The structure and function of the synaptinemal complex inLilium longiflorum sporocytes

The development of meiotic prophase in pollen mother cells ofLilium longiflorum is presented through photomicrographs of squashes and sections and through electron micrographs of thick and thin sections. Emphasis is placed on the first appearance of axial cores, the participation of axial cores in the formation of synaptinemal complexes, the fine structure of the complex and the fate of the complex at the end of pachytene. It is shown that axial cores are formed in early meiotic prophase chromosomes and that the two axial cores of a set of homologous chromosomes participate in the formation of a synaptinemal complex. It is proposed that the transverse filaments of each axial core meet and interdigitate and so produce the transverse filaments of the complex. It is shown that the complex is axial to the pachytene bivalent and that the association of the complex with chromosomal material is terminated at the end of pachytene. The pairing affinity of the cores in homologous and non-homologous chromosome associations is discussed. The zygotene stage is defined in terms of the occurrence of synaptinemal complexes and the attachment of the nucleolus to the nuclear membrane during this stage is noted.     

The fine structure of meiotic chromosome polarization and pairing in Locusta migratoria spermatocytes

At the leptotene stage of meiotic prophase in Locusta spermatocytes (2n=22 telocentric autosomes + X-chromosome), each chromosome forms an axial core. The 44 ends of the autosomal cores are all attached to the nuclear membrane in a small region opposite the two pairs of centrioles of the juxtanuclear mitochondrial mass. At later stages of meiotic prophase, the cores of homologous chromosomes synapse into synaptinemal complexes. Synapsis is initiated near the nuclear membrane, in the centromeric and the non-centromeric ends of the chromosomes. Homologous cores have their attachment points close together and some cores are co-aligned prior to synapsis. At subsequent stages of zygotene, the number of synaptinemal complexes at the membrane increases, while the number of unpaired axial cores diminishes. At pachytene, all 11 bivalents are attached to the membrane at both ends, so that there are 22 synaptinemal complexes at the membrane near the centrioles. Because each bivalent makes a complete loop, the configuration of the classic Bouquet stage is produced. The X-chromosome has a poorly defined single core at pachytene which also attaches to the nuclear membrane. These observations are based on consecutive serial sections (50 to 100) through the centriolar zone of the spermatocytes. Labeling experiments demonstrated that tritiated thymidine was incorporated in the chromatin of young spermatocytes prior to the formation of the axial cores at leptotene. It is concluded that premeiotic DNA synthesis is completed well in advance of pairing of homologous chromosomes, as marked by the formation of synaptinemal complexes.     

The assembly of the synaptinemal complex.

The assembly of the synaptinemal complex in the ascomycete Neottiella was studied by three-dimensional reconstruction of a late zygotene nucleus. A single banded lateral component is formed between the two sister chromatids of each homologous chromosome prior to their pairing. The central regions are pre-assembled in organized form in folds of the granular part of the nucleolus and then converted into an amorphous transport form. The latter appears to move through the nucleoplasm to sites between the lateral components of synapsing homologous chromosomes. The central region material is reorganized into blocks with a recognizable central component and attached to one lateral component. The last step in the completion of the synaptinemal complex is the association of the free surface of the organized central region with the corresponding segment of the homologous lateral component. The findings are discussed in relation to mechanisms of chromosome pairing and chiasma formation.     

The Relation between the Axial Complex of Meiotic Prophase Chromosomes and Chromosome Pairing in a Salamander (Plethodon cinereus)

An investigation of the structure of meiotic chromosomes from primary spermatocytes of two salamanders, Plethodon cinereus and Desmognathus fusca, has been made using correlated light and electron microscopy. Feulgen squashes were compared with stained sections and these related to adjacent thin sections in the electron microscope. A transition from the familiar cytological preparation to the electron image was thus effected. A linear complex consisting of three parallel strands has been observed with the electron microscope, passing along the central axis of primary spermatocyte chromosomes. The complex is similar to that found in comparable chromosomes from at least a dozen animal species. The structure in Plethodon is described in detail. Synapsis has been positively identified as the stage of meiotic prophase at which the complex occurs. Thus the complex is a part of bivalent chromosomes. It has not been seen in other stages or other divisions and is thus thought to be exclusively of synaptic occurrence. The term synaptinemal complex is suggested for the entire structure. By virtue of the material condensed around it, the complex is also seen in the light microscope where it appears as a fine, densely Feulgen-positive central core along the chromosome. The complex is thus closely associated with DNA, if not at least in part, composed of it. In the stages studied, homologous chromosomes are not always completely paired. The lateral elements of the complex separate and follow the single chromosome axes at these points. The central element disappears and thus may be a phenomenon of pairing. It is concluded that the lateral elements of the synaptinemal complex may more correctly be a "core" of the single meiotic prophase chromosome, possibly being concerned with its linear organization.     

Meiotic prophase in anthers of asynaptic wheat

The light microscope showed that zygotene and pachytene were completely suppressed in pollen mother cells of an asynaptic mutant of Triticum durum; the chromosomes passed through a normal chromomeral leptotene condition and remained unpaired throughout prophase. The electron microscope confirmed the absence of synaptinemal complexes, as would be expected with no pairing. Prominent opaque axial cores were present in the chromatin from the onset of leptotene up to an indeterminate stage during prophase condensation. At an early time during condensation 150 Å particles appeared between chromatin masses. Coincident to the disappearance of axial cores from the chromatin, polycomplexes consisting of linearly associated core fragments arrayed in single layer sheets appeared between chromatin masses. The aligned fragments were invariably spaced about 625 Å from centre to centre; this is approximately half the distance between centres of the lateral elements (axial cores) of the synaptinemal complex of pachytene of synaptic sister seedlings. There was no central element between the associated fragments. The significance of these observations is discussed, as is also the essential difference between asynapsis and desynapsia.     

The estimation of conversion parameters and the control of conversion in Ascobolus immersus

Summary Pasadena strains of Ascobolus immersus were used to study the controls of gene conversion. Formulae were derived for estimating conversion parameters according to different hybrid DNA models of recombination. Genetic factors influencing conversion were determined by using genetically different isolates and using alleles before and after they had undergone conversion. Conversion properties at particular sites were greatly affected by genetic factors very near to those sites: the nature of the mutations and factors elsewhere in the genome were much less important. These genetic factors and temperature both affected the frequency of hybrid DNA formation at particular sites, the efficiency of mispair correction and the relative frequencies of correction to wild-type or mutant. The effects of temperature on conversion parameters were usually complex.     

Meiotic Exchange without the Synaptinemal Complex

THE synaptinemal complex is a ribbonlike tripartite structure, normally restricted to the nucleus of meiocytes and located along the longitudinal axis of bivalent chromosomes¹. It consists of two dense lateral elements (about 400 Å in width) separated from the central element (about 250 Å in width) by spaces of about 400 Å (Fig. 1). Various functions have been proposed for it, primarily that it is intimately involved in meiotic exchange, either directly by promoting effective pairing between complementary nucleotide strands of homologous chromosomes^1–3 or indirectly by providing for the rough alignment of homologues before their more intimate association^4,5. In this view, the complex is an essential feature of the regular and extensive exchange process typical of meiosis. The firmest evidence in support of its role in exchange has been its concomitant presence in primary meiocytes whenever genetic or cytological evidence indicates that crossing-over is occurring¹. The presence of the complex in meiocytes which lack exchange and/or chiasmata, for example, the female of Bombyx mori⁶, intergeneric hybrids, haploid genomes and certain achiasmate male insects, as well as its presence in univalent X chromosomes of primary spermatocytes and in postmeiotic spermatids, has been interpreted as “the exceptions that prove, or at least refine, the rule¹.” Here, for the first time, we describe the converse situation, one in which high frequencies of meiotic exchange, as determined by genetic tests, are not accompanied by a detectable synaptinemal complex. This means that both pairing of homologues, which must precede exchange and the exchange process itself can occur in the meiocyte without the aid of the synaptinemal complex.     

DNA AND THE FINE STRUCTURE OF SYNAPTIC CHROMOSOMES IN THE DOMESTIC ROOSTER (GALLUS DOMESTICUS)

The indium trichloride method of Watson and Aldridge (38) for staining nucleic acids for electron microscopy was employed to study the relationship of DNA to the structure of the synaptinemal complex in meiotic prophase chromosomes of the domestic rooster. The selectivity of the method was demonstrated in untreated and DNase-digested testis material by comparing the distribution of indium staining in the electron microscope to Feulgen staining and ultraviolet absorption in thicker sections seen with the light microscope. Following staining by indium, DNA was found mainly in the microfibril component of the synaptinemal complex. When DNA was known to have been removed from aldehyde-fixed material by digestion with DNase, indium stainability was also lost. However, staining of the digested material with non-selective heavy metal techniques demonstrated the presence of material other than DNA in the microfibrils and showed that little alteration in appearance of the chromosome resulted from DNA removal. The two dense lateral axial elements of the synaptinemal complex, but not the central one to any extent, also contained DNA, together with non-DNA material.     

New equations and a method for finding nine parameter values for two alleles at one locus to study gene conversion using Ascobolus immersus.

A quantitative treatment is given for meiotic gene conversion with its parameters and equations for their interactions to determine allele segregation class frequencies from heterozygotes. The possible pairing of both pairs of nonsister chromatids in a bivalent at exactly the same point is included. Using sets of data from Ascobolus immersus, it is shown that values for all nine parameters for hybrid DNA models of recombination can be obtained using an iterative computer program. The accuracy of the values is estimated and the double-strand gap repair model is considered. The parameter values obtained invalidate most of the simplifications used in previous quantitative analyses of gene conversion data. They showed total bias in strand preference in asymmetric hybrid DNA formation and some bias in which type of chromatid is the invading one. There were slight differences in repair frequency between the two types of mispair and very large differences in the direction of repair. Conversion control factors had major effects on hybrid DNA formation and repair of mispairs.     

MULTIPLE CORE COMPLEXES IN GRASSHOPPER SPERMATOCYTES AND SPERMATIDS

At meiotic prophase, the grasshopper Chorthippus longicornis has normal synaptinemal complexes inside paired homologous chromosomes. Evidence is presented that short single cores and small multiple core complexes occur inside metaphase I chromosomes. At first anaphase, interphase, and early spermatid stage, large multiple core complexes are located in the cytoplasm. It is speculated that the multiple core complexes have some structural elements in common with the synaptinemal complexes, but that different forms of pairing behavior are exhibited by the different complexes.     

On the mechanism of pairing of single- and double-stranded DNA molecules by the recA and single-stranded DNA-binding proteins of Escherichia coli

The pairing of single- and double-stranded DNA molecules at homologous sequences promoted by recA and single-stranded DNA-binding proteins of Escherichia coli follows apparent first-order kinetics. The initial rate and first-order rate constant for the reaction are maximal at approximately 1 recA protein/3 and 1 single-stranded DNA-binding protein/8 nucleotides of single-stranded DNA. The initial rate increases with the concentration of duplex DNA; however, the rate constant is independent of duplex DNA concentration. Both the rate constant and extent of reaction increase linearly with increasing length of duplex DNA over the range 366 to 8623 base pairs. In contrast, the rate constant is independent of the size of the circular single-stranded DNA between 6,400 and 10,100 nucleotides. No significant effect on reaction rate is observed when a single-stranded DNA is paired with 477 base pairs of homologous duplex DNA joined to increasing lengths of heterologous DNA (627-2,367 base pairs). Similarly, heterologous T7 DNA has no effect on the rate of pairing. These findings support a mechanism in which a recA protein-single-stranded DNA complex interacts with the duplex DNA to produce an intermediate in which the two DNA molecules are aligned at homologous sequences. Conversion of the intermediate to a paranemic joint then occurs in a rate-determining unimolecular process.     

Synaptinemal complexes in the achiasmatic spermatogenesis of Bolbe nigra Giglio-Tos (Mantoidea)

In chiasmatic meiosis of mosquitoes, ascomycetes and lilies the synaptinemal complex (SC) disassociates from the bivalent before metaphase I. Conversely, in the achiasmatic meiosis of Bolbe nigra, the SC remains associated with the bivalent during first metaphase. Light microscopy reveals mid-bodies between disjoining half-bivalents during early first anaphase in Bolbe. Optically controlled serial sections for electron microscopy show that the mid-bodies seen in light micrographs and synaptinemal complexes seen in electron micrographs are the same structure. Electron micrographs indicate that the SC breaks transversely at a point corresponding to the chromosomal kinetochore during anaphase I as the chromatin and the SC begin to separate. During telophase I, SC remnants are at the poles with the chromosomes or between poles. Presently, the evidence is inadequate to state whether the SC serves alternately or simultaneously as a biological contrivance for conjunction and crossing-over or singly as a device for one of these phenomena.Supported by a University of Melbourne Research Fellowship.     

Intranucleolar bodies with axial structure in the fern Pteridium

Regions of nucleoli in Pteridium showing an axial structure are tentatively identified with nucleolar organizers. Certain structural similarities between these regions and the synaptinemal complex are discussed.     

FINE STRUCTURE OF SYNAPSED CHOMOSOMES IN F1 LYCOPERSICON ESCULENTUM-SOLANUM LYCOPERSICOIDES AND ITS PARENTS

Typical synaptinemal complexes consisting of electron-dense central and lateral elements and much less dense outer fibrillar material are formed at meiotic prophase in Lycopersicon esculentum (tomato), Solanum lycopersicoides, their diploid hybrid, and occasionally in tomato haploids (in which an average of about one chromosome region per cell is synapsed nonhomologously). Complexes in the hybrid (in which the chromosomes synapse completely but often fail to form chiasmata) are similar to those in the parents. Complexes in the haploid are similar to those of diploid tomato. The data suggest that synaptinemal complexes form whenever chromosomes undergo meiotic synapsis, regardless of whether synapsis leads to chiasmata.     

DNA-DEPENDENT FORMATION OF THE SYNAPTINEMAL COMPLEX AT MEIOTIC PROPHASE

Evalaution of microsporocytes cultured during discrete periods of meiotic prophase in the presence of deoxyadenosine, an inhibitor of DNA synthesis, indicate that: (1) late leptonema or early zygonema DNA synthesis is required to initiate the formation of the synaptinemal complex; (2) DNA synthesized during late zygonema is necessary for the disjunction of the paired homologs at diplonema; and (3) DNA synthesis in pachynema is a requisite for normal anaphase II separation of sister chromatids.     

Chromosome and DNA methylation dynamics during meiosis in the autotetraploid Arabidopsis arenosa

Variation in chromosome number due to polyploidy can seriously compromise meiotic stability. In autopolyploids, the presence of more than two homologous chromosomes may result in complex pairing patterns and subsequent anomalous chromosome segregation. In this context, chromocenter, centromeric, telomeric and ribosomal DNA locus topology and DNA methylation patterns were investigated in the natural autotetraploid, Arabidopsis arenosa. The data show that homologous chromosome recognition and association initiates at telomeric domains in premeiotic interphase, followed by quadrivalent pairing of ribosomal 45S RNA gene loci (known as NORs) at leptotene. On the other hand, centromeric regions at early leptotene show pairwise associations rather than associations in fours. These pairwise associations are maintained throughout prophase I, and therefore likely to be related to the diploid-like behavior of A. arenosa chromosomes at metaphase I, where only bivalents are observed. In anthers, both cells at somatic interphase as well as at premeiotic interphase show 5-methylcytosine (5-mC) dispersed throughout the nucleus, contrasting with a preferential co-localization with chromocenters observed in vegetative nuclei. These results show for the first time that nuclear distribution patterns of 5-mC are simultaneously reshuffled in meiocytes and anther somatic cells. During prophase I, 5-mC is detected in extended chromatin fibers and chromocenters but interestingly is excluded from the NORs what correlates with the pairing pattern.     

Saccharomyces cerevisiae cells lacking the homologous pairing protein p175 SEP1 arrest at pachytene during meiotic prophase

Saccharomyces cerevisiae cells containing null mutations in the SEP1 gene, which encodes the homologous pairing and strand exchange protein p175 ^SEP1 enter pachytene with a delay. They arrest uniformly at this stage of meiotic prophase, probably revealing a checkpoint in the transition from pachytene to meiosis I. At the arrest point, the cells remain largely viable and are cytologically characterized by the duplicated but unseparated spindle pole bodies of equal size and by the persistence of the synaptonemal complex, a cytological marker for pachytene. In addition, fluorescence in situ hybridization revealed that in arrested mutant cells maximal chromatin condensation and normal homolog pairing is achieved, typical for pachytene in wild type. A hallmark of meiosis is the high level of homologous recombination, which was analyzed both genetically and physically. Formation and processing of the double-strand break intermediate in meiotic recombination is achieved prior to arrest. Physical intragenic (conversion) and intergenic (crossover) products are formed just prior to, or directly at, the arrest point. Structural deficits in synaptonemal complex morphology, failure to separate spindle pole bodies, and/or defects in prophase DNA metabolism might be responsible for triggering the observed arrest. The pachytene arrest in sep1 cells is likely to be regulatory, but is clearly different from the RAD9 checkpoint in meiotic prophase, which occurs prior to the pachytene stage.     

Multiple synaptinemal complexes at the region of gene amplification in Acheta

Ovaries of Acheta domesticus (house cricket) were fixed for electron microscopy at two stages of development: (1) ovaries containing mainly oocytes at interphase and early prophase of meiosis, and (2) ovaries with oocytes mainly at pachytene and diplotene. The E.M. study was accompanied by three types of light microscopy controls consisting mainly of cytochemical tests. Every oocyte contains a DNA body which at pachytene and diplotene acquires the appearance of a puff. In the light microscope two zones can be distinguished inside the body: (1) an inner core of DNA and (2) and outer shell of RNA. In the E. M. the inner core consists of a fibrillar material and the outer shell is composed of areas of high electron opacity consisting mainly of tightly packed particles and fibrils. At these stages synaptinemal complexes are seldom seen associated with the DNA body but are present throughout the nucleus as part of the paired chromosomes. The complexes are present as single units. — In the oocytes at interphase and early prophase of meiosis, where the DNA body is active in DNA replication, the body appears in the light microscope as a large Feulgen positive sphere containing Feulgen negative areas. In the E. M. at these stages the DNA body consists of: (a) the two components found at pachytene, (b) a third electron dense component which is more homogeneous than the other two, and (c) of large assemblies of synaptinemal complexes originating from several centers. The most significant features of the axial complexes are: (1) the circular packing of the complexes, (2) their occurrence in packages of 300 to 400 units and (3) the fact that not all of the DNA body forms complexes but only a part of it.Biochemical experiments (Lima-de-Faria, Birnstiel and Jaworska, 1969) have demonstrated the amplification of ribosomal cistrons in the DNA body of Acheta. The simplest explanation is that the multiple complexes are formed either between the extra gene copies of the two homologues, or between the extra copies of each chromosome as well. There seems to be a correlation between the presence of multiple axial complex formation and gene amplification in Acheta but the exact relation between the two phenomena demands further study.Dedicated to Dr. Sally Hughes-Schrader on the occasion of the seventyfifth birthday on the twentyfifth of January 1970.     

The synaptinemal complex in yeast

The occurrence of a synaptinemal complex in yeast was demonstrated by an electron-microscopical examination of meiotic prophase I. The complex is formed during the interval between the maximum of meiotic DNA synthesis and the first division.