Sorting out in heterotypic cell aggregates is regulated by differences in the cell surface charge

Random aggregates of heterotypic cells derived from two different embryonic tissues sort out into homotypic zones, one enclosing the other. The specification of the enclosed or enclosing position is based on a tissue hierarchy. Cells differ in their net negative charge as indicated by their different isoelectric points (pI). The cells of higher pI enclose the cells of lower pI. Cell pI is lowered by treatment with heparin. Cells with experimentally altered pI also sort out, and their position is specified by the differences in their pI. It is suggested that the cell surface ionogenic groups determine the free surface energy which controls the positioning of cells in a mixed aggregate.     

The mechanics of heterotypic cell aggregates: insights from computer simulations

Finite element-based computer simulations are used to investigate a number of phenomena, including tissue engulfment, cell sorting, and checkerboard-pattern formation, exhibited by heterotypic cell aggregates. The simulations show that these phenomena can be driven by a single equivalent force, namely a surface (or interfacial) tension, that results from cytoskeletal components and cell-cell adhesions. They also reveal that tissue engulfment, cell sorting, and checkerboard-pattern formation involve several discernible mechanical features or stages. With the aid of analytical arguments, we identify the conditions necessary for each of these phenomena. These findings are consistent with previous experimental investigations and computer simulations, but pose significant challenges to current theories of cell sorting and tissue engulfment.     

Embryonic myocardial cell aggregates: volume and pulsation rate

Spontaneously beating aggregates of myocardial cells from whole heart, atria, and apical portions of the ventricles were prepared by trypsin-dissociation and gyratory reaggregation of 4-, 7-, and 14-day-old chick embryo tissue. Pulsation rate and volume of aggregates were determined. The pulsation rate for a given volume aggregate decreased as the age of the donor embryo increased. Atrial aggregates of a given size beat faster than ventricular aggregates of the same size. However, in all cases the pulsation rate varied inversely with the aggregate volume. These results are not in agreement with the pacemaker concept as generally accepted, which predicts that a mass of heart cells would take on the pulsation rate of the fastest cell or cells within it. Differential composition of large and small aggregates was ruled out as a determining factor in the inverse rate-volume relationship. We suggest that (a) limited diffusion in large aggregates compared to small aggregates or (b) the larger total membrane capacitance of the electrically coupled cells of larger aggregates compared with that of smaller aggregates, plays a major role in setting the pulsation rate.     

Relation between molecular shape and the morphology of self-assembling aggregates: a simulation study

Proteins can aggregate in a wide variety of structures, both compact and extended. We present simulations of a coarse-grained anisotropic model that reproduce many of the experimentally observed aggregate structures. Conversely, all structures predicted by our model have experimental counterparts (ribbons, multistranded fibrils, and vesicles). The model we use is that of a rodlike particle with an attractive (hydrophobic) stripe on its side. Our Monte Carlo simulations show that aggregate morphologies crucially depend on two parameters. The first one is the width of the attractive stripe and the second one is a presence or absence of attractive interactions at the particle ends. These results provide us with a generic insight into the relation between the shape of protein-protein interaction potential and the morphology of protein aggregates.     

Direct measurements of heterotypic adhesion between the cell surface proteins CD2 and CD48

Direct force measurements were used to investigate the molecular mechanism of heterophilic adhesion between the murine T-cell adhesion glycoprotein CD2 and its ligand CD48. From the distance dependence of the protein-protein interaction potential, we demonstrate directly that the full-length extracellular domains adhere in a head-to-head orientation. The absence of long-range electrostatic protein-protein attraction further indicates that the salt bridges between the binding surfaces only influence the interaction at short range. Despite the loss of a stabilizing disulfide bond in domain 1 (D1) of CD2, adhesive failure occurs abruptly with no evidence of partial protein unfolding during detachment. Finally, these measurements between extended membrane surfaces directly confirm that the low-affinity CD2-CD48 bond generates weak adhesion and that lateral receptor mobility is required for the development of appreciable adhesion. This is the first direct measurement of the range and magnitude of the forces governing heterotypic adhesion mediated by cell surface proteins. These results both verified the head-to-head CD2-CD48 docking alignment and demonstrated the ability to elucidate the structure-function relationships of adhesion proteins from the measured distance dependence of their interaction potentials.     

Cadherin-23 mediates heterotypic cell-cell adhesion between breast cancer epithelial cells and fibroblasts

In the early stages of breast cancer metastasis, epithelial cells penetrate the basement membrane and invade the surrounding stroma, where they encounter fibroblasts. Paracrine signaling between fibroblasts and epithelial tumor cells contributes to the metastatic cascade, but little is known about the role of adhesive contacts between these two cell types in metastasis. Here we show that MCF-7 breast cancer epithelial cells and normal breast fibroblasts form heterotypic adhesions when grown together in co-culture, as evidenced by adhesion assays. PCR and immunoblotting show that both cell types express multiple members of the cadherin superfamily, including the atypical cadherin, cadherin-23, when grown in isolation and in co-culture. Immunocytochemistry experiments show that cadherin-23 localizes to homotypic adhesions between MCF-7 cells and also to heterotypic adhesions between the epithelial cells and fibroblasts, and antibody inhibition and RNAi experiments show that cadherin-23 plays a role in mediating these adhesive interactions. Finally, we show that cadherin-23 is upregulated in breast cancer tissue samples, and we hypothesize that heterotypic adhesions mediated by this atypical cadherin may play a role in the early stages of metastasis.     

Control of cell polarity and mitotic spindle positioning in animal cells

Cell polarity is an essential feature of many animal cells. It is critical for epithelial formation and function, for correct partitioning of fate-determining molecules, and for individual cells to chemotax or grow in a defined direction. For some of these processes, the position and orientation of the mitotic spindle must be coupled to cell polarity for correct positioning of daughter cells and inheritance of localised molecules. Recent work in several different systems has led to the realisation that similar mechanisms dictate the establishment of polarity and subsequent spindle positioning in many animal cells. Microtubules and conserved PAR proteins are essential mediators of cell polarity, and mitotic spindle positioning depends on heterotrimeric G protein signalling and the microtubule motor protein dynein.     

Relation between rate of cell proliferation and formation of micronuclei after combined treatment with X-rays and caffeine

We studied the effects of caffeine (2 mM), X-rays (1 Gy) and the combination of both agents on cell proliferation and formation of micronuclei in the early stages of preimplantation mouse embryos in vitro. Two-cell embryos were exposed to the agents shortly before division to the 4-cell stage. Proliferation and micronucleus production was monitored every 2 h in the 4- and 8-cell stages. A rather peculiar pattern of micronucleus formation after radiation exposure alone was observed for 8-cell embryos: those embryos that were the first to enter the 8-cell stage showed two to three times higher numbers of micronuclei per cell when compared with those embryos that entered the 8-cell stage some hours later. Studies of the kinetics of cell proliferation and of micronucleus formation in 4- and 8-cell embryos and exposure to caffeine revealed that this result could be explained by two factors: a slight asynchrony in the developmental stage at the time of exposure and the length of the interval being available for repair processes. When caffeine was present, a third factor had to be taken into consideration: direct inhibition of repair by caffeine.Dedicated to Prof. W. Jacobi on the occasion of his 65th birthday     

Cadherin-catenin complexes during zebrafish oogenesis: heterotypic junctions between oocytes and follicle cells.

During vertebrate oogenesis, the germ cells and associated somatic cells remain connected by a variety of adhering junctional complexes. However, the molecular composition of these cellular structures is largely unknown. To identify the proteins forming the heterotypic adherens junctions between oocytes and follicle cells in the zebrafish (Danio rerio), the cDNAs encoding alphaE-catenin and plakoglobin were isolated. Using these cDNAs, in combination with the previously isolated beta-catenin cDNA, and antibodies specific for alpha- and beta-catenin, plakoglobin, and N- and E-cadherin, we found differences in catenin and plakoglobin gene expression during oogenesis. The immunolocalization of these plaque proteins, as well as of cadherins, in the ovarian follicle indicated an enrichment of alpha- and beta-catenin and of E-cadherin-like protein(s) in the oocyte cortex, notably at sites of oocyte-follicle cell contacts, suggesting the presence of hitherto unknown heterotypic adherens junctions between these cells. By contrast, plakoglobin and N-cadherin localization was restricted to cell-cell contacts in the follicle cell layer. During oocyte maturation, mRNAs for alphaE- and beta-catenin and plakoglobin accumulated, and all three plaque-forming proteins were stored in unfertilized eggs, either in complexed forms with cadherins or as free cytoplasmic pools. These findings suggest possible roles of these junctional proteins during early embryogenesis.     

Relation between growth rate and erythromycin production inStreptomyces erythraeus

Summary The relation between specific growth rate and specific rate of product formation was studied in phosphate-limited chemostat cultures ofStreptomyces erythraeus. Specific rates of formation were measured for both the final product, erythromycin A, and several of its biosynthetic precursors. In all cases rates of formation increased with inereasing growth rate, indicating that antibiotic production was strongly growth-linked.     

Concanavalin A increases spontaneous beat rate of embryonic chick heart cell aggregates

The plant lectin concanavalin A (Con A), at concentrations of 5–200 μg/ml, induced a twofold to fivefold increase in spontaneous beat rate of cultured aggregates of ventricular cells from seven-day chick embryos. This response was time, dose, and temperature dependent and was accompanied by a decrease in transmembrane potential. It could be blocked or reversed by α-methyl-D-mannoside but was not reversed by dilution alone. Binding of the lectin occurred in the cold, but a temperature-dependent process was also necessary to produce the response. Divalent (succinyl) Con A did not cause a beat rate increase. Whole heart aggregates responded similarly but less intensely than ventricular aggregates. Atrial aggregates, and whole heart aggregates treated with 5 μg/ml of Con A, produced a biphasic chronotropic response, first decreasing then increasing their beat rates. These results suggest that saccharide-bearing macromolecules on the heart cell surface play a role in regulating spontaneous beat rate.     

L-dopa and dopamine enhance the formation of aggregates under proteasome inhibition in PC12 cells

The formation of inclusion bodies in dopaminergic neurons is associated with the pathogenesis of Parkinson's disease. In order to clarify the role of dopamine/L-dopa in the formation of protein aggregates, we investigated dopamine/L-dopa-related aggregation using an experimental inclusion model. The inhibition of tyrosine hydroxylase (TH) by alpha-methyltyrosine dramatically decreased MG132-induced aggregate formation. In addition, the inhibition of TH caused the upregulation of proteasomes in cultured cells and the dopamine/L-dopa induced non-enzymatic polymerization of ubiquitin. This inhibition did not affect cell viability. These results suggest that dopamine/L-dopa might enhance aggregate formation, and that intracellular aggregates may not be toxic to cells.     

The relationship between surface protease activity and the rate of cell proliferation in normal and transformed cells

Surface protease activity and secreted protease activity has been determined on several cell lines utilizing ³H-acetyl casein as substrate. When normal rabbit aortic smooth muscle cells and fibroblasts stopped proliferating at high cell density a decrease in surface protease activity was observed. No decrease in surface protease activity or in the rate of cell proliferation was observed in either transformed melanoma or epidermal cells. The decrease of surface protease activity was related to a decrease in cell proliferation.     

The rate of fork movement during DNA replication in mammalian cells

DNA fiber autoradiography was used to measure the rate of replication fork progression along replication units in human diploid cells. The rate in different replication units differs very significantly and lies within the range 0.1 to 1.2 m/min. However, no significant changes were found in the rate of fork movement along single replication units operating during long intervals of S phase. Moreover, the fork progression rate is constant in many replication units of human cells.