Anaphase chromosome separation in dividing generative cells ofTradescantia

Summary In dividing generative cells ofTradescantia, kinetochore pairs do not line up on a typical metaphase plate, but instead are distributed along the length and depth of the cell prior to anaphase onset. Kinetochore (K) fibers are linked to each other and to a system of axial microtubule (Mt) bundles in an arrangement that makes discrete half spindles, if present, not immediately obvious. Because such arrangements may have important implications for the conduct of the remainder of division, anaphase events were closely scrutinized using a combination of tubulin and kinetochore immunocytochemistry (the latter with CREST serum). Anaphase appears to consist of three principal processes. Around the time of anaphase onset, K-fibers and surrounding Mts become reorganized into two large superbundles. To each superbundle is attached a set of nonfilial kinetochores bound for one end of the cell. The K-fibers then appear to shorten to varying degrees; in many cases, kinetochores become linked directly to the superbundles. The superbundles then separate in an anaphase B-like process, further moving the kinetochores toward opposite ends of the cell. The superbundles themselves shorten, and distances within the bundles also decrease, such that the kinetochores cluster closer together. The results indicate that reorganization of Mts into superbundles (and the consequential manifestation of bipolarity) is important for orderly chromosome separation.     

The relation between cell size,chromosome length and the orientation of chromosomes in dividing root cortex cells

Cells in the root meristem are organised in longitudinal files. Repeated transverse cell divisions in these files are the prime cause of root growth. Because of the orientation of the cell divisions, we expected to find mitoses with an spindle axis parallel to the file axis. However, we observed in the root cortex ofVicia faba large number of oblique chromosome orientations. From metaphase to telophase there was a dramatic increase of the rotation of the spindle axis. Measurements of both the size of the cortex cells and the chromosome configurations indicated that most cells were too small for an orientation of the spindle parallel to the file axis. Space limitation force the spindle into an oblique position. Despite this spindle axis rotation, most daughter cells remained within the original cell file. Only in extremely flat cells did the position of the daughter nuclei forced the cell to set a plane of division parallel to the file axis, which result in side-by-side orientation of the daughter cells. Telophase spindle axis rotations are also observed inCrepis capillaris andPetunia hybrida.. These species have respectively medium and small sized chromosomes compared toVicia. Since space limitation, which causes the rotation, depends both on cell and chromosome size, the frequency and extent of the phenomenon in former two species is comparatively low.     

The spatial distribution of chromosomes in metaphase neuroblast cells from subspecific F1 hybrids of the grasshopper Caledia captiva

The spatial distribution of chromosomes has been analysed in radial metaphase neuroblast cells in F₁ hybrid embryos generated by crossing individuals of the Moreton and Torresian (TT) chromosomal taxa of the grasshopper Caledia captiva. The Moreton individuals were of two kinds depending on whether they carried an acrocentric X (MAX) or a metacentric X (MMX). No significant associations were detected between any pair of homologous chromosomes in either male or female (MAX x TT) and (MMX x TT) F₁ hybrids. This result was supported by data which showed that the mean separation between homologues is greater, although not significantly so, than the mean separation between non-homologous chromosomes within the two Moreton genomes. Indeed, in a number of cases, genome separation was clearly observed in radial metaphase preparations from these F₁ hybrids. By comparison the analysis of pairwise associations between non-homologous chromosomes within the MMX and MAX Moreton genomes revealed a number of significant associations and dissociations which strongly suggests that at least some chromosomes in these genomes are organised non-randomly at metaphase. Of particular interest was the highly significant X-5 association in the MMX genome since in a previous study X-5 rearrangements were found to occur repeatedly among different backcross progeny involving Moreton x Torresian F₁ hybrids. Additionally a comparison of the organisation of chromosomes in the MAX and MMX genomes, which differ primarily by the type of X chromosome, revealed that in a number of cases pairs of chromosomes are arranged very differently with respect to each other. The distribution of chromosomes on the hollow spindle was also analysed to investigate whether a specific spatial ordering of chromosomes exists within these Moreton genomes based on the association of pairs of short arms and pairs of long arms of most similar length (the Bennett model). The twelve chromosomes in both genomes were uniquely ordered in a single chain. However, because of computing limitations, only the ordered arrangement of chromosomes 1–10 was investigated. An analysis of 48 cells in the MMX and 38 cells in the MAX genomes showed that the predicted order in the ten chromosome sub-set in each genome did not rank in the top 20% of the 181,440 possible orders. This suggests that, although there is a good evidence that some non-homologous chromosomes may be associated non-randomly at metaphase in these genomes, they do not appear to show a specific, ordered arrangement as predicted by the Bennett model. The significance of the observed non-random organisation of chromosomes in the MMX and MAX genomes is discussed in relation to the generation of novel chromosome rearrangements in Moreton x Torresian F₁ hybrids and the evolution of the Moreton and Torresian genomes.     

Steric hindrance and its effect on chromosome movement inVicia faba somatic cells

Summary The arrangement of chromosome arms in metaphases and anaphases has been studied inVicia faba root meristem cells. During metaphase, the long chromosome arms are aligned parallel to the spindle axis. As a consequence, at the onset of anaphase, one chromatid can move straight ahead to the spindle pole whereas the other has to invert its orientation. Specially in narrow cells it has been observed frequently that some chromatids move in a reverse orientation to the pole, i.e., they move telomere-first instead of centromere-first. This behaviour results in a chromatid which protrudes beyond the main group of late anaphase or telophase chromatids. It is dicussed that the most likely explanation for the phenomenon is that in narrow cells chromatid behaviour is influenced by steric hindrance by the tightly packed surrounding chromatids and microtubules. When there is insufficient room, some chromatids are unable to make the required U-turn. Under such conditions the kinetochore of a non-inverted chromatid pulls the chromatid in a reverse orientation to the pole. An alternative explanation, i.e., protruding chromatids being the result of a neocentric activity at the telomere end of a reverse-directed chromatid or the lateral associations of spindle microtubules, failed to find support by electron microscopical studies.     

Cytological effects of colchicine on the grasshopper neuroblast in vitro with special reference to the origin of the spindle

The effectiveness of colchicine in destroying or preventing the development of the spindle is determined by the concentration of the colchicine and the degree of development of the spindle at the time of exposure; the greater the concentration of colchicine, the greater will be its effectiveness in destroying the spindle or interfering with its development; the more completely the spindle is developed at the time of exposure to colchicine, the greater is the concentration of colchicine required to destroy it or prevent its further development.The series of changes in chromosome orientation that take place during the course of colchicine action, namely, approximation of centromeres, formation of “stars,” the breaking up of one “star” into several, and complete chromosome disorientation, represent successive stages in the destruction of the spindle.Destruction of the completely formed spindle is typically accompanied by the accumulation of the spindle material outside the diminishing spindle in a hyaline globule. Similarly, interference of colchicine with spindle development leads to the accumulation of the presumptive spindle material, i.e., the karyolymph, in one or more hyaline globules. It is suggested that colchicine does not destroy the spindle material but merely alters its molecular orientation, so that it comes to comprise a spherical mass with no mitotic function.Strong concentrations of colchicine cause middle and late prophase nuclei to revert to early prophase. Somewhat lower concentrations applied to late prophase nuclei occasionally delay the breakdown of the nuclear membrane without altering the rate of chromosome contraction. In greatly retarded late prophase nuclei the chromosomes lose their intranuclear orientation, which lends support to the concept that the centromeres normally maintain a fixed position within the nucleus.     

Stable and unstable chromosome aberrations in humans and other mammals in relation to the problems of biological dosimetry

Literature data of long-term cytogenetic follow-up of people exposed to radiation as a results of different radiation accidents are considered for the purpose of discussing of some problems of biological dosimetry. The results obtained for mammals are also presented. Of particular interest is a decrease in the level of dicentrics and symmetrical translocations in peripheral blood lymphocytes with the time after acute exposure depending on the dose of irradiation. The frequency of dicentrics decreases in accordance to the exponential law passing the fast and slow phases of elimination. In different radiation situations the values of the parameter which defines the half-life period of lymphocytes characterizing 50% reduction of cells with dicentrics markedly vary. However a general regularity is a decrease in the parameter value as the exposure dose increases. The level of stable translocations estimates by the EISH method remains relatively constant at doses below 1-2 Gy. At higher doses their level in peripheral blood lymphocytes declines with time due to which the retrospective dose appears to be underestimated. The reasons of such regularity, the role of various factors affecting the scoring of translocations, criteria of analysis of the given chromosome aberrations are discussed in the context of common agreements between leading European laboratories on the use of FISH for improving biological dosimetric estimates.     

Structural variability of human chromosome 9 in relation to its evolution

Summary Human chromosome 9 shows a high susceptibility for structural rearrangements, particularly pericentric inversions, which often are transmitted. Three types of pericentric inversions can be observed on No. 9: 1) Type I, showing the total constitutive heterochromatin in the short arm. 2) Type II with part of the C heterochromatin on the short arm, the rest located on the long arm proximal to the centromere. 3) Type III: a subtelocentric chromosome with part of the C heterochromatin in the very short arm and the rest located interstitially on the long arm. With these inversions as well as with other structural rearrangements, e.g. translocations, the break-points are located preferentially within the C heterochromatin or close to the heterochromatic-euchromatic junctions. These findings are in contrast to the findings in lymphocytes from 5 patients with Fanconi's anemia and after irradiation in vitro, reported in the literature. In lymphocytes break-points seem to be distributed more or less by chance. These observations together led us to speculate that human chromosome 9 primarily was an acrocentric chromosome; in morphology and at least in some functions similar to D-and G-group chromosomes. During evolution this acrocentric chromosome changed to a submetacentric one due to a pericentric inversion.The author is sponsored by the Deutsche Forschungsgemeinschaft.     

Effects of D2O on the movement of chromosomes and the shortening of kinetochore spindle fibers in anaphase in dividing spermatocytes of the grasshopper, Mongolotettix japonicus

Spindles in anaphase of dividing primary spermatocytes of the grasshopper, Mongolotettix japonicus, were examined with a sensitive polarizing microscope combined with a time-lapse video recorder and a cinematographic apparatus. The pole-to-pole distance of the meiotic spindles was increased and the kinetochore fibers were more birefringent in the presence of 40% D2O. However, the rate of shortening of the kinetochore fibers in anaphase was not affected by D2O. This indicates that D2O did not inhibit microtubule disassembly in anaphase, supporting the earlier observations (3, 18) that D2O did not "stabilize" the spindle microtubules at concentrations below 45%. We confirmed that D2O, at the concentration mentioned above, neither promotes nor inhibits the anaphase A. However, the overall sequence of anaphase was considerably extended in the presence of D2O, presumably due to the increased pole-to-pole distance.     

Oviduct development and its relation to other aspects of reproduction in domesticated canaries

The histology and development of the oviduct of unpaired female canaries during the natural breeding season were examined. The histology resembles that of the fowl. The tubular glands develop by invagination of the epithelial cells, and albumen granules subsequently form in their cytoplasm. The epithelium differentiates into ciliated columnar cells and goblet cells. The histology of the magnum is uniform along its length at all stages of development.
Oviduct development is closely correlated with that of the ovary. In its early stages there appears to be little correlation between oviduct development and that of the brood patch or of nest-building. The formation of albumen coincides with the enlargement of one ovarian follicle more than the rest, the completion of defeathering, and intensive nest-building behaviour.