Differential staining of tannin in sections of epoxy-embedded plant cells.

A staining procedure is described for the light microscopic localization of ergastic tannins in epoxy sections of plant cells embedded for study by transmission electron microscopy. Callus and cell suspensions of Pseudotsuga menziesii and Pinus taeda fixed in glutaraldehyde:acrolein and then OsO4, followed by epoxy embedding, were sectioned 0.5 mum thick, stained on a glass slide with ethanolic Sudan black B at 60 C as described by Bronner, and then mounted in Karo syrup. Tannin deposits stained brownish-orange and were easily distinguished from lipid bodies of similar size, which stained dark blue to black, and from starch grains, which were unstained. The significance of this differential polychromasia was confirmed by transmission electron microscopy. This staining procedure should prove valuable in the cytoplasmic evaluation of the plant cell ergastics (especially tannins) via light microscopy whether or not electroc microscopic examination is intended.     

Differential staining of plant chromosomes with Giemsa

Simple Giemsa staining techniques for revealing banding patterns in somatic chromosomes of plants are described. The value of the methods in the recognition of heterochromatin was demonstrated using five monocotyledonous and two dicotyledonous species. In Trillium grandiflorum the stronger Giemsa stained chromosome segments were shown to be identical with the heterochromatic regions (H-segments) revealed by cold treatment. Preferential staining of H-segments was also observed in chromosomes from three species of Fritillaria and in Scilla sibirica. Under suitable conditions the chromosomes of Vicia faba displayed a characteristic banding pattern and the bands were identified as heterochromatin. The Giemsa techniques proved to be more sensitive than Quinacrine fluorescence in revealing a longitudinal differentiation of the chromosomes of Crepis capillaris, where plants with and without B-chromosomes were examined. Again all chromosome types had their characteristic bands but there was no difference in Giemsa staining properties between the B-chromosomes and those of the standard complement.     

History of modern chromosomal analysis. Differential staining of plant chromosomes

Differential staining methods found extensive use in karyotype studies of many plant and animal species and provide for reliable identification of all chromosomes of the organism. Below we describe the most widespread methods and history of their advent. In addition, we discuss specific structure of the chromosomes and possible mechanisms responsible for differential segmentation.     

Differential nuclear fluorescence during the cell cycle.

With a modified quinacrine dihydrochloride staining method interphase nuclei show differences in their fluorescent characteristics. In human embryonic fibroblasts and synchronized HeLa cells (S₃), it could be demonstrated that these patterns reflect their position within the cell cycle. This study provides further evidence for conformational changes of chromatin during interphase and offers a cytological method for distinguishing cell cycle stages.     

Limitations of safranin 'O' staining in proteoglycan-depleted cartilage demonstrated with monoclonal antibodies

The intensity of safranin 'O' staining is directly proportional to the proteoglycan content in normal cartilage. Safranin 'O' has thus been used to demonstrate any changes that occur in articular disease. In this study, staining patterns obtained using monoclonal antibodies against the major components of cartilage proteoglycan chondroitin sulphate (anti CS) and keratan sulphate (anti KS), have been compared with those obtained with safranin 'O' staining, in both normal and arthritic tissues. In cartilage where safranin 'O' staining was not detectable, the monoclonal antibodies revealed the presence of both keratan and chondroitin sulphate. Thus, safranin 'O' is not a sensitive indicator of proteoglycan content in diseases where glycosaminoglaycan loss from cartilage has been severe.     

Differential accumulation of virus-specific RNA during the cell cycle of adenovirus-transformed rat embyro cells.

In adenovirus type 2-transformed rat embryo cells there is a threefold greater incorporation of [3-H]uridine into virus-specific RNA early in S phase than in late S or G2. This heightened accumulation of labeled RNA is true for both nuclear and cytoplasmic virus-specific labeling. Inhibition of DNA synthesis decreases the virus-specific RNA labeling, whereas reversal of inhibition again allows the elevated level of virus-specific RNA labeling.     

Studies on the control of the cell cycle in cultured plant cells

Summary Patterns of cell cycle arrest or temporal modification have been investigated using suspension cultures ofAcer pseudoplatanus under nutrient limiting and nutrient starvation conditions. The results of nitrogen, phosphorous and carbohydrate starvation have been compared and contrasted with reference to the Principal Control Point hypothesis ofVan't Hof andKovacs (1972). Whilst cells suffering phosphorus or carbohydrate starvation arrest in the G 1 and G 2 phases in the approximate ratio of 4 to 1, nitrogen starved cells accumulate virtually exclusively in G 1.     

A standardized method for the three-way differential staining of plant chromosomes and the scoring of SCEs per cell cycle

We have made use of 2 alternative methodologies to obtain 3-way differential staining (TWD) in third-mitosis (M₃) chromosomes of Allium cepa, which involve different uptakes of bromodeoxyuridine (BrdU) through 3 cell divisions, in order to evaluate the sister-chromatid exchanges (SCE) frequency on a per-cell-cycle basis.The main innovation introduced by us to the original protocols previously reported has been the use of 5-fluorodeoxyuridine (FdU) to inhibit endogenous thymidine (dT) synthesis. By using different [BrdU]: [dT] ratios in the presence of FdU the relative incorporation of BrdU into replicating DNA can be controlled.The use of 2 different approaches to obtain 3-way differentiation of sister chromatids allowed us to evaluate the role of BrdU in the induction of SCEs in our system. Both procedures rendered nearly 100% of M₃ chromosomes showing TWD. An additional advantage of our methodologies is their high degree of reproducibility.     

The plant cell cycle

The first aim of this paper is to review recent progress in identifying genes in plants homologous to cell division cycle (cdc) genes of fission yeast. In the latter, cdc genes are well-characterised. Arguably, most is known about cdc2 which encodes a 34 kDa protein kinase (p34^cdc2) that functions at the G2-M and G1-S transition points of the cell cycle. At G2-M, the p34^cdc2 protein kinase is regulated by a number of gene products that function in independent regulatory pathways. The cdc2 kinase is switched on by a phosphatase encoded by cdc25, and switched off by a protein kinase encoded by weel. p34 Must also bind with a cyclin protein to form maturation promoting factor before exhibiting protein kinase activity. In plants, homologues to p34^cdc2 have been identified in pea, wheat, Arabidopsis, alfalfa, maize and Chlamydomonas. They all exhibit the PSTAIRE motif, an absolutely conserved amino acid sequence in all functional homologues sequenced so far. As in animals, some plant species contain more than one cdc2 protein kinase gene. but in contrast to animals where one functions at G2-M and the other (CDK2 in humans and Egl in Xenopus) at G1-S, it is still unclear whether there are functional differences between the plant p34^cdc2 protein kinases. Again, whereas in animals cyclins are well characterised on the basis of sequence analysis, into class A, class B (G2-M) and CLN (G1 cyclins), cyclins isolated from several plant species cannot be so clearly characterised. The differences between plant and animal homologues to p34^cdc2 and cyclins raises the possibility that some of the regulatory controls of the plant genes may be different from those of their animal counterparts. The second aim of the paper is to review how planes of cell division and cell size are regulated at the molecular level. We focus on reports showing that p34^cdc2 binds to the preprophase band (ppb) in late G2 of the cell cycle. The binding of p34^cdc2 to ppbs may be important in regulating changes in directional growth but, more importantly, there is a requirement to understand what controls the positioning of ppbs. Thus, we highlight work resolving proteins such as the microtubule associated proteins (MAPs) and those mitogen activated protein kinases (MAP kinases), which act on, or bind to, mitotic microtubules. Plant homologues to MAP kinases have been identified in alfalfa. Finally, some consideration is given to cell size at division and how alterations in cell size can alter plant development. Transgenic tobacco plants expressing the fission yeast gene, cdc25, exhibited various perturbations of development and a reduced cell size at division. Hence, cdc25 affected the cell cycle (and as a consequence, cell size at division) and cdc25 expression was correlated with various alterations to development including precocious flowering and altered floral morphogenesis. Our view is that the cell cycle is a growth cycle in which a cell achieves an optimal size for division and that this size control has an important bearing on differentiation and development. Understanding how cell size is controlled, and how plant cdc genes are regulated, will be essential keys to ‘the cell cycle locks’, which when ‘opened’, will provide further clues about how the cell cycle is linked to plant development.     

The plant cell cycle

Molecular controls of the plant cell cycle must integrate environmental signals within developmental contexts. Recent advances highlight the fundamental conservation of underlying cell cycle mechanisms between animals and plants, overlaid by a rich molecular and regulatory diversity that is specific to plant systems. Here we review plant cell cycle regulators and their control.     

Epothilone D affects cell cycle and microtubular pattern in plant cells

Epothilones, macrocyclic lactones from culture filtrates of the myxobacterium Sorangium cellulosum, are known as taxol-like microtubular drugs in human medicine. To date, nothing is known about the effect of epothilones on microtubules (MTs) in plant cells and/or on the plant cell cycle. As shown in this report, the treatment of tomato cell suspension cultures with epothilone D produced a continuous increase in the mitotic index. Dose-response curves revealed that epothilone D alters the mitotic index at concentrations as low as 1.5 microM. Mitotic arrest was already visible after only 2 h of treatment, and 55% of the cells were arrested after 24 h. As shown by immunocytological methods, abnormal spindles are formed during metaphase, which leads to a random distribution of chromosomes in the whole cell and prevents the formation of a metaphase plate. The process of chromosome decondensation does not seem to be affected, because micronuclei form at the same place with the distributed chromosomes. This suggests that epothilone D influences the stability of plant MTs mainly during metaphase of the mitotic cycle. In metaphase, the effects of epothilone D seem to be irreversible, because cells with an abnormal spindle could not be recovered after removal of the drug.