Synaptonemal complex spreading in Allium

A surface-spreading technique for synaptonemal complexes was applied to triploid Allium sphaerocephalon L. (Liliaceae). In early pachytene two of the three axial elements of each set of three homologues are synapsed, the third is intimately aligned with and accompanies them throughout their whole length. The unsynapsed axis is attached to the synaptonemal complex of the other 2 at up to 50 association sites per trivalent. The distribution of these sites within the trivalents is not even; they are under-represented in the proximal regions. From nought to eight switches (pairing partner exchanges), where the accompanying axis joins in synapsis in exchange for one of the two other strands, occur per trivalent. Very often the telomeres of the aligned axes are attached to their synapsed counterparts by dense spherules, which makes this type of association different from the interstitial ones. Frequently the unsynapsed axes show a double structure along short distances. In late pachytene the intercalary associations are abolished, allowing the unsynapsed axes to engage in various types of non-homologous pairing. Since the association sites involve homologous chromosomes and are less abundant in the pericentric regions (which are usually the last to synapse), it is conceivable that similar structures are responsible for the pre-synaptic alignment of homologues and provide the initiation sites for synaptonemal complex formation in diploids.     

Expression and functional analysis of <Emphasis Type="Italic">TaASY1</Emphasis> during meiosis of bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis>)

Background  

Pairing and synapsis of homologous chromosomes is required for normal chromosome segregation and the exchange of genetic material via recombination during meiosis. Synapsis is complete at pachytene following the formation of a tri-partite proteinaceous structure known as the synaptonemal complex (SC). In yeast, HOP1 is essential for formation of the SC, and localises along chromosome axes during prophase I. Homologues in Arabidopsis (AtASY1), Brassica (BoASY1) and rice (OsPAIR2) have been isolated through analysis of mutants that display decreased fertility due to severely reduced synapsis of homologous chromosomes. Analysis of these genes has indicated that they play a similar role to HOP1 in pairing and formation of the SC through localisation to axial/lateral elements of the SC.     

Synaptonemal complex analysis in spermatocytes of diploid and triploid Chinese shrimp Fenneropenaeus chinensis

A modified surface spreading technique for synaptonemal complex (SC) analysis was tested to assess the process of chromosome synapsis in spermatocytes of diploid and induced triploid Fenneropenaeus chinensis. Spermatocytes of diploid shrimp showed typical morphological characteristics of eukaryote SC, with complete synapsis of bivalents. No recognizable bivalent associated with sex chromosomes was observed in spermatocytes of diploid shrimp. However, differences in morphology of SC, including unsynapsed univalents, bivalents, totally paired trivalents with non-homologous synapsis, partner switches and triple synapsis were identified at early pachytene stage of triploid spermatocytes. Triple synapsis was especially common at late pachytene stage in spermatocytes of triploid shrimp. The observed abnormal synapsis behavior of chromosomes in spermatocytes indicated that triploid male shrimp may find it difficult to develop normal haploid sperm.     

The maize desynaptic1 mutation disrupts meiotic chromosome synapsis

In most eukaryotes, homologous chromosomes undergo synapsis during the first meiotic prophase. A consequence of mutations that interfere with the fidelity or completeness of synapsis can be failure in the formation or maintenance of bivalents, resulting in univalent formation at diakinesis and production of unbalanced spores or gametes. Such mutations, termed desynaptic mutations, can result in complete or partial sterility. We have examined the effect of the maize desynaptic1-9101 mutation on synapsis, using the nuclear spread technique and electron microscopy to examine microsporocytes ranging from early pachytene until the diplotene stage of prophase I. Throughout the pachytene stage, there was an average of about 10 sites of lateral element divergence (indicating nonhomologous synapsis), and during middle and late pachytene, an average of two and three sites of foldback (intrachromosomal) synapsis, per mutant nucleus, respectively. By the diplotene stage, the number of sites of lateral element divergence had decreased to seven, and there was an average of one foldback synapsis site per nucleus. Lateral element divergence and foldback synapsis were not found in spread pachytene nuclei from normal plants. These results imply that the normal expression of the dsy1 gene is essential for the restriction of chromosome synapsis to homologues. The abundance of nonhomologous synapsis and the persistence of extended stretches of unsynapsed axial elements throughout the pachytene stage of dsy1–9101 meiocytes suggests that this mutation disrupts both the fidelity of homology search and the forward course of the synaptic process. This mutation may identify a maize mismatch repair gene. Dev. Genet. 21:146–159, 1997. © 1997 Wiley-Liss, Inc.     

Longitudinal axis thickenings in whole-mount spreads of synaptonemal complexes from Tradescantia

The whole-mount spreading technique was used to examine the chromosome complement in ten zygotene nuclei of Tradescantia ohiensis var. paludosa. Spread preparations have normal synaptonemal complex (SC) morphology. Neither kinetochores nor recombination nodules were regularly visible. Cloudlike structures (LFSs) 2–6 m in diameter were sometimes associated with SC and with unsynapsed lateral components (LCs). They differed in number and location in different nuclei. Thickenings of the lateral elements and LCs were observed in mid through late zygotene nuclei. These longitudinal axis thickenings (LATS) were distributed fairly uniformly amongst the chromosomes and occurred in both synapsed and unsynapsed regions. There was a stage-dependent increase in the number and size of LATS. They were nonrandomly distributed along the length of a chromosome, being more frequent in synapsed areas, especially near junctions with unsynapsed regions.     

Effects of elevated temperature on meiotic chromosome synapsis in Allium ursinum

Synaptonemal complex (SC) formation in microsporocytes of Allium ursinum is severely affected by exposure of plants to 35° C for 30 h or longer. In spread preparations made from fresh and freeze-conserved material it was found that a high proportion of meiocytes is arrested at leptotene and shows no synapsis at all. In another group of nuclei synaptonemal polycomplex-like structures do occur between converging axial elements at presumed rudimentary SC initiation sites. Axial elements are virtually always thickened at these sites which seem to involve primarily heterologous chromosomes. A third situation is seen in nuclei where two or more lateral elements are engaged in the formation of longer stretches of aberrant SCs. These feature surplus material filling the central space. It may be assumed that this abnormal condition precludes crossing over and hence may be one of several ways by which elevated temperatures cause the chiasma reduction described here for A. ursinum and reported for several other organisms in the literature.     

Sex-dependent synaptic behaviour in triploid turbot,Scophthalmus maximus (Pisces,Scophthalmidae)

A surface-spreading synaptonemal complex (SC) technique was used to analyse spermatocytes and oocytes of triploid turbot (Scophthalmus maximus) in order to visualise the process of chromosome synapsis. The most conspicuous characteristic of triploid oocytes is that, in the trivalents, the lateral elements of the SC were frequently associated in threes, either completely along the length of the trivalent, or partially, forming a variety of forked structures. In these nuclei, synapsis usually occurred among homologous chromosomes and the number of bivalents observed was significantly higher than that expected under the assumption of random chromosome association among all partners. However, the frequency of trivalents was very low in triploid spermatocytes, triple synapsis being also scarce. In these nuclei chromosomes that were excluded from homologous synapsis become engaged in random SC formation, and, therefore a considerable number of non-homologous associations are produced. The causes of the synaptic differences observed in triploid males and females of turbot and their possible relation to the sterility displayed by these animals are discussed.     

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.     

Ultrastructure of the synaptic autosomes and the ZW bivalent in chicken oocytes

Chromosomal axes of chicken oocytes from pre- and post-hatching chickens were analyzed with a microspreading technique for electron microscopy. At leptotene, chromosomal axes begin to be formed as discontinuous, non-polarized axial segments. During zygotene synaptonemal complex (SC) formation begins at the axial ends attached to the nuclear envelope. Polarization of axial ends is nearly simultaneous with the beginning of SC formation. The complete SC set is found at pachytene and it consists of 38 SC's and an unequal SC which has been identified as the ZW pair. This unequal SC is formed by two axes of different length. The Z and W axes represent 6.2% and 4.5% respectively of the combined length of the SC set plus the Z axis. The unpaired segment of the Z axis shortens markedly from early to mid-pachytene and becomes thicker than the lateral elements of SCs. In the paired region the Z axis forms most of the twists around a straighter W axis, suggesting some extent of non-homologous pairing between the Z and W chromosomes in this region. The existence of partial synapsis of the Z and W axes without heteropycnosis of the sex chromosomes is in marked contrast to partial synapsis in the heteropycnotic XY body of mammalian spermatocytes.     

Synaptonemal complex formation in pollen mother cells of Tradescantia

Seven nuclei of Tradescantia sp. (2n=12) were prepared using Gillies' modification of the Counce-Meyer whole-mount spreading technique. These nuclei were examined for the type (homologous and nonhomologous), amount, and location of synaptonemal complex (SC) formation. Estimates of the total potential number of discrete initiations of SC formation ranged from 251–299 per nucleus. The average distance between sites of initiation ranged from 7.3 to 11.2 m in the different nuclei. Two groups of Tradescantia were used. Of the T. ohiensis var. paludosa plants, the one instance of irregularity in synapsis was associated with a pairing partner switchpoint. In the other plants derived from Mericle's Clone 02, all nuclei, even those in early zygotene, had several examples of foldback synapsis. The significance of the location of SC formation, and the occurrence of foldback synapsis is considered and a model of SC formation is proposed. In this model, a recognition of homology step is not considered necessary for SC formation; homologous synapsis is usually accomplished by spatial and temporal coordination of zygotene DNA synthesis.     

Synaptonemal complex analysis of heteromorphic trivalents in Lemur hybrids

Synaptonemal complexes (SCs) in surface spread pachytene spermatocytes of Lemur resemble those in other mammals and are of two types: metacentric (or submetacentric) and acrocentric, with a very short second arm. In autosomal SC and mitotic karyotypes of Lemur fulvus (2n=60) a 11 proportionality in relative length is observed as in other mammals. In an intraspecific lemur hybrid (2n=55) obtained by mating L. fulvus rufus (2n=60) x L. fulvus collaris (2n=51), G-band patterns show that 10 single acrocentric mitotic chromosomes correspond to the arms of 5 single metacentrics, implying homology. It is inferred that the metacentrics have evolved by centric (Robertsonian) fusion of the acrocentrics. In the SC karyotype of the hybrid all SCs are normal except for five which have the configurations expected of metacentric-acrocentric trivalents. Similarly, in L. f. collaris (2n= 51), with one unpaired metacentric and two unpaired acrocentrics, one such SC trivalent is present in the complement. In an SC trivalent, each of the acrocentric long axes is synapsed with an arm of the metacentric axis, confirming the homology predicted from banding similarities. At late zygotene, the acrocentric short arms, which are non-homologous, are the last to pair, demonstrating that synapsis of the homologous arms occurs first. At later pachytene the acrocentric short arms are fully synapsed, producing a short SC side arm. This subsequent non-homologous synapsis is taken to be an instance of the synaptic adjustment phenomenon which has been shown to lead to non-homologous synapsis in a duplication and several inversions in the mouse. The kinetochore of the metacentric is the same size as those of the acrocentrics, and thus is unlikely to have arisen by true centromeric fusion, but rather by a translocation. The kinetochores of the acrocentrics always lie together on the same side of the metacentric kinetochore (cis configuration), implying a single pairing face on the metacentric axis. The observed trivalent configuration may well constitute a prerequisite for proper meiotic disjunction in metacentric-acrocentric heterozygotes. Such a mechanism is consistent with fertility regularly observed in such hybrid lemurs.     

The Expression of Mutation sy2 Causing Nonhomologous Synapsis in Meiosis of Diploid Rye Secale cereale L.

The cytological expression of spontaneous mutation sy2 isolated from a population of weedy rye was examined. It was demonstrated that the primary defect of meiosis in the mutant plants is nonhomologous synapsis, which occurs simultaneously with the homologous one. An electron microscope study of the synaptonemal complex (SC) at prophase I showed synaptic abnormalities that were manifested as switches of synapting axial elements to the nonhomologous partner and the formation of foldbacks of lateral SC elements. The sy2 mutants are characterized by one to two such events per meiocyte. Nonhomologous synapsis leads to the appearance of univalents at metaphase I (on average 4.16 ± 0.002 per meiocyte) and multivalents (on average 0.12 ± 0.007 per meiocyte). The presence of multivalents in 12% of meiocytes at metaphase I may result from recombination in ectopic regions of homology. It is suggested that the sy2 mutation impairs a component of the system that limits synapsis in meiocytes to only homologous chromosome pairs.     

Synaptonemal complex analysis of mouse chromosomal rearrangements

Electron microscopy of surface-spread spermatocytes from mice heterozygous for a tandem duplication shows the heteromorphic synaptonemal complex (SC) to comprise two lateral elements of unequal length, the longer of which is buckled out in a characteristic loop, representing the unsynapsed portion of the duplication. The loop is a regular feature of late zygotene-early pachytene nuclei; it is longest at these early stages, but, through equalization of the two axes as a consequence of synaptic adjustment, it is replaced by a normal appearing SC at late pachytene. Because equalization, as indicated by a decrease in the percent difference between axes, may begin shortly after completion of synapsis, estimates of duplication segment length are restricted to a sample selected for least adjustment. — Although the mean position of the loop is constant at various pachytene substages, individual positions vary widely from cell to cell, consistent with the behavior expected of a duplication, but not of a deletion or an inversion. The length of the segment that is duplicated is estimated to be 22% of the normal chromosome, the midpoint of the segment is mapped at 0.61 of the chromosome distal to the kinetochore, and the ends of the segment are mapped at 0.50 to 0.72. Measurements of G-banded mitotic chromosomes give comparable values: duplication length, 24%; midpoint, 0.60, and segment ends, 0.48 and 0.71. This agreement constitutes further validation of the SC/spreading method for detecting and analyzing chromosomal rearrangements at pachytene and substantiates the fidelity with which the axes and SCs represent the behavior of chromosomes in synapsis.     

Meiotic mutants of rye Secale cereale L. II. The nonhomologous synapsis in desynaptic mutants sy7 and sy10

We studied the expression and inheritance of two spontaneous mutations found in different populations of rye Secale cereale L. that cause high univalent frequency in meiosis and low fertility. Both mutations were inherited as monogenic recessives. For each of the mutations the corresponding gene symbols (sy7 and sy10) were suggested although their allelism has not been studied. These mutants differ in chiasma frequency and in the number of univalents per meiocyte. Electron microscopy of the wholemount surface-spread synaptonemal complexes (SCs) from microsporocytes of both mutants revealed that during meiotic prophase I random synapsis began and progressed that involved not only homologous but also nonhomologous chromosomes. SCs were formed with frequent changes of pairing partners (switches) and intrachromosomal foldbacks of unpaired axial elements. As a result, incompletely synapsed, non-homologous and multivalent SCs were formed in mutants by the stage analogous to pachytene in normal plants. In sy7 a maximum in the number of switches and foldbacks were observed at zygotene, whereas in sy10 this occurred at pachytene. We suggest that it is the process of recognition of homology that is impaired in both mutants. This leads to indiscriminate synapsis and prevents chiasma formation. Both mutants may be classified as desynaptic.     

The Ph1 and Ph2 loci play different roles in the synaptic behaviour of hexaploid wheat Triticum aestivum

Triticum aestivum is an allohexaploid wheat (AABBDD) that shows diploid-like behaviour at metaphase-I. This behaviour is influenced by the action of several loci, Ph1 and Ph2 being the main loci involved. To study the effect of these two loci on chromosome pairing in T. aestivum we have analysed the synaptic pattern in fully traced spread nuclei at mid- and late-zygotene, and at pachytene, of three different genotypes of cv Chinese Spring: standard line, ph1b and ph2b mutants. The analysis of the synaptic progression showed that only a few nuclei accomplish synapsis in the ph2b genotype, whereas most nuclei completed synapsis in the standard and ph1b genotypes. This result indicates that the Ph2 locus affects synaptic progression. The number of synaptonemal complex (SC) bivalents and of the different SC multivalent associations were determined in each nucleus. The mean number of lateral elements involved in SC multivalent associations (LEm) at mid- zygotene was relatively high and showed similar values in the three genotypes. These values decreased progressively between mid-zygotene and pachytene in the genotypes with the Ph1 locus because of the transformation of multivalents into bivalents. In the ph1b genotype, this value only decreased between late-zygotene and pachytene. Therefore, multivalent correction was more efficient in the presence than in the absence of the Ph1 locus.It is concluded that the Ph1 and Ph2 loci bring about diploidization of allohexaploid wheat via a different mechanism. Received: 31 July 2000 / Accepted: 15 November 2000     

A Method for Preparation of Synaptonemal Complexes of Meiotic Chromosomes from Basidial Protoplasts of the White Button Mushroom Agaricus bisporus (Lange) Imbach.

For the first time, preparations of synaptonemal complexes (SCs) were made from meiotic chromosomes of white button mushroom (Agaricus bisporus) basidia. It is the first experience of obtaining SC preparations of filamentous fungi from isolated meiosporangium protoplasts. Previously, only yeast SC preparations were obtained following this approach. The method includes four major stages: isolation of basidium protoplasts by treatment of basidia with lytic enzymes, spreading of protoplast nuclei on a filmy support by osmotic shock, staining the preparations with silver nitrate, and examination under light and electron microscopes. The structures of spread premeiotic nuclei, axial elements of chromosomes, SCs, chromatin, and nucleoli were studied at the leptotene–diplotene stage of meiotic prophase I.     

Maize meiotic mutants with improper or non-homologous synapsis due to problems in pairing or synaptonemal complex formation

During meiotic prophase homologous chromosomes find each other and pair. Then they synapse, as the linear protein core (axial element or lateral element) of each homologous chromosome is joined together by a transverse central element, forming the tripartite synaptonemal complex (SC). Ten uncloned Zea mays mutants in our collection were surveyed by transmission electron microscopy by making silver-stained spreads of SCs to identify mutants with non-homologous synapsis or improper synapsis. To analyse the mutants further, zyp1, the maize orthologue of the Arabidopsis central element component ZYP1 was cloned and an antibody was made against it. Using antibodies against ZYP1 and the lateral element components AFD1 and ASY1, it was found that most mutants form normal SCs but are defective in pairing. The large number of non-homologous synapsis mutants defective in pairing illustrates that synapsis and pairing can be uncoupled. Of the ten mutants studied, only dsy2 undergoes normal homologous chromosome recognition needed for homologous pairing. The dsy2 mutation fails to maintain the SC. ZYP1 elongation is blocked at zygotene, and only dots of ZYP1 are seen at prophase I. Another mutant, mei*N2415 showed incomplete but homologous synapsis and ASY1 and AFD1 have a normal distribution. Although installation of ZYP1 is initiated at zygotene, its progression is slowed down and not completed by pachytene in some cells and ZYP1 is not retained on pachytene chromosomes. The mutants described here are now available through the Maize Genetics Cooperation Stock Center (http://maizecoop.cropsci.uiuc.edu/).     

Yeast axial-element protein,Red1, binds SUMO chains to promote meiotic interhomologue recombination and chromosome synapsis

The synaptonemal complex (SC) is a tripartite protein structure consisting of two parallel axial elements (AEs) and a central region. During meiosis, the SC connects paired homologous chromosomes, promoting interhomologue (IH) recombination. Here, we report that, like the CE component Zip1, Saccharomyces cerevisiae axial-element structural protein, Red1, can bind small ubiquitin-like modifier (SUMO) polymeric chains. The Red1–SUMO chain interaction is dispensable for the initiation of meiotic DNA recombination, but it is essential for Tel1- and Mec1-dependent Hop1 phosphorylation, which ensures IH recombination by preventing the inter-sister chromatid DNA repair pathway. Our results also indicate that Red1 and Zip1 may directly sandwich the SUMO chains to mediate SC assembly. We suggest that Red1 and SUMO chains function together to couple homologous recombination and Mec1–Tel1 kinase activation with chromosome synapsis during yeast meiosis.