeptides within the testis was analyzed by immunofluorescence staining of cryostat sections. All these polypeptides turned out to be specific for nuclei of zygotene up to and including diplotene spermatocytes. Only in some early spermatids could the 190-, 30-, and 33-kDa polypeptides be detected, presumably in remnants of synaptonemal complexes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Abnormalities in synaptonemal complexes in pollen mother cells of a lily hybrid

Two abnormalities, one in lateral elements of synaptonemal complexes the other involving whole complexes, have been studied with the electron microscope in pollen mother cells of the lily hybrid, Lilium aureliensis × L. henryi, which with the light microscope showed almost complete bivalent formation at metaphase. Brief water treatment of pollen mother cells prior to fixation, revealed that the aberrant configurations in lateral elements arose by breakage and subsequent folding of severed fragments up to about 0.8 m long. The abnormality ocurred at recognisable heterologous regions, apparently immediately after pairing. The folded fragments were eliminated from the chromosomes at some time during pachytene. Pseudo pairing was observed after synapsis between either more than one pair of homologues or one pair bent back on themselves, so as to produce polycomplexes. Seemingly, central elements could develop between lateral elements on their outer face under these conditions.     

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.     

Synaptonemal complex analysis in a human male carrier of a 4;6 translocation: heterosynapsis without previous homosynapsis

Summary Silver-stained synaptonemal complexes in surface-spread pachytene nuclei from a man, heterozygous for a reciprocal translocation, were analysed by electron microscopy. Contrary to the classically expected cross-shaped configuration, extensive non-homologous pairings were observed with asymetrical association in the lateral elements of the non-homologous arms of the quadrivalents. A possible role of the heterosynapsis in reproductive failure is discussed.     

Analysis of synaptonemal complexes in a heterozygous human male carrier of a reciprocal translocation involving an acrocentric chromosome: heterosynapsis without previous homosynapsis

Summary Silver-stained synaptonemal complexes in surface-spread pachytene nuclei from an oligospermic man, heterozygous for a reciprocal translocation involving an acrocentric chromosome, were analyzed by electron microscopy. Contrary to the classically expected configuration, nonhomologous pairing was observed with asymetrical association of the lateral elements of the nonhomologous arms of the quadrivalents. A possible role of heterosynapsis in germ cell conservation is discussed.     

An electron microscopic study of synaptonemal complex formation at zygotene in rye

A spreading technique was used to allow ultrastructural analysis of seventeen zygotene nuclei of rye (Secale cereale). Twenty pachytene nuclei were also examined. Lateral element lengths of the haploid complements decreased from 742 m at the beginning of zygotene to 451 m at the end of zygotene. Variation in pachytene synaptonemal complex lengths was also noted. Zygotene synaptonemal complex formation in rye is characterised by: (1) existence of a bouquet, with telomeric pairing initiation earliest; (2) multiple sites of initiation in each bivalent (maximum of 76 synaptonemal complex segments seen in one nucleus); (3) the potential number of pairing initiation sites may be higher (the average spacing of 4.42 m would allow approximately 160 sites per nucleus); (4) new pairing initiations occur almost until the end of zygotene; (5) initiation of new synaptonemal complexes and extension of existing synaptonemal complexes occur simultaneously. A simple zipping up of a few initiation sites is not the case in rye. Pairing in different bivalents of a nucleus is not completely synchronised, and the NOR in particular is often late to pair. Interlocking of lateral elements and synaptonemal complexes may lead to delayed completion of pairing in portions of bivalents, but interlocks are ultimately resolved. This resolution may involve breakage and rejoining of lateral elements.     

The meiotic prophase in Bombyx mori females analyzed by three-dimensional reconstructions of synaptonemal complexes

Serial sectioning followed by three dimensional reconstruction of lateral components of the synaptonemal complex have been used to follow chromosome pairing during the prophase of the achiasmatic meiotic division in the silkworm, Bombyx mori. During leptotene and early zygotene, the lateral components become attached to the nuclear envelope at a specific region, thus forming a chromosome bouquet. The attachment of lateral components to the nuclear envelope precedes the completion of the components between their attachment points. Synapsis and synaptonemal complex formation start during the period of lateral component organization in the individual nucleus. Telomeric movements on the nuclear envelope occur at two stages of the prophase: the chromosome pairing appears to be initiated by an association of unpaired ends of homologous chromosomes, the nature of this primary attraction and recognition being unknown. Secondly, the paired chromosomes become dispersed in the nucleus by shifting of attachment sites of completed synaptonemal complexes at the end of zygotene. This movement is possibly related to a membrane flow occurring during this stage. Membrane material is synthesized at the region of synaptonemal complex attachment. Later, the excess membrane material is shifted to the opposite pole where it protrudes into the lumen of the nuclei thus forming vacuoles. — Two previously undescribed features of chromosome pairing were revealed. In late zygotene, chromosome pairing and synaptonemal complex formation were frequently observed to be delayed or even prevented over a short distance by interlocking of two bivalents, both being attached to the nuclear envelope. Such interlocking of bivalents was not found in pachytene. Secondly, one nucleus was found in which two homologous chromosomes were totally unpaired while the remaining 27 bivalents were completed or in a progressed state of pairing. The lateral components of the two unpaired chromosomes had the same length and were located several microns apart, thus eliminating the possibility of a permanent association of homologous chromosomes before the onset of meiosis in Bombyx mori females. — During pachytene, one of the 8 cells belonging to the syncytial cell cluster characteristic of oogenesis continues the meiotic prophase whereas the remaining 7 cells, the nurse cells, enter a different developmental sequence, finally resulting in their degeneration. The synaptonemal complex of the oocyte develops into a sausage-like structure after pachytene by a deposition of dense material onto the lateral components, thus filling out most of the central region. The diameter of this modified synaptonemal complex reaches at least 300 nm, as compaired to a pachytene width of approximately 130 nm. Also, the length of synaptonemal complexes increases from 212 at zygotene/pachytene to at least 300 at the modified pachytene stage. In nurse cells, synaptonemal complexes are shed from the bivalents shortly after pachytene simultaneously with a condensation of the chromatin. These free synaptonemal complex fragments associate and form various aggregates, either more or less normal looking polycomplexes or various complex figures formed by reorganized synaptonemal complex subunits. Later stages have not been included in the present investigation.     

Alteration of meiotic chromosomal pairing and synaptonemal complexes by cycloheximide

When cells are exposed to cycloheximide during the synaptic period of meiotic prophase, the structure of the synaptonemal complex is markedly altered. The bulk of the lateral component is removed. When lily zygotene microsporocytes are subsequently transferred into a culture medium free from cycloheximide, normal synaptonemal complexes are again seen. Modification of the structure of the synaptonemal complex by treatment with cycloheximide for 4 days has little permanent effect on meiosis except at late zygonema or early pachynema. Treatment at this time produces meiocytes in which no synaptonemal complexes reform. When these cells proceed into diplotene and diakinesis they are devoid of chiasmatic chromosomes. The data suggest that the synaptonemal complex is essential if chiasmata are to be formed, and that a unique period exists when the formation can be interrupted.This work was supported by grants from the National Science Foundation (GB 5173X and GB 6476) and the National Institutes of Health (GM 16882).     

Sequential study of the synaptonemal complex in Syrian hamster (Mesocricetus auratus) and mouse (Mus musculus) oocytes by light and electron microscopy

We describe the behaviour of synaptonemal complexes (SCs) in Syrian hamster and mouse oocytes. InMesocricetus auratus, synaptonemal complexes can be observed from birth up to 7 days of life. In foetuses fromMus musculus, synaptonemal complexes can be observed from the 14th day of gestation up to the first day post-partum, when the cells enter the dictyotene stage. In both species, synaptonemal complexes show, in general, the same morphology described in male cells by light and electron microscopy, with the exception that the axes of the sex bivalent are not identifiable. The leptotene stage can be identified although it is probably of short duration. Only one type of zygotene (zygote ne II of Dietrich and Mulder(Chromosoma 88: 377), 1983) has been observed. In the hamster we also describe a desynaptic diplotene stage previous to the desintegration of the SCs. In oocytes from both species late pairing (or precocious separation) of a single bivalent can be seen in a few cells. Interlocking of some bivalents with delayed pairing of the affected region is rather frequent. Furthermore, hamster oocytes may show heterosynapsis of the telomeres of autosomal bivalents by pachytene.     

Two-dimensional spreads of synaptonemal complexes from solanaceous plants. I. The technique

Using beta-glucuronidase the cell walls of tomato and potato primary microsporocytes can be digested. When the resulting protoplasts are exposed to distilled water, they burst, and complete sets of synaptonemal complexes are released to settle on plastic coated slides. After drying and formalin fixation, the synaptonemal complexes can be stained with silver or phosphotungstic acid and observed in the light and/or electron microscope. Silver staining gives better contrast for both light and electron microscopy but stains only lateral elements and kinetochores. Phosphotungstic acid staining gives little or no contrast for light microscopy, but stains both the lateral and central elements of the synaptonemal complex, kinetochores, and structures that are probably recombination nodules for electron microscopy. This technique offers a powerful tool for genome analysis by allowing (1) the determination of relative and absolute lengths of synaptonemal complexes and chromosome arm ratios at pachytene, (2) the analysis of complex patterns of synapsis, and (3) the location of what are probably recombination nodules along the length of synaptonemal complexes.     

Two-Dimensional Spreads of Synaptonemal Complexes from Solanaceous Plants. I. The Technique

Using β-glucuronidsase the cell walls of tomato and potato primary microsporocytes can be digested. When the resulting protoplasts are exposed to distilled water, they burst, and complete sets of synaptonemal complexes are released to settle on plastic coated slides. After drying and formalin fixation, the synaptonemal complexes can be stained with silver or phosphotungstic acid and observed in the light and/or electron microscope. Silver staining gives better contrast for both light and electron microscopy but stains only lateral elements and kinetochores. Phosphotungstic acid staining gives little or no contrast for light microscopy, but stains both the lateral and central elements of the synaptonemal complex, kinetochores, and structures that are probably recombination nodules for electron microscopy. This technique offers a powerful tool for genome analysis by allowing (1) the determination of relative and absolute lengths of synaptonemal complexes and chromosome arm ratios at pachytene, (2) the analysis of complex patterns of synapsis, and (3) the location of what are probably recombination nodules along the length of synaptonemal complexes.     

Precocious formation of synaptonemal-like polycomplexes and their subsequent fate in female Ascaris lumbricoides var. suum

During meiotic interphase, before leptotene, synaptonemal-like polycomplexes are seen in the cytoplasm of the Ascaris lumbricoides oocytes and in the communal anucleate rachis. In some females short intranuclear synaptonemal complexes are present briefly at that early stage. The number of extranuclear complexes increases just before leptotene, some are attached to the pores of the nuclear membrane. During zygotene most polycomplexes disappear. At late pachytene they reappear in some females but not in others. The morphology, when first seen, is that of disorganized filamentous bodies, later lateral elements appear among the filaments. The dimensions of the lateral elements of the polycomplexes are variable. In the male the distribution of polycomplexes among the rachis, the cell cytoplasm, and at the nuclear envelope is similar to that observed in the female.These observations confirm the precocious occurrence of synaptonemal-like polycomplexes reported by Bogdanov (1977). Ascaris lumbricoides thus, uniquely, appears to manufacture synaptonemal complex-like material in the communal cytoplasm of the germ cells prior to the time that the full complement of synaptonemal complexes appears in the nucleus.     

Ultrastructural analysis of maize pachytene karyotypes by three dimensional reconstruction of the synaptonemal complexes

Aldehyde fixation followed by staining with phosphotungstic acid produces differential contrast between the synaptonemal complex and the chromatin of maize pachytene bivalents. Centromeres, heterochromatic knobs and large chromomeres are easily recognised. With this and other staining techniques the nucleolus organizer region can be differentiated into two components. — Microsporocyte nuclei at pachytene were serially sectioned and all ten bivalents reconstructed in five nuclei. An idiogram was derived from the mean chromosome (= synaptonemal complex) lengths, the arm ratios, positions of knobs and the nucleolus organizer region. The idiogram agrees well with that published from light microscopic analyses. However, bivalent lengths are only two thirds of those observed by light microscopy of squash preparations. Many telomeres of the bivalents are connected via chromatin to the nuclear envelope, but a varying number of free bivalent ends are observed in all five reconstructed nuclei. — Bivalents heterozygous for inversion 3b were reconstructed. In the presence of abnormal chromosome 10 (K10) the lateral components of the synaptonemal complex of chromosome 3 formed a typical inversion loop, while in one of the nuclei having no K10 the two lateral components of the long arms of chromosome 3 remained unpaired in the region of inversion heterozygosity. The presence of K10, which increases crossing-over frequencies and promotes intimate pairing at the light microscopic level, was thus found to permit formation of complete synaptonemal complexes in the inverted region. The extra terminal portion of the K10 chromosome folded back on itself and formed a morphologically normal synaptonemal complex in this — possibly non-homologously paired — region. The chromatin of centromeres and knobs from different bivalents were sometimes found to fuse, but the synaptonemal complexes transversing the fused centromeres or knobs retained their individuality.     

The synaptonemal complex and the spindle plaque during meiosis in yeast

Meiosis in Saccharomyces cerevisiae proceeds principally in the same manner as in other Ascomycetes. Leptotene is characterized by unpaired lateral components and pachytene by the presence of extensive synaptonemal complexes. The synaptonemal complex has the same dimensions and is similar in structure to those described for other organisms. Chromosome counts can now be made by reconstructing the synaptonemal complexes. Diplotene nuclei consistently contain a single polycomplex. The behaviour, doubling and the fine structure of the spindle plaque provide additional markers for the different stages of meiosis.     

Identification of two major components of the lateral elements of synaptonemal complexes of the rat

This paper describes the identification of two major components of the lateral elements of synaptonemal complexes of the rat by immunocytochemical techniques. We prepared monoclonal antibodies against synaptonemal complexes (SCs) by immunization of mice with purified SCs. One of these antibodies, II52F10, reacts with a 30 and a 33 kDa polypeptide, which are major components of purified SCs. Using this antibody, we studied the localization of its antigens light microscopically, by means of the indirect immunoperoxidase technique, as well as ultrastructurally, by means of the immunogold labeling technique. The immunolocalization was carried out on whole-mount preparations of lysed spermatocytes. The antibody reacts with paired as well as unpaired segments of zygotene, pachytene and diplotene SCs. In light microscopic preparations, the attachment plaques, particularly those of late pachytene and diplotene SCs, also appear to react strongly. In electron micrographs the lateral elements in paired as well as unpaired segments could be seen to react. No reaction was observed in the attachment plaques; however, in late pachytene and diplotene SCs the swollen terminal segments of the lateral elements did react with the antibody. Thus, we conclude that a 30 and a 33 kDa polypeptide make part of the lateral elements of synaptonemal complexes of the rat.     

X-Y chromosome univalency in the testes of hyperthermic mice: II. Light and electron microscopic analysis of synaptonemal complexes

Hyperthermia-induced X-Y dissociation has been observed in diakinesis-metaphase I sper-matocytes but not in pachytene spermatocytes, which have been implicated as highly susceptible to heat stress. To determine X-Y dissociation in pachytene spermatocytes and to compare levels of dissociation between pachytene and diakinesis-metaphase I spermatocytes male ICR mice were exposed to 35°C ± 0.07°C and 65% ± 0.14% relative humidity for 2 or 4 days. Control mice were housed at 24°C ± 0.04°C and 43% ± 0.58% relative humidity. Mice were killed 0, 3, 5, 8, or 10 days after stress and the testes processed for meiotic chromosome display at diakinesis-metaphase I and synaptonemal complex display at pachynema. Twenty-five to thirty cells per mouse at both stages of meiosis were observed with light microscopy, and pachytene spreads with transmission electron microscopy to determine heat-stress effects on synaptonemal complex structure. Statistical analyses revealed significant linear increases in X-Y dissociation with prolonged exposure to heat at pachynema and diakinesis-metaphase I. Levels of pachytene dissociation were one-half the levels of dissociation at diakinesis-metaphase I. The resolvable structure of the lateral elements of the synaptonemal complex was not affected by heat stress.