The prevention of cell division by anti-clotting agents

Summary We have continued to interpret cell division in terms of the colloidal theory. This theory maintains that cell division is initiated by those substances which induce mitotic gelation and is prevented by those which inhibit this gelation, and that furthermore the mitotic gelation represents a type of clotting in many respects similar to the clotting of vertebrate blood. The bacterial polysaccharide of Shear, a substance which has a marked effect in causing regression of tumors, is a heparin or heparinlike substance. It prevents mitotic gelation and cell division in theChaetopterus egg. Dicoumarol has marked effects on protoplasmic viscosity, first causing enhanced gelation and then pronounced liquefaction. Its action on cell division is related to these effects. A synthetic vitamin K (2-methyl-1, 4 naphthoquinone) tends to liquefy and then markedly to clot the protoplasm of theChaetopterus egg. In very low concentrations it stops mitosis irreversibly.Aided by a grant from the U. S. Public Health Service.     

Cytological and biochemical characterization of the FtsA cell division protein of Bacillus subtilis

The actin-like protein FtsA is present in many eubacteria, and genetic experiments have shown that it plays an important, sometimes essential, role in cell division. Here, we show that Bacillus subtilis FtsA is targeted to division sites in both vegetative and sporulating cells. As in other organisms FtsA is probably recruited immediately after FtsZ. In sporulating cells of B. subtilis FtsZ is recruited to potential division sites at both poles of the cell, but asymmetric division occurs at only one pole. We have now found that FtsA is recruited to only one cell pole, suggesting that it may play an important role in the generation of asymmetry in this system. FtsA is present in much higher quantities in B. subtilis than in Escherichia coli, with approximately one molecule of FtsA for five of FtsZ. This means that there is sufficient FtsA to form a complete circumferential ring at the division site. Therefore, FtsA may have a direct structural role in cell division. We have purified FtsA and shown that it behaves as a dimer and that it has both ATP-binding and ATP-hydrolysis activities. This suggests that ATP hydrolysis by FtsA is required, together with GTP hydrolysis by FtsZ, for cell division in B. subtilis (and possibly in most eubacteria).     

Tumour physics

During the cell division dynamic processes take place, the origin of which are to find in the physical characteristics of cell components. The most important characteristics are the electrical charge and the energy of the moving base components in a viscous cytoplasm. The interactions between the components lead as well known, to the emergence of hydrogen bonds between two DNA strands. The computations show that the strength of these bindings depends on three factors: first it is dependent on the length of a monotonous sequence, second it is dependent on the viscosity of the cytoplasm, and third it is dependent on the replication speed. In the study in detail is stated, how it affects the effectiveness of the DNA repair mechanism, mutation susceptibility, and thus also affects the cancer susceptibility.     

A chemical instability mechanism for asymmetric cell differentiation

We propose a mechanism of asymmetric mitosis applicable for cells even without inherent architectural asymmetry and in the presence of symmetric conditions such as a homogeneous environment. The theory is based on the instability of the symmetric development in time of the prospective daughters of a cell in mitosis. The macroscopic equations of chemical reaction, diffusion, and permeation of the various chemical species in the cell are given formal expression, and are then linearized about the symmetric development in order to test the stability to asymmetric perturbations. Instability to such perturbations indicates the deterministic onset of asymmetric division (differentiation). Only small external gradients of concentration, temperature, light, etc. are necessary to polarize the asymmetry for the purpose of a particular morphology. The theory is compared qualitatively with experiments on melanocytogenesis, is used to suggest new experiments, and is proposed as a possible alternative to other mechanisms. Possible application of the theory to the experiments on the first division in the egg of Fucus is considered. Finally, a simple model of a product-enhanced reaction mechanism is developed in detail which shows that the history of the initial preparation of the cell prior to mitosis may play a role in determining the possibility of asymmetric division.     

The effect of cobalt on the structure of chromosomes and on the mitosis

Summary Cobalt exerts an effect on the structure of chromosomes and on the course and intensity of cell division in root tips of Vicia faba is.Despiralisation of chromosomes and an increase of the viscosity of the matrix substance causing stickiness of the chromosomes are induced by the treatment with cobalt.A cytostatic effect of cobalt was observed. The intensity of cell division is strikingly reduced after treatment with cobalt. Cobalt inhibits the passage of interphase cells into prophase so that this element can be considered to be a preprophase poison.     

Control of cell division: a unifying hypothesis.

A constant feature of the initiation of cell division in a number of different cells is a rise in the intracellular level of calcium. The importance of cyclic nucleotides may depend on the way they interact with calcium. Cyclic AMP is apparently not an essential regulator of cell division but through its ability to modulate the intracellular level of calcium this cyclic nucleotide can exert profound effects on cell growth. In some systems (liver and salivary glands) cyclic AMP seems to augment the calcium signal whereas in others (lymphocytes and fibroblasts) it opposes calcium and can thus inhibit cell division. A rise in the level of calcium may be responsible for the parallel increase in cyclic GMP level which is usually associated with the stimulus to divide. An appealing feature of this calcium hypothesis is that it can account for the growth characteristics revealed by fibroblasts in tissue culture or embryonic cells during development. In both cases there is an initial phase of exponential growth during which I have proposed that the high level of calcium at mitosis persists into early G1 to provide the signal for the next division. In order to account for the sudden cessation of cell division at confluency, or at a specific stage during development, it is necessary to postulate that there is something different about the final mitosis which sets it apart from earlier mitoses. It is proposed that as the cells leave the last mitosis the level of calcium falls much more rapidly than it did during preceeding mitoses perhaps as a result of a more rapid rise in the level of cyclic AMP. This rapid rise in cyclic AMP level may have a dual function. Not only will it lower the level of calcium thus preventing further division, but it may also stimulate differentiation. Many of the embryonic cells which differentiate into specialized cells (lymphocytes, liver, salivary gland) retain the ability to divide if provided with appropriate stimuli. Although the nature of these stimuli vary considerably, they all seem to act by elevating the intracellular level of calcium.     

Immortal DNA or epigenetic signature ?

During mitosis each daughter cell inherits a full copy of the maternal genomic material. DNA replication, however, is an imprecise process, thus errors can arise resulting in potentially deleterious mutations over extended rounds of cell division and these may lead to cancinogenesis. Over thirty years ago, J. Cairns proposed that a cell could avoid the accumulation of mutations arising from DNA replication if all template DNA strands are inherited in one daughter cell during cell division, thus giving rise to the notion of < immortal > DNA strands. In this model the stem cells would retain the template DNA (older) strands. Proving or disproving this notion experimentally has been challenging. Further, it has recently become apparent that epigenetic regulation of gene expression plays a critical role in governing cell states, self-renewal and differentiation. In light of these data, can the phenomenon on template DNA strand segregation also reflect this epigenetic signature? In this review we explore these notions, discuss the evidence in support of this theory, the implications, and some of the mechanisms which could explain this phenomenon.     

Cell division and tissue repair following localized damage to the mammalian lung.

Small local wounds on the surface of the mouse lung, produced by cauterization, healed by a typical reparative process involving cell migration and increased cell division in alveolar and bronchial tissues. The local cell division response closely resembled the compensatory cell division response in the same organ which follows unilateral pneumonectomy or unilateral collapse of the lung: initially there was an increase in the rate of DNA synthesis followed by an increased rate of entry into mitosis, both of these functions returning to normal levels within a few days. It is therefore suggested that both types of response are governed by a single regulatory mechanism. The results do not support the view that the rate of cell division is regulated by systemically-circulating mitotic control factors and it is proposed that changes in the cell division rate, both in the reparative and in the compensatory types of response, are determined by local alterations in the concentration of regulatory metabolites. The magnitude of the cell division response was much greater in bronchial than in alveolar tissue, a result which is consistent with the view that new alveolar tissue may be produced by the proliferation and diffentiation of bronchial cells.     

Phenotypic plasticity and effects of selection on cell division symmetry in Escherichia coli

Aging has been demonstrated in unicellular organisms and is presumably due to asymmetric distribution of damaged proteins and other components during cell division. Whether the asymmetry-induced aging is inevitable or an adaptive and adaptable response is debated. Although asymmetric division leads to aging and death of some cells, it increases the effective growth rate of the population as shown by theoretical and empirical studies. Mathematical models predict on the other hand, that if the cells divide symmetrically, cellular aging may be delayed or absent, growth rate will be reduced but growth yield will increase at optimum repair rates. Therefore in nutritionally dilute (oligotrophic) environments, where growth yield may be more critical for survival, symmetric division may get selected. These predictions have not been empirically tested so far. We report here that Escherichia coli grown in oligotrophic environments had greater morphological and functional symmetry in cell division. Both phenotypic plasticity and genetic selection appeared to shape cell division time asymmetry but plasticity was lost on prolonged selection. Lineages selected on high nutrient concentration showed greater frequency of presumably old or dead cells. Further, there was a negative correlation between cell division time asymmetry and growth yield but there was no significant correlation between asymmetry and growth rate. The results suggest that cellular aging driven by asymmetric division may not be hardwired but shows substantial plasticity as well as evolvability in response to the nutritional environment.     

Risk factors evaluation in some cardiovascular diseases

Cardiovascular risk factors are associated with limitations of blood fluidity. Rheological behaviour of blood in transient flow may result from the internal organization, which in turn depends upon many parameters, which may be considered as possible elements of a profiling algorithm for diagnostic and prognostic values in various pathophysiological states. This study was designed to investigate haemorheological parameters in patients being treated for hypertension, coronary heart disease and myocardial infarct. On the basis of plasma viscosity, whole blood viscosity, haematocrit, red cell aggregation and red cell deformation, the risk was evaluated. In cases of hypertension there was a significant rise in plasma viscosity, whole blood viscosity, red cell aggregation and a fall in red cell deformability. In cases of coronary disease, plasma viscosity and red cell aggregation was increased, while in patients with myocardial infarcts, where the degree of severity is greater it was found that there was a significant rise in both plasma and whole blood viscosity. Haematocrit values were unaffected in all three groups.     

Environmental carcinogenesis: an integrative model.

An integrative theory is proposed in which environmental carcinogenesis is viewed as a process by which the genetic control of cell division and differentiation is altered by carcinogens. In this theory, carcinogens include physical, chemical, and viral "mutagens," as well as chemical and viral gene modulators. Existing explanations of carcinogenesis can be considered either as somatic mutation theories or as epigenetic theories. Evidence seems to support the hypothesis that both mutations and epigenetic processes are components of carcinogenesis. The mutational basis of cancer is supported by the clonal nature of tumors, the mutagenicity of most carcinogens, high mutation frequencies in cells of cancer-prone human fibroblasts lacking DNA repair enzymes, the correlation of in vitro DNA damage and in vitro mutation and transformation frequencies with in vivo tumorigenesis, age-related incidences of various hereditary tumors, and the correlation between photoreactivation of DNA damage and the biological amelioration of UV-induced neoplasms. Since both mutagens and gene modulators can be carcinogenic it may be that carcinogens affect genes which control cell division. An integration of the mutation and epigenetic theories of cancer with the "two-stage" theory and Comings's general theory of carcinogenesis is proposed. This integrative theory postulates that carcinogens can affect regulatory genes which control a series of "transforming genes." A general hypothesis is advanced that involves a common mechanism of somatic mutagenesis via error-prone repair of DNA damage which links carcinogenesis, teratogenesis, atherosclerosis and aging. Various concepts are presented to provide a framework for evaluating the scientific, medical, and social implications of cancer.     

Sloppy size control of the cell division cycle

In an asynchronous, exponentially proliferating cell culture there is a great deal of variability among individual cells in size at birth, size at division and generation time (= age at division). To account for this variability we assume that individual cells grow according to some given growth law and that, after reaching a minimum size, they divide with a certain probability (per unit time) which increases with increasing cell size. This model is called sloppy size control because cell division is assumed to be a random process with size-dependent probability. We derive general equations for the distribution of cell size at division, the distribution of generation time, and the correlations between generation times of closely related cells. Our theoretical results are compared in detail with experimental results (obtained by Miyata and coworkers) for cell division in fission yeast, Schizosaccharomyces pombe. The agreement between theory and experiment is superior to that found for any other simple models of the coordination of cell growth and division.     

Co-Ordination of Cell Division and Tissue Expansion in Sunflower, Tobacco, and Pea Leaves: Dependence or Independence of Both Processes?

Abstract Temporal analyses of cell division and tissue expansion in pea, tobacco, and sunflower leaves reveal that both processes follow similar patterns during leaf development. Relative cell division and relative tissue expansion rates are maximal and constant during early leaf development, but they decline later. In contrast, relative cell expansion rate follows a bell-shaped curve during leaf growth. Cell division and tissue expansion have common responses to temperature, intercepted radiation, and water deficit. As a consequence, final leaf area and cell number remain highly correlated throughout a large range of environmental conditions for these different plant species, indicating that cell division and tissue expansion are co-ordinated during leaf development. This co-ordination between processes has long been explained by dependence between both processes. Most studies on dicotyledonous leaf development indicate that leaf expansion rate depends on the number of cells in the leaf. We tested this hypothesis with a large range of environmental conditions and different plant species. Accordingly, we found a strong correlation between both absolute leaf expansion rate and leaf cell number. However, we showed that this relationship is not necessarily causal because it can be simulated by the hypothesis of independence between cell division and tissue expansion according to Green's theory of growth (1976). Received 23 February 2000; accepted 3 March 2000     

Electrokinetic effects on luminal and transmural fluid flow in capillaries

The influence on fluid flow of the fixed charge on the surface of capillaries is calculated using the linearised Poisson-Boltzmann equations. The results depend strongly upon the ratio of the capillary radius to the Debye length. At physiological ionic strength, the Debye length is less than 1 nm and electrostatic effects are negligible. In particular, they can not explain the Copley-Scott Blair phenomenon in artificial capillaries. Electrostatic effects can be significant in smaller channels and it is calculated that in intercellular clefts in the capillary endothelium the apparent viscosity of the fluid may increase more than 50%. These effects can also be important in the flow in the narrow gap between a red cell and the blood capillary wall. Using the Fitzgerald-Lighthill model of this flow and parameters typical of the human microcirculation, the theory predicts that the apparent viscosity in the gap will be increased by about 5%.     

Trehalose-enzyme interactions result in structure stabilization and activity inhibition. The role of viscosity

Stress resistance is essential for survival. The mechanisms of molecule stabilization during stress are of interest for biotechnology, where many enzymes and other biomolecules are increasingly used at high temperatures and/or salt concentrations. Diverse organisms, exhibit rapid synthesis and accumulation of the disaccharide trehalose in response to stress. Trehalose is also rapidly hydrolyzed as soon as stress ends. In isolated enzymes, trehalose stabilizes both, structure and activity. In contrast, at optimal assay conditions, trehalose inhibits enzyme activity. A general mechanism underlying the trehalose effects observed at all temperatures probably is the trehalose-mediated increase in solution viscosity that leads to protein domain motion inhibition. This may be analyzed using Kramer's theory. The role of viscosity in the effects of trehalose is analyzed in examples from the literature and in studies on the plasma membrane H(+)-ATPase from Kluyveromyces lactis. In the cell, it may be proposed that the large concentration of trehalose reached during stress stabilizes structures through viscosity. However, once stress ends trehalose has to be rapidly hydrolyzed in order to avoid the viscosity-mediated inhibition of enzymes.     

Lessons from development: A role for asymmetric stem cell division in cancer

Asymmetric stem cell division has emerged as a major regulatory mechanism for physiologic control of stem cell numbers. Reinvigoration of the cancer stem cell theory suggests that tumorigenesis may be regulated by maintaining the balance between asymmetric and symmetric cell division. Therefore, mutations affecting this balance could result in aberrant expansion of stem cells. Although a number of molecules have been implicated in regulation of asymmetric stem cell division, here, we highlight known tumor suppressors with established roles in this process. While a subset of these tumor suppressors were originally defined in developmental contexts, recent investigations reveal they are also lost or mutated in human cancers. Mutations in tumor suppressors involved in asymmetric stem cell division provide mechanisms by which cancer stem cells can hyperproliferate and offer an intriguing new focus for understanding cancer biology. Our discussion of this emerging research area derives insight from a frontier area of basic science and links these discoveries to human tumorigenesis. This highlights an important new focus for understanding the mechanism underlying expansion of cancer stem cells in driving tumorigenesis.     

Studies in fission yeast on mechanisms of cell division site placement

One fundamental problem in cytokinesis is how the plane of cell division is established. In this review, we describe our studies on searching for "signals" that position the cell division plane, using fission yeast Schizosaccharomyces pombe. First, we take a genetic approach to determine how the nucleus may position the contractile ring in fission yeast. mid1p appears to link the position of the ring with the nuclear position, as it is required for proper placement of the contractile ring and is localized in a band at the cell surface overlying the nucleus. Second, we study how microtubules may function in the establishment of cell polarity at the cell tips. tea1p may be deposited on the cell surface by microtubules and function to recruit proteins involved in making actin structures. These studies suggest how microtubules may direct the assembly of the contractile ring in animal cells.     

Dr. Haifan Lin. Interviewed by Han Lee and Rachel Rosenstein

Dr. Haifan Lin is professor of Cell Biology at Yale University, where he studies the mechanism of stem cell self-renewal in fruit flies, mice, and human cancer cells. Recently named director of the Yale Stem Cell Center, Dr. Lin has made seminal contributions to the stem cell field, most notably his demonstration of the stem cell niche theory using the fruit fly model, his discovery of the PIWI/AGO gene family that is essential for stem cell division in diverse organisms, and his recent finding of a group of small RNAs called PIWI-interacting, or piRNAs, which may play a crucial role in stem cell proliferation and germline development. Dr. Lin’s work on piRNAs was recognized by Science Magazine as a top scientific breakthrough of 2006. Recently, the Lin lab has begun exploring the role of these molecules in stem cell division and oncogenesis.     

The interplay of ClpXP with the cell division machinery in Escherichia coli

ClpXP is a two-component protease composed of ClpX, an ATP-dependent chaperone that recognizes and unfolds specific substrates, and ClpP, a serine protease. One ClpXP substrate in Escherichia coli is FtsZ, which is essential for cell division. FtsZ polymerizes and forms the FtsZ ring at midcell, where division occurs. To investigate the role of ClpXP in cell division, we examined the effects of clpX and clpP deletions in several strains that are defective for cell division. Together, our results suggested that ClpXP modulates cell division through degradation of FtsZ and possibly other cell division components that function downstream of FtsZ ring assembly. In the ftsZ84 strain, which is temperature sensitive for filamentation due to a mutation in ftsZ, we observed that deletion of clpX or clpP suppresses filamentation and reduces FtsZ84 degradation. These results are consistent with ClpXP playing a role in cell division by modulating the level of FtsZ through degradation. In another division-defective strain, ΔminC, the additional deletion of clpX or clpP delays cell division and exacerbates filamentation. Our results demonstrate that ClpXP modulates division in cells lacking MinC by a mechanism that requires ATP-dependent degradation. However, antibiotic chase experiments in vivo indicate that FtsZ degradation is slower in the ΔminC strain than in the wild type, suggesting there may be another cell division component degraded by ClpXP. Taken together these studies suggest that ClpXP may degrade multiple cell division proteins, thereby modulating the precise balance of the components required for division.     

Role of cell division in branching morphogenesis and differentiation of the embryonic pancreas

A new culture system for the embryonic pancreas enables the formation of a branched organ in vitro. In such cultures, each terminal branch originates as a small bud and the number of buds and of terminal branches increases progressively with the expansion of the culture. However buds can also be resorbed during growth. The normal labelling index of cells in incipient buds ("tips") is greater than between buds ("dips") suggesting that budding may be driven by a local increase of cell division. Consistent with this, treatments that reduce cell division repress the formation of buds and branches. It is not possible to initiate budding in isolated endodermal epithelium by treatment with fibroblast growth factor, although this does increase the degree of differentiation of exocrine cells. Cultures in which cell division is completely inhibited by aphidicolin treatment will produce more endocrine cells than usual and inhibit the differentiation of exocrine cells. Consistent with this it is found that in untreated cultures the division of endocrine precursors cannot be detected by BrdU labelling whereas the division of exocrine precursors is frequent. It is concluded that cell division is necessary for bud formation in the embryonic pancreas and that the growth factors required for this normally come from the mesenchyme. Cell division is also necessary for exocrine differentiation. Endocrine cells, however, can arise from undifferentiated progenitors without cell division.