Chromosome segregation

The ability to visualise specific genes and proteins within bacterial cells is revolutionising knowledge of chromosome segregation. The essential elements appear to be the driving force behind DNA replication, which occurs at fixed cellular positions, the condensation of newly replicated DNA by a chromosome condensation machine located at the cell 1/4 and 3/4 positions, and molecular machines that act at midcell to allow chromosome separation after replication and movement of the sister chromosomes away from the division septum prior to cell division. This review attempts to provide a perspective on current views of the bacterial chromosome segregation mechanism and how it relates to other cellular processes.     

Chromosome segregation: pulling from the poles

Dual wavelength video microscopy has been used to evaluate how chromatids move poleward upon chromosome separation at anaphase. The data reveal that poleward microtubule flux provides the dominant force for separating chromatids in Drosophila embryos during anaphase A.     

Chromosome segregation in Eubacteria

It is now clear that bacterial chromosomes rapidly separate in a manner independent of cell elongation, suggesting the existence of a mitotic apparatus in bacteria. Recent studies of bacterial cells reveal filamentous structures similar to the eukaryotic cytoskeleton, proteins that mediate polar chromosome anchoring during Bacillus subtilis sporulation, and SMC interacting proteins that are involved in chromosome condensation. A picture is thereby developing of how bacterial chromosomes are organized within the cell, how they are separated following duplication, and how these processes are coordinated with the cell cycle.     

Chromosome segregation and genomic stability

The acquisition of genomic instability is a crucial step in the development of human cancer. Genomic instability has multiple causes of which chromosomal instability (CIN) and microsatellite instability (MIN) have received the most attention. Whereas the connection between a MIN phenotype and cancer is now proven, the argument that CIN causes cancer remains circumstantial. Nonetheless, the ubiquity of aneuploidy in human cancers, particularly solid tumors, suggests a fundamental link between errors in chromosome segregation and tumorigenesis. Current research in the field is focused on elucidating the molecular basis of CIN, including the possible roles of defects in the spindle checkpoint and other regulators of mitosis.     

Chromosome segregation: seeing is believing

For chromosome segregation in mitosis, each centromere directs assembly of a complex, proteinaceous structure - the kinetochore, which connects the chromosome to microtubules of the mitotic spindle. A recent study has provided important new insights into the mechanism by which kinetochores capture spindle microtubules.     

Chromosome segregation: monopolin attracts condensin

To segregate chromosomes properly, the cell must prevent merotely, an error that occurs when a single kinetochore is attached to microtubules emanating from both spindle poles. Recent evidence suggests that cooperation between Pcs1/Mde4 and condensin complexes plays an important role in preventing merotely.     

Chromosome segregation: pushing plasmids apart

The ParM ATPase from Escherichia coli plasmid R1 assembles into F-actin-like filaments which appear to push replicated copies of the plasmid to opposite ends of the cell, ensuring partitioning into daughter cells. Might bacterial chromosomes use a similar mitotic strategy for segregation?     

Chromosome organization and segregation in bacteria

In the recent years, considerable advances have been made towards understanding the structure and function of the bacterial chromosome. A number of different factors appear to cooperate in condensing DNA into a highly dynamic assembly of supercoiled loops. Despite this variability in the lower levels of chromatin structure, the global arrangement of chromosomal DNA within the cell is surprisingly conserved, with loci being arrayed along the cellular long axis in line with their order on the genomic map. This conserved pattern is propagated during the course of DNA segregation. First, after entry into S-phase, the newly synthesized origin regions are segregated in an active and directed process, involving the bacterial actin homolog MreB. Subsequent DNA segments then follow by different mechanisms. They are separated immediately after release from the replisome and move rapidly to their conserved positions in the incipient daughter cell compartments. Partitioning of the bacterial chromosome thus takes place while DNA replication is in progress.     

Chromosome segregation: correcting improper attachment

Accurate chromosome segregation requires that the two sister kinetochores attach to microtubules from opposite spindle poles. New work reveals how a kinetochore can segregate properly while remaining improperly attached to two spindle poles.     

Chromosome segregation: centromeres get bent

Work over the last several decades has shown that kinetochores play an active part in chromosome segregation, while the chromatin and, more to the point, the DNA have gathered little attention. In two intriguing papers, the Bloom and Khodjakov groups show that intercentromeric chromatin plays a much more active part in chromosome segregation than previously suspected.     

Chromosome segregation from cell hybrids. VII. Reverse segregation from karyoplast hybrids suggests control by cytoplasmic factors.

Using human and Chinese hamster established lines as cell parents, we constructed hamster-human cell hybrids and human cell - hamster karyoplast hybrids. The cell hybrids retained one or two sets of hamster chromosomes and lost most of the human chromosomes. The karyoplast hybrids, however, retained a full set of human chromosomes and lost most of the Chinese hamster chromosomes. This reverse segregation pattern implies that cytoplasmic factors are major determinants of the direction of chromosome segregation.     

Chromosome positioning in the interphase nucleus

Chromosomes occupy distinct territories in the interphase cell nucleus. These chromosome territories are non-randomly arranged within the nuclear space. We are only just uncovering how chromosome territories are organized, what determines their position and how their spatial organization affects the expression of genes and genomes. Here, we discuss emerging models of non-random nuclear chromosome organization and consider the functional implications of chromosome positioning for gene expression and genome stability.     

Chromosome segregation: correcting improperly attached chromosomes

Two new studies show that Aurora B kinase corrects improperly attached chromosomes by recruiting molecules necessary for eliminating the bad attachments and by regulating the turnover of the kinetochore fiber.     

Chromosome segregation: playing polo in prophase

During mitosis, in most eukaryotes, cohesin is removed from chromosomes in two steps. A paper in the March issue of Molecular Cell identifies Polo-like kinase as a key regulator for the first step that releases much of cohesin during prophase.     

Chromosome segregation: Aurora B gets Tousled

Aurora B kinases play important roles during mitosis in eukaryotic cells; new work in Caenorhabditis elegans has identified the Tousled kinase TLK-1 as a substrate activator of the model nematode's Aurora B kinase AIR-2 which acts to ensure proper chromosome segregation during cell division.     

Chromosome segregation: taking the passenger seat

The chromosomal passenger complex (CPC) is a major regulator of mitotic and?meiotic chromosome segregation. Three recent papers now elucidate the mechanisms that determine the localization of the CPC to the inner centromere.     

Chromosome strand segregation during sporulation in Bacillus subtilis

After the initiation of spore formation in Bacillus subtilis, the products of the final round of DNA replication segregate into two cells, i.e. the prespore and the mother cell. The prespore, which is known to contain a single completed chromosome, develops into a mature endospore which can be readily separated from mother cells and non-sporulating cells on the basis of its resistance properties. We have used a procedure originally developed to label the terminus region of the B. subtilis chromosome to specifically label the newly synthesized strands of DNA during the final round of DNA replication before sporulation. We have purified prespore DNA and used strand-specific probes to measure the radioactivity incorporated. The results show that the sister chromosomes segregate at random into the prespore. This result has implications for the segregation of chromosomes during vegetative growth and for the generation of cellular asymmetry during sporulation.     

Chromosome reproduction: units of DNA for segregation

Evidence is summarized which indicates that the DNA loop anchoring proteins in chromosomes are effectively heterodimers that stack and are fastened into a bilaterally symmetrical array along the chromonemal axis. The evidence consists primarily of the observations made twenty five to thirty years ago on the pattern of sister chromatid exchanges and the way the DNA chains are sorted in the formation of diplochromosomes in cells that have undergone endoreduplication. The evidence indicates that each chain of DNA in the single duplex, which is assumed to run the length of a chromosome, is anchored to a bilaterally symmetrical axis of heterodimers that sort the two original chains among the four derived chromatids of each diplochromosome in a very precise way. These observations are considered in the context of investigations on the nature of scaffold proteins and the loop anchorage sequences, as well as the advances being made on the nature of DNA binding proteins and the roles of topoisomerase II.