Specificity of cell-cell interactions in sea urchin embryos: Appearance of new cell-surface determinants at gastrulation

Studies on normal and hybrid sea urchin embryos show that, beginning at gastrulation, hybrid cells express cell-surface antigens specific to both species. The appearance of these antigens is shown to be correlated with a change in the adhesive specificity of hybrid cells: Beginning at gastrulation, hybrid cells recognize and adhere to embryonic cells of both normal genotypes. Prior to gastrulation, hybrid cells adhere to cells of the maternal genotype only. Two adhesion assays demonstrate these adhesive preferences. (i) When cell aggregates are placed together in a dish, Lytechnius aggregates fuse together, and Tripneustes aggregates fuse together, but aggregates of the two species do not fuse with each other. Hybrid cell aggregates, if they are past the beginning of gastrulation, fuse to both Tripneustes and Lytechinus aggregates. (ii) In a collection assay, midgastrula cells of the hybrid embryos are collected at a high rate to aggregates of either species. Pregastrula hybrid cells collect at a high rate to aggregates of the maternal species only. This change in adhesive preference is temporally correlated with the appearance of new cell surface antigens. Antiserum was prepared in rabbits against membranes from Lytechinus gastrulae. Indirect immunofluorescence tests show that hybrid cells of the cross (T♀ × L♂) express Lytechinus-specific antigens at the cell surface beginning at gastrulation. Furthermore, an apparent relationship between the new cell-surface antigens and adhesion exists in that Lytechinus cell adhesion is inhibited specifically after binding Fab fragments of the Lytechinus antiserum. The antiserum has no effect on Tripneustes adhesion. The Lytechinus adhesion-inhibiting activity can be removed by absorption of the antiserum with Lytechinus cells.     

A kinetic study of embryonic cell adhesion

A new assay is described for measuring the kinetics of adhesion of cells to collecting aggregates. The parameter measured is the percentage of cells in suspension adhering to a large number of collecting aggregates per unit time. Using this assay on trypsinized cells it is shown that several hours of recovery are required before the maximum adhesion rate is reached. The recovery period is sensitive to cycloheximide and to low temperature (4°C). As the cells approach the maximum adhesion rate, their collection to aggregates becomes increasingly insensitive to the addition of cycloheximide; this adhesion remains sensitive to low temperature. Specificity studies show that the rate of adhesion of embryonic cells to collecting aggregates is highest between cells and aggregates of the same histotype. This rate is affected by the embryonic age of the cells. Finally, when cells of a tissue are fractionated on Ficoll gradients, it is shown that subpopulations of cells adhere to collecting aggregates at different rates.     

The Reaggregation of Dissociated Embryonic Sea Urchin Cells

Studies carried out on reaggregating sea urchin embryonic cellsreveal that reaggregating cells can give rise to normal pluteuslarvae by three developmental pathways: (i) from clusters, (ii)from chains of beads, and (iii) from a tissue culture phase.Experiments carried out on a mixture of cells from two differentspecies, Arbacia punctulata and Lytechinus pictus, demonstratethat reaggregation is species specific and that the sortingout of cells according to species occurs. Movement of cellswithin an aggregate is non-random and unidirectional. Electronmicroscope analysis of mixed aggregates of cells of the twospecies indicates that cells of the same species make initialcontact and adhere to one another by means of numerous microvilliand with the formation of an intercellular hyaline-like material.Cells of the two different species adhere, but never by meansof microvilli and no hyaline-like material can be detected onthe cell surfaces. The results indicate a role in reaggregationof an intercellular material, possibly an intercellular cement.     

Phytohemagglutinin-mediated blastomere aggregation and development of allophenic mice

Phytohemagglutinin (PHA) causes cells from two or more preimplantation-stage mouse embryos (after removal of the zona pellucida) to adhere rapidly and firmly upon a few minutes' exposure in vitro. Adhesion is successful at room temperature, and the cells remain agglutinated after transfer to room-temperature culture medium without PHA. The incubated aggregates continue their development. After surgical transfer to pseudopregnant recipients, aggregates comprising two different cellular genotypic populations can give rise to viable allophenic mice with both cellular genotypes. PHA treatment is thus a simple substitute for temperature-induced (37°C) aggregation of mouse blastomeres in vitro, and it provides a new and efficient tool for experimental studies of mammalian development.     

Adhesive specificity in normal and transformed mouse fibroblasts

Adhesive specificity was studied in normal and transformed $\text{Balb}\text{c}$ mouse fibroblasts by comparing the number of labeled cells collected from a suspension of these cells by aggregates of various cell types. Aggregates of the two malignant cells examined collected either very many cells (aggregates of SV3T3 cells) or very few cells (aggregates of 3T12 cells). In addition, the relative adhesive behavior of these two aggregate types did not vary according to the cell suspension in which they were circulated. These data make it unnecessary to assume that malignancy is always accompanied by a decrease in intercellular adhesion.The adhesive behavior of normal 3T3 cell aggregates, compared to the aggregates composed of either malignant cell type, varied according to the type of cells in the suspension. Aggregates of 3T3 cells collected an appreciable number of SV3T3 cells but few 3T12 cells. Collection of 3T3 cells by 3T3 aggregates was also low if the 3T3 cells of the suspension were harvested from confluent cultures. However, collection of 3T3 cells by 3T3 aggregates increased significantly, as compared to collection by SV3T3 and 3T12 aggregates in the same cell suspension, if the 3T3 suspension was prepared from sparse cultures.Flat-revertants of SV3T3 cells were also studied. These cells behave like nonmalignant 3T3 cells rather than like the SV3T3 cells from which they were derived.We suggest that malignancy may not be caused by decreased intercellular adhesion as compared to normal cells but, perhaps, by decreased intercellular recognition.     

In the footsteps of sea stars: deciphering the catalogue of proteins involved in underwater temporary adhesion

Sea stars adhere strongly but temporarily to underwater substrata via the secretion of a blend of proteins, forming an adhesive footprint that they leave on the surface after detachment. Their tube feet enclose a duo-gland adhesive system comprising two types of adhesive cells, contributing different layers of the footprint and de-adhesive cells. In this study, we characterized the catalogue of sea star footprint proteins (Sfps) in the species Asterias rubens to gain insights in their potential function. We identified 16 Sfps and mapped their expression to type 1 and/or type 2 adhesive cells or to de-adhesive cells by double fluorescent in situ hybridization. Based on their cellular expression pattern and their conserved functional domains, we propose that the identified Sfps serve different functions during attachment, with two Sfps coupling to the surface, six providing cohesive strength and the rest forming a binding matrix. Immunolabelling of footprints with antibodies directed against one protein of each category confirmed these roles. A de-adhesive gland cell-specific astacin-like proteinase presumably weakens the bond between the adhesive material and the tube foot surface during detachment. Overall, we provide a model for temporary adhesion in sea stars, including a comprehensive list of the proteins involved.     

DO MORPHOGENETIC TISSUE REARRANGEMENTS REQUIRE ACTIVE CELL MOVEMENTS? : The Reversible Inhibition of Cell Sorting and Tissue Spreading by Cytochalasin B

Previous studies have indicated that cell sorting and tissue spreading are caused by cell combination-specific differences in intercellular adhesive energies, acting in a system of motile cells. We wished to determine whether these adhesive energies could drive cell rearrangements as well as guide them. Accordingly, aggregates of intermixed embryonic cells were cultured in solutions of the drug cytochalasin B (CCB) at a concentration shown to inhibit the locomotion of cells on a solid surface. In addition, spherical aggregates of several kinds were cultured in mutual contact under similar conditions. Both cell sorting and tissue spreading were found to be inhibited. The prompt release of this inhibition upon removal of the CCB showed that the inhibited cells were not merely injured. Moreover, aggregation experiments showed that CCB did not prevent cells of several kinds from initiating mutual adhesions. In fact, heart cell aggregation was enhanced by CCB. We conclude that interfacial forces, originating outside the cell, act together with forces originating inside it in bringing about the morphogenetic movements of cell sorting and tissue spreading. We propose the term "cooperative cell locomotion" to describe translational movements of cells arising from such a combination of intrinsic and extrinsic forces.     

CadF expression in Campylobacter jejuni strains incubated under low-temperature water microcosm conditions which induce the viable but non-culturable (VBNC) state

Campylobacter jejuni is a major gastrointestinal pathogen that colonizes host mucosa via interactions with extracellular matrix proteins such as fibronectin. The aim of this work was to study in vitro the adhesive properties of C. jejuni ATCC 33291 and C. jejuni 241 strains, in both culturable and viable but non-culturable (VBNC) forms. To this end, the expression of the outer-membrane protein CadF, which mediates C. jejuni binding to fibronectin, was evaluated. VBNC bacteria were obtained after 46–48 days of incubation in freshwater at 4 °C. In both cellular forms, the expression of the cadF gene, assessed at different time points by RT-PCR, was at high levels until the third week of VBNC induction, while the intensity of the signal declined during the last stage of incubation. CadF protein expression by the two C. jejuni strains was analysed using 2-dimensional electrophoresis and mass spectrometry; the results indicated that the protein, although at low levels, is also present in the VBNC state. Adhesion assays with culturable and VBNC cells, evaluated on Caco-2 monolayers, showed that non-culturable bacteria retain their ability to adhere to intestinal cells, though at a reduced rate. Our results demonstrate that the C. jejuni VBNC population maintains an ability to adhere and this may thus have an important role in the pathogenicity of this microorganism.     

Calcium-dependent adhesion of Drosophila embryonic cells

Summary By using an in vitro functional assay, we have shown that Drosophila embryonic cells possess Ca²⁺-dependent adhesive sites, which resemble in many respects those described for vertebrate cells and tissues. The cells, obtained by mechanical disruption of gastrulastage embryos, form aggregates within 30 min when maintained under constant rolling. The aggregation is completely dependent on the presence of Ca²⁺ in the medium. In its absence, the cells remain dispersed but the process is reversible by readdition of Ca²⁺. In addition the aggregation is temperature-dependent. No aggregation occurs at 4° C but it can be restored by raising the temperature to 25° C. These properties are characteristic of these cells: established cell lines do not aggregate under the same conditions and mixing of cell lines and embryonic cells does not result in chimeric aggregates, thus pointing towards cell-type selectivity with respect to aggregability. Observations in electron microscopy have shown that the embryonic cells in the aggregates tightly adhere to one another and form, as early as after 30 min, maculae adherens junctions. Drosophila embryonic cells have adhesion sites that are protected from trypsin proteolysis in the presence of Ca²⁺ and sensitive in its absence. The cells' aggregation can be inhibited by a mouse antiserum directed against cell-surface components and a good correlation exists between neutralization of the inhibitory activity of the antiserum and the presence of trypsin-sensitive sites on the cells. These data are in favour of cell-cell adhesion mediated by specific adhesion proteins.     

The pattern of cell wall adhesive formation by Fucus zygotes

As a first step in understanding the mechanism of algal adhesion, we describe the adhesive process during early development in Fucus gardneri zygotes. These brown algal embryos adhere to the intertidal substrate shortly after fertilization. Zygotes adhered nonspecifically to hydrophilic and hydrophobic substrates and microspheres. Initial binding of microspheres to the zygote surface coincided with initial zygote adhesion to the substrate. Binding of monodisperse dyed microspheres was used for adhesive localization and quantitation. The timing and extent of adhesive development were variable in populations of synchronously-fertilized zygotes. Small adhesive patches first appeared at 3–6 h, indicating secretion of adhesive components from cytoplasmic vesicles. The zygote hemisphere toward the substrate became sticky by 7–8 h. The entire surface was sticky after rhizoid germination at 12 h. Localization of adhesive at both the outer wall surface and along strands attached to the wall implicates cell wall polymers as a glue component. Loss of microspheres from the rhizoid surface in high salt or chelators indicates that initial adhesive attachment to the wall is noncovalent. Formation of adhesive aggregates in medium showed that the mechanism of adhesive formation includes two separable processes, secretion of adhesive components and extracellular interactions between adhesive components and the wall.     

Saliva-Induced Aggregation of Oral Streptococci

Cells of several species of oral microorganisms have been shown, in earlier studies, to be aggregated by saliva. In the present study some of the basic properties of the aggregation system are examined. The observation is made that the saliva-induced aggregates of Streptococcus sanguis and S. mitis can be dissociated to stable particles which consist of about 100 cells and have a median diameter of about 4.5 μm. It is proposed that these are subunits, or core aggregates, of the large primary aggregates. Counts of the core aggregates can be taken as a precise and accurate measure of aggregation. Experiments based on this procedure show that the aggregation of S. sanguis is maximal at 10 C and at 1 meq of Ca²⁺ ions per liter and is not affected by a change in pH between 3.9 and 8.7 or by a change in the phase of growth of the microorganisms. Core aggregates diminish in number with prolonged incubation, suggesting that the aggregating factors break down with time. Formalinized cells yield stable aggregates. However, with Formalinized cell aggregation is maximal between 20 and 30 C and proceeds in the absence of calcium ions. Evidence is presented that whole saliva contains separate aggregating factors for S. sanguis and S. mitis. The factors differ in their affinity for intact cells and for hydroxyapatite and differ in their stability to dialysis. These findings suggest that many different aggregating factors exist in saliva, each of which may be capable of interacting with cells of one or several bacterial species.     

Cell Substratum Adhesion during Early Development of Dictyostelium discoideum

Vegetative and developed amoebae of Dictyostelium discoideum gain traction and move rapidly on a wide range of substrata without forming focal adhesions. We used two independent assays to quantify cell-substrate adhesion in mutants and in wild-type cells as a function of development. Using a microfluidic device that generates a range of hydrodynamic shear stress, we found that substratum adhesion decreases at least 10 fold during the first 6 hr of development of wild type cells. This result was confirmed using a single-cell assay in which cells were attached to the cantilever of an atomic force probe and allowed to adhere to untreated glass surfaces before being retracted. Both of these assays showed that the decrease in substratum adhesion was dependent on the cAMP receptor CAR1 which triggers development. Vegetative cells missing talin as the result of a mutation in talA exhibited slightly reduced adhesive properties compared to vegetative wild-type cells. In sharp contrast to wild-type cells, however, these talA mutant cells did not show further reduction of adhesion during development such that after 5 hr of development they were significantly more adhesive than developed wild type cells. In addition, both assays showed that substrate adhesion was reduced in 0 hr cells when the actin cytoskeleton was disrupted by latrunculin. Consistent with previous observations, substrate adhesion was also reduced in 0 hr cells lacking the membrane proteins SadA or SibA as the result of mutations in sadA or sibA. However, there was no difference in the adhesion properties between wild type AX3 cells and these mutant cells after 6 hr of development, suggesting that neither SibA nor SadA play an essential role in substratum adhesion during aggregation. Our results provide a quantitative framework for further studies of cell substratum adhesion in Dictyostelium.     

Spatial Organization of Dual-Species Bacterial Aggregates on Leaf Surfaces

The spatial organization of cells within bacterial aggregates on leaf surfaces was determined for pair-wise mixtures of three different bacterial species commonly found on leaves, Pseudomonas syringae, Pantoea agglomerans, and Pseudomonas fluorescens. Cells were coinoculated onto bean plants and allowed to grow under moist conditions, and the resulting aggregates were examined in situ by epifluorescence microscopy. Each bacterial strain could be localized because it expressed either the green or the cyan fluorescent protein constitutively, and the viability of individual cells was assessed by propidium iodide staining. Each pair of bacterial strains that was coinoculated onto leaves formed mixed aggregates. The degree of segregation of cells in mixed aggregates differed between the different coinoculated pairs of strains and was higher in mixtures of P. fluorescens A506 and P. agglomerans 299R and mixtures of P. syringae B728a and P. agglomerans 299R than in mixtures of two isogenic strains of P. agglomerans 299R. The fractions of the total cell population that were dead in mixed and monospecific aggregates of a gfp-marked strain of P. agglomerans 299R and a cfp-marked strain of P. agglomerans 299R, or of P. fluorescens A506 and P. agglomerans 299R, were similar. However, the proportion of dead cells in mixed aggregates of P. syringae B728a and P. agglomerans 299R was significantly higher (13.2% ± 8.2%) than that in monospecific aggregates of these two strains (1.6% ± 0.7%), and it increased over time. While dead cells in such mixed aggregates were preferentially found at the interface between clusters of cells of these strains, cells of these two strains located at the interface did not exhibit equal probabilities of mortality. After 9 days of incubation, about 77% of the P. agglomerans 299R cells located at the interface were dead, while only about 24% of the P. syringae B728a cells were dead. The relevance of our results to understanding bacterial interactions on leaf surfaces and the implications for biological control of pathogenic and other deleterious microorganisms is discussed.     

Restructuring dynamics of du 145 and LNCaP prostate cancer spheroids

Summary Neoplastic cells acquire multidrug resistance as they assemble into multicellular spheroids. Image analysis and Monte Carlo simulation provided an insight into the adhesion and motility events during spheroid restructuring in liquid-overlay culture of DU 145 and LNCaP human prostate cancer cells. Irregularly shaped, two-dimensional aggregates restructured through incremental cell movements into three-dimensional spheroids. Of the two cultures examined, restructuring was more pronounced for DU 145 aggregates. Motile DU 145 cells formed spheroids with a minimum cell overlay of 30% for 25-mers as estimated by simulation versus 5% for adhesive LNCaP cells in aggregates of the same size. Over 72 h, the texture ratio increased from 0.55±0.05 for DU 145 aggregates with projected areas exceeding 2000 μm² to a value approaching 0.75±0.02 (P<0.05). For LNCaP aggregates of comparable size, the increase in texture ratio was more modest, less than 15% during the same time period (P<0.05). Combined, these data suggest that motility events govern the overall rate of spheroid restructuring. This information has application to the chemosensitization of solid tumors and kinetic modeling of spheroid production.     

Aβ Oligomers and Fibrillar Aggregates Induce Different Apoptotic Pathways in LAN5 Neuroblastoma Cell Cultures

Fibril deposit formation of amyloid β-protein (Aβ) in the brain is a hallmark of Alzheimer's disease (AD). Increasing evidence suggests that toxicity is linked to diffusible Aβ oligomers, which have been found in soluble brain extracts of AD patients, rather than to insoluble fibers. Here we report a study of the toxicity of two distinct forms of recombinant Aβ small oligomers and fibrillar aggregates to simulate the action of diffusible Aβ oligomers and amyloid plaques on neuronal cells. Different techniques, including dynamic light scattering, fluorescence, and scanning electron microscopy, have been used to characterize the two forms of Aβ. Under similar conditions and comparable incubation times in neuroblastoma LAN5 cell cultures, oligomeric species obtained from Aβ peptide are more toxic than fibrillar aggregates. Both oligomers and aggregates are able to induce neurodegeneration by apoptosis activation, as demonstrated by TUNEL assay and Hoechst staining assays. Moreover, we show that aggregates induce apoptosis by caspase 8 activation (extrinsic pathway), whereas oligomers induce apoptosis principally by caspase 9 activation (intrinsic pathway). These results are confirmed by cytochrome c release, almost exclusively detected in the cytosolic fraction of LAN5 cells treated with oligomers. These findings indicate an active and direct interaction between oligomers and the cellular membrane, and are consistent with internalization of the oligomeric species into the cytosol.     

Properties and usefulness of aggregates of synovial mesenchymal stem cells as a source for cartilage regeneration

Introduction

Transplantation of mesenchymal stem cells (MSCs) derived from synovium is a promising therapy for cartilage regeneration. For clinical application, improvement of handling operation, enhancement of chondrogenic potential, and increase of MSCs adhesion efficiency are needed to achieve a more successful cartilage regeneration with a limited number of MSCs without scaffold. The use of aggregated MSCs may be one of the solutions. Here, we investigated the handling, properties and effectiveness of aggregated MSCs for cartilage regeneration.

Methods

Human and rabbit synovial MSCs were aggregated using the hanging drop technique. The gene expression changes after aggregation of synovial MSCs were analyzed by microarray and real time RT-PCR analyses. In vitro and in vivo chondrogenic potential of aggregates of synovial MSCs was examined.

Results

Aggregates of MSCs cultured for three days became visible, approximately 1 mm in diameter and solid and durable by manipulation; most of the cells were viable. Microarray analysis revealed up-regulation of chondrogenesis-related, anti-inflammatory and anti-apoptotic genes in aggregates of MSCs. In vitro studies showed higher amounts of cartilage matrix synthesis in pellets derived from aggregates of MSCs compared to pellets derived from MSCs cultured in a monolayer. In in vivo studies in rabbits, aggregates of MSCs could adhere promptly on the osteochondral defects by surface tension, and stay without any loss. Transplantation of aggregates of MSCs at relatively low density achieved successful cartilage regeneration. Contrary to our expectation, transplantation of aggregates of MSCs at high density failed to regenerate cartilage due to cell death and nutrient deprivation of aggregates of MSCs.

Conclusions

Aggregated synovial MSCs were a useful source for cartilage regeneration considering such factors as easy preparation, higher chondrogenic potential and efficient attachment.     

Ploidy instability in long-term in vitro cultures of Coffea arabica L. monitored by flow cytometry

Somatic embryogenesis of Coffea arabica L. has been mainly carried out in liquid medium for clonal and mass propagation of elite lines. This in vitro system involves suspension cultures of embryogenic aggregates, with high multiplication rate and unorganized growth. These characteristics are linked to the occurrence of somaclonal variation (SV), especially considering that cell aggregates are usually maintained for long periods in media supplemented with the synthetic auxin 2,4-dichlorophenoxyacetic acid. Because SV detection has been considered essential in in vitro tissue cultures, flow cytometry (FCM) was applied to verify ploidy instability in embryogenic cell aggregates of C. arabica, throughout successive subcultures. FCM allowed us to detect the occurrence of non-true-to-type aggregates in all samples collected after approximately 4 months in liquid medium. These aggregates showed octaploid and/or aneuploid cells, with DNA ploidy level being corroborated by chromosome counting. Considering this result, we recommend a limit of <4 months for true-to-type mass propagation of C. arabica cell aggregate suspensions. Besides, FCM was an important tool to detect SV at an early stage of tissue culture in this species, proving to be very useful for quality control in clonal propagation and in the introduction of somaclones to breeding programs.     

Post-translational modifications distinguish cell surface from Golgi-retained {beta}1,4 galactosyltransferase molecules. Golgi localization involves active retention

ß1,4 Galactosyltransferase (GalT) is a membrane-boundenzyme localized predominantly to the trans-Golgi cisternae.Our previous studies have shown that the transmembrane domainof bovine GalT plays a critical role in Golgi localization (Teasdale,R.D.,D'Agostaro,G. and Gleeson,P.A., J. Biol. Chem., 267, 4084–4096,1992). Here we have compared the localization and post-translationalmodifications of fulllength bovine GalT with a GalT/hybrid moleculewhere the transmembrane domain of GalT was replaced with thatof the transferrin receptor. GalT/hybrid molecules were expressedon the surface of transfected cells; however, differences wereobserved in the distribution of the hybrid molecules betweentransfected COS and murine L cells. In transfected COS cells,the GalT/hybrid protein was expressed efficiently at the cellsurface, with little Golgilocalized material, whereas in stablemurine L cells, which expressed lower levels of the construct,hybrid molecules were detected both at the cell surface andwithin the Golgi apparatus. Expression of the GalT constructsin either COS or L cells produced two glycoprotein productswhich differed in molecular mass by 7 kDa. The difference insize between the two products is due to post-translational modiicationswhich are inhibited by brefeldin A and are therefore likelyto occur in the trans-Golgi network (TGN). Very little of thehigh-molecular-weight species was detected for full-length GalT,whereas it was a major product for the GalT/hybrid protein.Only the higher molecular weight species was expressed at thecell surface. Thus, this additional 7 kDa post-translationalmodification distinguishes molecules retained within the Golgiapparatus (lower M_r species) from those transported throughthe TGN to the cell surface. These studies indicate that (i)the level of expression influences the intracellular distributionof GalT/hybrid molecules and (ii) the localization of full-lengthGalT involves active retention within the Golgi stack, and notretrieval from later compartments. After treatment of membranepreparations from stable L cell clones with a heterobifunctionalcross-linking agent, full-length bovine GalT molecules werefound almost exclusively as high-molecular-weight aggregates,suggesting that GalT exists as an oligomer or aggregate. Thisability to oligomerize may be a requirement for Golgi retention. galactosyltransferase Golgi retention glycosyltransferase protein sorting     

Formation,collective motion,and merging of macroscopic bacterial aggregates

Chemotactic bacteria form emergent spatial patterns of variable cell density within cultures that are initially spatially uniform. These patterns are the result of chemical gradients that are created from the directed movement and metabolic activity of billions of cells. A recent study on pattern formation in wild bacterial isolates has revealed unique collective behaviors of the bacteria Enterobacter cloacae. As in other bacterial species, Enterobacter cloacae form macroscopic aggregates. Once formed, these bacterial clusters can migrate several millimeters, sometimes resulting in the merging of two or more clusters. To better understand these phenomena, we examine the formation and dynamics of thousands of bacterial clusters that form within a 22 cm square culture dish filled with soft agar over two days. At the macroscale, the aggregates display spatial order at short length scales, and the migration of cell clusters is superdiffusive, with a merging acceleration that is correlated with aggregate size. At the microscale, aggregates are composed of immotile cells surrounded by low density regions of motile cells. The collective movement of the aggregates is the result of an asymmetric flux of bacteria at the boundary. An agent-based model is developed to examine how these phenomena are the result of both chemotactic movement and a change in motility at high cell density. These results identify and characterize a new mechanism for collective bacterial motility driven by a transient, density-dependent change in motility.     

Measurement of fresh and dry densities of suspended plant cells and estimation of their water content

A new method that considers the osmotic pressure of a culture broth for measurement of fresh cell density was developed. The water content of suspended plant cells was calculated using the value of the density obtained by the method. In the method, the optical density (O.D.) of cells and cell aggregates in a sedimentation equilibrium state in various solutions of known density and equal osmotic pressure to that of the culture broth was measured. The fresh cell density and density distribution of heterogeneous cell aggregates could be measured quantitatively. It was found that the fresh cell density of Catharanthus roseus (a dicotyledonous plant) had a relatively narrow distribution (1.010-1.028 g/cm³) with light cell aggregates; however, Oryza sativa (a monocotyledonous plant) had a wide distribution (1.030-1.064 g/cm³) with relatively heavy cell aggregates. In both cell lines, the distribution of fresh cell density at the logarithmic growth phase was more localized in the heavier density area compared with that at the stationary phase, and the small cell aggregates group had a heavier density distribution than the large cell aggregates group. The dry cell density was measured by a pycnometer method designed for plant cells using tridecane as immersion liquid. The water contents [% (v/v)] of C. roseus (92.2% at 7 d and 95.0% at 12 d) and O. sativa (82.6% at 7 d and 89.8% at 12 d) were calculated by using the values of both the fresh cell density and the dry cell density. The maximum cell concentration in suspension culture was calculated from the value of the solid content of cells on the assumption that the volume of water existing in the spaces among cells is half the total volume of the culture vessel. The result showed that the maximum cell concentration in a suspension culture of C. roseus was about half that of the O. sativa culture.