How do meiotic chromosomes meet their homologous partners?: lessons from fission yeast

Homologous chromosome pairing is required for proper chromosome segregation and recombination during meiosis. The mechanism by which a pair of homologous chromosomes contact each other to establish pairing is not fully understood. When pairing occurs during meiotic prophase in the fission yeast, Schizosaccharomyces pombe, the nucleus oscillates between the cell poles and telomeres remain clustered at the leading edge of the moving nucleus. These meiosis-specific activities produce movements of telomere-bundled chromosomes. Several lines of evidence suggest that these movements facilitate homologous chromosome pairing by aligning homologous chromosomes and promoting contact between homologous regions. Since telomere clustering and nuclear or chromosome movements in meiotic prophase have been observed in a wide range of eukaryotic organisms, it is suggested that telomere-mediated chromosome movements are general activities that facilitate homologous chromosome pairing.     

Microtubules,chromosome movement,and reorientation after chromosomes are detached from the spindle by micromanipulation

The relationship between chromosome movement and mirotubules was explored by combining micromanipulation of living grasshopper spermatocytes with electron microscopy. We detached chromosomes from the spindle and placed them far out in the cytoplasm. Soon, the chromosomes began to move back toward the spindle and the cells were fixed at a chosen moment. The microtubules seen in three-dimensional reconstructions were correlated with the chromosome movement just prior to fixation. Before movement began, detached chromosomes had no kinetochore microtubules or a single one at most. Renewed movement was always accompanied by the reappearance of kinetochore microtubules; a single kinetochore microtubule appeared to suffice. Chromosome movements and kinetochore microtubule arrangements were unusual after reattachment, but their relationship was not: poleward forces, parallel to the kinetochore microtubule axis (as in normal anaphase), would explain the movement, however odd. The initial arrangement of kinetochore microtubules would have led to aberrant chromosome distribution if it persisted, but instead, reorientation to the appropriate arrangement always followed. Observations on living cells permitted us to place in sequence the kinetochore microtubule arrangements seen in fixed cells, revealing the microtubule transformations during reorientation. From the sequence of events we conclude that chromosome movement can cause reorientation to begin and that in the changes which follow, an unstable attachment of kinetochore microtubules to the spindle plays a major role.     

The positioning of rye homologous chromosomes added to wheat through the cell cycle in somatic cells untreated and treated with colchicine

The arrangement of chromosome pairs 5RL and 7R added to the wild type and the ph1b mutant line of hexaploid wheat are analyzed in 2N somatic root tip cells during the cell cycle relative to the arrangement that chromosomes 5RL show in 4N tapetal cells produced after colchicine treatment. Both homologous chromosome pairs are identified at interphase and mitosis by fluorescence in situ hybridization. In nuclei at interphase, chromosomes appear as discrete domains that show the Rabl orientation. Homologous chromosomes are predominantly non-associated and their positioning seems not to be influenced by the Ph1 gene that suppresses homoeologous meiotic pairing. This pattern of arrangement contrasts with the high level of somatic pairing that sister chromosomes show in the interphase that follows chromosome duplication induced by colchicine. Disruption of pairing observed in some 4N nuclei is produced at c-anaphase which suggests no topological redistribution of homologues during conformation of the new nucleus. Homologous chromosomes show no predominant arrangement in ellipsoidal metaphase plates, which contrasts with the preferential opposite location of homologues in human prometaphase rosettes. Differences between chromosomes in the variation of the length through the cell cycle and in the chromatin morphology when the Ph1 is absent suggest different patterns of chromatin condensation in both chromosomes.     

Global chromosome positions are transmitted through mitosis in mammalian cells

We investigated positioning of chromosomes during the cell cycle in live mammalian cells with a combined experimental and computational approach. By non-invasive labeling of chromosome subsets and tracking by 4D imaging, we could show that no global rearrangements occurred in interphase. Using the same assay, we also observed a striking order of chromosomes throughout mitosis. By contrast, our computer simulation based on stochastic movements of individual chromosomes predicted randomization of chromosome order in mitosis. In vivo, a quantitative assay for single chromosome positioning during mitosis revealed strong similarities between daughter and mother cells. These results demonstrate that global chromosome positions are heritable through the cell cycle in mammalian cells. Based on tracking of labeled chromosomes and centromeres during chromosome segregation and experimental perturbations of chromosomal order, we propose that chromosome specific timing of sister chromatid separation transmits chromosomal positions from one cell generation to the next.     

Tissue-Specific Differences in the Spatial Interposition of X-Chromosome and 3R Chromosome Regions in the Malaria Mosquito Anopheles messeae Fall.

Spatial organization of a chromosome in a nucleus is very important in biology but many aspects of it are still generally unresolved. We focused on tissue-specific features of chromosome architecture in closely related malaria mosquitoes, which have essential inter-specific differences in polytene chromosome attachments in nurse cells. We showed that the region responsible for X-chromosome attachment interacts with nuclear lamina stronger in nurse cells, then in salivary glands cells in Anopheles messeae Fall. The inter-tissue differences were demonstrated more convincingly in an experiment of two distinct chromosomes interposition in the nucleus space of cells from four tissues. Microdissected DNA-probes from nurse cells X-chromosome (2BC) and 3R chromosomes (32D) attachment regions were hybridized with intact nuclei of nurse cells, salivary gland cells, follicle epithelium cells and imaginal disсs cells in 3D-FISH experiments. We showed that only salivary gland cells and follicle epithelium cells have no statistical differences in the interposition of 2BC and 32D. Generally, the X-chromosome and 3R chromosome are located closer to each other in cells of the somatic system in comparison with nurse cells on average. The imaginal disсs cell nuclei have an intermediate arrangement of chromosome interposition, similar to other somatic cells and nurse cells. In spite of species-specific chromosome attachments there are no differences in interposition of nurse cells chromosomes in An. messeae and An. atroparvus Thiel. Nurse cells have an unusual chromosome arrangement without a chromocenter, which could be due to the special mission of generative system cells in ontogenesis and evolution.     

Chromosome organization and dynamics in plants

The past few years have brought renewed interest in understanding the dynamics of chromosomes in interphase cells as well as during cell division, particularly meiosis. This research has been fueled by new imaging methods, particularly three-dimensional, high-resolution, and live microscopy. Major contributors are also new genetic tools that allow elucidation of mechanisms controlling chromosome behavior. Recent studies in plants have explored chromatin arrangement in interphase nuclei, chromosome interactions and movement during meiotic prophase I, and mechanisms that ensure correct segregation of chromosomes during anaphase. These studies shed light on chromosome dynamics in a small-genome plant Arabidopsis thaliana, as well as in plants with large and complex genomes of polyploid origin, such as wheat and maize.     

Interphase chromosome arrangement in Arabidopsis thaliana is similar in differentiated and meristematic tissues and shows a transient mirror symmetry after nuclear division

Whole-mount fluorescence in situ hybridization (FISH) was applied to Arabidopsis thaliana seedlings to determine the three-dimensional (3D) interphase chromosome territory (CT) arrangement and heterochromatin location within the positional context of entire tissues or in particular cell types of morphologically well-preserved seedlings. The interphase chromosome arrangement was found to be similar between all inspected meristematic and differentiated root and shoot cells, indicating a lack of a gross reorganization during differentiation. The predominantly random CT arrangement (except for a more frequent association of the homologous chromosomes bearing a nucleolus organizer) and the peripheric location of centromeric heterochromatin were as previously observed for flow-sorted nuclei, but centromeres tend to fuse more often in nonendoreduplicating cells and NORs in differentiated cells. After mitosis, sister nuclei revealed a symmetric arrangement of homologous CTs waning with the progress of the cell cycle or in the course of differentiation. Thus, the interphase chromosome arrangement in A. thaliana nuclei seems to be constrained mainly by morphological features such as nuclear shape, presence or absence of a nucleolus organizer on chromosomes, nucleolar volume, and/or endopolyploidy level.     

The spatial organization of the genome in mammalian cells

A number of recent studies have indicated that the location of a given mammalian chromosome within the interphase nucleus is related to its size, whereas other work has implicated a chromosome's gene density as a factor. Recent investigations of the degree to which an ordered arrangement of mitotic chromosomes on the metaphase plate is inherited and perpetuated during successive cell cycles have also yielded somewhat controversial results. The arrangement of chromosomes in the nucleus also has been investigated by the analysis of chromosomal translocations, with some surprising recent findings.     

Conservation of relative chromosome positioning in normal and cancer cells

Chromosomes exist in the interphase nucleus as individual chromosome territories. It is unclear to what extent chromosome territories occupy particular positions with respect to each other and how structural rearrangements, such as translocations, affect chromosome organization within the cell nucleus. Here we analyze the relative interphase positioning of chromosomes in mouse lymphoma cells compared to normal splenocytes. We show that in a lymphoma cell line derived from an ATM(-/-) mouse, two translocated chromosomes are preferentially positioned in close proximity to each other. The relative position of the chromosomes involved in these translocations is conserved in normal splenocytes. Relative positioning of chromosomes in normal splenocytes is not due to their random distribution in the interphase nucleus and persists during mitosis. These observations demonstrate that the relative arrangement of chromosomes in the interphase nucleus can be conserved between normal and cancer cells and our data support the notion that physical proximity facilitates rearrangements between chromosomes.     

A probabilistic model for the arrangement of a subset of human chromosome territories in WI38 Human fibroblasts

There is growing evidence that chromosome territories have a probabilistic non‐random arrangement within the cell nucleus of mammalian cells. Other than their radial positioning, however, our knowledge of the degree and specificity of chromosome territory associations is predominantly limited to studies of pair‐wise associations. In this study we have investigated the association profiles of eight human chromosome pairs (numbers 1, 2, 3, 4, 6, 7, 8, 9) in the cell nuclei of G₀‐arrested WI38 diploid lung fibroblasts. Associations between heterologous chromosome combinations ranged from 52% to 78% while the homologous chromosome pairs had much lower levels of association (3–25%). A geometric computational method termed the Generalized Median Graph enabled identification of the most probable arrangement of these eight chromosome pairs. Approximately 41% of the predicted associations are present in any given nucleus. The association levels of several chromosome pairs were very similar in a series of lung fibroblast cell lines but strikingly different in skin and colon derived fibroblast cells. We conclude that a large subset of human chromosomes has a preferred probabilistic arrangement in WI38 cells and that the resulting chromosomal associations show tissue origin specificity. J. Cell. Physiol. 221: 120–129, 2009. © 2009 Wiley‐Liss, Inc     

Cell type specific chromosome territory organization in the interphase nucleus of normal and cancer cells

Numerous studies indicate that the genome of higher eukaryotes is organized into distinct chromosome territories and that the 3‐D arrangement of these territories may be closely connected to genomic function and the global regulation of gene expression. Despite this progress, the degree of non‐random arrangement remains unclear and no overall model has been proposed for chromosome territory associations. To address this issue, a re‐FISH approach was combined with computational analysis to analysis the pair‐wise associations for six pairs of human chromosomes (chr #1, 4, 11, 12, 16, 18) in the G₀ state of normal human WI38 lung fibroblast and MCF10A epithelial breast cells. Similar levels of associations were found in WI38 and MCF10A for several of the chromosomes whereas others showed striking differences. A novel computational geometric approach, the generalized median graph (GMG), revealed a preferred probabilistic arrangement distinct for each cell line. Statistical analysis demonstrated that ～50% of the associations depicted in the GMG models are present in each individual nucleus. A nearly twofold increase of chromosome 4/16 associations in a malignant breast cancer cell line (MCFCA1a) compared to the related normal epithelial cell line (MCF10A) further demonstrates cancer related changes in chromosome arrangements. Our findings of highly preferred chromosome association profiles that are cell type specific and undergo alterations in cancer cells, lead us to propose a probabilistic chromosome code whereby the 3‐D association profile of chromosomes contributes to the functional landscape of the cell nucleus, the global regulation of gene expression and the epigenetic state of chromatin. J. Cell. Physiol. 221: 130–138, 2009. © 2009 Wiley‐Liss, Inc     

The spatial arrangement of chromosomes during prometaphase facilitates spindle assembly

Error-free chromosome segregation requires stable attachment of sister kinetochores to the opposite spindle poles (amphitelic attachment). Exactly how amphitelic attachments are achieved during spindle assembly remains elusive. We employed photoactivatable GFP and high-resolution live-cell confocal microscopy to visualize complete 3D movements of individual kinetochores throughout mitosis in nontransformed human cells. Combined with electron microscopy, molecular perturbations, and immunofluorescence analyses, this approach reveals unexpected details of chromosome behavior. Our data demonstrate that unstable lateral interactions between kinetochores and microtubules dominate during early prometaphase. These transient interactions lead to the reproducible arrangement of chromosomes in an equatorial ring on the surface of the nascent spindle. A computational model predicts that this toroidal distribution of chromosomes exposes kinetochores to a high density of microtubules which facilitates subsequent formation of amphitelic attachments. Thus, spindle formation involves a previously overlooked stage of chromosome prepositioning which promotes formation of amphitelic attachments.     

Laser microirradiation of kinetochores in mitotic PtK2 cells: chromatid separation and micronucleus formation

Irradiation of the kinetochore region of PtK2 chromosomes by laser light of 532 nm was used to study the function of the kinetochore region in chromosome movement and to create an artificial micronuclei in cells. When the sister kinetochores of a chromosome were irradiated at prometaphase, the affected chromosome detached from the spindle and exhibited no further directed movements for the duration of mitosis. The chromatids of the chromosome remained attached to one another until anaphase, at which point they separated. No poleward movement of the chromatids was observed, and at telophase they passively moved to one of the daughter cells and were enclosed in a micronucleus. The daughter cell containing the micronucleus was then isolated by micromanipulation and followed through subsequent mitoses. At the next mitosis, two chromosomes, each with two chromatids, condensed in the micronucleus. These chromosomes did not attach to the spindle and showed chromatid separation, but no poleward movements at anaphase. They were again enclosed in micronuclei at telophase. The third generation mitosis was similar to the second. Occasionally, both the irradiation-produced and naturally occurring micronuclei exhibited no chromosome condensation at mitosis. Feulgen-stained monolayers of PtK2 cells with naturally occurring micronuclei showed that some micronuclei stain positive for DNA and others do not. This finding raises questions about the fate of chromosomes in a micronucleus.     

Interphase chromosome order: A proposal

A model for the arrangement of chromosomes in interphase nuclei is proposed. The model assumes that interphase chromosomes have a Rabl orientation (a relic telophase arrangement). During interphase and prophase telomeres are attached to the nuclear envelope often in pairs. The association of telomeres, homologous or nonhomologous, is based on similarity of arm lengths and occurs at the time the nuclear envelope reforms. At this stage arm lengths will vary to some extent due to the amount of uncoiling etc. The sequence of chromosomes resulting from telomere-telomere pairing may vary among cells, but the number of arrangements will be restricted by arm length similarities.The ramifications of this model on melotic pairing, the constant attachment of chromosomes to some structure throughout the cell cycle, the distribution of genes within nuclei, and chromosome evolution are raised.     

Use of two-color fluorescence-tagged transgenes to study interphase chromosomes in living plants

Sixteen distinct sites distributed on all five Arabidopsis (Arabidopsis thaliana) chromosomes have been tagged using different fluorescent proteins and one of two different bacterial operator-repressor systems: (1) a yellow fluorescent protein-Tet repressor fusion protein bound to tet operator sequences, or (2) a green or red fluorescent protein-Lac repressor fusion protein bound to lac operator sequences. Individual homozygous lines and progeny of intercrosses between lines have been used to study various aspects of interphase chromosome organization in root cells of living, untreated seedlings. Features reported here include distances between transgene alleles, distances between transgene inserts on different chromosomes, distances between transgene inserts on the same chromatin fiber, alignment of homologous chromosomes, and chromatin movement. The overall findings are consistent with a random and largely static arrangement of interphase chromosomes in nuclei of root cells. These transgenic lines provide tools for in-depth analyses of interphase chromosome organization, expression, and dynamics in living plants.     

Laser microirradiation of kinetochores in mitotic PtK2 cells

Irradiation of the kinetochore region of PtK₂ chromosomes by laser light of 532 nm was used to study the function of the kinetochore region in chromosome movement and to create artificial micronuclei in cells. When the sister kinetochores of a chromosome were irradiated at prometaphase, the affected chromosome detached from the spindle and exhibited no further directed movements for the duration of mitosis. The chromatids of the chromosome remained attached to one another until anaphase, at which point they separated. No poleward movement of the chromatids was observed, and at telophase they passively moved to one of the daughter cells and were enclosed in a micronucleus. The daughter cell containing the micronucleus was then isolated by micromanipulation and followed through subsequent mitoses. At the next mitosis, two chromosomes, each with two chromatids, condensed in the micronucleus. These chromosomes did not attach to the spindle and showed chromatid separation, but no poleward movements at anaphase. They were again enclosed in micronuclei at telophase. The third generation mitosis was similar to the second. Occasionally, both the irradiation-produced and naturally occurring micronuclei exhibited no chromosome condensation at mitosis. Feulgenstained monolayers of PtK₂ cells with naturally occurring micronuclei showed that some micronuclei stain positive for DNA and others do not. This finding raises questions about the fate of chromosomes in a micronucleus.     

Spatial organization of chromosome territories in the interphase nucleus of trisomy 21 cells

In the interphase cell nucleus, chromosomes adopt a conserved and non-random arrangement in subnuclear domains called chromosome territories (CTs). Whereas chromosome translocation can affect CT organization in tumor cell nuclei, little is known about how aneuploidies can impact CT organization. Here, we performed 3D-FISH on control and trisomic 21 nuclei to track the patterning of chromosome territories, focusing on the radial distribution of trisomic HSA21 as well as 11 disomic chromosomes. We have established an experimental design based on cultured chorionic villus cells which keep their original mesenchymal features including a characteristic ellipsoid nuclear morphology and a radial CT distribution that correlates with chromosome size. Our study suggests that in trisomy 21 nuclei, the extra HSA21 induces a shift of HSA1 and HSA3 CTs out toward a more peripheral position in nuclear space and a higher compaction of HSA1 and HSA17 CTs. We posit that the presence of a supernumerary chromosome 21 alters chromosome compaction and results in displacement of other chromosome territories from their usual nuclear position.     

Microsurgically-extracted metaphase chromosomes of the Indian muntjac examined with phase contrast and scanning electron microscopy.

Metaphase chromosomes are extracted from Indian muntjac cultured fibroblasts either through the use of microneedles or by the application of a droplet of silicone oil onto the cell surface. Interconnecting fibers among the chromosomes allow the entire diploid complement to be extracted from the cell. The seven muntjac chromosomes are brought to the surface of a glass coverslip for analysis. Each chromosome can be identified on the basis of morphology, and particular chromosomes or chromosome parts can be isolated. Many of the fibers which interconnect the chromosomes may be attributed to adhesions formed between the sticky chromosome surfaces during extraction. However, when interchromosomal contacts are avoided during extraction, the chromosomes are found to be arranged radially with the centromeres near the center and interconnected by fibers. This arrangement is similar to that seen inside muntjac cells at metaphase. Scanning electron microscopy reveals the chromosome surfaces to consist of looping fibers, except for regions near the centromeres and the secondary constrictions. Chromosome fibers at these sites are organized into parallel bundles. Chromosome interconnections are strands composed of multiple fibers which seem to be continuous with chromosome fibers.     

Condensin: crafting the chromosome landscape

The successful transmission of complete genomes from mother to daughter cells during cell divisions requires the structural re-organization of chromosomes into individualized and compact structures that can be segregated by mitotic spindle microtubules. Multi-subunit protein complexes named condensins play a central part in this chromosome condensation process, but the mechanisms behind their actions are still poorly understood. An increasing body of evidence suggests that, in addition to their role in shaping mitotic chromosomes, condensin complexes have also important functions in directing the three-dimensional arrangement of chromatin fibers within the interphase nucleus. To fulfill their different functions in genome organization, the activity of condensin complexes and their localization on chromosomes need to be strictly controlled. In this review article, we outline the regulation of condensin function by phosphorylation and other posttranslational modifications at different stages of the cell cycle. We furthermore discuss how these regulatory mechanisms are used to control condensin binding to specific chromosome domains and present a comprehensive overview of condensin’s interaction partners in these processes.