Seasonal variation in the frequency of abnormal anaphases and mitotic index values in wild populations of herb-Paris (Paris quadrifolia L., Trilliaceae): implications for genetic monitoring

The main aim of our study was to investigate seasonal variation in the frequency of abnormal anaphases and mitotic index values in wild populations of herb-Paris (Paris quadrifolia L., Trilliaceae). Plant material was collected in the year 2000 in Norway and in the year 2001 in Lithuania. There was statistically significant variation in the mitotic index values (chi(2)=1087.9, d.f.=16, P<0.0001) with the highest values during the active growth period in May and the lowest values at the end of vegetation period in September. Seasonal variation in the frequency of abnormal anaphases was statistically significant as well (chi(2)=28.23, d.f.=16, P=0.0297). The most frequent type of anaphase abnormality was vagrant chromosomes (64.2%) followed by bridges (28.6%), fragments (3.6%), sticky chromosomes (2.4%) and multipolar anaphases (1.2%). During the fieldwork, quite deep late frosts occurred. Mitotic index was lower in the plants collected immediately after the frosts or 1 week later than in the plants sampled before the frosts (52+/-13 and 123+/-15, respectively, P=0.0014). On the contrary, frequency of abnormal anaphases was statistically significantly elevated (P=0.0082) in plants after the frosts (6.35+/-1.54%) when compared to plants before the frosts (2.49+/-0.56%). Our results clearly indicated significant variation in the mitotic index values and frequency of abnormal anaphases in the wild populations of herb-Paris during the growth season. This variation may be related to the physiological conditions of the analysed plants as well as to certain ecological factors.     

Anaphase chromosome movement in the unequally dividing grasshopper neuroblast and its relation to anaphases of other cells

The positions of the two sets of chromosome kinetochores, the spindle poles, cell membrane adjacent to the poles, and cleavage furrow of grasshopper neuroblasts in culture at 38°C were determined at short-time intervals during anaphase. The percent of motion due to poleward movement and spindle elongation, which coincide in time, were calculated for each minute, the former falling from 61% in the first minute to 15% in the seventh minute, and increasing to 86% in the final minute, probably as a result of pressure and bending of the spindle. Of the total chromosome movement during anaphase 44.6% is due to poleward movement of the daughter kinetochores and 55.4% to spindle elongation. The maximum velocity of a set of kinetochores is 3.41 m/min and the mean velocity 1.86 m/min (one-half the rate of separation). Various studies of anaphase chromosome movement in different cells and different species suggest certain generalizations, some of which are based on very small samples and so must be considered quite tentative: (1) The combination of poleward movement and spindle elongation is much more frequent than either acting alone. (2) These components of movement may coincide in time, overlap, or spindle elongation may follow poleward movement, but spindle elongation never begins before poleward chromosome movement. (3) There is an optimum temperature for the rate of chromosome movement, above and below which the rate gradually decreases. (4) In homoiothermic animals this optimum occurs at normal body temperature. (5) In homoiothermic animals the velocity falls more rapidly with a decrease in temperature than in poikilothermic animals. (6) Animals with large chromosomes (amphibia, grasshoppers) have higher chromosome velocities than those with small chromosomes. (7) Non-meiotic cells and secondary spermatocytes have higher velocities than primary spermatocytes of the same species. (8) Chromosome velocity is lower in malignant than non-malignant cells. (9) Chromosome velocity tends to be positively correlated with the distance the chromosomes travel during anaphase.     

Chromatid segregation analysis in native human lymphocyte anaphases using sequential fluorescence in situ hybridization

A sequential multiprobe fluorescence in situ hybridization technique was developed to study the 13, 18, 21, X and Y chromatid segregation in human lymphocytes anaphases cultures without antimitotic treatment. This method was used to know if exist any different chromosomes segregation in lymphocytes from Down syndrome patients and compared it with controls. The results show that the prevalent sequence of centromere separation was X, 13, 21, Y and 18 in Down syndrome patients and Y, 13, X, 21 and 18 in controls. Chromatid segregation in early anaphase was asynchronic for all chromosome pairs studied. Late anaphase showed a frequency of non-disjunction of 4.5% in the controls, affecting only chromosomes 18 and Y; in the Down syndrome patients, the frequency was higher (20.3%) and affected all chromosomes studied. This technique could be applicated to know the incidence of non disjunction in couples with repetitive abortions or in cases with different aneuploidies in the offspring. This revised version was published online in September 2006 with corrections to the Cover Date.     

Chromosome movements in chloral hydrate treated endosperm cells in vitro

The influence of chloral hydrate on endosperm cells of Haemanthus katherinae was studied. Four types of mitotic disturbances were described: a) Normal bipolar mitosis with one or few chromosomes lying out of the metaphase plate. Bipolar mitoses are sometimes arrested in anaphase and followed by the formation of a restitution nucleus. b) Tri — or multipolar anaphases. c) Diffuse anaphase movements i.e., active anaphase movements without distinct poles followed by the formation of multipolar phragmoplasts and cell walls. d) C-mitosis resembling the effect of colchicine. Some aspects of the described phenomena were discussed.     

Progress in studies of ZW10, a proper chromosome segregation protein

The conserved protein ZW10 is found in various organisms. It is localized on the kinetochores or spindle microtubules during cell division. ZW10 regulates not only the segregation of homologous chromosomes, each consisting of attached sister chromatids (during the first meiotic division), but also the separation of individual chromatids (during mitosis and the second meiotic division). ZW10 is required for proper chromosome segregation during both mitosis and meiosis. The effects of zwl0 mutations are similar for both equational and reductional divisions, giving rise to anaphases with lagging chromosomes and/or unequal numbers of chromosomes at the two poles. The localization of ZW10 is similar during mitosis, meiosis I, and meiosis II. In interphase the distribution of ZW10 changes; it is localized in the endoplasmic reticulum, Golgi apparatus, and in the cytosol and is involved in membrane trafficking between the endoplasmic reticulum and Golgi apparatus. ZW10 forms a subcomplex with RINT-1 and p31 which are involved in a larger complex comprising syntaxin 18, an endoplasmic reticulum-localized t-SNARE that is implicated in membrane trafficking. The text was submitted by the authors in English.     

Immediate disruption of spindle poles and induction of additional microtubule-organizing centres by a phenylcarbamate, during plant mitosis

Summary The herbicide carbetamide [(R)-1-(ethylcarbamoyl) ethylphenylcarbamate], in the 0.4 to 0.8 mM range, efficiently induced multipolar mitoses inAllium cepa L. The frequency of multipolar anaphases rose earlier and reached higher values when both concentration and time of treatment increased, up to a maximum of 90% after 1 h of treatment. To identify the physiological target, the kinetics of induction of multipolar mitoses were followed during recovery from very short treatments (5, 10, and 15 min). Tubulin immunodetection showed that phenylcarbamate immediately disrupts the cohesion between the different bundles of microtubule minus ends which converge at the pole. The spindle was rendered multipolar about three times more efficiently in metaphase than in anaphase. The observations do not support any effect of the herbicide on the tubulin polymerization-depolymerization cycle, and suggest that the minus ends of the microtubules remained stabilized in carbetamide. Thus, the density of kinetochore microtubules and their lengths were unmodified in the individual chromosomes which became detached from both spindle poles in response to the herbicide. Extra microtubule-organizing centres for the assembly of both preprophase band and phragmoplast (the tubulin arrays which characterize the microtubular cycle responsible for cytokinesis in plant cells) were also rapidly induced.Abbreviations MTOCs microtubule-organizing centres     

A technique for quantitative estimation of small mammals traversing water obstacles

A new method for quantitative study of small mammals swimming across water obstacles was developed. A line of 25 traps was installed on either poles or boards (“rafts”) with anchors at a distance of 20–25 m from the bank and with 10-m distances between the items. The study was performed upstream along the Ilych River in August 2013. A total of 300 trap/day were accumulated. Twenty-four small mammal individuals of 8 species were captured. Their relative abundance was estimated as the number of individuals per 100 trap/day. It was found experimentally that floating poles neither repel nor attract animals. When an individual accidentally finds a floating pole, it climbs up and explores it for some time. The number of animals per total length of rafts per time unit can be suggested as an index of intensiveness of migration across a water obstacle. In the area studied, the number of small mammals of various species crossing the river was estimated at 26.7 individuals per 1 km/day. A length of 5 m for floating poles/boards and installation of two traps at the ends of an item is suggested to be used.     

Persistence of anaphase abnormalities in fast neutron irradiated tomato

The percentage of abnormal anaphases was determined in rooted leaf and stem cuttings from irradiated diploid and tetraploid tomato plants. It was confirmed that somatic selection is very fast but that even drastic abnormalities, giving rise to abnormal anaphases, seem to be stabilised at a low frequency. Little difference was found between diploid and tetraploid lines or between different genotypes. A considerable part of the anaphase abnormalities found are considered to have arisen de novo.     

Disruption of organization of mitotic microtubules in root meristem cells of Allium cepa induced by chloral hydrate

Data are presented on the effect of chlorahydrate on microtubule organization in the root meristem of Allium cepa. Our studies show that an incomplete preprophase band commonly appears during G2-prophase transition, yet the major effect is the lack of perinuclear microtubules, leading to inhibition of the prophase spindle formation and transition to C-mitosis. Upon chloralhydrate treatment of metaphase cells, we found cells with chromosomes regularly aligned within the metaphase plate and differently disorganized mitotic spindles. Concurrently, C-metaphase cells with remnants of kinetochore fibers were present. In addition, normal bipolar and abnormal irregular types of chromosome segregation were detected, this representing multipolar and diffuse anaphases. The major difference between them is the presence of polar microtubules during multipolar anaphase, and their lacking during diffuse anaphase. Alternatively, microtubule clusters between segregated groups of chromosomes are typical for cells with diffuse anaphase. During bipolar anaphase, excessive aster-like microtubules emanate from the spindle poles, and in telophase accessory phragmoplasts are observed at the cell periphery. The formation of incomplete phragmoplasts was observed after normal bipolar and abnormal chromosome segregation. We conclude that chloralhydrate may affect the nuclear surface capability to initiate the growth of perinuclear microtubules, thus blocking the prophase spindle formation. It also disturbs the spatial interaction between microtubules, which is crucial for the formation and functioning of various microtubular systems (preprophase band, spindle and phragmoplast).     

Chromosome damage induced by artificial seed aging in barley

Summary Barley (Hordeum vulgare L. Himalaya) seeds were artificially aged under two storage conditions (32 °C/12% moisture content (m.c.) and 38 °C/18% m.c.) to study the behavior of induced chromosomal aberrations during plant growth. The frequencies of aberrant anaphases at first mitosis in root tips were correlated with loss of germinability. However, after 3 and 5 weeks' growth, aberration frequency declined. In plants grown from artificially aged seeds, the frequency of aberrant anaphases appeared to be stabilized at about 1% after 5 weeks' growth, in spite of the large differences in the frequencies at first mitosis. This suggests that because of their genetic imbalance, cells with chromosomal aberrations induced by seed aging were being excluded during plant growth. Meiotic chromosome configurations at MI were normal (7 II) in all plants studied, although a few precocious separations were found. Meiotic aberrations were found at AI-TI, AII-TII and the tetrad stages in the pollen mother cells of plants grown from the control and artificially aged seeds. However, there were no clear differences among the control and the two aging treatments. It was obvious that some cells with meiotic chromosomal aberrations were lost between the AI-TI and AII-TII stages, and still more between the AII-TII and tetrad stages. The frequency of tetrads with micronuclei in plants produced from artificially aged seeds was the same as in the control. The plants grown from artificially aged seeds showed high pollen fertility (95.2 to 97.0%) and seed fertility (90.1 to 97.2%) which was comparable to the control values (97.4 and 97.9%) respectively, indicating no special effects of seed aging. Anaphase cells of the first mitosis in the next (A₂) generation were analyzed to study the transmission of chromosomal aberrations through mitotic and meiotic cell divisions in the A₁ generation. Aberrant anaphases in the progeny from the artificially aged seeds were not higher than those of the control progeny. This indicates that the chromosomal aberrations induced by seed aging are not transmitted to the next generation.Published with the approval of the Director of the Colorado state Experiment Station as Scientific Series No. 2776     

The occurrence of "mixed" nuclear bag intrafusal fibers in the cat muscle spindle

A total of 147 muscle spindles was studied histochemically in serial transverse sections of 42 cat tenuissimus muscle specimens. Nuclear bag1, nuclear bag2 and nuclear chain intrafusal muscle fibers were distinguished by the differential staining resulting from the reactions for myosin adenosine 5'-triphosphatase and nicotinamide adenine dinucleotide tetrazolium reductase. The majority of intrafusal fibers were of the same histochemical type at both fiber poles. However, seven muscle spindles contained one nuclear bag fiber each that presented as a bag1 in one pole and as a bag2 in the other pole. These "mixed" nuclear bag fibers were found in spindles that also contained at least one bag1 and one bag2 fiber of equivalent histochemical presentation in both fiber poles. The "mixed" bag fibers displayed differences of apparent fiber diameter and relative polar length between the two fiber poles. The motor innervation pattern, as revealed by staining for cholinesterase, was also dissimilar between the two poles of "mixed" bag fibers. The study indicates that the spindle equatorial region may in some instances serve as a boundary between two morphologically and histochemically different poles of the same intrafusal fiber.     

DISTRIBUTION OF LABELED CHROMATIN : I. M1 and M2 Anaphases of Diploid and Tetraploid Cultured Mammalian Cells

The question of whether distribution of chromatids to daughter cells in mitosis is a random or nonrandom process was investigated by study of the distribution of labeled chromatin in anaphase pairs at M₁ and M₂ after a pulse of tritiated thymidine. Diploid and tetraploid rat and diploid human fibroblast-like cells in serial monlayer culture were synchronized by two different methods to "purify" M₁ and M₂ anaphases: metaphase shake, and FUdR block to DNA synthesis followed by exogenous thymidine. Exposed grains of NTB-2 emulsion were counted over M₁ and M₂ anaphase pairs. An analysis (by pair) of diploid M₂ anaphase grain counts showed two discrete populations of daughters with less and with more radioactivity. A similar analysis of diploid M₁ and tetrapolid M₂ anaphases showed a single grain-count distribution. These findings may support a nonrandom model of chromatid segregation for diploid mammalian cells but do not rule out random segregation until sound mathematical models are formulated for expected random grain distributions in M₂ anaphases of cells with differing numbers of chromosomes.     

Terbutol Affects Spindle Microtubule Organizing Centres

Light, immunofluorescence, and electron microscopy were utilizedto investigate the effects of the herbicide terbutol (2,6-di-tert-butyl-p-tolylmethylcarbamate) on onion root tips. So-called ‘star anaphases,’chromosomes drawn in at their centromeres at both poles, resultingin a starburst of chromosomes were the predominant form of mitoticabnormality noted in root tip squashes of the terbutol-treatedroots. Immunofluorescence microscopy using antitubulin serareveals a cluster of microtubules radiating from the centreof the chromosome mass at each of the poles. Nuclear envelopesapparently reform around the radially-arranged chromosome masses,resulting in extensively lobed ‘star telophase’nuclei. Branched and curved phragmoplast arrays are observed,due to interference by the lobes of the star telophase nucleus.These abnormal phragmoplasts result in incomplete and/or abnormally-orientedcell walls. Star anaphase figures are observed after 2 h ofherbicide treatment, indicating that this terbutolinduced chromosomalabnormality is a primary effect of the herbicide. Tradescantiastamen hairs were treated with terbutol and mitosis was monitoredin vivo by Nomarski differential interference microscopy; thesetreated stamen hairs produce star anaphase figures as a primaryeffect of the herbicide. This series of abnormalities has notbeen observed with any other herbicide, indicating that terbutolhas a unique mechanism of action, perhaps interacting with spindlemicrotubule organizing centres. Key words: Terbutol, Onion, root tips, star-anaphase figures     

Protein Localization in Escherichia coli Cells: Comparison of the Cytoplasmic Membrane Proteins ProP,LacY, ProW,AqpZ, MscS,and MscL

Fluorescence microscopy has revealed that the phospholipid cardiolipin (CL) and FlAsH-labeled transporters ProP and LacY are concentrated at the poles of Escherichia coli cells. The proportion of CL among E. coli phospholipids can be varied in vivo as it is decreased by cls mutations and it increases with the osmolality of the growth medium. In this report we compare the localization of CL, ProP, and LacY with that of other cytoplasmic membrane proteins. The proportion of cells in which FlAsH-labeled membrane proteins were concentrated at the cell poles was determined as a function of protein expression level and CL content. Each tagged protein was expressed from a pBAD24-derived plasmid; tagged ProP was also expressed from the chromosome. The osmosensory transporter ProP and the mechanosensitive channel MscS concentrated at the poles at frequencies correlated with the cellular CL content. The lactose transporter LacY was found at the poles at a high and CL-independent frequency. ProW (a component of the osmoregulatory transporter ProU), AqpZ (an aquaporin), and MscL (a mechanosensitive channel) were concentrated at the poles in a minority of cells, and this polar localization was CL independent. The frequency of polar localization was independent of induction (at arabinose concentrations up to 1 mM) for proteins encoded by pBAD24-derived plasmids. Complementation studies showed that ProW, AqpZ, MscS, and MscL remained functional after introduction of the FlAsH tag (CCPGCC). These data suggest that CL-dependent polar localization in E. coli cells is not a general characteristic of transporters, channels, or osmoregulatory proteins. Polar localization can be frequent and CL independent (as observed for LacY), frequent and CL dependent (as observed for ProP and MscS), or infrequent (as observed for AqpZ, ProW, and MscL).Modern developments in fluorescence microscopy have led to a new understanding of the organization of bacterial cells, particularly protein and lipid localization (21, 56). Analysis of the subcellular localization of diverse proteins and lipids has shown that they are not uniformly distributed. The phospholipid cardiolipin (CL) localizes at the poles and septal regions (36), and there is evidence for segregation of phosphatidylethanolamine (PE) from phosphatidylglycerol (PG) in the membranes of living Escherichia coli cells (69). Localization of many proteins that are integral or peripheral to the cytoplasmic membrane has been studied by fusing them to green fluorescent protein (GFP) (or its derivatives), and it is possible to classify the fusion proteins according to their subcellular localization. The first group, comprised of proteins that are concentrated at the cell poles, includes chemoreceptors (31, 62), the lactose permease LacY (43), and the metabolic sensor kinases DcuS and CitA (55). Members of the second group form helices that extend from pole to pole and include MreB (25), MinD (57), the Sec protein export system (58), and RNase E, which is the main component of the RNA degradosome in E. coli (67). Other proteins may appear to be similarly distributed due to their association with the Sec system (58). Members of the third group are uniformly distributed and include the mechanosensitive channel MscL (45) and the sensor kinase KdpD (32).The polar localization of proteins appears to be a critical feature of the complicated internal localization of bacteria. For example, it is important for temporally and spatially accurate placement of the septum during cell division (15). However, the mechanism of protein organization at bacterial cell poles is still unclear, and in many cases its functional role has not been determined. Do the poles merely serve as a receptacle for proteins, superstructures, or membrane domains with no functional effects, or is this location functionally important for membrane proteins and lipids?Recent evidence indicates that the subcellular localization of the transporter ProP in E. coli is related to membrane phospholipid composition, cardiolipin localization, and ProP function (51, 52). E. coli cells from cultures grown to exponential phase contain mostly the zwitterionic phospholipid PE (approximately 75 mol%) and the anionic phospholipids PG (approximately 20 mol%) and CL (approximately 5 mol%) (8). (Note that cardiolipin is diphosphatidylglycerol.) However, the phospholipid composition depends on the bacterial growth conditions. We found that the proportion of CL among E. coli lipids varies directly with growth medium osmolality (68), and increased CL synthesis was at least partially attributed to regulation of the cls locus encoding cardiolipin synthase (52). There is residual CL in cls bacteria, indicating that there is an alternative pathway for CL synthesis (51). The CL-specific fluorescent dye 10-N-nonyl-acridine orange (NAO) was used to show that CL clusters at the poles and septa in growing E. coli cells (36, 52). This result was corroborated by analyzing the phospholipid composition of E. coli minicells (DNA-free cells resulting from asymmetric cell division) (24, 51).ProP is an osmosensory transporter that senses increasing osmolality and responds by mediating the cytoplasmic accumulation of organic osmolytes (e.g., proline, glycine betaine, and ectoine). Biochemical regulation of the ProP protein ensures that ProP activity increases with increasing assay medium osmolality (49). We showed that ProP and CL colocalize at the poles and near the septa of dividing E. coli cells and that the polar concentration of ProP correlates with the polar concentration of CL (52). Moreover, we showed that the osmolality required to activate ProP increased in parallel to the CL content when E. coli was cultivated in media with increasing osmolality (51, 52, 68). The osmolality required to activate ProP was also a direct function of CL content in proteoliposomes reconstituted with purified ProP (51). We concluded that concentration at the cell poles controlled the osmoregulatory function of ProP by placing the transporter in a cardiolipin-rich environment.To determine whether CL-dependent membrane protein localization is a general phenomenon in E. coli, we compared the subcellular localization of ProP with that of its paralogue LacY, a well-characterized lactose transporter (16). LacY and ProP are both members of the major facilitator superfamily and H⁺ symporters. LacY transports the nutrient lactose, and LacY activity decreases while ProP activity increases with increasing osmolality (9). Nagamori et al. reported polar localization of a LacY-GFP fusion protein in E. coli (43). We confirmed this observation and demonstrated that, in contrast to the behavior of ProP, the polar concentration of LacY did not correlate with the polar concentration of CL (51).In this work we further explored the relationship between CL and protein localization in E. coli. We compared ProP with other proteins related to cellular osmoregulation. Bacteria use arrays of osmoregulatory mechanisms to survive and function when the osmotic pressure of their environment changes. In E. coli, the aquaporin AqpZ mediates transmembrane water flux, the transporters ProP, ProU, BetT, and BetU mediate organic osmolyte accumulation at high osmotic pressure, and the mechanosensitive (MS) channels MscL and MscS mediate solute efflux in response to osmotic downshock (71). Localization of these proteins might be expected since AqpZ might influence cell morphology changes by accelerating water flux at particular positions on the cell surface and the pressure sensitivities of MscL and MscS are known to depend on membrane curvature in vitro (18).For ProP and LacY, we labeled the inserted peptide tag CCPGCC with the biarsenical fluorescein reagent FlAsH-EDT₂ (fluorescein arsenical helix binder, bis-EDT adduct) (1, 2) to examine the subcellular localization of AqpZ, the integral membrane component ProW of the osmoregulatory ATP-binding cassette (ABC) transporter ProU, and the MS channel proteins MscS and MscL in cls⁺ and cls bacteria. Fluorescence microscopy was used to determine the proportion of cells with labeled protein concentrated at the poles as a function of bacterial CL content and protein expression level. For ProP, the frequency with which MscS was concentrated at cell poles was proportional to the level and polar concentration of CL. LacY concentrated at the cell poles at a high and CL-independent frequency. The frequencies with which AqpZ, MscL, and ProW concentrated at the cell poles and septa were low (up to 12%) and CL independent.     

Light microscopical studies of chromosomes in embryos of cod, Gadus morhua L.

The chromosomes in the cells of 1–2-day-old cod embryos were studied using light microscopic techniques. The observations revealed slightly non-synchronous cell divisions, with at least three different mitotic phases present in a 1-day-old embryo. Surprisingly high percentages of abnormal metaphases and anaphases were found in normal-looking embryos. In the 2-day-old embryos, free-lying nuclei were observed in the periblast zone. Chromosome studies of these nuclei revealed a cleavage pattern of the chromosomes which differed from that of the other cells.     

Vegetation, substrate and hydrology in floating marshes in the Mississippi river delta plain wetlands, USA

In the 1940s extensive floating marshes (locally called flotant) were reported and mapped in coastal wetlands of the Mississippi River Delta Plain. These floating marshes included large areas of Panicum hemitomon-dominated freshwater marshes, and Spartina patens/Scirpus olneyi brackish marshes. Today these marshes appear to be quite different in extent and type. We describe five floating habitats and one non-floating, quaking habitat based on differences in buoyancy dynamics (timing and degree of floating), substrate characteristics, and dominant vegetation. All floating marshes have low bulk density, organic substrates. Nearly all are fresh marshes. Panicum hemitomon floating marshes presently occur within the general regions that were reported in the 1940's by O'Neil, but are reduced in extent. Some of the former Panicum hemitomon marshes have been replaced by seasonally or variably floating marshes dominated, or co-dominated by Sagittaria lancifolia or Eleocharis baldwinii.     

The invertebrate fauna of the floating vegetation of Bung Borapet,a reservoir in Central Thailand

In Bung Borapet, a reservoir in Central Thailand, quantitative studies were made on stands of different floating hydrophytes with respect to their colonisation by aquatic invertebrates. Differences in animal colonisation between the stands are explained by

1. type and morphological characteristics of the vegetation layer;
2. the physico-chemical properties of the surrounding water.

Biomass values are compared with those found in floating hydrophyte stands in other tropical regions.     

Heterochromatinization,chromatin elimination and haploidization in the parahaploid mite Metaseiulus occidentalis (Nesbitt) (Acarina: Phytoseiidae)

Embryogenic mitoses, mitoses in females and spermatogenesis are described in the predatory mite Metaseiulus occidentalis (Nesbitt). At 22° C, egg development lasts approximately 4 days. Six chromosomes are seen in mitotic metaphases and anaphases of 0–24 h eggs. Toward the end of this period some embryo squashes have patches of cells containing nuclei which are partially heteropycnotic. These patches of cells apparently increase in size with the age of the embryo. In approximately 1/2 of all 24–48 h-old eggs they encompass all or most cells of the embryo. In these embryos metaphases involved 6 chromosomes, anaphases 3. Either prior to, or following metaphase, a pairing of chromosomes appeared to take place to form 3 units which resembled meiotic diplotene chromosomes where there is opening out between homologues. At metaphase, two sets of 3 chromosomes were slightly differentially stained. One, designated the H set, was darker and slightly more contracted than the other, the E set. At anaphase, 3H and 3E chromosomes segregated in a reductional division retaining the differential contraction until telophase. No cytokinesis appeared. The H set appeared to remain contracted while the E set decontracted to assume the appearance of an interphase nucleus. Both of these entities, side-by-side, created the partially heteropycnotic nucleus mentioned above. The H set then appeared to be excluded from the cell. Mitotic meta and anaphases involving 6 chromosomes were noted in female deutonymphs. Spermatogenesis appeared to encompass an equational division of 3 chromosomes, with the formation of a binucleate spermatid. Two tail structures appeared juxtaposed at the edge of each spermatid and thereafter a separation into two individual sperms occurred. —While mitosis was not studied in known males, we believe that the embryos exhibiting heterochromatinization and elimination of chromosomes in most or all cells were in fact demonstrating parahaploidization.This paper is dedicated to the memory of Professor S.W. Brown and is presented to Professor H. Bauer in honor of his 75th birthday     

Induction of chromosomal disturbances other than tetraploidy in barley root tips by colchicine treatment

Barley embryos were treated by 0.1% colchicine for 30 min. Samples of root tips were fixed after 4 h, 8 h and 12 h. In the first sample,c-metaphases, normal metaphases and anaphases were present jointly. Inc-metaphases, chromosomes sometimes tended to make two groups with 7 chromosomes in each. In anaphases, lagging chromosomes, tripolar and multipolar anaphasos were found. No chromosomal aberrations were detected in anaphases and metaphases. No chromosome disturbances were found in root tips sampled 8 h and 12 h after colchicine treatment.     

A simple,mechanistic model for directional instability during mitotic chromosome movements

During mitosis, chromosomes become attached to microtubules that emanate from the two spindle poles. Thereafter, a chromosome moves along these microtubule "tracks" as it executes a series of movements that bring it to the spindle equator. After the onset of anaphase, the sister chromatids separate and move to opposite spindle poles. These movements are often characterized by "directional instability" (a series of runs with approximately constant speed, punctuated by sudden reversals in the direction of movement). To understand mitosis, it is critical to describe the physical mechanisms that underlie the coordination of the forces that drive directional instability. We propose a simple mechanistic model that describes the origin of the forces that move chromosomes and the coordination of these forces to produce directional instability. The model demonstrates that forces, speeds, and direction of motion associated with prometaphase through anaphase chromosome movements can be predicted from the molecular kinetics of interactions between dynamic microtubules and arrays of microtubule binding sites that are linked to the chromosome by compliant elements.