Size and number of tandem repeat arrays can determine somatic homologous pairing of transgene loci mediated by epigenetic modifications in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> nuclei

The chromosomal arrangement of different transgenic repeat arrays inserted at various chromosomal positions was tested by FISH in Arabidopsis 2C leaf and root nuclei. Large lacO (∼10 kb) but not tetO (4.8 kb) or small lacO (∼2 kb) arrays were, in general, more often spatially associated with heterochromatic chromocenters (CC) than flanking regions (that either overlap the array insert position or are between 5 and 163 kb apart from the insert site). Allelic and ectopic pairing frequencies of lacO arrays were significantly increased only in nuclei of lines with two large lacO arrays inserted at different positions on the same chromosome arm. Within the same lines, root nuclei showed a significantly lower increase of pairing frequencies at the insert position compared to leaf nuclei but still a higher frequency than in the wild-type situation. Thus, the frequencies of homologous pairing and association with heterochromatin of transgenic repeats may differ with the construct, the chromosomal insertion position, the cell type and with the number and repetitiveness of inserts. Strong CpG methylation is correlated with a high frequency of homologous pairing at large repeat array loci in somatic cells but has no impact on their association with CCs. These results show that single low-copy arrays apparently do not alter interphase chromatin architecture and are more suitable for chromatin tagging than multiple high copy arrays.     

Detection of chromosomes tagged with green fluorescent protein in live Arabidopsis thaliana plants

Background

Structural and dynamic studies of chromosomes tagged with green fluorescent protein (GFP) in yeast and cultured animal cells have revealed some surprises. Although this technology can be very powerful, only a few studies using this approach with developed multicellular systems have been reported for the study of chromatin behavior in situ.

Results

We established vectors and conditions to visualize tagged loci stably inserted in the Arabidopsis genome via GFP fused to a bacterial DNA-binding protein. Using this system, three-dimensional coordinates for tagged loci within nuclei from cells of a live plant can be directly determined with concomitant visualization of the position of the nucleolus. Chromosome polyploidization in epidermal cells at the elongation zone of the root in transgenic plants can be visualized in situ using this technique.

Conclusion

We have established that GFP fusion with DNA-binding proteins can be used in conjunction with concatameric binding-site arrays to track genomic loci in living Arabidopsis plants. It should now be feasible to study the mechanisms of organization and dynamics of chromatin in specific cell types during various times of plant development, taking advantage of the well developed genetic systems and resources available for Arabidopsis.     

Transposon Assisted Gene Insertion Technology (TAGIT): A Tool for Generating Fluorescent Fusion Proteins

We constructed a transposon (transposon assisted gene insertion technology, or TAGIT) that allows the random insertion of gfp (or other genes) into chromosomal loci without disrupting operon structure or regulation. TAGIT is a modified Tn5 transposon that uses Kan^R to select for insertions on the chromosome or plasmid, β-galactosidase to identify in-frame gene fusions, and Cre recombinase to excise the kan and lacZ genes in vivo. The resulting gfp insertions maintain target gene reading frame (to the 5′ and 3′ of gfp) and are integrated at the native chromosomal locus, thereby maintaining native expression signals. Libraries can be screened to identify GFP insertions that maintain target protein function at native expression levels, allowing more trustworthy localization studies. We here use TAGIT to generate a library of GFP insertions in the Escherichia coli lactose repressor (LacI). We identified fully functional GFP insertions and partially functional insertions that bind DNA but fail to repress the lacZ operon. Several of these latter GFP insertions localize to lacO arrays integrated in the E. coli chromosome without producing the elongated cells frequently observed when functional LacI-GFP fusions are used in chromosome tagging experiments. TAGIT thereby faciliates the isolation of fully functional insertions of fluorescent proteins into target proteins expressed from the native chromosomal locus as well as potentially useful partially functional proteins.     

Chromosomal localization of microsatellite loci in Drosophila mediopunctata

Drosophila mediopunctata has been used as a model organism for genetics and evolutionary studies in the last three decades. A linkage map with 48 microsatellite loci recently published for this species showed five syntenic groups, which had their homology determined to Drosophila melanogaster chromosomes. Then, by inference, each of the groups was associated with one of the five major chromosomes of D. mediopunctata. Our objective was to carry out a genetic (chromosomal) analysis to increase the number of available loci with known chromosomal location. We made a simultaneous analysis of visible mutant phenotypes and microsatellite genotypes in a backcross of a standard strain and a mutant strain, which had each major autosome marked. Hence, we could establish the chromosomal location of seventeen loci; including one from each of the five major linkage groups previously published, and twelve new loci. Our results were congruent with the previous location and they open new possibilities to future work integrating microsatellites, chromosomal inversions, and genetic determinants of physiological and morphological variation.     

Homologous Chromosome Pairing in Drosophila melanogaster Proceeds through Multiple Independent Initiations

The dynamics by which homologous chromosomes pair is currently unknown. Here, we use fluorescence in situ hybridization in combination with three-dimensional optical microscopy to show that homologous pairing of the somatic chromosome arm 2L in Drosophila occurs by independent initiation of pairing at discrete loci rather than by a processive zippering of sites along the length of chromosome. By evaluating the pairing frequencies of 11 loci on chromosome arm 2L over several timepoints during Drosophila embryonic development, we show that all 11 loci are paired very early in Drosophila development, within 13 h after egg deposition. To elucidate whether such pairing occurs by directed or undirected motion, we analyzed the pairing kinetics of histone loci during nuclear cycle 14. By measuring changes of nuclear length and correlating these changes with progression of time during cycle 14, we were able to express the pairing frequency and distance between homologous loci as a function of time. Comparing the experimentally determined dynamics of pairing to simulations based on previously proposed models of pairing motion, we show that the observed pairing kinetics are most consistent with a constrained random walk model and not consistent with a directed motion model. Thus, we conclude that simple random contacts through diffusion could suffice to allow pairing of homologous sites.     

Distribution of Nonstructural Variation along Three Chromosome Arms between Wheat Cultivars Chinese Spring and Cheyenne

Metaphase I (MI) pairing of wheat homologous chromosomes is usually reduced in hybrids between cultivars relative to the parental inbred lines. Previous work suggested that this phenomenon is caused by polymorphism in nucleotide sequences (nonstructural chromosome variation) among wheat cultivars. The present work investigated the distribution of this variation along three selected chromosome arms between cultivars Chinese Spring and Cheyenne. Chinese Spring ditelosomics 3Aq, 6Ap and 6Bp were crossed with disomic substitutions of Cheyenne chromosomes 3A, 6A and 6B in Chinese Spring, respectively. The resulting F₁ plants, called substituted monotelodisomics, were crossed with the respective Chinese Spring monosomics, producing potentially "recombinant" substituted monosomics. When these "recombinant" chromosomes were combined with the parental Chinese Spring telosomes, marked reductions in mean telosome-pairing frequency were found compared with the corresponding Chinese Spring monotelodisomics. The mean pairing frequencies of the "recombinant" chromosomes showed a continuous distribution between those of the substituted and Chinese Spring monotelodisomics. The results suggest that the nonstructural variation that reduces MI pairing between chromosomes of different wheat cultivars is not localized in a specific site but distributed along each chromosome arm. Little variation was found among monotelodisomics for either the number of ring bivalents per cell or the number of univalents other than those constituting the heteromorphic pair. This implies that the reductions in MI pairing between the Cheyenne and Chinese Spring chromosomes are caused by something residing within these specific chromosomes that does not affect the pairing of the remaining Chinese Spring chromosomes in the same cell. Furthermore, the absence of parental types among the "recombinant"-substituted monotelodisomics suggests that the sequences involved in the variation studied here are capable of converting heterohomologous chromosomes to something intermediate in nature in the span of only a single generation.     

The Effect of Heterozygosity for Marker Loci on Recombination Fraction in Adjacent Chromosomal Regions in Maize

Analysis of maize F₂ plants revealed a decrease in the recombination fraction (rf) between the marker loci in case of heterozygosity of adjacent chromosomal regions. The relative decrease in rf was positively associated with the length of the heterozygous region. Heterozygosity had no effect onrfin other chromosomes. These results can be explained by defective pairing of heterozygous chromosomal regions in meiosis.     

Distribution of centromere-like parS sites in bacteria: insights from comparative genomics

Partitioning of low-copy-number plasmids to daughter cells often depends on ParA and ParB proteins acting on centromere-like parS sites. Similar chromosome-encoded par loci likely also contribute to chromosome segregation. Here, we used bioinformatic approaches to search for chromosomal parS sites in 400 prokaryotic genomes. Although the consensus sequence matrix used to search for parS sites was derived from two gram-positive species, putative parS sites were identified on the chromosomes of 69% of strains from all branches of bacteria. Strains that were not found to contain parS sites clustered among relatively few branches of the prokaryotic evolutionary tree. In the vast majority of cases, parS sites were identified in origin-proximal regions of chromosomes. The widespread conservation of parS sites across diverse bacteria suggests that par loci evolved very early in the evolution of bacterial chromosomes and that the absence of parS, parA, and/or parB in certain strains likely reflects the loss of one of more of these loci much later in evolution. Moreover, the highly conserved origin-proximal position of parS suggests par loci are primarily devoted to regulating processes that involve the origin region of bacterial chromosomes. In species containing multiple chromosomes, the parS sites found on secondary chromosomes diverge significantly from those found on their primary chromosomes, suggesting that chromosome segregation of multipartite genomes requires distinct replicon-specific par loci. Furthermore, parS sites on secondary chromosomes are not well conserved among different species, suggesting that the evolutionary histories of secondary chromosomes are more diverse than those of primary chromosomes.     

Preferential transposition of aDrosophila P element to the corresponding region of the homologous chromosome

Genetic and physical analyses have demonstrated an intimate interaction or pairing of homologous chromosomes in the nuclei of manyDrosophila cell types. Experiments were performed to determine whether P elements transposing from a given chromosome to its homolog would preferentially insert in the region corresponding to the donor site, perhaps due to such a proximity. AP[lacZ;ry ⁺] element at thecactus locus (35F) on the second chromosome was mobilized and 96 insertions on the homolog were recovered. The distribution of these new insertions was determined by recombination mapping and molecular analysis, and compared with a control set of 93 second-chromosome insertions originating from theX chromosome. A nearly threefold preference was observed for re-insertion in a region of two to three number divisions aroundcactus on the homolog. However, none of these “local” insertions was actually within ～ 50 kb of the site atcactus corresponding to the starting site. This is in marked contrast to the previously described phenomenon of intrachromosomal local transposition, where the majority of local transpositions are within 10 kb. The data suggest that the mechanisms for intrachromosomal and interchromosomal local transposition are distinct, and are consistent with a model for interchromosomal local transposition involving proximity of homologous chromosomal regions in the nuclei of the germline cells.     

Pairing of <Emphasis Type="Italic">lacO</Emphasis> tandem repeats in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> nuclei requires the presence of hypermethylated,large arrays at two chromosomal positions,but does not depend on H3-lysine-9-dimethylation

Fluorescent chromatin tagging by the lacO operator/lac repressor system in Arabidopsis thaliana is useful to trace distinct chromatin domains in living cells. Nevertheless, the tandem repeats of the tagging system may alter the spatial organisation of chromatin within nuclei by increasing homologous pairing as well as association with heterochromatin. Efficient homologous pairing occurs if lacO repeat arrays of ∼10 kb are present at two loci, either on the same chromosome or on different chromosomes. DNA hypomethylation of lacO repeats results in reduced homologous pairing. Because, in plants, DNA methylation can serve as a signal for H3-lysine9-dimethylation (H3K9me2), and subsequently for non-CG-context DNA methylation, SET-domain histone methyltransferase and chromodomain dna methyltransferase 3 (cmt3) mutations were introgressed. In suvh4 suvh5 suvh6 and cmt3 mutants, H3K9me2 associated with lacO repeats is diminished, but homologous pairing persists. Thus, neither H3K9me2 nor CMT3-mediated non-CG methylation are required at wild-type level for homologous pairing of lacO repeat loci.     

Expanding duplication of the testis PHD Finger Protein 7 (PHF7) gene in the chicken genome

Gene duplications increase genetic and phenotypic diversity and occur in complex genomic regions that are still difficult to sequence and assemble. PHD Finger Protein 7 (PHF7) acts during spermiogenesis for histone-to-histone protamine exchange and is a determinant of male fertility in Drosophila and the mouse. We aimed to explore and characterise in the chicken genome the expanding family of the numerous orthologues of the unique mouse Phf7 gene (highly expressed in the testis), observing the fact that this information is unclear and/or variable according to the versions of databases. We validated nine primer pairs by in silico PCR for their use in screening the chicken bacterial artificial chromosome (BAC) library to produce BAC-derived probes to detect and localise PHF7-like loci by fluorescence in situ hybridisation (FISH). We selected nine BAC that highlighted nine chromosomal regions for a total of 10 distinct PHF7-like loci on five Gallus gallus chromosomes: Chr1 (three loci), Chr2 (two loci), Chr12 (one locus), Chr19 (one locus) and ChrZ (three loci). We sequenced the corresponding BAC by using high-performance PacBio technology. After assembly, we performed annotation with the FGENESH program: there were a total of 116 peptides, including 39 PHF7-like proteins identified by BLASTP. These proteins share a common exon-intron core structure of 8–11 exons. Phylogeny revealed that the duplications occurred first between chromosomal regions and then inside each region. There are other duplicated genes in the identified BAC sequences, suggesting that these genomic regions exhibit a high rate of tandem duplication. We showed that the PHF7 gene, which is highly expressed in the rooster testis, is a highly duplicated gene family in the chicken genome, and this phenomenon probably concerns other bird species.     

Meiosis-specific yeast Hop1 protein promotes synapsis of double-stranded DNA helices via the formation of guanine quartets

In most eukaryotes, genetic exchange between paired homologs occurs in the context of a tripartite proteinaceous structure called the synaptonemal complex (SC). Genetic analyses have revealed that the genes encoding SC proteins are vital for meiotic chromosome pairing and recombination. However, the number, nature and/or the mechanism used by SC proteins to align chromosomes are yet to be clearly defined. Here, we show that Saccharomyces cerevisiae Hop1, a component of SC, was able to promote pairing of double-stranded DNA helices containing arrays of mismatched G/G sequences. Significantly, pairing was rapid and robust, independent of homology in the arms flanking the central G/G region, and required four contiguous guanine residues. Furthermore, data from truncated DNA double helices showed that 20 bp on either side of the 8 bp mismatched G/G region was essential for efficient synapsis. Methylation interference indicated that pairing between the two DNA double helices involves G quartets. These results suggest that Hop1 is likely to play a direct role in meiotic chromosome pairing and recombination by its ability to promote synapsis between double-stranded DNA helices containing arrays of G residues. To our knowledge, Hop1 is the first protein shown to promote synapsis of DNA double helices from yeast or any other organism.     

Relationship between the levels of wheat-rye metaphase I chromosomal pairing and recombination revealed by GISH

The metaphase I and anaphase I stages of meiosis of wheat×rye hybrids carrying the ph1b mutation were analyzed by genomic in situ hybridization. This technique allows distinction between three different types of wheat-rye associations in metaphase I configurations as well as detection of wheat-rye recombinant chromosomes in anaphase I cells. The frequency of associations between wheat and rye chromosomes greatly exceeded the level of wheat-rye recombination found in the three hybrids examined. Extremely distal associations, which account for about 50% of the total wheat-rye metaphase I chromosomal pairing, can explain such a discrepancy between metaphase I and anaphase I data. It is further discussed whether these associations reflect very distally located chiasmata or nonchiasmatic pairing. The sizes of the segments exchanged in wheat-rye recombinant chromosomes provide cytological evidence that wheat-rye recombination is restricted to the distal chromosomal regions. Received: 24 August 1995; in revised form: 27 February 1996 / Accepted: 28 March 1996     

Latent Nonstructural Differentiation among Homologous Chromosomes at the Diploid Level: Chromosome 6B of AEGILOPS LONGISSIMA

Previous work has shown that chromosome pairing at metaphase I (MI) of wheat homologous chromosomes from different inbred lines (heterohomologous chromosomes) is reduced relative to that between homologous chromosomes within an inbred line (euhomologous chromosomes). In order to determine if a potential for this phenomenon exists in diploid species closely related to the wheat B genome, MI chromosome pairing was investigated between euhomologous and heterohomologous 6B^e (=6S^e) chromosomes, each from a different population of Aegilops longissima Schweinf. et Muschl. (2n = 2x = 14) substituted for chromosome 6B of Chinese Spring wheat (Triticum aestivum L., 2n = 6x = 42). Euhomologous and heterohomologous monotelodisomics, i.e., plants with one complete chromosome 6B^e and a telosome of either 6B^ep or 6B^eq, were constructed in the isogenic background of Chinese Spring. Pairing at MI of the Ae. longissima chromosomes was reduced in heterohomologous monotelodisomics compared to that in the corresponding euhomologous monotelodisomics. The remaining 20 pairs of Chinese Spring chromosomes paired equally well in the euhomologous and heterohomologous monotelodisomics. Thus, the cause of the reduced pairing must reside specifically in the Ae. longissima heterohomologues. In the hybrids between the Ae. longissima lines that contributed the substituted chromosomes, pairing between the heterohomologous chromosomes was normal and did not differ from that of the euhomologous chromosomes. These data provide evidence that a potential for reduced pairing between the heterohomologues is present in the diploid species, but is expressed only in the polyploid wheat genetic background. The reduction in heterohomologous chromosome pairing was greater in the p arm than in the q arm, exactly as in chromosome 6B of wheat. It is concluded that the reduced pairing between Ae. longissima heterohomologues has little to do with constitutive heterochromatin. The value of chromosome pairing as an unequivocal means of determining the origin of genomes in polyploid plants is questioned.     

Homologous pairing and chromosome dynamics in meiosis and mitosis

Pairing of homologous chromosomes is an essential feature of meiosis, acting to promote high levels of recombination and to ensure segregation of homologs. However, homologous pairing also occurs in somatic cells, most regularly in Dipterans such as Drosophila, but also to a lesser extent in other organisms, and it is not known how mitotic and meiotic pairing relate to each other. In this article, I summarize results of recent molecular studies of pairing in both mitosis and meiosis, focusing especially on studies using fluorescent in situ hybridization (FISH) and GFP-tagging of single loci, which have allowed investigators to assay the pairing status of chromosomes directly. These approaches have permitted the demonstration that pairing occurs throughout the cell cycle in mitotic cells in Drosophila, and that the transition from mitotic to meiotic pairing in spermatogenesis is accompanied by a dramatic increase in pairing frequency. Similar approaches in mammals, plants and fungi have established that with few exceptions, chromosomes enter meiosis unpaired and that chromosome movements involving the telomeric, and sometimes centromeric, regions often precede the onset of meiotic pairing. The possible roles of proteins involved in homologous recombination, synapsis and sister chromatid cohesion in homolog pairing are discussed with an emphasis on those for which mutant phenotypes have permitted an assessment of effects on homolog pairing. Finally, I consider the question of the distribution and identity of chromosomal pairing sites, using recent data to evaluate possible relationships between pairing sites and other chromosomal sites, such as centromeres, telomeres, promoters and heterochromatin. I cite evidence that may point to a relationship between matrix attachment sites and homologous pairing sites.     

A novel fission yeast gene, kms1 +, is required for the formation of meiotic prophase-specific nuclear architecture

In the meiotic prophase nucleus of the fission yeast Schizosaccharomyces pombe, chromosomes are arranged in an oriented manner: telomeres cluster in close proximity to the spindle pole body (SPB), while centromeres form another cluster at some distance from the SPB. We have isolated a mutant, kms1, in which the structure of the meiotic prophase nucleus appears to be distorted. Using specific probes to localize the SPB and telomeres, multiple signals were observed in the mutant nuclei, in contrast to the case in wild-type. Genetic analysis showed that in the mutant, meiotic recombination frequency was reduced to about one-quarter of the wild-type level and meiotic segregation was impaired. This phenotype strongly suggests that the telomere-led rearrangement of chromosomal distribution that normally occurs in the fission yeast meiotic nucleus is an important prerequisite for the efficient pairing of homologous chromosomes. The kms1 mutant was also impaired in karyogamy, suggesting that the kms1 ⁺ gene is involved in SPB function. However, the kms1 ⁺ gene is dispensable for mitotic growth. The predicted amino acid sequence of the gene product shows no significant similarity to known proteins.