Axel J. J. Dietrich

The gene encoding a major component of the lateral elements of synaptonemal complexes of the rat is related to X-linked lymphocyte-regulated genes.

The lateral elements of synaptonemal complexes (SCs) of the rat contain major components with relative electrophoretic mobilities (M(r)S) of 30,000 and 33,000. After one-dimensional separation of SC proteins on polyacrylamide-sodium dodecyl sulfate gels, these components show up as two broad bands. These bands contain closely related proteins, as judged from their peptide maps and immunological reactivity. Using affinity-purified polyclonal anti-30,000- and anti-33,000-M(r) component antibodies, we isolated a cDNA encoding at least one of the 30,000- or 33,000-M(r) SC components. The protein predicted from the nucleotide sequence of the cDNA, called SCP3 (for synaptonemal complex protein 3), has a molecular mass of 29.7 kDa and a pI value of 9.4. It has a potential nucleotide binding site and contains stretches that are predicted to be capable of forming coiled-coil structures. In the male rat, the gene encoding SCP3 is transcribed exclusively in the testis. SCP3 has significant amino acid similarity to the pM1 protein, which is one of the predicted products of an X-linked lymphocyte-regulated gene family of the mouse: there are 63% amino acid sequence similarity and 35% amino acid identity between the SCP3 and pM1 proteins. However, SCP3 differs from pM1 in several respects, and whether the proteins fulfill related functions is still an open question.

Localization of SCP2 and SCP3 protein molecules within synaptonemal complexes of the rat

Abstract. SCP2 and SCP3 are major protein components of the lateral elements (LEs) of synaptonemal complexes (SCs) of the rat, with Mrs of 173,000 and 30,000. We performed a detailed immunocytochemical comparison of the localization of SCP2 and SCP3 within SCs at the electron microscopic level. The ultrastructural localization of SCP2 and SCP3 was analyzed by immunogold labeling of two types of preparations, namely surface-spread spermatocytes and ultrathin sections of Lowicryl-embedded testicular tissue of the rat. For each of the antisera used, the distribution of immunogold label over SCs in surface-spread spermatocytes differed significantly from the distribution of label on sections. We attributed this difference to artifacts caused by the surface-spreading technique, and therefore we relied on sections for the precise localization of epitopes. On sections, the distribution of label obtained with two antisera against nonoverlapping, widely separated fragments of SCP2 did not differ significantly. There was a small but significant difference between the labeling pattern obtained with an anti-SCP3 serum and the pattern obtained with either of the two antisera against fragments of SCP2; although for all three antisera the peak of the immunogold label coincided with the center of the LE, the distributions of label obtained with the antisera against fragments of SCP2 were asymmetrical, with a shoulder at the inner side of the LE, whereas the distribution of label obtained with anti-SCP3 serum was symmetrical. Furthermore, we observed fuzzy connections between the LEs that were labeled by anti-SCP2 but not anti-SCP3 antibodies. It is possible that labeling of these fuzzy bridges caused the shoulder in the gold label distributions obtained with anti-SCP2 antibodies.

Two major components of synaptonemal complexes are specific for meiotic prophase nuclei

Monoclonal antibody II52F10 was elicited against purified synaptonemal complexes (SCs); it recognizes two major components of the lateral elements of SCs, namely an Mr=30 000 and an Mr=33000 protein. We studied the distribution of the antigens of II52F10 within tissues and cells of the male rat by immunoblot analysis and immuno-cytochemical techniques. Nuclear proteins from various cell types, including spermatogonia and spermatids, did not react with antibody II52F10 on immunoblots; the same holds for proteins from isolated mitotic chromosomes. As expected, an Mr=30 000 and an Mr=33 000 protein from spermatocyte nuclei did react with the antibody. In cryostat sections of liver, brain, muscle and gut we could not detect any reaction with II52F10. In the testis the reaction was confined to SCs or SC fragments. Partly on the basis of indirect evidence we identified the antigen-containing cells as zygotene up to and including post-diffuse diplotene spermatocytes. The persistence of some antigen-containing fragments in the earliest stages of spermatids could not be excluded. We conclude that the lateral elements (LEs) of SCs are not assembled by rearrangement of pre-existing components of the nucleus: at least two of their major components are newly synthesized, presumably during zygotene. Furthermore we conclude partly from indirect evidence that the major components of the LEs of SCs are not involved in the chromosome condensation processes that take place during the earliest stages of meiotic prophase.

A light- and electron microscopic analysis of meiotic prophase in female mice.

In this paper we describe meiotic prophase of female mice on successive days of embryonic and early postnatal development. For this purpose we used three different techniques on ovarian material, i.e., Giemsa staining for the light microscopic study of chromatin, silver staining for the light microscopic study of the synaptonemal complex (SC), and agar filtration followed by uranyl acetate staining for the electron microscopic study of the SC. — In all types of preparation it was impossible to distinguish leptotene stages, and we conclude that if leptotene really exists, it is of very short duration. — Two types of zygotene stages were found: the “normal” one, resembling zygotene stages in male mice, and a second type that has never been described in males and is characterized by, probably stable, unpaired regions together with totally unpaired axial elements of the SC. — The duration of pachytene was found to be 3–4 days, which is considerably shorter than in males. During early diplotene despiralization of the chromatin and disintegration of the axes of the SC were usually found together with desynapsis. — A considerable variation in distribution of meiotic stages was found between different litters in the same day of gestation. Fetuses in the same litter showed no significant variation. However, the oocytes in an ovary did not pass through meiosis synchronously, with differences up to several days. The appearance of chromosomes in a highly contracted state could not be interpreted as a preleptotene condensation stage but probably is a mitotic phenomenon.

Tissue distribution of two major components of synaptonemal complexes of the rat

In this paper we describe an analysis of the tissue distribution of two recently identified components of synaptonemal complexes (SCs), an Mr 125000 and an Mr 190000 protein, in the male rat by immunoblot analysis and immunocytochemical techniques. We compared the tissue distribution of these antigens with that of two earlier identified SC components, an Mr 30000 and an Mr 33000 polypeptide. For this purpose we used monoclonal antibodies (Mabs) that react exlusively with SCs in lysed spermatocytes, and that recognize the above mentioned antigens specifically in immunoblots of SC proteins or of nuclear proteins from spermatocytes: these were Mab IX9D5 (anti-190000), Mab IX5B2 (anti-125000), Mab II52F10 (anti-30000+33000), and Mab IX8G9 (anti-30000+33000). In the immunoblot experiments, we could detect the Mr 190000 and 125000 antigens exclusively in blots of SC proteins or nuclear proteins from spermatocytes; these antigens were not detectable in blots of nuclear proteins from liver, brain, spermatogonia or spermatids or in blots of proteins from mitotic chromosomes or nuclear laminae. With the anti-30000+33000 Mabs we obtained essentially the same result, except that Mab IX8G9, but not II52F10, recognizes a small amount of Mr 30000 antigen in blots of nuclear proteins from spermatids and spermatogonia. Although this might be ascribed to contamination of the isolated spermatids and spermatogonia, we cannot exclude that a small amount of Mr 30000 antigen is present in these cells. In the immunofluorescence analysis, the testis was the only tissue that reacted detectably with the above antibodies. Within the testis, spermatocytes and some early spermatids were the only cell types that contained detectable amounts of antigen. The Mr 125000 antigen was exclusively observed in nuclei of spermatocytes, from zygotene up to and including diplotene, in paired segments of SCs. The Mr 30000+33000 and 190000 antigens were present in paired as well as unpaired segments of SCs in nuclei of permatocytes, from zygotene up to and including diplotene and in the nuclei of some early spermatids in presumed remnants of SCs. We conclude that SCs consist largely of meiosisspecific proteins.

Meiotic interference among MLH1 foci requires neither an intact axial element structure nor full synapsis

During meiosis, homologous chromosomes (homologs) perform reciprocal exchanges (crossovers) at a high frequency. Crossovers display interference, i.e. their spacing is more even than would be expected if they were placed randomly along the chromosomes. Concomitantly with crossover formation, synaptonemal complexes (SCs) appear between homologs: each chromosome forms an axial structure, the axial element (AE); the AEs of homologs align, and numerous transverse filaments connect the AEs to form an SC. Both the AE and the SC have been implicated in the imposition of interference. We investigated whether intact AEs or SCs are required for crossover interference in the mouse, using a mutant lacking AE protein SYCP3, which displays structurally abnormal AEs and incomplete synapsis. We estimated the level of interference from the spacing of immunofluorescent MLH1 foci, which mark almost all crossover sites in the mouse, along the SCs. The levels of interference among MLH1 foci in wild-type and Sycp3–/– mice were comparable, implying that neither an intact AE structure nor full synapsis is required for wild-type levels of interference.

A change in the phosphorylation pattern of the 30000-33000 M-r synaptonemal complex proteins of the rat between early and mid-pachytene

The lateral elements (LEs) of synaptonemal complexes (SCs) of the rat contain major components with relative electrophoretic mobilities (Mr, s) of 30000–33000, which are the products of a single gene. After one-dimensional separation of SC proteins on polyacrylamide-SDS gels, these components show up as two major bands, whereas upon two-dimensional electrophoresis they are resolved in at least 24 spots, which focus at pH 6.5 to 9.5. In this paper we show that these spots represent phosphorylation variants. For the analysis of the phosphorylation of the 30000-to 33000-Mr SC components during progression through meiotic prophase, we developed a procedure for isolation of fractions of testicular cells of the rat that are enriched in separate stages of meiotic prophase. Analysis of the 30000-to 33000-Mr SC components in these fractions by two-dimensional electrophoresis and immunoblotting showed that phosphorylated variants of the 30000-to 33000-Mr SC proteins occur throughout meiotic prophase. However, the extent of phosphorylation changes between early and mid-pachytene, when one phosphate group is probably added to each of the variants.

A light microscopic study of the development and behaviour of the synaptonemal complex in spermatocytes of the mouse

A method is presented for the sequential analysis of male meiosis using hydroxyurea (HU). HU produces a gap in the spermatogenic line. The front of surviving cells behind the gap was examined day by day using silverstained whole mount spreads on glass slides. With this method it was possible to study the development and behaviour of the synaptonemal complex (SC) in mouse spermatocytes by the light microscope. At zygotene no unpaired axial elements could be seen. Unpaired axial elements were found to be specific for the diplotene stage. The axes of the XY pair could be recognized from late zygotene up to diplotene.

Ultrastructural evidence for a triple structure of the lateral element of the synaptonemal complex

This study describes composition and localization of several substructures of the synaptonemal complex (SC) using different techniques. The techniques which were used were surface spreading, critical point drying of isolated SCs, and sectioning of Lowicryl embedded testis material. The lateral elements (LEs) of the SC appear to be composed of three lateral substructures: two morphologically identical major strands and a third strand which is considerably thinner. The thinner strand is localized on the inner side of the two major strands of the lateral element. In late pachytene/early diplotene stages when the SC starts to disintegrate more than three strands can be observed in the LEs. A model is presented and the function of the different substructures is speculated upon.

The application of microwave denaturation in comparative genomic hybridization

Comparative genomic hybridization (CGH) is a powerful tool for analyzing unbalanced chromosomal rearrangements in a variety of tissues. However, reproducibility of the technique is poor. We have developed an alternative protocol involving microwave denaturation of the metaphase chromosome preparations prior to the hybridization step. The advantage of this method for CGH is the retention of the morphology of the chromosomes and hence an improved chromosome banding pattern. Furthermore, it results in a consistently strong hybridization which is not dependent on the batch of lymphocytes used to obtain the metaphase chromosome spreads. This procedure has also proved to be applicable to nucleic acid hybridizations in general. The protocol, its application and the results of this method in CGH is discussed. Furthermore preliminary results of this method in paint and DNA probe hybridizations to chromosome spreads and to RNA in tissue sections are presented.