Behavior ofPseudomonas fluorescens within the hydrodynamic boundary layers of surface microenvironments

Phase, darkfield, and computer-enhanced microscopy were used to observe the surface microenvironment of flow cells during bacterial colonization. Microbial behavior was consistent with the assumptions used previously to derive surface colonization kinetics and to calculate surface growth and attachment rates from cell number and distribution. Surface microcolonies consisted of closely packed cells. Each colony contained 2ⁿ cells, where n is the number of cell divisions following attachment. Initially, cells were freely motile while attached, performing circular looping movements within the plane of the solid-liquid interface. Subsequently, cells attached apically, maintained a fixed position on the surface, and rotated. This type of attachment was reversible and did not necessarily lead to the formation of microcolonies. Cells became irreversibly attached by progressing from apical to longitudinal attachment. Longitudinally attached cells increased in length, then divided, separated, moved apart laterally, and slid next to one another. This resulted in tight cell packing and permitted simultaneous growth and adherence. After approximately 4 generations, individual cells emigrated from developing microcolonies to recolonize the surface at new locations. Surface colonization byPseudomonas fluorescens can thus be subdivided into the following sequential colonization phases: motile attachment phase, reversible attachment phase, irreversible attachment phase, growth phase, and recolonization phase.     

Scanning electron microscopy and epifluorescence investigation of bacterial colonization of marine sand sediments

Scanning electron microscopy (SEM) was employed for the investigation of microorganisms living in marine sand sediments. Epifluorescence, as well as sediment analyses, gave further data on the parameters of the sediment samples.SEM revealed a correlation between the site and density of bacterial colonization and the microtopography of the individual sand grains.Sand grains with a medium roundness showed the greatest density of bacterial colonization. Protected surface sites were favored in the colonization process. The mode of bacterial attachment varied; mostly the barren sand grain surface was colonized. However, bacteria were also observed close to or within detritus or attached to diatoms. Many of the attaching bacteria observed were found to produce polymer strands.In some cases special structures were discovered which could serve bacterial attachment. Entire colonies attached by means of polymer nets, and disc-shaped bacteria were observed.     

The colony architectonics in Bacillus subtilis 2335

Colonies grown from vegetative B. subtilis 2335 cells had a standard structure, with bacillar cells occupying the whole colony volume. At the same time, the colonies of this bacterium grown from germinated spores had an abnormal structure characterized by the location of cells in a surface layer 100-200 microns thick at the colony boundary with the air. The glycocalyx of the colonies grown from spores was characterized by a wetting angle theta e of 120 degrees-160 degrees, whereas that of the colonies grown from vegetative cells had an angle theta e as low as 5 degrees-30 degrees. It is suggested that spores and vegetative cells follow different strategies of substrate colonization and that the architectonics of bacterial colonies is determined by the physicochemical properties of the glycocalyx.     

球形棕囊藻的生长、囊体形态以及囊体细胞的分布

球形棕囊藻(Phaeocystis globosa)是中国近海海区常见有害藻华原因种, 其异型生活史中包含单细胞和球形囊体两种形态。游离单细胞直径一般为几微米, 囊体最大直径可达3 cm, 巨大的体积可能导致囊体具有特殊的结构和细胞分布。以球形棕囊藻汕头株为研究对象, 测定了囊体直径、囊体细胞丰度和游离单细胞丰度, 并探讨球形棕囊藻囊体形态与细胞分布的关系。研究结果表明, 囊体形态在其异型生活史中占优势, 囊体对生物量的贡献介于38%–95%之间, 在对数生长期的后期和稳定期, 囊体细胞与单细胞相比占绝对优势。囊体细胞数量与囊体直径的对数呈线性相关, 回归线斜率为1.34, 该值显著低于世界海区其它球形棕囊藻株系的研究结果, 表明汕头株单位囊体表面上分布的细胞数更少。中国海区的球形棕囊藻囊体结构和细胞分布与其它株系不同, 在爆发球形棕囊藻的海区, 巨大的囊体能够有效地抵御摄食, 可能对区域海洋食物链结构和功能有重要影响。     

Kinetic model of Proteus mirabilis swarm colony development

 Proteus mirabilis colonies display striking symmetry and periodicity. Based on experimental observations of cellular differentiation and group motility, a kinetic model has been developed to describe the swarmer cell differentiation-dedifferentiation cycle and the spatial evolution of swimmer and swarmer cells during Proteus mirabilis swarm colony development. A key element of the model is the age dependence of swarmer cell behaviour, in particular specifying a minimal age for motility and maximum age for septation and dedifferentiation to swimmer cells. Density thresholds for collective motility by mature swarmer cells serve to synchronize the movements of distinct swarmer cell groups and thus help provide temporal coherence to colony expansion cycles. Numerical computations show that the model fits experimental data by generating a complete swarming plus consolidation cycle period that is robust to changes in parameters which affect other aspects of swarmer cell migration and colony development. The kinetic equations underlying this model provide a different mathematical basis for a temporal oscillator from reaction-diffusion partial differential equations. The modelling shows that Proteus colony geometries arise as a consequence of macroscopic rules governing collective motility. Thus, in this case, pattern formation results from the operation of an adaptive bacterial system for spreading on solid substrates, not as an independent biological function. Kinetic models similar to this one may be applicable to periodic phenomena displayed by other biological systems with differentiated components of defined lifetimes. Received 3 July 1996; received in revised form 9 December 1996     

Living on a surface: swarming and biofilm formation

Swarming is the fastest known bacterial mode of surface translocation and enables the rapid colonization of a nutrient-rich environment and host tissues. This complex multicellular behavior requires the integration of chemical and physical signals, which leads to the physiological and morphological differentiation of the bacteria into swarmer cells. Here, we provide a review of recent advances in the study of the regulatory pathways that lead to swarming behavior of different model bacteria. It has now become clear that many of these pathways also affect the formation of biofilms, surface-attached bacterial colonies. Decision-making between rapidly colonizing a surface and biofilm formation is central to bacterial survival among competitors. In the second part of this article, we review recent developments in the understanding of the transition between motile and sessile lifestyles of bacteria.     

Characteristics and differential T-cell dependency of human B-cell colony precursors

Studies were performed to characterize the human peripheral blood non-T cells forming colonies in semisolid cultures stimulated with Staph protein A (SpA). Negative selection experiments revealed that colony precursors largely consisted of cells bearing Fc receptors, complement receptors (CR), surface immunoglobulin (sIg), and Ia-like antigens. Most colony precursors expressed sIgM and sIgD, but not sIgG. Also, colony-forming cells were shown to be distinct from non-T cells proliferating in SpA-stimulated liquid cultures as evidenced by the greater sensitivity of colony precursors to anti-K,λ, or -Ia plus complement depletion. Two distinct categories of colony-forming cells could be distinguished by the expression of CR. CR-positive cells were responsible for greater than 85% of the colonies formed in the absence of optimal T cell numbers. Although under identical conditions CR^? cells demonstrated minimal colony growth, the addition of optimal T cell numbers significantly augmented colony responses. Thus, colony precursors express surface markers characteristic of B cells relatively advanced in the developmental pathway. However, less advanced cells are capable of colony growth in the presence of optimal T cell numbers.     

A human GM-CSF receptor expressed in transgenic mice stimulates proliferation and differentiation of hemopoietic progenitors to all lineages in response to human GM-CSF.

Granulocyte-macrophage colony-stimulating factor (GM-CSF) mainly stimulates proliferation and maturation of myeloid progenitor cells. Although the signal transduction pathways triggered by GM-CSF receptor (GMR) have been extensively characterized, the roles of GMR signals in differentiation have remained to be elucidated. To examine the relationship between receptor expression and differentiation of hemopoietic cells, we used transgenic mice (Tg-mice) that constitutively express human (h) GMR at almost all stages of hemopoietic cell development. Proliferation and differentiation of hemopoietic progenitors in bone marrow cells from these Tg-mice were analyzed by methylcellulose colony formation assay. High affinity GMR interacts with GM-CSF in a species-specific manner, therefore one can analyze the effects of hGMR signals on differentiation of mouse hemopoietic progenitors using hGM-CSF. Although mouse (m) GM-CSF yielded only GM colonies, hGM-CSF supported various types of colonies including GM, eosinophil, mast cell, erythrocyte, megakaryocyte, blast cell, and mixed hemopoietic colonies. Thus, the effects of hGM-CSF on colony formation more closely resembled mIL-3 than those of mGM-CSF. In addition, hGM-CSF generated a much larger number of blast cell colonies and mixed cell colonies than did mIL-3. hGM-CSF also generated erythrocyte colonies in the absence of erythropoietin. Therefore, GM-CSF apparently has the capacity to promote growth of cells of almost all hemopoietic cell lineages, if functional hGMR is present.     

Development of the stages of the cycle in mouse seminiferous epithelium after transplantation of green fluorescent protein-labeled spermatogonial stem cells

To study the mechanism of male germ cell differentiation, testicular germ cells carrying green fluorescent protein (GFP) as a transgene marker were transplanted into infertile mouse testis. Fluorescence-positive seminiferous tubule segments colonized with GFP-labeled donor germ cells were isolated and measured, and differentiated germ cells were analyzed in living squashed preparations. Cell associations in normal stages of the seminiferous epithelial cycle were also studied and used as a reference. Two months after transplantation, the average length of the colonies was 1.3 mm. The cell associations of transplanted colonies were consistent with those of normal stages of the cycle. However, stages of the cycle were not necessarily identical in different colonies. Three months after transplantation, the average length of transplanted colonies was 3.4 mm, and the cell association in every portion of a colony was similar to that of the corresponding stage of the cycle. Even in long fused colonies made by transplantation of a higher concentration of male germ cells, the cell association patterns in various regions of a single colony were similar and consistent with those of some of the normal stages of the cycle. Development of different stages inside the colony was observed by 6 mo after transplantation. These results indicate that the commencement of spermatogonial stem cell differentiation occurs randomly to develop different stages of the cycle in different colonies. Then, each colony shows one single stage of the cycle for a long time, even if it becomes a very large colony or fuses with other colonies. These observations indicate the existence of some kind of synchronization mechanism. By 6 mo, however, normal development of the stages of the cycle appeared in seminiferous tubules.     

The significances of bacterial colony patterns

Bacteria do many things as organized populations. We have recently learned much about the molecular basis of intercellular communication among prokaryotes. Colonies display bacterial capacities for multicellular coordination which can be useful in nature where bacteria predominantly grow as films, chains, mats and colonies. E. coli colonies are organized into differentiated non-clonal populations and undergo complex morphogenesis. Multicellularity regulates many aspects of bacterial physiology, including DNA rearrangement systems. In some bacterial species, colony development involves swarming (active migration of cell groups). Swarm colony development displays precise geometrical controls and periodic phenomena. Motile E. coli cells in semi-solid media form organized patterns due to chemotactic autoaggregation. On poor media, B. subtilis forms branched colonies using group motility and longrange chemical signalling. The significances of bacterial colony patterns thus reside in a deeper understanding of prokaryotic biology and evolution and in experimental systems for studying self-organization and morphogenesis.     

Microbial expansion–collision dynamics promote cooperation and coexistence on surfaces

Microbes colonizing a surface often experience colony growth dynamics characterized by an initial phase of spatial clonal expansion followed by collision between neighboring colonies to form potentially genetically heterogeneous boundaries. For species with life cycles consisting of repeated surface colonization and dispersal, these spatially explicit “expansion‐collision dynamics” generate periodic transitions between two distinct selective regimes, “expansion competition” and “boundary competition,” each one favoring a different growth strategy. We hypothesized that this dynamic could promote stable coexistence of expansion‐ and boundary‐competition specialists by generating time‐varying, negative frequency‐dependent selection that insulates both types from extinction. We tested this experimentally in budding yeast by competing an exoenzyme secreting “cooperator” strain (expansion–competition specialists) against nonsecreting “defectors” (boundary–competition specialists). As predicted, we observed cooperator–defector coexistence or cooperator dominance with expansion–collision dynamics, but only defector dominance otherwise. Also as predicted, the steady‐state frequency of cooperators was determined by colonization density (the average initial cell–cell distance) and cost of cooperation. Lattice‐based spatial simulations give good qualitative agreement with experiments, supporting our hypothesis that expansion–collision dynamics with costly public goods production is sufficient to generate stable cooperator–defector coexistence. This mechanism may be important for maintaining public–goods cooperation and conflict in microbial pioneer species living on surfaces.     

Zur Frage der Anheftung des Pollens an blütenbesuchende Insekten mittels Pollenkitt und Viscinfäden

The attachment of pollen grains among themselves, on the loculus wall, and on flower-visiting insects is quite different in entomophilous angiosperms using pollenkitt and those using viscin threads as pollen adhesives. The sticky and viscous pollenkitt makes the pollen grains adhere, while the thin, non-elastic, non-sticky, and flexible viscin fibers fasten them like ropes on insect hairs or bristles. Nectar vomited by honey-bees, sticky stigma secretions or other additional sticky substances further improve the pollen adherence to flower-visiting insects.

Herrn Univ.-Prof. Dr.Walter Leinfellner zum 70. Geburtstag gewidmet.     

Neisseria gonorrhoeae subverts formin-dependent actin polymerization to colonize human macrophages

Dynamic reorganization of the actin cytoskeleton dictates plasma membrane morphogenesis and is frequently subverted by bacterial pathogens for entry and colonization of host cells. The human-adapted bacterial pathogen Neisseria gonorrhoeae can colonize and replicate when cultured with human macrophages, however the basic understanding of how this process occurs is incomplete. N. gonorrhoeae is the etiological agent of the sexually transmitted disease gonorrhea and tissue resident macrophages are present in the urogenital mucosa, which is colonized by the bacteria. We uncovered that when gonococci colonize macrophages, they can establish an intracellular or a cell surface-associated niche that support bacterial replication independently. Unlike other intracellular bacterial pathogens, which enter host cells as single bacterium, establish an intracellular niche and then replicate, gonococci invade human macrophages as a colony. Individual diplococci are rapidly phagocytosed by macrophages and transported to lysosomes for degradation. However, we found that surface-associated gonococcal colonies of various sizes can invade macrophages by triggering actin skeleton rearrangement resulting in plasma membrane invaginations that slowly engulf the colony. The resulting intracellular membrane-bound organelle supports robust bacterial replication. The gonococci-occupied vacuoles evaded fusion with the endosomal compartment and were enveloped by a network of actin filaments. We demonstrate that gonococcal colonies invade macrophages via a process mechanistically distinct from phagocytosis that is regulated by the actin nucleating factor FMNL3 and is independent of the Arp2/3 complex. Our work provides insights into the gonococci life-cycle in association with human macrophages and defines key host determinants for macrophage colonization.     

Cryopreservation of adherent human embryonic stem cells

Standard human embryonic stem (HES) cell cryopreservation methodologies, including slow freezing and vitrification of colonies in suspension, are plagued by poor viability and high differentiation rates upon recovery. To facilitate research studies and clinical applications of HES cells, we have developed a cryopreservation technique based on stabilizing HES colonies adherent to or embedded in a Matrigel matrix. This method increases cell viability by over an order of magnitude compared with cryopreservation in suspension and reduces differentiation. Loading adherent HES cells with the disaccharide trehalose prior to cryopreserving in a dimethylsulfoxide-containing cryoprotectant solution further improves cell viability under certain conditions. Our proposed approach has the potential to reduce the time required to amplify frozen stocks of HES cells, minimize risk of clonal selection during freeze-thaw cycles, and facilitate storage of HES cell clone libraries.     

Genetic diversity and genotypic differentiation between the sexes in swarm aggregations decrease inbreeding in the Formosan subterranean termite

The life of a colony of subterranean termites, such as Coptotermes formosanus Shiraki (Isoptera: Rhinotermitidae), has natural inbreeding and outbreeding cycles. Reproductives of mature colonies can be replaced by their offspring, which increases the degree of inbreeding in each generation. High degrees of inbreeding may lead to inbreeding depression. In this study we focused on mechanisms for inbreeding avoidance during swarming that do not require kin recognition. We investigated genetic differentiation between swarm aggregations (isolation by distance), genetic diversity within swarm aggregations (multiple colony origin) and genetic differentiation between sexes. Alates were collected from five swarm aggregations in New Orleans, La. The genetic make-up of each swarm aggregation was then described by microsatellite genotyping. Alates from the different swarm aggregations were genetically differentiated; however, no isolation by distance up to at least 1000 m was detected. The dispersal distance of alates was sufficient to guarantee mixing of an average of 13 colonies within swarm aggregations. On average, eleven percent of all possible pairs of alates in each swarm aggregation were putative full siblings. Genotypic frequencies differed significantly between males and females. This could not be explained by sex-biased dispersal. We hypothesize sex-biased investment at the colony level to account for this difference. Genetic differentiation between the sexes and dispersal distances sufficient to promote high genetic diversity within swarm aggregations each facilitate inbreeding avoidance. These observations are consistent with the results of previous studies demonstrating that the majority of simple family colonies in Louisiana populations are headed by unrelated and outbred pairs of reproductives. Received 11 August 2005; revised 5 December 2005; accepted 20 December 2005.     

The relationship between auto-agglutination, cell surface hydrophobicity and virulence of the fish pathogen Renibacterium salmoninarum

Abstract The cell surface hydrophobicity of Renibacterium salmoninarum strains was examined using a salt aggregation method. Those strains which were virulent in the test animal were sticky, auto-agglutinating and possessed a hydrophobic cell surface. Those strains with a low virulence were non-sticky, non-agglutinating and failed to aggregate in a high molar salt. Strains could not be distinguished using biochemical tests. There was no change in hydrophobicity following re-isolation of the bacteria from experimentally infected rainbow trout, Salmo gairdneri .     

Derivation of a growth rate equation describing microbial surface colonization

A surface growth rate equation is derived which describes simultaneous growth and attachment during microbial surface colonization. The equation simplifies determination of attachment and growth rate, and does not require a computer program for solution. This rate equation gives the specific growth rate (Μ) as a function of the number of cells on the surface (N), the incubation period (t), and the number of colonies (C_i) containing either one cell, two cells, four cells, etc, as shown below. $$\mu = \frac{{\ln (\frac{N}{{C_i }} + 1)}}{t}$$ The attachment rate (A) is given by the following relationship: $$A = \mu C_i $$ The proposed colonization kinetics are compared with exponential growth kinetics using 3-dimensional computer plots. Colonization kinetics diverged most from exponential kinetics when the growth rate was low or the attachment rate was high. Using these kinetics, it is possible to isolate the effects of growth and attachment on microbial surface colonization.     

Human B lymphocyte colony responses. I. General characteristics and modulation by monocytes

The present study investigated the ability of human B cell-enriched subpopulations to focally proliferate and form colonies in semisolid cultures after stimulation with staph protein A (SpA). After 6 days of incubation, cultures of B-enriched populations exhibited distinct colonies, the number being dependent on the concentration of SpA and the cell density. Optimal colony responses were 1.6 x 10(3) per 1 x 10(6) B lymphocytes, and greater than 83% of the colony-forming cells expressed surface immunoglobulin (sIg). The depletion of adherent monocytes from the B cell-enriched preparations decreased the colony responses approximately 3-fold compared with the nondepleted B cell populations. Adding optimal numbers of adherent monocytes to the monocyte-depleted B cells restored the colony responses; however, less augmentation was observed in single-layer co-cultures containing greater than optimal numbers of monocytes. Identical experiments in double-layer semisolid cultures revealed that relatively greater numbers of monocytes were required to enhance B cell colony responses. Thus, progressively higher ratios of monocytes to B cells resulted in increasing numbers of colonies and failed to demonstrate the diminished colony responses observed in the single-layer system. These studies demonstrate that human B cells form distinct colonies when activated by SpA and that normal adherent monocytes modulate the magnitude of colony responses. Although monocytes predominately enhance B cell clonal differentiation, the evidence presented also suggests that, to a lesser extent, soluble inhibitory materials are elaborated.