Synchronization of cell division in root tips of seven major cereal species for high yields of metaphase chromosomes for flow-cytometric analysis and sorting

Plant tissues that yield large numbers of mitotic cells are useful for cytogenetic analyses and prerequisite to flow-cytometric analysis and sorting of plant chromosomes. Synchronization of cell division in samples from which chromosomes are to be isolated is necessary to ensure high yields of chromosomes. A method developed for synchronizing cell division in root tips ofVicia faba (Dolezel et al., 1992; Lucretti et al., 1993) has been modified, and parameters are presented for the effective synchronization of cell division in root tips ofAvena sativa (oat),Hordeum vulgare (barley),Oryza sativa (rice),Secale cereale (rye),Sorghum bicolor (sorghum),Triticum aestivum (wheat), andZea mays (maize). Optimum parameters for metaphase arrest and collection of chromosomes from synchronized samples are also presented. Using these parameters, the yield and quality of chromosome preparations are appropriate for flow-cytometric characterization and sorting.     

High-order structure of metaphase chromosomes: evidence for a multiple coiling model

When chromosome preparations made by the conventional air-drying method were processed with the OsO₄/TCH technique and examined by scanning electron microscopy (SEM), spiral structures in chromatids, which have been frequently observed to be present by light microscopy, were found to be composed of 30 nm fibres. In some portions these fibres appeared to be arranged in coils to form thicker fibres. When chromosome preparations were processed for SEM without air drying, chromosomes appeared to consist of fairly homogeneous thick fibrous structures measuring about 200 nm in diameter. In relatively condensed chromosomes, these 200 nm fibres appeared to be arranged perpendicular to the long axis of the chromatid. These findings suggest that chromatid spiral structures represent a regularly loosened state of the compactly spiralized 200 nm fibres which in turn consist of spiralized 30 nm fibres.     

Direct binding of Lgl2 to LGN during mitosis and its requirement for normal cell division

The Drosophila tumor suppressor protein lethal (2) giant larvae (l(2)gl) is involved in asymmetric cell division during development and epithelial cell polarity through interaction with the aPKC.Par-6 complex. We showed here that Lgl2, a mammalian homolog of l(2)gl, directly bound to LGN, a mammalian homolog of Partner of inscuteable in HEK293 cells. The C-terminal tail of Lgl2 bound to LGN with a K(d) value of about 56 nm. Endogenous Lgl2 formed a complex with aPKC, Par-6, and LGN. This complex formation was enhanced in metaphase of the synchronized cells by treatment with thymidine and nocodazole. Immunofluorescence staining of the complex was the strongest at the cell periphery of the metaphase cells. Overexpression of the C-terminal tail of Lgl2 induced mis-localization of the nuclear mitotic apparatus protein NuMA and disorganization of the mitotic spindle during mitosis, eventually causing formation of multiple micronuclei. Knockdown of endogenous Lgl (Lgl1 and Lgl2) also induced disorganization of the mitotic spindle, thereby causing formation of multiple micronuclei. The binding between Lgl2 and LGN played a role in the mitotic spindle organization through regulating formation of the LGN.NuMA complex. These results indicate that Lgl2 forms a Lgl2.Par-6.aPKC.LGN complex, which responds to mitotic signaling to establish normal cell division.     

Identification of isolated metaphase chromosomes. II. A comparison with the recognizability of chromosomes in metaphase plates

The metaphase chromosomes (MC) isolated from the Chinese hamster cells were identified with the aid of differential staining (G-bands). It was shown that differences in the relative recognizability of MC in metaphase plates and after their isolation are determined by changes in composition of isolated MC, rather than by those in staining capacity of MC after their isolation. The frequencies of identified MC are constant and independent upon the type of MC preparations and relation between identified and unidentified MC in certain preparations. At allows to apply the described method for the analysis of chromosome fractionation, using changes in frequencies of identified MC as a criterion of efficiency of the fractionation method. Possible ways of increasing the recognizability level of isolated MC are discussed.     

Effects of ethidium bromide on mitosis and chromosomes: a possible material basis for chromosome stickiness

When two types of mammalian cells were treated with ethidium bromide for several hours, the mitotic figures showed no chromatid breaks or exchanges but a high incidence of sticky chromosomes. Electron microscopic examinations revealed that many chromosomes are connected by submicroscopic chromatin strands of various widths. Chromosome stickiness, therefore, is interpreted as entanglement of chromatin fibers between unrelated chromosomes, probably caused by abnormal condensation behaviors prior to mitosis. Presumably, chromatin breaks would occur when sticky chromosomes separate during anaphase. Such microscopically undetectable breaks expressed as various kinds of chromosomal aberrations in the next mitosis when the damaged cells were permitted to recover in the absence of ethidium bromide.     

Specific attachment of nuclear-mitotic apparatus protein to metaphase chromosomes and mitotic spindle poles: possible function in nuclear reassembly

NuMA protein is the largest, abundant, primate-specific chromosomal protein. The protein was purified from HeLa cells and monospecific monoclonal antibodies were prepared that react exclusively with NuMA protein in immunoblot analysis. These antibodies were used to define the intracellular location and properties of NuMA protein. Using indirect immunofluorescence, NuMA protein was detected only in the nucleus of interphase cells and on the chromosomes in mitotic cells. One class of monoclonal antibody called the 2E4-type antibody, caused NuMA protein (or a complex of proteins including NuMA) to be released from its binding site on metaphase or anaphase chromosomes. The separation of NuMA protein from chromosomes was observed either with the immunofluorescence assay or in electrophoretic analyses of proteins released from isolated metaphase chromosomes after reaction with 2E4 antibody. The immunofluorescence studies also showed that after release of the NuMA protein from chromosomes of metaphase or anaphase cells, the protein bound specifically to the polar region of the mitotic spindle. It was shown that exogenously added NuMA antigen/antibody complex bound only to the mitotic spindle poles of permeabilized primate cells and not to the spindle poles of other mammalian cells, thus demonstrating the specificity of the spindle-pole interaction. The antibody mediated transfer of NuMA from chromosomes to poles was blocked when the chromosomes were treated with cross-linking fixatives. Results suggest that the NuMA protein has specific attachment sites on both metaphase chromosomes and mitotic spindle poles (the site where post-mitotic nuclear assembly occurs). A model is proposed suggesting that a protein having such dual binding sites could function during nuclear reassembly to link mitotic chromosomes into the reforming nucleus.     

Patterns in the occurrence and the submicroscopic organization of elongated metaphase chromosomes isolated from the cell

Chinese hamster metaphase chromosomes were investigated under different conditions of isolation. Light microscopic study demonstrated different forms of stretched chromosomes, from those in which merely a small region is stretched to rope-like structures 20-25 microns long with diameter of about 0.4 micron. The ratio between the number of stretched and of compact chromosomes is dependent on the concentration of bivalent cations, on the pH and temperature of the isolation buffer. A study of the submicroscopic organization of stretched chromosomes revealed lengthwise fibrils that disappeared after the treatment with 0.6 NaCl and staphylococcal nuclease. Distinct aggregates were seen, whose array is maintaining the stretched chromosome structure. It is suggested that stretched chromosomes appear due to the existing in vivo lability of bonds between the main chromosome components involved in organization of chromatin fiber packing. It is proposed that the structure obtains rigidity in the course of isolation with bivalent cations.     

Linking cell division to cell growth in a spatiotemporal model of the cell cycle

Cell division must be tightly coupled to cell growth in order to maintain cell size, yet the mechanisms linking these two processes are unclear. It is known that almost all proteins involved in cell division shuttle between cytoplasm and nucleus during the cell cycle; however, the implications of this process for cell cycle dynamics and its coupling to cell growth remains to be elucidated. We developed mathematical models of the cell cycle which incorporate protein translocation between cytoplasm and nucleus. We show that protein translocation between cytoplasm and nucleus not only modulates temporal cell cycle dynamics, but also provides a natural mechanism coupling cell division to cell growth. This coupling is mediated by the effect of cytoplasmic-to-nuclear size ratio on the activation threshold of critical cell cycle proteins, leading to the size-sensing checkpoint (sizer) and the size-independent clock (timer) observed in many cell cycle experiments.     

Q- and C-bands in the metaphase chromosomes of Drosophila nasutoides

The large heterochromatic chromosome of Drosophila nasutoides reveals distinctive C- and Q-bands. The regions which are negative in C-banding appear positive in Q-banding. The isochromosomic nature of this chromosome and the locality of the satellite DNAs in this chromosome are discussed with respect to these banding patterns.     

Poleward kinetochore fiber movement occurs during both metaphase and anaphase-A in newt lung cell mitosis

Microtubules in the mitotic spindles of newt lung cells were marked using local photoactivation of fluorescence. The movement of marked segments on kinetochore fibers was tracked by digital fluorescence microscopy in metaphase and anaphase and compared to the rate of chromosome movement. In metaphase, kinetochore oscillations toward and away from the poles were coupled to kinetochore fiber shortening and growth. Marked zones on the kinetochore microtubules, meanwhile, moved slowly polewards at a rate of approximately 0.5 micron/min, which identifies a slow polewards movement, or "flux," of kinetochore microtubules accompanied by depolymerization at the pole, as previously found in PtK2 cells (Mitchison, 1989b). Marks were never seen moving away from the pole, indicating that growth of the kinetochore microtubules occurs only at their kinetochore ends. In anaphase, marked zones on kinetochore microtubules also moved polewards, though at a rate slower than overall kinetochore-to-pole movement. Early in anaphase-A, microtubule depolymerization at kinetochores accounted on average for 75% of the rate of chromosome-to-pole movement, and depolymerization at the pole accounted for 25%. When chromosome-to-pole movement slowed in late anaphase, the contribution of depolymerization at the kinetochores lessened, and flux became the dominant component in some cells. Over the whole course of anaphase-A, depolymerization at kinetochores accounted on average for 63% of kinetochore fiber shortening, and flux for 37%. In some anaphase cells up to 45% of shortening resulted from the action of flux. We conclude that kinetochore microtubules change length predominantly through polymerization and depolymerization at the kinetochores during both metaphase and anaphase as the kinetochores move away from and towards the poles. Depolymerization, though not polymerization, also occurs at the pole during metaphase and anaphase, so that flux contributes to polewards chromosome movements throughout mitosis. Poleward force production for chromosome movements is thus likely to be generated by at least two distinct molecular mechanisms.     

Congression of achiasmate chromosomes to the metaphase plate in Drosophila melanogaster oocytes

Chiasmata established by recombination are normally sufficient to ensure accurate chromosome segregation during meiosis by physically interlocking homologs until anaphase I. Drosophila melanogaster female meiosis is unusual in that it is both exceptionally tolerant of nonexchange chromosomes and competent in ensuring their proper segregation. As first noted by Puro and Nokkala [Puro, J., Nokkala, S., 1977. Meiotic segregation of chromosomes in Drosophila melanogaster oocytes. A cytological approach. Chromosoma 63, 273-286], nonexchange chromosomes move precociously towards the poles following formation of a bipolar spindle. Indeed, metaphase arrest has been previously defined as the stage at which nonexchange homologs are symmetrically positioned between the main chromosome mass and the poles of the spindle. Here we use studies of both fixed images and living oocytes to show that the stage in which achiasmate chromosomes are separated from the main mass does not in fact define metaphase arrest, but rather is a component of an extended prometaphase. At the end of prometaphase, the nonexchange chromosomes retract into the main chromosome mass, which is tightly repackaged with properly co-oriented centromeres. This repackaged state is the true metaphase arrest configuration in Drosophila female meiosis.     

Combination of silver and fluorescent staining for metaphase chromosomes.

A convenient and reliable method for simulatneous visualization of silver staining (Ag-NOR) of the nucleolus organizers and fluorescent bandings in metaphase chromosomes is described. Studies employing this combined procedure on human chromosomes revealed that the Ag-NOR patterns may be characteristic for each chromosome of each individual.     

Ultrastructure of the centrometric regions of mouse chromosomes in metaphase chromosomes and interphase nuclei]

The chromatin ultrastructure was studied in the centromeric region of mitotic chromosomes and in interphase nuclei of mouse cells after differential staining on C-band. A new method is suggested to study centromeric region of chromosomes treated by the Giemsa banding technique. Fibers of chromosomes appeared to be packed denser in the centromeric regions of mitotic chromosomes than in arms. The disposition of chromatin fibers in the centromeric chromocentres of interphase nuclei is the same as in the centromeric regions of mitotic chromosomes.     

A new method for the preparation of metaphase chromosomes for flow analysis

A new method for the preparation of metaphase chromosomes for flow analysis has been evaluated. It has been shown that this method, which involves detergent lysis of metaphase cells and polyamines to stabilize the DNA, yields lower coefficients of variation and background levels in the DNA histograms than is currently obtained by hexylene glycol based methods. A conventional flow cytometer (FACS-II) has been used to resolve the human karyotype into about 14 peaks after ethidium bromide staining and excitation with a relatively low level of illumination (0.4 W at 488 nm). Flow karyotypes have also been obtained from suspension cell lines, in particular from the mouse cell line, Friend 707/B10. The only disadvantage of this method is that the chromosomes are highly condensed and therefore banding studies on sorted chromosomes may not be possible.     

A MAP kinase is activated late in plant mitosis and becomes localized to the plane of cell division.

In eukaryotes, mitogen-activated protein kinases (MAPKs) are part of signaling modules that transmit diverse stimuli, such as mitogens, developmental cues, or various stresses. Here, we report a novel alfalfa MAPK, Medicago MAP kinase 3 (MMK3). Using an MMK3-specific antibody, we detected the MMK3 protein and its associated activity only in dividing cells. The MMK3 protein could be found during all stages of the cell cycle, but its protein kinase activity was transient in mitosis and correlated with the timing of phragmoplast formation. Depolymerization of microtubules by short treatments with the drug amiprophosmethyl during anaphase and telophase abolished MMK3 activity, indicating that intact microtubules are required for MMK3 activation. During anaphase, MMK3 was found to be concentrated in between the segregating chromosomes; later, it localized at the midplane of cell division in the phragmoplast. As the phragmoplast microtubules were redistributed from the center to the periphery during telophase, MMK3 still localized to the whole plane of division; thus, phragmoplast microtubules are not required to keep MMK3 at this location. Together, these data strongly support a role for MMK3 in the regulation of plant cytokinesis.