The synaptonemal complexes of Caenorhabditis elegans: pachytene karyotype analysis of male and hermaphrodite wild-type and him mutants

Only five synaptonemal complexes (SC), representing the 5 autosomes, are present in wild-type, him-4 and him-8, Caenorhabditis elegans males, whereas there are six SCs, accounting for 5 autosomal bivalents and the XX bivalent, in the C. elegans hermaphrodite. The univalent X chromosome of the male is present as a heterochromatic X-body in spermatocyte pachytene nuclei. The XX bivalent in wild-type, him-4 and him-8 hermaphrodites (SC1, 2.5 m in length) represented 6% of the total karyotype length and a SC of this size is missing from the respective male karyotypes. This corresponds with the fact that the total male karyotype length is only approximately 94% that of the hermaphrodite. Associated with the central element of the SC are structures termed SC knobs that were first described in the wild-type hermaphrodite. The six SC knobs present in the wild-type hermaphrodite oocyte pachytene nuclei and the two SC knobs in the male spermatocyte pachytene nuclei are apparently randomly placed with the exception that they are never found at the ends of the SC. This is also true in him-4 and him-8 in which case there are 3 and zero SC knobs in the hermaphrodites, respectively, and one SC knob each in the male pachytene nuclei. The decrease in number of SC knobs in hermaphrodite to male represents a true sex difference. The presence or absence of the SC knobs may influence the X chromosome nondisjunction process and this effect is not localized to the region of the SC on which the SC knob is located.     

Three-Dimensional Ultrastructural Karyotype Analysis from the Meiotic Parthenogenetic Nematode Heterodera betulae

Meiotic chromosome structure and function are described in the plant-parasitic nematode Heterodera betulae. Twelve synaptonemal complexes (SCs) were reconstructed from pachytene nuclei; therefore, n=12 is predicted for this species. Morphologically distinct sex chromosomes were not observed. Only one end of the SC is attached to the nuclear envelope, and there is no bouquet arrangement at pachytene. The structure of the SC in this meiotic parthenogenetic nematode was different than in other nematodes that reproduce via amphimixis; a striated central element with transverse filaments was not observed. Multiple SCs, or polycomplexes, were present in the nucleus. Recombination nodules were not observed. The centrioles were comprised of nine doublet microtubules connected by a ring, which is a distinct modification from the typical nine triplet microtubules without any interconnecting structure.     

Localised chiasmata due to partial pairing: A 3D reconstruction of synaptonemal complexes in male Stethophyma grossum

The possible role of localised pairing as a mechanism producing localised chiasmata in Stethophyma grossum spermatocytes has been examined ultrastructurally. Nuclei at four successive stages of meiosis from leptotene to pachytene were reconstructed from a series of ultrathin sections and the extent of synapsis as demonstrated by synaptonemal complex (SC) formation was calculated. On the basis of the relative lengths of SCs and condensed chromosomes it was reasoned that only the centromeric ends of the long and medium length bivalents paired, and only one end of these SCs was found attached to the nuclear envelope. Only the three shortest bivalents paired completely, and both their SC ends were attached to the nuclear envelope. Thus pairing was directly related to the distribution of chiasmata. The extent of pairing at different stages suggests that the shortest bivalent paired very quickly, the longer ones progressively slower, and that pairing proceeded zip-like from a point at or very close to the end attached to the nuclear envelope, since all stretches of SC were attached to the envelope, and there were never more than 11 pieces, one for each bivalent. Chromosome decondensation and axial core formation did not occur far in advance of SC formation, and synapsis appeared to be much slower in S. grossum than in other species with non-localised chiasmata, as a larger proportion of the meiotic cysts were in zygotene, compared to Stauroderus scalaris and Locusta migratoria, although this was not quantified.     

Meiotic Structures in the Animal-Parasitic Nematode Ascaris megalocephala: Synaptonemal Complexes,Recombination Nodules,and Centrioles

Two synaptonemal complexes (SCs) were present in the pachytene nuclei of Ascaris megalocephala. The SC was tripartite and comprised of two lateral elements (25 nm) with a striated central element (25 nm) and a central region of 65 nm. Spherical recombination nodules were observed to be associated only with the central element, although they are non-existent in the related A. lumbricoides var. suum (Goldstein, 1977). The SCs were attached to the nuclear envelope at only one end, while the other end was free in the nucleoplasm. This lack of bouquet formation of the chromosomes is consistent with all other nematodes studied. Morphologically distinct sex chromosomes were not observed, which differs from the presence of five Y-chromosomes present in A. lumbricoides var. suum (Goldstein and Moens, 1976). Centrioles (0.2 µm wide) reproduced by budding off the parental centriole. The centrioles consisted of nine singlet microtubules connected by an electron-dense proteinaceous ring. This structure is consistent with centrioles described in other nematodes, yet distinctly different from the centriole structure observed in most organisms in which it consists of nine triplet microtubules without any connecting ring. Multiple synaptonemal complexes, or polycomplexes, are found in A. megalocephala and A. lumbriocoides var. suum. They appear as stacked SC and are present inside the nucleus during zygotene and in the cytoplasm at pachytene.     

The synaptonemal complexes of Meloidogyne: relationship of structure and evolution of parthenogenesis

The synaptonemal complexes of three amphimictic (meiotic) strains of Meloidogyne are examined in this study. M. microtyla (n = 19) has a tripartite synaptonemal complex (SC) comprised of two lateral elements and one central region with a distinct central element. The central region of the SC in both M. carolinensis (n = 18) and M. megatyla (n = 18) lack a distinct central element. The evolutionary history is different in the strains since M. microtyla has arisen by a mechanism involving an increase in chromosome number (from an ancestral stock of n = 18) while both M. carolinensis and M. megatyla have maintained the number of chromosomes of the ancestral stock. The structure of the SCs of the latter two strains are identical to the structure of the SC of the meiotic parthenogenetic M. hapla. Thus, the pachytene karyotype of M. carolinensis was reconstructed to establish the pairing pattern and identify any changes that may be related to the different morphology of the SC in an amphimictic stock. Although recombination nodules (RN) have been observed in the parthenogenetic M. hapla, none of the three amphimictic strains had any SC associated structures that resembled a RN.     

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.     

Surface spreading of synaptonemal complexes in three isopod crustacean species

The technique of whole mount spreading is used to investigate the SC of three species of Asellidae (isopod crustaceans), Asellus aquaticus, Proasellus coxalis and Proasellus meridianus, which display considerable differences in genomic DNA content.The three species, originally considered to belong to the same genus Asellus, were subsequently assigned to two separate genera: Asellus and Proasellus. The SCs of the three species differ in morphological details related to the shape of the centromere region, the attachments to the nuclear envelope, the width of the central region and the presence of twists of the lateral elements. Furthermore, they display some differences in the degree of compaction of genomic DNA in the mitotic chromosomes. The greatest differences are found between A. aquaticus and P. coxalis, while P. meridianus has several features in common with either species.     

The synaptonemal complexes of Caenorhabditis elegans: the dominant him mutant mnT6 and pachytene karyotype analysis of the X-autosome translocation

The dominant X-autosome heterozygous translocation mutant mnT6 of the nematode Caenorhabditis elegans has an X chromosome that has been reduced in size by 40%, yet the remainder of the bivalent pairs effectively at pachytene and has a synaptonemal complex (SC) that has a normal appearance. Six SCs are present in pachytene nuclei of this mutant which correspond to a haploid value of n=6. Nondisjunction of the X chromosome occurs at a rate of 37% and there are no Disjunction Regulator Regions (DRR) in this him (high incidence of males) mutant. This is consistent with the notion that DRRs either promote disjunction or inhibit nondisjunction of the X chromosome. Their occurrence in pachytene nuclei is independent of the mechanism responsible for nondisjunction, i.e. point mutations as in him-8 versus chromosomal aberrations as in mnT6. Although an SC is present along the entire length of the X chromosome, crossover suppression is observed in mnT6.     

The synaptonemal complexes of Caenorhabditis elegans: Pachytene karyotype analysis of the rad-4 radiation-sensitive mutant

In the rad-4 mutant of C. elegans there is a specific increase in the number of ‘Disjunction Regulator Regions’ (DDR) present on the synaptonemal complexes (SC) in pachytene nuclei. These DDRs either promote disjunction or inhibit nondisjunction of the X-chromosome as evidenced by the 10-fold decrease in the rate of X-chromosome nondisjunction as compared to the wild-type. The structure of the tripartite SC is normal, thus, the decrease in the rate of X-chromosome nondisjunction in the rad-4 mutant is not related to the structure of the SC but may be related to the number of DDRs. Other changes are also associated with the sensitivity to irradiation, i.e. the pachytene nuclear morphology is altered such that nuclei and nucleoli are 50% the size of wild-type. In addition, the autosomal: X-chromosome size ratio is reduced in the rad-4 mutant. That there are six SCs confirms n = 6 in this mutant and of these six SCs three can be identified: (1) the XX bivalent, SC No. 1, is the shortest and pairs synchronously with the autosomes; (2) the longest bivalent, SC No. 6, carries the nucleolar organizer region at one extreme end; and (3) SC No. 5 has two DDRs located approximately on μm apart from each other.     

Pachytene karyotype analysis of tetraploid Meloidogyne hapla females by electron microscopy

Pairing of homologous chromosomes results in the formation of 34 synaptonemal complexes (SC) at pachytene, corresponding to the 34 bivalents at metaphase I. No multivalent associations were observed and pairing occurs two-by-two. The modified SC, which lacks a central element, does not affect the pairing process. Only one end of the SC is attached to the nuclear envelope, although either end can attach. Total SC length and the number of recombination nodules in the tetraploid were about 1.5 times greater than in the diploid.     

Formation of cytoplasmic synaptonemal-like polycomplexes at leptotene and normal synaptonemal complexes at zygotene in Ascaris suum male meiosis

A thread-like (more than 70 cm long) testis of Ascaris suum, when examined under the light and electron microscope, reveals the linear succession of meiotic stages. Beginning from, at least, late leptotene, the spermatocytes are synchronous in their development. Thus within each transverse section of the testis all the spermatocytes are in the same stage. The spermatocytes at each stage of prophase I occupies several (4 to 10) cm of the whole testis length. — At leptotene, synaptonemal-like polycomplexes of lateral and central stacked elements are formed in the cytoplasm of spermatocytes. At late leptotene, the polycomplexes are attached to the external nuclear membrane. The polycomplexes disappear at zygotene. Slightly discernable axial cores are observed in the late leptotene chromosomes. The synaptonemal complexes (SCs) are formed at the zygotene stage, their structure being characteristically tripartite. The SCs disappear from the nuclei at the diffuse stage of prophase I. In other organisms completely developed polycomplexes of stacked lateral and central elements were never found during the presynaptic period of meiosis, although single or two parallel layers of aggregated central regions of SC were found in Neottiella meiocytes at the stage prior to chromosome pairing (Westergaard and von Wettstein, 1970, 1972). — First appearance of the polycomplexes in the cytoplasm insetead of the nucleus is also a novel fact. It is concluded that the polycomplexes at leptotene are formed by a self-assembly of the SC molecular material precociously synthesized in the cytoplasm. Two hypotheses regarding possible function and the further fate for leptotene polycomplexes are discussed.     

Surface spreading of synaptonemal complexes in locusts

Details are given of techniques for preparing surface spreads of locust spermatocytes for light and electron microscopy. The pachytene synaptonemal complex (SC) karyotypes of Locusta migratoria and Schistocerca gregaria are analysed and compared. Up to six different SCs can be identified in Locusta migratoria based on lengths, centromere positions, and possession of nucleolar organiser regions, but only two SCs are identifiable in Schistocerca gregaria. The total SC length is significantly greater in Schistocerca gregaria than in Locusta migratoria, and this difference is almost exactly proportional to the difference in the genomic DNA contents of the two species.     

Nodules associated with axial cores and synaptonemal complexes during zygotene in Psilotum nudum

Two-dimensional spreads of synaptonemal complexes (SCs) from the lower vascular plant Psilotum nudum were examined after staining with uranyl acetate-lead citrate (UP). Staining with UP allows visualization of lateral elements/axial cores (ACs), central elements, kinetochores, and nodules. Numerous darkly stained nodules were associated with forming SCs. In addition to nodules found on the central element of SC segments, other nodules were found at points of convergence between two adjacent ACs. Of these latter nodules, some were obviously associated with a fiber that connected adjacent ACs. No central element material was visible between the ACs, and the nodule complex appeared to be the only structure holding the ACs together. Although the function(s) of nodules during zygotene is unknown, the presence of a nodule-fiber complex that connects adjacent ACs before central element formation suggests that at least some of the nodules may be involved in synaptic initiation.     

Synaptonemal complex karyotyping in spermatocytes of the Chinese hamster (Cricetulus griseus)

Using the Counce-Meyer spreading technique, in over 70 spermatocytes it was possible consistently to obtain whole, flattened nuclei containing complete sets of pachytene SCs. The SCs are visible in both the phase and electron microscopes. Each SC is morphologically intact, preferentially stained, and attached to the nuclear envelope by a dense, terminal plaque. It is thus possible to trace each SC for its entire length. Also, a structure representing the kinetochore is clearly visible in each autosomal SC. Karyotypes comparable to the somatic karyotype can be constructed by arranging SCs according to length and kinetochore position. The observed regularity of SC morphology implies structural stability sufficient to withstand the stresses imposed by the procedure.— A coarse network of closely packed nuclear annuli connecting SC attachment plaques often provides end-to-end associations and may tend to immobilize SCs during processing.— Three kinds of perturbation of SC structure are encountered. Twists in the SC frequently occur, but no regular pattern or correspondence with chiasma distribution is observed. SCs occasionally hook around each other without disruption, but in two instances the unpaired axis of the X apparently was interlocked within an autosomal SC. Stretching of the SC is infrequent; it is conspicuous when it occurs and is usually associated with other obvious distortions of the nucleus.— Distinctive morphologies of the X and Y chromosomes facilitate their identification in all preparations. — During zygotene, autosomal synapsis, i.e., the formation of SCs from the pairing of single axial elements, initiates at distal ends and terminates at the kinetochore region; neither initiation nor termination is synchronous among all autosomes.     

The impact of entropy on the spatial organization of synaptonemal complexes within the cell nucleus

We employ 4Pi-microscopy to study SC organization in mouse spermatocyte nuclei allowing for the three-dimensional reconstruction of the SC's backbone arrangement. Additionally, we model the SCs in the cell nucleus by confined, self-avoiding polymers, whose chain ends are attached to the envelope of the confining cavity and diffuse along it. This work helps to elucidate the role of entropy in shaping pachytene SC organization. The framework provided by the complex interplay between SC polymer rigidity, tethering and confinement is able to qualitatively explain features of SC organization, such as mean squared end-to-end distances, mean squared center-of-mass distances, or SC density distributions. However, it fails in correctly assessing SC entanglement within the nucleus. In fact, our analysis of the 4Pi-microscopy images reveals a higher ordering of SCs within the nuclear volume than what is expected by our numerical model. This suggests that while effects of entropy impact SC organization, the dedicated action of proteins or actin cables is required to fine-tune the spatial ordering of SCs within the cell nucleus.     

Spermatocytes of the caddisfly Potamophylax rotundipennis (Trichoptera, Insecta): a fine structure study with emphasis on synaptonemal complex plates associated with chromatin

Electron microscopy of ultrathin sections was used to study the restructuring of primary spermatocytes in a caddisfly, Potamophylax rotundipennis (Limnephilidae). Spindle structure was also examined using light microscopy of dividing spermatocytes lysed in a microtubule-stabilizing buffer. The bulk of pachytene spermatocytes was usual in that the nuclei contained tripartite synaptonemal complexes (SCs). The SCs were attached end-on to the inner face of the nuclear envelope and loosely surrounded by electron-dense chromatin. Cells of this type gave rise to late prophase I spermatocytes, where SCs were missing and chromatin condensation was advanced. By metaphase I, a conventional bipolar spindle apparatus assembled, bivalents were aligned at the spindle equator, and membrane sheets were scattered throughout the spindle matrix. Prominent interzone spindles were typical of telophase spermatocytes. However, a subset of prophase I spermatocytes possessed unusual forms of SCs. The analysis of short series of ultrathin sections through the nuclei revealed plates composed of synaptonemal complex material. These elements will be referred to as 'SC plates'. Within the SC plates, the tripartite organization typical of regular SCs was preserved. The chromatin surrounding the SC plates was highly condensed. The SC plates ended abruptly within the nuclear lumen and did not reach the nuclear envelope. Finally, branching of SC plates was common. In light of the bizarre organization of SC material and its relation to the chromatin, and because spermatocytes with SC plates do not readily fit into the regular development of male germ cells in the caddisfly, we venture the suggestion that the SC plates are not physiological intermediates of SC disassembly. The affected cells most probably fail to complete meiosis.     

Synaptonemal complexes of normal and mutant yeast chromosomes (Saccharomyces cerevisiae)

Synaptonemal complex (SC) analysis of six laboratory yeast strains showed the SC karyotypes to be repeatable within strains. Chromosomal differences were found between strains. In five of the strains, two SCs insert into the nucleolus. This represents a single bivalent with a nucleolar organizer in a medial position as is suggested by genetic data or two bivalents each with a terminal nucleolar organizer. In the first interpretation, n=16; in the second, n=17. Strain Tris has a single nucleolar SC and n=17. In strains DCx374, DCx416 and x 8366a the genetically determined rearrangements of linkage group III could not be identified. Presumably the short SC (0.33 m) associated with linkage group III cannot accommodate an inversion loop or a translocation configuration. The strains however were found to harbour a reciprocal translocation involving the nucleolar chromosome. Trisomy for one of the longer chromosomes was observed in Tris and spo10. It is concluded that rearrangements of the medium and long but not short yeast chromosomes can be detected cytologically. — Measurements of nuclear volumes show SC length to vary with artifactually induced swelling of the nucleus. Linear regression of SC length over nuclear radius indicates that actual SC length is only about one-half the observed length. As a result the DNA packing per SC unit length is higher then previously estimated.     

Development of the synaptonemal complex and the “recombination nodules” during meiotic prophase in the seven bivalents of the fungus Sordaria macrospora Auersw

Complete reconstruction of seven leptotene, six zygotene, three pachytene and three diplotene nuclei has permitted to follow the pairing process in the Ascomycete Sordaria macrospora. The seven bivalents in Sordaria can be identified by their length. The lateral components of the synaptonemal complexes (SC) are formed just after karyogamy but are discontinuous at early leptotene. Their ends are evenly distributed on the nuclear envelope. The homologous chromosomes alignment occurs at late leptotene before SC formation. The precise pairing starts when a distance of 200–300 nm is reached. Each bivalent has several independent central component initiation sites with preferentially pairing starting near the nuclear envelope. These sites are located in a constant position along the different bivalents in the 6 observed nuclei. The seven bivalents are not synchronous either in the process of alignment or in SC formation: the small chromosomes are paired first. At pachytene the SC is completed in each of the 7 bivalents. Six bivalents have one fixed and one randomly attached telomeres. The fixed end of the nucleolar organizer is the nucleolus anchored end. At diffuse stage and diplotene, only small stretches of the SC are preserved. The lateral components increase in length is approximately 34% between leptotene and pachytene. Their lengths remain constant during pachytene. From zygotene to diplotene the central components contain local thickenings (nodules). At late zygotene and pachytene each bivalent has 1 to 4 nodules and the location of at least one is constant. The total number of nodules remains constant from pachytene to diplotene and is equal to the mean total number of chiasmata. The observations provide additional insight into meiotic processes such as chromosome movements, initiation and development of the pairing sites during zygotene, the existence of fixed telomeres, the variations in SC length. The correspondence between nodules and chiasmata are discussed.     

An exploration of the role of Sertoli cells on fetal testis development using cell ablation strategy

Sertoli cells (SCs) are presumed to be the center of testis differentiation because they provide both structural support and biological regulation for spermatogenesis. Previous studies suggest that SCs control germ cell (GC) count and Leydig cell (LC) development in mouse testes. However, the regulatory role of SCs on peritubular myoid (PTM) cell fate in fetal testis has not been clearly reported. Here, we employed Amh‐Cre; diphtheria toxin fragment A (DTA) mouse model to selectively ablate SCs from embryonic day (E) 14.5. Results found that SC ablation in the fetal stage caused the disruption of testis cords and the massive loss of GCs. Furthermore, the number of α‐smooth muscle actin‐labeled PTM cells was gradually decreased from E14.5 and almost lost at E18.5 in SC ablation testis. Interestingly, some Ki67 and 3β‐HSD double‐positive fetal LCs could be observed in Amh‐Cre; DTA testes at E16.5 and E18.5. Consistent with this phenomenon, the messenger RNA levels of Hsd3b1, Cyp11a1, Lhr, Star and the protein levels of 3β‐HSD and P450Scc were significantly elevated by SC ablation. SC ablation appears to induce ectopic proliferation of fetal LCs although the total LC number appeared reduced. Together, these findings bring us a better understanding of SCs’ central role in fetal testis development.     

Altered distribution of MLH1 foci is associated with changes in cohesins and chromosome axis compaction in an asynaptic mutant of tomato

In most multicellular eukaryotes, synapsis [synaptonemal complex (SC) formation] between pairs of homologous chromosomes during prophase I of meiosis is closely linked with crossing over. Asynaptic mutants in plants have reduced synapsis and increased univalent frequency, often resulting in genetically unbalanced gametes and reduced fertility. Surprisingly, some asynaptic mutants (like as1 in tomato) have wild-type or increased levels of crossing over. To investigate, we examined SC spreads from as1/as1 microsporocytes using both light and electron microscopic immunolocalization. We observed increased numbers of MLH1 foci (a crossover marker) per unit length of SC in as1 mutants compared to wild-type. These changes are associated with reduced levels of detectable cohesin proteins in the axial and lateral elements (AE/LEs) of SCs, and the AE/LEs of as1 mutants are also significantly longer than those of wild-type or another asynaptic mutant. These results indicate that chromosome axis structure, synapsis, and crossover control are all closely linked in plants.