Condensin I reveals new insights on mouse meiotic chromosome structure and dynamics.

Chromosome shaping and individualization are necessary requisites to warrant the correct segregation of genomes in either mitotic or meiotic cell divisions. These processes are mainly prompted in vertebrates by three multiprotein complexes termed cohesin and condensin I and II. In the present study we have analyzed by immunostaining the appearance and subcellular distribution of condensin I in mouse mitotic and meiotic chromosomes. Our results demonstrate that in either mitotically or meiotically dividing cells, condensin I is loaded onto chromosomes by prometaphase. Condensin I is detectable as a fuzzy axial structure running inside chromatids of condensed chromosomes. The distribution of condensin I along the chromosome length is not uniform, since it preferentially accumulates close to the chromosome ends. Interestingly, these round accumulations found at the condensin I axes termini colocalized with telomere complexes. Additionally, we present the relative distribution of the condensin I and cohesin complexes in metaphase I bivalents. All these new data have allowed us to propose a comprehensive model for meiotic chromosome structure.

Expression and behaviour of CENP-E at kinetochores during mouse spermatogenesis.

Centromere protein E (CENP-E) is a microtubule motor protein localised in the outer kinetochore plate and in the fibrous corona that relocalises to the midzone in early anaphase. While its expression in somatic cells has been widely analysed, an accurate description of its behaviour during the two meiotic divisions has not yet been reported. We have carefully analysed by immunofluorescence the subcellular distribution of CENP-E during mouse spermatogenesis. CENP-E first appears during late diakinesis/early prometaphase I as very bright C-shaped or "crescent" signals at each homologous centromere. These crescent CENP-E signals are also observed in unaligned prometaphase I bivalents that are not attached to spindle microtubules, while in bioriented metaphase I bivalents two kinds of fainter signals are observed. Thus, some bivalents present a plate-like signal while others show a pair of spots representing sister kinetochores at each homologous centromere. Double labelling of CENP-E with CENP-G and an anti-centromere serum indicates that in meiosis CENP-E is also located at the outer kinetochore plate and the fibrous corona. During early anaphase I CENP-E relocalises from kinetochores to the midzone where it is detected as fibrous strands, although some residual labelling persists at kinetochores until telophase I. During this stage CENP-E is detected as two parallel plates at the intercellular bridge. The general pattern of labelling during meiosis II is similar to that found during meiosis I. Our results suggest that CENP-E is implicated in the spindle checkpoint, and in chromosome alignment, during the two meiotic divisions in vertebrate males. We also demonstrate that the centromere changes its structure once alignment of all bivalents at the metaphase I plate has been reached.