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.     

Unequal Exchange and Meiotic Instability of Disease-Resistance Genes in the Rp1 Region of Maize

The Rp1 region of maize was originally characterized as a complex locus which conditions resistance to the fungus Puccinia sorghi, the causal organism in the common rust disease. Some alleles of Rp1 are meiotically unstable, but the mechanism of instability is not known. We have studied the role of recombination in meiotic instability in maize lines homozygous for either Rp1-J or Rp1-G. Test cross progenies derived from a line that was homozygous for Rp1-J, but heterozygous at flanking markers, were screened for susceptible individuals. Five susceptible individuals were derived from 9772 progeny. All five had nonparental combinations of flanking markers; three had one combination of recombinant flanking markers while the other two had the opposite pair. In an identical study with Rp1-G, 20 susceptible seedlings were detected out of 5874 test cross progeny. Nineteen of these were associated with flanking marker exchange, 11 and 8 of each recombinant marker combination. Our results indicate that unequal exchange is the primary mechanism of meiotic instability of Rp1-J and Rp1-G.     

Meiotic Instability of Pythium Sylvaticum as Demonstrated by Inheritance of Nuclear Markers and Karyotype Analysis

Progeny from a sexual outcross between opposite mating types of Pythium sylvaticum were analyzed for inheritance of RFLP and random amplified polymorphic DNA (RAPD) markers. Although most were inherited in expected Mendelian frequencies, several were not. Pulsed field gel electrophoresis was employed to examine these unexpected patterns of marker inheritance at a karyotypic level. Parental oogonial and antheridial isolates had different electrophoretic karyotypes and minimum number of chromosome-sized DNAs (13 and 12, respectively), however, summation of the sizes of all chromosomal bands for each isolate was similar at ~37 Mb. Progeny karyotypes differed significantly from each other and the parental isolates, ranging in estimated minimum number of chromosome-sized DNAs from 9 to 13 and the summation of band sizes within each isolate from 28.1 to 39.0 Mb. For the eight isolates most extensively analyzed, 80% of the progeny chromosome-sized DNAs were nonparental in size or hybridization grouping of cDNA clones and isolated RAPD markers. Based on the results of Southern analysis it appears that length mutations and perhaps aneuploidy and translocations have contributed to generation of karyotypic polymorphisms. Nineteen field isolates of P. sylvaticum collected from the same location also exhibited significantly different karyotypes, suggesting that the meiotic instability observed in the laboratory also is occurring in field populations.     

Absence of Complex I Implicates Rearrangement of the Respiratory Chain in European Mistletoe

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Effects of Homology, Size and Exchange on the Meiotic Segregation of Model Chromosomes in Saccharomyces Cerevisiae

In most eukaryotic organisms, chiasmata, the connections formed between homologous chromosomes as a consequence of crossing over, are important for ensuring that the homologues move away from each other at meiosis I. Some organisms have the capacity to partition the rare homologues that have failed to experience reciprocal recombination. The yeast Saccharomyces cerevisiae is able to correctly partition achiasmate homologues with low fidelity by a mechanism that is largely unknown. It is possible to test which parameters affect the ability of achiasmate chromosomes to segregate by constructing strains that will have three achiasmate chromosomes at the time of meiosis. The meiotic partitioning of these chromosomes can be monitored to determine which ones segregate away from each other at meiosis I. This approach was used to test the influence of homologous yeast DNA sequences, recombination intiation sites, chromosome size and crossing over on the meiotic segregation of the model chromosomes. Chromosome size had no effect on achiasmate segregation. The influence of homologous yeast sequences on the segregation of noncrossover model chromosomes was negligible. In meioses in which two of the three model chromosomes experienced a crossover, they nearly always disjoined at meiosis I.     

长鬣蜥的染色体组型和减数分裂联会复合体的研究

本文报道长鬣蜥(Physignathus cocincinus)有丝分裂染色体及C-,Ag-带以及减数分裂联会复合体核型。染色体数2n=36,NF=48,核型组成为12V+24m(V为双臂大染色体,其中No.2为亚中着丝粒染色体,m为微小染色体)。结构异染色质主要分布在小染色体上。一对Ag-NORs分布于第2对亚中着丝粒染色体末端。     

A Meiotic Chromosomal Core Consisting of Cohesin Complex Proteins Recruits DNA Recombination Proteins and Promotes Synapsis in the Absence of an Axial Element in Mammalian Meiotic Cells

The behavior of meiotic chromosomes differs in several respects from that of their mitotic counterparts, resulting in the generation of genetically distinct haploid cells. This has been attributed in part to a meiosis-specific chromatin-associated protein structure, the synaptonemal complex. This complex consist of two parallel axial elements, each one associated with a pair of sister chromatids, and a transverse filament located between the synapsed homologous chromosomes. Recently, a different protein structure, the cohesin complex, was shown to be associated with meiotic chromosomes and to be required for chromosome segregation. To explore the functions of the two different protein structures, the synaptonemal complex and the cohesin complex, in mammalian male meiotic cells, we have analyzed how absence of the axial element affects early meiotic chromosome behavior. We find that the synaptonemal complex protein 3 (SCP3) is a main determinant of axial-element assembly and is required for attachment of this structure to meiotic chromosomes, whereas SCP2 helps shape the in vivo structure of the axial element. We also show that formation of a cohesin-containing chromosomal core in meiotic nuclei does not require SCP3 or SCP2. Our results also suggest that the cohesin core recruits recombination proteins and promotes synapsis between homologous chromosomes in the absence of an axial element. A model for early meiotic chromosome pairing and synapsis is proposed.     

A Guaninine Nucleotide Exchange Factor Is a Component of the Meiotic Spindle Pole Body in Schizosaccharomyces pombe

Spore morphogenesis in yeast is driven by the formation of membrane compartments that initiate growth at the spindle poles during meiosis II and grow to encapsulate daughter nuclei. Vesicle docking complexes, called meiosis II outer plaques (MOPs), form on each meiosis II spindle pole body (SPB) and serve as sites of membrane nucleation. How the MOP stimulates membrane assembly is not known. Here, we report that SpSpo13, a component of the MOP in Schizosaccharomyces pombe, shares homology with the guanine nucleotide exchange factor (GEF) domain of the Saccharomyces cerevisiae Sec2 protein. ScSec2 acts as a GEF for the small Rab GTPase ScSec4, which regulates vesicle trafficking from the late-Golgi to the plasma membrane. A chimeric protein in which the ScSec2-GEF domain is replaced with SpSpo13 is capable of supporting the growth of a sec2Δ mutant. SpSpo13 binds preferentially to the nucleotide-free form of ScSec4 and facilitates nucleotide exchange in vitro. In vivo, a Spspo13 mutant defective in GEF activity fails to support membrane assembly. In vitro specificity experiments suggest that SpYpt2 is the physiological substrate of SpSpo13. These results demonstrate that stimulation of Rab-GTPase activity is a property of the S. pombe MOP essential for the initiation of membrane formation.     

Yeast Intrachromosomal Recombination: Long Gene Conversion Tracts Are Preferentially Associated with Reciprocal Exchange and Require the Rad1 and Rad3 Gene Products

A yeast intrachromosomal recombination system based on an inverted repeat has been designed to examine mitotic gene conversion tract length and the association of crossing over with gene conversion as a function of the conversion tract length. Short conversion tracts are found to be preferentially noncrossover while conversion tracts longer than 1.16 kb show a 50% association with crossover. Mutation in the excision repair gene RAD1 leads to a reduction in conversion tracts of at least 1.16 kb and a reduction in crossovers associated with conversion, regardless of the length of the conversion tract. Mutation in the excision repair gene RAD3, which encodes a DNA helicase, also leads to a reduction in conversion tracts of at least 1.16 kb, but has no effect on the frequency of associated crossovers. The roles of RAD1 and RAD3 in recombination are discussed.     

Genetic Exchange across a Paracentric Inversion of the Mouse T Complex

Mouse t haplotypes are distinguished from wild-type forms of chromosome 17 by four nonoverlapping paracentric inversions which span a genetic distance of 20 cM. These inversion polymorphisms are responsible for a 100-200-fold suppression of recombination which maintains the integrity of complete t haplotypes and has led to their divergence from the wild-type chromosomes of four species of house mice within which t haplotypes reside. As evidence for the long period of recombinational isolation, alleles that distinguish all t haplotypes from all wild-type chromosomes have been established at a number of loci spread across the 20-cM variant region. However, a more complex picture emerges upon analysis of other t-associated loci. In particular, "mosaic haplotypes" have been identified that carry a mixture of wild-type and t-specific alleles. To investigate the genetic basis for mosaic chromosomes, we conducted a comprehensive analysis of eight t complex loci within 76 animals representing 10 taxa in the genus Mus, and including 23 previously characterized t haplotypes. Higher resolution restriction mapping and sequence analysis was also performed for alleles at the Hba-ps4 locus. The results indicate that a short tract of DNA was transferred relatively recently across an inversion from a t haplotype allele of Hba-ps4 to the corresponding locus on a wild-type homolog leading to the creation of a new hybrid allele. Several classes of wild-type Hba-ps4 alleles, including the most common form in inbred strains, appear to be derived from this hybrid allele. The accumulated data suggest that a common form of genetic exchange across one of the four t-associated inversions is gene conversion at isolated loci that do not play a role in the transmission ratio distortion phenotype required for t haplotype propagation. The implications of the results pose questions concerning the evolutionary stability of gene complexes within large paracentric inversions and suggest that recombinational isolation may be best established for loci residing within a short distance from inversion breakpoints.     

Centromere Pairing in Early Meiotic Prophase Requires Active Centromeres and Precedes Installation of the Synaptonemal Complex in Maize

Pairing of homologous chromosomes in meiosis is critical for their segregation to daughter cells. In most eukaryotes, clustering of telomeres precedes and facilitates chromosome pairing. In several species, centromeres also form pairwise associations, known as coupling, before the onset of pairing. We found that, in maize (Zea mays), centromere association begins at the leptotene stage and occurs earlier than the formation of the telomere bouquet. We established that centromere pairing requires centromere activity and the sole presence of centromeric repeats is not sufficient for pairing. In several species, homologs of the ZIP1 protein, which forms the central element of the synaptonemal complex in budding yeast (Saccharomyces cerevisiae), play essential roles in centromere coupling. However, we found that the maize ZIP1 homolog ZYP1 installs in the centromeric regions of chromosomes after centromeres form associations. Instead, we found that maize STRUCTURAL MAINTENANCE OF CHROMOSOMES6 homolog forms a central element of the synaptonemal complex, which is required for centromere associations. These data shed light on the poorly understood mechanism of centromere interactions and suggest that this mechanism may vary somewhat in different species.     

Intrachromosomal Gene Conversion and the Maintenance of Sequence Homogeneity among Repeated Genes

Intrachromosomal gene conversion is the non-reciprocal transfer of information between a pair of repeated genes on a single chromosome. This process produces eventual sequence homogeneity within a family of repeated genes. An evolutionary model for a single chromosome lineage was formulated and analyzed. Expressions were derived for the fixation probability, mean time to fixation or loss, and mean conditional fixation time for a variant repeat with an arbitrary initial frequency. It was shown that a small conversional advantage or disadvantage for the variant repeat (higher or lower probability of producing two variant genes by conversion than two wild-type genes) can have a dramatic effect on the probability of fixation. The results imply that intrachromosomal gene conversion can act sufficiently rapidly to be an important mechanism for maintaining sequence homogeneity among repeated genes.     

Rapid Evolution of a Coadapted Gene Complex: Evidence from the Segregation Distorter (Sd) System of Meiotic Drive in Drosophila Melanogaster

Segregation Distorter (SD) is a system of meiotic drive found in natural populations of Drosophila melanogaster. Males heterozygous for an SD second chromosome and a normal homologue (SD(+)) produce predominantly SD-bearing sperm. The coadapted gene complex responsible for this transmission advantage spans the second chromosome centromere, consisting of three major and several minor interacting loci. To investigate the evolutionary history of this system, we surveyed levels of polymorphism and divergence at six genes that together encompass this pericentromeric region and span seven map units. Interestingly, there was no discernible divergence between SD and SD(+) chromosomes for any of these molecular markers. Furthermore, SD chromosomes harbored much less polymorphism than did SD(+) chromosomes. The results suggest that the SD system evolved recently, swept to appreciable frequencies worldwide, and carried with it the entire second chromosome centromeric region (roughly 10% of the genome). Despite its well-documented genetic complexity, this coadapted system appears to have evolved on a time scale that is much shorter than can be gauged using nucleotide substitution data. Finally, the large genomic region hitchhiking with SD indicates that a multilocus, epistatically selected system could affect the levels of DNA polymorphism observed in regions of reduced recombination.     

Distress Arising from the end of a Guide Dog Partnership

ABSTRACT

The Guide Dogs for the Blind Association (GDBA) wished to evaluate its service to Guide Dog Owners (GDOs) undergoing a transition between guide dog partners. Therefore, a survey was carried out that was designed to gain an understanding of the end of a guide dog partnership from the owner's point of view.

Participants included 75 GDOs whose previous partnership had ended within the past year. Emotional distress was measured by the Goldberg General Health Questionnaire (GHQ-28) and a specially constructed Grief Rating Scale (GRS). Among the 59 GDOs who had no other reason for being upset at the time the partnership ended, high distress levels were found in those whose dog had died, been withdrawn from the partnership, or rehomed through GDBA, and low levels in those whose dog retired and continued to live with the owner or was placed in a home of the owner's choosing. Sixteen GDOs with other adverse events in their lives around the time the partnership ended recorded high levels of distress irrespective of why the dog stopped work or what happened to it thereafter.

Other evidence from the survey questionnaire suggested that the ending of a partnership is especially painful if the dog has had some special significance for the owner; if the partnership ends abruptly; if it is the end of the first partnership; or if there is a poor relationship with GDBA. Emotions experienced at the end of a partnership may be similar to those following the death of a pet, the loss of a close friend or relative, or the loss of sight.

Transitions between guide dog partners are a recurring consequence of guide dog mobility, and support as a partnership ends is beneficial in making a smooth transition. The issues raised in this study are relevant to assistance dog partnerships of all types. Methodological problems in designing a study for a vulnerable population are discussed.     

Intragenic duplication and divergence in the spectrin superfamily of proteins

Many structural, signaling, and adhesion molecules contain tandemly repeated amino acid motifs. The alpha-actinin/spectrin/dystrophin superfamily of F-actin-crosslinking proteins contains an array of triple alpha-helical motifs (spectrin repeats). We present here the complete sequence of the novel beta-spectrin isoform beta(Heavy)- spectrin (beta H). The sequence of beta H supports the origin of alpha- and beta-spectrins from a common ancestor, and we present a novel model for the origin of the spectrins from a homodimeric actin-crosslinking precursor. The pattern of similarity between the spectrin repeat units indicates that they have evolved by a series of nested, nonuniform duplications. Furthermore, the spectrins and dystrophins clearly have common ancestry, yet the repeat unit is of a different length in each family. Together, these observations suggest a dynamic period of increase in repeat number accompanied by homogenization within each array by concerted evolution. However, today, there is greater similarity of homologous repeats between species than there is across repeats within species, suggesting that concerted evolution ceased some time before the arthropod/vertebrate split. We propose a two-phase model for the evolution of the spectrin repeat arrays in which an initial phase of concerted evolution is subsequently retarded as each new protein becomes constrained to a specific length and the repeats diverge at the DNA level. This evolutionary model has general applicability to the origins of the many other proteins that have tandemly repeated motifs.