Showing papers on "Metaphase published in 1980"

Chromosome banding in amphibia. IV. Differentiation of GC- and AT-rich chromosome regions in Anura.

Abstract: The chromosomes of 26 species of Anura from variously highly envolved groups were analysed with the fluorescent GC-specific antibiotics mithramycin and chromomycin A3 as well as with the AT-specific quinacrine. The mithramycin- and chromomycin A3-stainings generally resulted in a pattern of the constitutive heterochromatin opposite to the one obtained with quinacrine stain. The weaker a heterochromatic region fluoresces with quinacrine, the stronger is the intensity of the fluorescence achieved with mithramycin and chromomycin A3. Some of the telomeric and interstitial heterochromatic regions, however, exhibit no enhanced fluorescence with any of the fluorochromes. The nucleolar constrictions of the nucleolus organizer regions (NORs) displayed the brightest mithramycin- and chromomycin A3-fluorescence in the karyotypes and interphase nuclei of all species examined. The contrast of the brightly fluorescing GC-rich heterochromatin and of the NORs is considerably enhanced, when the non-fluorescent AT-specific oligopeptide distamycin A is employed as a counterstain. No banding patterns were observed with the fluorochromes in the euchromatic regions of the metaphase chromosomes; this attributed to the strong spiralization of the anuran chromosomes. A cytochemical classification of the various chromatin types in the anuran chromosomes is discussed on the basis of the differential labelings found on the constitutive heterochromatin by means of the fluorochromes.

Nonrandom Abnormalities in Chromosome 1 in Human Testicular Cancers

Abstract: Trypsin G banding was performed on metaphase chromosomes from 14 cell lines derived from primary tumors or metastases of 11 patients with testicular cancer Most of the cell lines, 11 of 14, have a modal number between 51 and 61 All lines have numerical and structural changes involving chromosome 1 with trisomy of the q arm being the common aberration Break points in chromosome 1 were nonrandom, being concentrated in the regions of p12, q12, p36, and p22, which resulted in morphologically identical marker chromosomes in different cases These changes probably are not artifacts of cell culture In one instance, three lines derived from the same patient, one from tissue removed at operation, and two from separate metastases removed at autopsy nearly 3 years later after unsuccessful radiotherapy and chemotherapy had identical chromosome compositions In another case, lines derived from a primary tumor and a metastasis from the same patient also had identical marker chromosomes The consistent involvement of chromosome 1 in aberrations may be associated with the highly malignant nature of testicular cancers

Surface functions during mitosis. II. Quantitation of pinocytosis and kinetic characterization of the mitotic cycle with a new fluorescence technique.

Abstract: The profound depression of fluid pinocytosis observed in mitotic cells (Berlin, R. D., et al. 1978. Cell. 15:327--341) is documented by quantitative microspectrofluorimetry of fluorescein-labeled dextran uptake in single cells. In J774.2 macrophages, fluid pinocytosis is reduced 30-fold during mitosis. The depression develops within 30 s of entry into prophase and recovers with equal rapidity upon emergence from telophase into G1. This characteristic pattern of fluid pinocytosis forms the basis of a new method for detailed kinetic analysis of the duration of mitosis and its phases. The analysis is applied to the J774.2 macrophage cell line but should be generally applicable to other lines. Effects of ouabain and colchicine on the length of mitosis and its phases are evaluated, revealing a selective prolongation of metaphase by ouabain and suggesting a role for microtubules in the transition from G2 into mitosis.

Parameters governing the transfer of the genes for thymidine kinase and dihydrofolate reductase into mouse cells using metaphase chromosomes or DNA

Abstract: The conditions necessary to achieve high frequency transfer of the thymidine kinase and dihydrofolate reductase genes from hamster cells into mouse cells were investigated. Of the parameters examined, the length of adsorption time, input gene dosage, and treatment with dimethylsulfoxide (DMSO) were found to significantly alter the transfer frequency using either metaphase chromosomes or purified DNA as the transfer vehicle. With the mouse cell line as a recipient, the optimal adsorption period for DNA or chromosomes from MtxRIII cells was found to vary from 8 to 16 h in those experiments where the recipient cells were subsequently treated with DMSO. Without DMSO, similar frequencies could be obtained by extending the period of adsorption. Increasing the dosage of DNA or chromosomes resulted in an almost linear increase in the number of transformants. The optimal conditions for transfer did not significantly differ for the two genes studied. On the average, the optimal conditions yielded 1.5 x 10(3) transformants per 10(7) recipient cells with chromosomes; with DNA an average of only 60 transformants were observed. In general, DNA transformants grown in the absence of methotrexate were unstable; whereas, under the same conditions about 20% of the transformants from the chromosome experiments were stable.

Evidence for the involvement of H1 histone phosphorylation in chromosome condensation

Abstract: Changes in the structural organisation of chromatin are necessary for the progression of the cell cycle. These changes are thought to be regulated mainly by the modification of chromosomal proteins by reactions such as phosphorylation1–8, acetylation9–12, methylation13,14 and poly(ADP-ribosyl)-ation15,16. Among these modifications, phosphorylation of histones, especially that of the H1 histone, is the most likely candidate for a factor which regulates chromosome condensation1–8. It has been proposed that the phosphorylated form of H1 histone may be involved in the initiation of chromosome condensation1–4 or in the maintenance of the condensed state of chromatin8. The latter possibility is unlikely because zinc chloride, which inhibits phosphatase in vivo and preserves the highly phosphorylated form of H1 histone at metaphase, does not prevent the dispersion of chromosomes at the end of mitosis17. As for the former possibility, Bradbury et al. reported2 that the activity of H1 histone phosphorylation is closely correlated with mitotic triggering in the cell cycle and suggest3,4 that H1 histone phosphokinase is involved in the initiation of mitosis. However, no causal relationship has been established. To analyse the mechanism of the progression of the cell cycle, we have isolated several temperature-sensitive (ts) growth mutants from FM3A, a cell line derived from C3H mouse mammary carcinoma18. We report here on one of these ts mutants, designated the ts85 strain, which shows an abnormal chromosome condensation as well as deficiency in H1 histone phosphorylation at the non-permissive temperature. Our results support the hypothesis that H1 histone phosphorylation controls the initiation step of mitosis through chromosome condensation.

Energy transfer and binding competition between dyes used to enhance staining differentiation in metaphase chromosomes

Abstract: The ability of electronic energy transfer and direct binding competition between pairs of dyes to enhance contrast in human or bovine metaphase chromosome staining patterns is illustrated, and the relative effectiveness of these two mechanism compared. The existence of energy transfer between quinacrine or 33258 Hoechst and 7-amino-actinomycin D in doubly stained chromosomes is demonstrated directly by microfluorometry. The ability of the dyes 7-amino-actinomycin D, methyl green, or netropsin, acting as counterstains, to displace quinacrine, 33258 Hoechst, or chromomycin A3 from chromosomes, is estimated by quantitative analysis of energy transfer data, by photobleaching of the counterstains, or by selective removal of counterstains by appropriate synthetic polynucleotides. Effects on the fluorescence of soluble 33258 Hoechst-DNA complexes due to energy transfer or binding displacement, by actinomycin D or netropsin, respectively, are further differentiated by nanosecond fluorescence decay measurements. Examples are presented of dye combinations for which (a) energy transfer is the primary mechanism operative, (b) binding competition exists, with consequences reinforcing those due to energy transfer, or (c) binding competition is the most important interaction. These analyses of mechanisms responsible for contrast enhancement in doubly stained chromosomes are used to derive information about the relationship between chromosome composition and banding patterns.

Cell division in two large pennate diatoms Hantzschia and Nitzschia III. A new proposal for kinetochore function during prometaphase.

Abstract: Prometaphase in two large species of diatoms is examined, using the following techniques: (a) time-lapse cinematography of chromosome movements in vivo; (b) electron microscopy of corresponding stages: (c) reconstruction of the microtubules (MTs) in the kinetochore fiber of chromosomes attached to the spindle. In vivo, the chromosomes independently commence oscillations back and forth to one pole. The kinetochore is usually at the leading edge of such chromosome movements; a variable time later both kinetochores undergo such oscillations but toward opposite poles and soon stretch poleward to establish stable bipolar attachment. Electron microscopy of early prometaphase shows that the kinetochores usually laterally associate with MTs that have one end attached to the spindle pole. At late prometaphase, most chromosomes are fully attached to the spindle, but the kinetochores on unattached chromosomes are bare of MTs. Reconstruction of the kinetochore fiber demonstrates that most of its MTs (96%) extend past the kinetochore and are thus apparently not nucleated there. At least one MT terminates at each kinetochore analyzed. Our interpretation is that the conventional view of kinetochore function cannot apply to diatoms. The kinetochore fiber in diatoms appears to be primarily composed of MTs from the poles, in contrast to the conventional view that many MTs of the kinetochore fiber are nucleated by the kinetochore. Similarly, chromosomes appear to initially orient their kinetochores to opposite poles by moving along MTs attached to the poles, instead of orientation effected by kinetochore MTs laterally associating with other MTs in the spindle. The function of the kinetochore in diatoms and other cell types is discussed.

Filamin concentration in cleavage furrow and midbody region: frequency of occurrence compared with that of alpha-actinin and myosin.

Abstract: Affinity-purified rabbit antibody to purified chicken gizzard filamin was used in indirect immunofluorescence to localize filamin in dividing chick embryo cells. The antibody was shown to bind only chick embryo cell filamin when whole cell extracts were analyzed by the sensitive sodium dodecyl sulfate-polyacrylamide gel electrophoresis overlay technique described by Adair et al. (1978, J. Cell Biol. 790:281-285). The results show that filamin is located in stress fibers and membrane ruffles during interphase. As cells prophase, the condensing chromosomes are surrounded by diffuse antifilamin staining. No stress fibers are apparent. During metaphase and anaphase, the staining is bright but diffuse. There is often peripheral membrane staining. Filamin is not concentrated in the spindle region but neither is it excluded from the spindle. During cytokinesis, filamin is found highly concentrated in the cleavage furrow in 16 out of 100 cells examined. This frequency of concentration in the furrow is comparable to that observed for alpha-actinin (14%). Myosin concentration in the furrow is more frequent; it is observed in 37% of the cells examined. Neither myosin, alpha-actinin, nor filamin is observed concentrated in the furrow 100% of the time. We conclude that the results are consistent with, but not sufficient to prove, the hypothesis that alpha-actinin and filamin are essential components of the mechanism of cytokinesis.

Mechanisms of chromosome orientation revealed by two meiotic mutants in Drosophila melanogaster.

Abstract: Two disjunction defective meiotic mutants, ord and mei-S332, each of which disrupts meiosis in both male and female Drosophila melanogaster, were analyzed cytologically and genetically in the male germ-line. It was observed that sister-chromatids are frequently associated abnormally during prophase I and metaphase I in ord. Sister chromatid associations in mei-S332 are generally normal during prophase I and metaphare I. By telophase I, sister chromatids have frequently precociously separated in both mutants. During the first division sister chromatids disjoin from one another frequently in ord and rarely in mei-S332. It is argued that the simplest interpretation of the observations is that each mutant is defective in sister chromatid cohesiveness and that the defect in ord manifests itself earlier than does the defect in mei-S332. In addition, based on these mutant effects, several conclusions regarding normal meiotic processes are drawn. (1) The phenotype of these mutants support the proposition that the second meiotic metaphase (mitotic-type) position of chromosomes and their equational orientation is a consequence of the equilibrium, at the metaphase plate, of pulling forces acting at the kinetochores and directed towards the poles. (2) Chromosomes which lag during the second meiotic division tend to be lost. (3) Sister chromatid cohesiveness, or some function necessary for sister chromatid cohesivenss, is required for the normal reductional orientation of sister kinetochores during the first meiotic division. (4) The kinetochores of a half-bivalent are double at the time of chromosome orientation during the first meiotic division. Finally, functions which are required throughout meiosis in both sexes must be considered in the pathways of meiotic control.

Initiation of the Cell Cycle and Establishment of Bilateral Symmetry in Xenopus Eggs

Abstract: Publisher Summary This chapter discusses the initiation of the cell cycle and establishment of bilateral symmetry in Xenopus egg. In the establishment of the cell cycle, in unfertilized Xenopus laevis eggs the cell cycle is arrested at second meiotic metaphase where no DNA synthesis is taking place. The period after fertilization in amphibian eggs is concerned with the completion of meiosis, fusion of the pronuclei, restarting the cell cycle, and the establishment of the dorsal–ventral asymmetry of the future embryo. Directly after fertilization there are a number of cortical and internal movements that are related to these events. Fertilized Xenopus eggs when rotated, sperm entrance point (SEP) down acquire the same yolk configuration as do unrotated eggs, that is, vitelline wall on the dorsal side, whereas Xenopus eggs rotated with the SEP up, acquire a mirror image configuration of vegetal yolk. Thus, the rearrangement of yolk correlates well with the reversal of the axis orientation by gravity, indicating a role for the yolk.

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

Abstract: 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.

Cytochemical studies of metaphase chromosomes by flow cytometry

Abstract: The cytochemical properties of metaphase chromosomes from Chinese hamster and human cells were studied by flow cytometry. This technique allows precise quantitation of the fluorescence properties of individual stained chromosome types. Chromosomes were stained with the following fluorescent DNA stains: Hoechst 33258, DAPI, chromomycin A3, ethidium bromide, and propidium iodide. The relative fluorescence of individual chromosome types varied depending on the stain used, demonstrating that individual chromosome types differ in chemical properties. Flow measurements were performed as a function of stain and chromosome concentration to characterize the number and distribution of stain binding sites. Flow analysis of double stained chromosomes show that bound stains interact by energy transfer with little or no binding competition. For most hamster chromosomes, there is a strong correlation between relative fluorescence and stain base preference suggesting that staining differences may be determined primarily by differences in average base composition. A few hamster chromosome types exhibit anomalous staining which suggests that some other property, such as repetitive DNA sequences, also may be an important determinant of chromosomal staining.

Isolation and partial characterization of a cage of filaments that surrounds the mammalian mitotic spindle.

Abstract: Mitotic cells have been detergent extracted under conditions that support microtubule assembly. When HeLa cells are lysed in the presence of brain tubulin, mitotic-arrested cells nucleate large asters and true metaphase cells yield spindles that remain enclosed within a roughly spherical cage of filamentous material. Detergent-extracted mitotic Chinese hamster ovary (CHO) cells show a similar, insoluble cage but the mitotic apparatus is only occasionally stabilized. In later stages of mitosis, HeLa cages are observed in elongated and furrowed configurations. In the terminal stages of cell division, two daughter filamentous networks are connected by the intercellular bridge. When observed in the electron microscope the cages include fibers 7-11 nm in diameter. The polypeptide composition of cages isolated from mitotic HeLa cells is complex, but the major polypeptides are a group with mol wt ranging from 43,000-60,000 daltons and a high molecular weight polypeptide. CHO cells contain a subset of these proteins which includes a major 58,000-dalton and a high molecular weight polypeptide. Two different antisera directed against the vimentin-containing intermediate filaments bind to polypeptides in the electrophoretic profiles of isolated HeLa and CHO cages and stain the cages, as visualized by indirect immunofluorescence. These results suggest that the HeLa and CHO cages include intermediate filaments of the vimentin type. The polypeptide composition of HeLa cages suggests that they also contain tonofilaments. The cages apparently form as the cells enter mitosis. We propose that these filamentous cages maintain the structural continuity of the cytoplasm while the cell is in mitosis.

Isolation and structural organization of human mitotic chromosomes

Abstract: New methods are presented for the bulk isolation of metaphase chromosomes from HeLa cells, and an electron microscopic study of thin sections of these chromosomes is presented. The techniques for chromosome isolation were developed to utilize solution conditions that are as mild as possible, so that further biochemical and structural studies can be directly related to the in situ state of chromosomes. — Electron micrographs of thin sections of isolated HeLa metaphase chromosomes reveal the general organization of the nucleosome-containing fibers. Chromosomes in isolation buffer show a dense, relatively uniform distribution of material across the chromatids. Swollen chromosomes reveal the primary mode of organization of the fibers to be a radial distribution from the central axes of the chromatids. A significant proportion of the fibers could also be oriented longitudinally.

Adriamycin induced genetic toxicity as demonstrated by the Allium test.

Abstract: The present investigation was carried out to study the cytological effects of adriamycin on root tip cells of Allium cepa. The roots of selected onion bulbs were placed in 3 different concentrations 0.1%, 1% and 10% of adriamycin solution for different durations, ranging from 3 hours to 24 hours. The treatments were so timed as to study the effects of the drug at specific stages in the mitotic cycle.The most important effect of the drug was the drastic lowering of the mitotic index. Interphasic cell death, nuclear lesions, nuclear dissolution, nuclear polymorphism and somatic reduction of chromosomes were also observed. Important abnormalities encountered at metaphase were C-metaphase, clumping, abnormal equatorial plate and delayed metakinesis. Chromatid bridges, sticky bridges, chromosome fragments, unequal distribution of chromosomes with paired chromatids, acute fragmentation leading to chromatin globules etc. were frequent in treated cells. Failure of cytokinesis resulting in multinucleate cells was also noticed.The present results suggest that adriamycin inhibits not only DNA synthesis but also protein synthesis, either directly or indirectly by its binding with DNA resulting in the prevention of its unwinding for transcription of spindle protein messengers. To arrest cell division, the best time of application appears to be the G1, just before the onset of DNA synthesis.

A search for protein cores in chromosomes: Is the scaffold an artifact?

Abstract: A protein chromosome scaffold structure has been proposed that acts as a structural framework for attachment of chromosomal DNA There are several troubling aspects of this concept: (1) such structures have not been seen in many previous thin-section and whole-mount electron microscopy studies of metaphase chromosomes, while they are readily seen in leptotene and zygotene chromosomes; (2) such a structure poses problems for sister chromatid exchanges; and (3) the published photographs show a marked variation in the amount of scaffold in different whole-mount preparations An alternative explanation is that the scaffold in whole-mount preparations represents incomplete dispersion of the high concentration of chromatin in the center of chromosomes, and when the histones are removed and the DNA dispersed, the remaining nonhistone proteins (NHPs) aggregate to form a chromosome-shaped structure Two studies were done to determine if the scaffold is real or an artifact: (1) Chinese hamster mitotic cells and isolated chromosomes were examined using two protein stains —EDTA-regressive staining and phosphotungstic acid (PTA) stain The EDTA-regressive stain showed ribonucleoprotein particles at the periphery of the chromosomes but nothing at the center of the chromosomes The PTA stain showed the kinetochore plates but no central structures; and (2) isolated chromosomes were partially dispersed to decrease the high concentration of chromatin in the center of the chromosome, then treated with 4 M ammonium acetate or 2 M NaCl to dehistonize them and disperse the DNA Under these circumstances, no chromosome scaffold was seen We conclude that the scaffold structure is an artifact resulting from incomplete dispersion of central chromatin and aggregation of NHPs in dehistonized chromosomes

Packing DNA into chromosomes.

Abstract: Electron microscopy of HeLa metaphase nucleoids (i.e. whole metaphase cells exposed to 2 M salt and non-ionic detergent) spread by the Kleinschmidt technique, reveals a variety of protein-depleted structures (spreads) derived from chromosomes. Spreads vary in size and shape. At one extreme are oval structures with one or more cores surrounded by a network of supercoiled fibres. These fibres are probably arranged as loops and we estimate that 600–1000 may emerge from a single, large core region. At the other extreme are chromosome-shaped spreads with an elongated core which takes the form of a multifibred axis. At intervals groups of lateral fibres appear to emerge from each axis to produce the network. Spreads intermediate between these extremes occur in which axial fibres can be resolved in only part of the elongated core. Similar structures are observed in chromosomes deproteinized and spread after isolation by a procedure which preserves high molecular weight DNA. The appearance of chromosomes isolated by the Wray-Stubblefield hexylene glycol procedure agrees in general with previous findings of others, except that in some more extended spreads axial fibres are visible. We believe our observations are consistent with the idea that the chromonema of each metaphase chromatid contains regions of multistranded DNA. We do not propose, however, that the chromatid is functionally multineme, but rather that axial fibre folding either within or between chromomere regions contributes to packing of DNA in the metaphase chromosome. These regions of constraint re also postulated as the locations of emergence of lateral loops. In spread preparations the axial fibres are seen clearly only when chromatids have been elongated beyond the contracted metaphase length. Elongation would be produced both by relaxation of chromosomal coils (gyres) and by extension of the chromonema upon deproteinization and spreading. Whereas in deproteinized nucleoids the long axis is liable to elongate, fragment or collapse, the chromomena of Wray-Stubblefield chromosomes is locked at the metaphase (gyred) length and axial fibres are generally not visible. We propose that the assembly of the complex DNA axis of the metaphase chromosome from its extended interphase counterpart plays a major part in increasing the DNA packing ratio in the mitotic cell.

Amino acid analysis and cell cycle dependent phosphorylation of an H1-like, butyrate-enhanced protein (BEP; H1(0); IP25) from Chinese hamster cells.

Abstract: A fraction enriched in the butyrate-enhanced protein (BEP) has been isolated from Chinese hamster (line CHO) cells by perchloric acid extraction and Bio-Rex 70 chromatography. Amino acid analyses indicate that the composition of BEP resembles that of CHO H1; however, BEP contains 11% less alanine than H1, and, in contrast to H1, BEP contains methionine. Treatment of BEP with cyanogen bromide results in the cleavage of a small fragment of approximately 20 amino acids so that the large fragment seen in sodium dodecyl sulfate--acrylamide gels has a molecular weight of approximately 20 000. Radiolabeling and electrophoresis indicate that BEP is phosphorylated in a cell cycle dependent fashion. In G1-arrested cells, little or no phosphate is incorporated into BEP. As cells progress through interphase, BEP becomes phosphorylated so that 12--35% of the BEP molecules are phosphorylated at one to two sites by late interphase. During mitosis, all BEP molecules become phosphorylated at approximately four sites per molecule (BEPM). Electrophoresis and the analysis of cell populations by electron microscopy indicate that the appearance of BEPM is temporally correlated with the mitotic phosphorylation of histone H1 (H1M) and with chromosomal condensation during prophase, metaphase, and anaphase. During exit from mitosis, BEPM undergoes dephosphorylation. The dephosphorylation of BEPM is temporally correlated with dephosphorylation of H1M and with the unraveling of fully condensed chromosomes near the anaphase--telophase transition. These data suggest that (1) BEP is a specialized histone of the H1 class and (2) BEP is the species equivalent of calf lung histone H1(0) [Panyim, S., & Chalkley, R. (1969) Biochem. Biophys. Res. Commun. 37, 1042], rat H1(0) [Medvedev, Zh. A., Medvedeva, M. N., & Huschtscha, L. I. (1977) Gerontology (Basel) 23, 334], and IP25, a protein enhanced in differentiated Friend erythroleukemia cells [Keppel, F., Allet, B., & Eisen, H. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 653]. The data also indicate that putative HMG1 and HMG2 proteins do not undergo the extensive cell cycle dependent phosphorylations measured for histone H1 and BEP.

Surface and shape changes during cell division.

Abstract: Rat kangaroo cells (PtK2) were studied with scanning and transmission electron microscopy in order to correlate shape changes during the cell cycle with the presence or absence of microvilli andd stress fibers. During interphase, bundles of actin are prominent in the cytoplasm, and microvilli are localized over and around the centrally positioned nucleus. As mitosis begins, the interphase bundles of actin and the microvilli disappear, but the mitotic cells maintain a flattened shape. At metaphase the cell is still so flat that both the chromosomes and spindle apparatus are visible through the intact cell membrane. Microvilli reappear in late anaphase above the chromosomes and poles. Before cleavage begins, microvilli increase in number until they cover the apical surface of the cell. At the same time, the cell increases in height so that the chromosomes and mitotic apparatus can no longer be detected through the cell membrane. During cleavage, microvilli continue to cover the cell in a uniform manner but become greatly diminished in number after cytokinesis is completed and the cells flatten and enter interphase. It is suggested that the microvilli organize a network of actin filaments which interact with cortical myosin to produce the cell rounding porior to cleavage.

Chromosome-mediated gene transfer results in two classes of unstable transformants

Abstract: The human thymidine kinase gene has been transferred from HeLa S3 cells to mouse LM(TK-) cells via isolated metaphase chromosomes. Efficient transfer of the thymidine kinase gene (1.8 X 10(-5) colonies per recipient cell) was obtained when the donor chromosomes were precipitated with calcium phosphate and the recipient cells were treated with 10% (vol/vol) dimethyl sulfoxide. Thirty-five independent cell lines were analyzed in detail. Cytologically detectable donor chromosome fragments were observed in 14% of the cell lines. Many of the transformed cell lines were also found to express the human genes for galactokinase (23% of the transformed cell lines) and procollagen type I (69% of the transformed cell lines), which are syntenic to thymidine kinase on human chromosome 17. On the basis of stability analyses, three classes of transformed cell lines were defined and characterized. One class of transformants was stable, showing no loss of the transferred phenotype in the absence of selection. A second group of transformants was unstable, losing the thymidine kinase phenotype at a rate of 1.5-2.5% per day. This group of transformants was found to possess large donor chromosome fragments (macrotransgenomes) and relatively low levels of donor gene activity. The third group of transformants lost the thymidine kinase phenotype rapidly, at a rate of 6-10% per day. These cell lines contained small, cytologically undetectable transgenomes (microtransgenomes) and overexpressed the transferred thymidine kinase gene.

Evidence for microtubule subunit addition to the distal end of mitotic structures in vitro.

Abstract: HeLa cells blocked in metaphase with 0.04 micrograms/ml of the microtubule poison nocodazole were shown to contain large numbers of microtubules with typical mitotic organization but no cenriole. Lysis of nocodazole-poisoned cells in a microtubule reassembly buffer containing 0.5 M PIPES, 2.5% dimethyl sulfoxide, 1 mM EDTA, 1 mM MgCl2, 1 mM GTP, 1% Triton X-165, 0.5% sodium deoxycholate, 0.2% SDS, pH 6.9, preserved metaphase aster structures 5 micrograms in diameter surrounded only by a thin, fibrous cell remnant. Inclusion of 2 mg/ml porcine brain microtubule protein in the lysis buffer produced asters up to 20 micrometers in diameter with a birefringent retardation of 5-6 nm. In these large asters the central microtubules had normal morphology, but peripheral microtubules were clearly abnormal. Our interpretation is that in high PIPES lysis buffer, exogenous brain tubulin adds to the distal ends of preexisting aster microtubules to form abnormal microtubules. This observation supports the assumptions made by Borisy and by Summers and Kirschner in their interpretation of growth experiments to determine the microtubule polarity in mitotic structures.

Interactions between pairs of DNA‐binding dyes: Results and implications for chromosome analysis

Abstract: A number of DNA-binding dyes, with spectral properties making them suitable as components of energy donor-acceptor pairs, are described. If such pairs are used to stain metaphase chromosomes, and if the energy acceptor (e.g., actinomycin D or methyl green) has a binding specificity opposite to the binding or fluorescence specificity of the donor (e.g., 33258 Hoechst, quinacrine or chromomycin A3), contrast in donor fluorescence can be enhanced, leading to patterns selectively highlighting standard or reverse chromosome bands or particular polymorphic regions. Such results presumably reflect chromosomal regions enriched in 10-20 base pair clusters to which the donor binds and fluoresces but to which the acceptor cannot bind. For other pairs, involving counterstains such as netropsin or echinomycin, which are not suitable as energy acceptors, specific changes observed in polymorphic region fluorescence are most likely due to binding competition between dyes. Dye pairs producing contrast by either method can be used to differentiate between homologous chromosomes or to facilitate detection of specific chromosomal rearrangements. Preliminary data indicate that contrast enhancement generated in fixed metaphase chromosomes spread on microscopic slides can also be observed in suspensions of unfixed metaphase chromosomes, reinforcing the expectation that the methodology described will be of use in flow cytometry.

Behavior of kinetochores during mitosis in the fungus Saprolegnia ferax.

Abstract: In rapidly growing hyphae of Saprolegnia ferax, all nuclei contain arrays of kinetochore microtubules, which suggests that the nuclei are all in various phases of mitosis, with no apparent interphase. In prophase nuclei, kinetochore microtubules form a single, hemispherical array adjacent to the centrioles. This array separates into two similar arrays after centriole replication. The two arrays form by separation of the initial group of microtubules, with no kinetochore replication. During metaphase, between 6.5 and 85% of the kinetochores occur as amphitelic pairs, with a slight tendency for pairing to increase as the spindle elongates. 100% pairing has never been observed. The interkinetochore distance in these pairs is consistently similar to or approximately 0.17 microns. Throughout metaphase and early anaphase, there is extensive and increasing diversity in kinetochore microtubule length, so that a true metaphase plate has not been found. During metaphase, anaphase, and telophase, kinetochore numbers vary considerably, with a mean of similar to or approximately 30 per half spindle. A number of artefactual causes for this variability were examined and discarded. Thus, these results are accepted as real, suggesting either variable ploidy levels in the coenocytic hyphae or kinetochore replication during mitosis.

Relationship between secondary constrictions and nucleolus organizing regions in Allium sativum chromosomes.

Abstract: Allium sativum L. (2 n=16) had three types of clones with regard to the number of chromosomes carrying well-defined secondary constrictions: the first type had two secondary constricted chromosomes (type I), the second had three (type II) and the third had four (type III). Silver staining was applied to these three types of cells to determine the number of nucleolus organizing regions (NORs) per cell and to study the relationship between the morphological appearance of the secondary constrictions and the ability of the chromosomes to form nucleoli. Ag-positive regions appeared on two chromosomes in type I, on three in type II and on four in type III. The comparison of Giemsa and Feulgen stained chromosomes with the silver stained ones clearly indicated that the positive reaction with silver occurred exclusively on the secondary constricted regions that responded negatively to both Giemsa and Feulgen staining, indicating that the size of the achromatic secondary constrictions directly reflects the volume of the Ag-positive materials. However, all three types of clones had a maximum of four nucleoli at interphase. Of the four nucleoli, either two or one was extremely small (less than 1 μm in diameter) in types I and II respectively. The size variations of the other nucleoli seemed to be positively correlated with those of the Ag-positive regions. This and the observation that the maximum number of nucleoli per cell did not coincide with the number of Ag-positive regions on the metaphase chromosome complement suggest strongly that the NORs responsible for the minute nucleoli cannot be detected on the metaphase chromosomes. The present observations indicate that not all NORs are indicated by the morphological appearance of secondary constrictions.