Noise-Induced Coherence in Multicellular Circadian Clocks

In higher organisms, circadian rhythms are generated by a multicellular genetic clock that is entrained very efficiently to the 24-h light-dark cycle. Most studies done so far of these circadian oscillators have considered a perfectly periodic driving by light, in the form of either a square wave or a sinusoidal modulation. However, in natural conditions, organisms are subject to nonnegligible fluctuations in the light level all through the daily cycle. In this article, we investigate how the interplay between light fluctuations and intercellular coupling affects the dynamics of the collective rhythm in a large ensemble of nonidentical, globally coupled cellular clocks modeled as Goodwin oscillators. On the basis of experimental considerations, we assume an inverse dependence of the cell-cell coupling strength on the light intensity, in such a way that the larger the light intensity, the weaker the coupling. Our results show a noise-induced rhythm generation for constant light intensities at which the clock is arrhythmic in the noise-free case. Importantly, the rhythm shows a resonancelike phenomenon as a function of the noise intensity. Such improved coherence can be only observed at the level of the overt rhythm and not at the level of the individual oscillators, thus suggesting a cooperative effect of noise, coupling, and the emerging synchronization between the oscillators.     

Multicellular Organization in a Degradative Biofilm Community

Diclofop methyl, a commercial herbicide, was used as the sole carbon source to cultivate diclofop-degrading biofilms in continuous-flow slide culture. The biofilms were analyzed by using scanning confocal laser microscopy and image analysis. Spatial relationships among members of the community were distinctive to diclofop-grown biofilms. These relationships did not develop when the biofilms were grown on more labile substrates but were conserved when the biofilms were cultivated with other chlorinated ring compounds. The structures included conical bacterial consortia rising to 30 μm above the surrounding biofilm, grape-like clusters of cocci embedded in a matrix of perpendicularly oriented bacilli, and other highly specific patterns of intra- and intergeneric cellular coaggregation and growth. These unique consortial relationships indicated that syntrophic interactions may be necessary for optimal degradation of diclofop methyl and other chlorinated ring compounds.     

A heterogeneous in vitro three dimensional model of tumour-stroma interactions regulating sprouting angiogenesis

Angiogenesis, the formation of new blood vessels, is an essential process for tumour progression and is an area of significant therapeutic interest. Different in vitro systems and more complex in vivo systems have been described for the study of tumour angiogenesis. However, there are few human 3D in vitro systems described to date which mimic the cellular heterogeneity and complexity of angiogenesis within the tumour microenvironment. In this study we describe the Minitumour model--a 3 dimensional human spheroid-based system consisting of endothelial cells and fibroblasts in co-culture with the breast cancer cell line MDA-MB-231, for the study of tumour angiogenesis in vitro. After implantation in collagen-I gels, Minitumour spheroids form quantifiable endothelial capillary-like structures. The endothelial cell pre-capillary sprouts are supported by the fibroblasts, which act as mural cells, and their growth is increased by the presence of cancer cells. Characterisation of the Minitumour model using small molecule inhibitors and inhibitory antibodies show that endothelial sprout formation is dependent on growth factors and cytokines known to be important for tumour angiogenesis. The model also shows a response to anti-angiogenic agents similar to previously described in vivo data. We demonstrate that independent manipulation of the different cell types is possible, using common molecular techniques, before incorporation into the model. This aspect of Minitumour spheroid analysis makes this model ideal for high content studies of gene function in individual cell types, allowing for the dissection of their roles in cell-cell interactions. Finally, using this technique, we were able to show the requirement of the metalloproteinase MT1-MMP in endothelial cells and fibroblasts, but not cancer cells, for sprouting angiogenesis.     

Multicellular Stalk-Like Structures in Saccharomyces cerevisiae

Stalk formation is a novel pattern of multicellular organization. Yeast cells which survive UV irradiation form colonies that grow vertically to form very long (0.5 to 3.0 cm) and thin (0.5 to 4 mm in diameter) multicellular structures. We describe the conditions required to obtain these stalk-like structures reproducibly in large numbers. Yeast mutants, mutated for control of cell polarity, developmental processes, UV response, and signal transduction cascades were tested and found capable of forming stalk-like structures. We suggest a model that explains the mechanism of stalk formation by mechanical environmental forces. We show that other microorganisms (Candida albicans, Schizosaccharomyces pombe, and Escherichia coli) also form stalks, suggesting that the ability to produce stalks may be a general property of microorganisms. Diploid yeast stalks sporulate at an elevated frequency, raising the possibility that the physiological role of stalks might be disseminating spores.     

Protein A-Mediated Multicellular Behavior in Staphylococcus aureus

The capacity of Staphylococcus aureus to form biofilms on host tissues and implanted medical devices is one of the major virulence traits underlying persistent and chronic infections. The matrix in which S. aureus cells are encased in a biofilm often consists of the polysaccharide intercellular adhesin (PIA) or poly-N-acetyl glucosamine (PNAG). However, surface proteins capable of promoting biofilm development in the absence of PIA/PNAG exopolysaccharide have been described. Here, we used two-dimensional nano-liquid chromatography and mass spectrometry to investigate the composition of a proteinaceous biofilm matrix and identified protein A (spa) as an essential component of the biofilm; protein A induced bacterial aggregation in liquid medium and biofilm formation under standing and flow conditions. Exogenous addition of synthetic protein A or supernatants containing secreted protein A to growth media induced biofilm development, indicating that protein A can promote biofilm development without being covalently anchored to the cell wall. Protein A-mediated biofilm formation was completely inhibited in a dose-dependent manner by addition of serum, purified immunoglobulin G, or anti-protein A-specific antibodies. A murine model of subcutaneous catheter infection unveiled a significant role for protein A in the development of biofilm-associated infections, as the amount of protein A-deficient bacteria recovered from the catheter was significantly lower than that of wild-type bacteria when both strains were used to coinfect the implanted medical device. Our results suggest a novel role for protein A complementary to its known capacity to interact with multiple immunologically important eukaryotic receptors.Staphylococcus aureus is a gram-positive bacterium that lives as part of the normal microflora on the skin and mucous membranes of humans and animals. If S. aureus passes through the epithelial barrier and reaches internal organs, it can cause a variety of diseases, ranging from minor skin infections, such as furuncles or boils, to severe infections, such as bacteremia, pneumonia, osteomyelitis, or endocarditis. Despite the progress with antibiotics in the treatment of bacterial infections over the last 2 decades, the number of infections due to S. aureus has increased (11, 30). The infection rate has been correlated with an increase in the use of prosthetic and indwelling devices in modern medical practices (24, 26). S. aureus, as well as other coagulase-negative staphylococci, displays a strong capacity to irreversibly attach to the surface of implanted medical devices and forms multilayered communities of bacteria, known as biofilms, that grow embedded in a self-produced extracellular matrix (23). The biofilm formation process occurs in two steps: first, bacterial cells irreversibly attach to a surface, and second, they interact with each other and accumulate in multilayered cell clusters embedded in a self-produced extracellular matrix. Primary attachment is mediated by physico-chemical cell surface properties as well as specific factors that mediate the attachment to the host-derived extracellular matrix components that rapidly coat the biomaterial following insertion into the patient. Numerous proteins from the MSCRAMMs family (microbial surface components recognizing adhesive matrix molecules) are involved in the first step of S. aureus biofilm formation, such as clumping factors ClfA (37) and ClfB (41) and fibrinogen and fibronectin binding proteins (FnBPA and FnBPB) (25, 31). Once bacteria accumulate in multilayered cell clusters, most have no direct contact with the surface, and thus cell-to-cell interactions become essential for biofilm development and maintenance. An extracellular polysaccharide intercellular adhesin (PIA, or PNAG), produced by icaADBC operon-encoded enzymes, is currently the best-characterized element mediating intercellular interactions in vitro (8, 23, 34, 35, 38). Alternatively, a number of surface proteins can replace PIA/PNAG exopolysaccharide in promoting intercellular adhesion and biofilm development, including the surface protein Bap (9). All the tested staphylococcal isolates harboring the bap gene were shown to be strong biofilm producers, and inactivation of the icaADBC operon in bap-positive strains had no effect on in vitro biofilm formation (57). Remarkably, proteins homologous to Bap are involved in the biofilm formation process in diverse bacterial species (33). A second surface protein, SasG, as well as its homologous protein in Staphylococcus epidermidis, Aap, also mediates intercellular interactions and biofilm development in the absence of the ica operon (7, 51). More recently, two independent laboratories have shown that fibronectin binding proteins A and B (FnBPA and FnBPB) induce biofilm development of clinical isolates of S. aureus (45, 55). Finally, there is growing evidence that extracellular DNA, despite not being sufficient to replace PIA/PNAG exopolysaccharide, is an important S. aureus biofilm matrix component (50).During the course of a systematic mutagenesis study of the 17 two-component systems of S. aureus that aimed to identify biofilm-negative regulators, we found that S. aureus agr arlRS double mutants developed an alternative, ica-independent biofilm in a chemically defined medium, Hussain-Hastings-White (HHW) medium (56). This study focused on the identification of the proteinaceous compound responsible for the biofilm developed by S. aureus agr arlRS mutants. Here, we show that S. aureus protein A is responsible for the aggregative phenotype and capacity for biofilm formation displayed by this strain. Furthermore, overproduction of protein A in wild-type S. aureus strains or addition of soluble protein A to bacterial growth medium induced aggregation and biofilm development, suggesting that protein A does not need to be covalently linked to the cell wall to promote multicellular behavior. Moreover, deletion of the spa gene significantly decreased the capacity of S. aureus to colonize subcutaneously implanted catheters. Our findings support a novel role for protein A in promoting multicellular behavior and suggest that protein A-mediated biofilm development may have a critical function during the infection process of S. aureus.     

Expression of decorin by sprouting bovine aortic endothelial cells exhibiting angiogenesis in vitro.

In our recent studies, we have demonstrated that monolayer cultures of bovine aortic endothelial (BAE) cells that do not express type I collagen also fail to express and synthesize decorin, a small chondroitin/dermatan sulfate proteoglycan that interacts with type I collagen and regulates collagen fibrillogenesis in vitro. However, BAE cells exhibiting a spontaneous sprouting phenotype and a predisposition toward the formation of cords and tube-like structures (an in vitro model for angiogenesis) initiate the synthesis of type I collagen during their morphological transition from a polygonal monolayer to an angiogenic phenotype. In the present study, we examined whether BAE cells also initiate the synthesis of the proteoglycan decorin during this morphological transition. We show by Northern blot analysis and by immunochemical methods that BAE cell cultures containing sprouting cells and cords, but not monolayer cultures of these cells, express and synthesize decorin (M(r) approximately 100,000). We also show that type I collagen expression by BAE cell cultures is initiated concomitantly. However, the localization of decorin and type I collagen in cord and tube-forming BAE cell cultures is not completely identical. Type I collagen is detected only in sprouting BAE cells and in endothelial cords, whereas decorin is also apparent in BAE cells surrounding the cords and tubes. Our results indicate that the synthesis of decorin as well as type I collagen is associated with endothelial cord and tube formation in vitro.     

Influence of exogenous gangliosides on the three-dimensional sprouting of goldfish retinal explants in vitro

To investigate the 3-dimensional outgrowth of ganglion cells of normal and regenerating goldfish retina, retinal explants were cultured in a serum free 3-D fibrin matrix. Daily applications of exogenous gangliosides (GM1), injected either intraocularly (i.o.) or intraperitoneally (i.p.) had no significant effect on the sprouting activity of retinal explants prepared from lesion-activated goldfish whose corresponding optic nerve had been transected. However, in normal, unlesioned animals, a local i.o. injection of GM1 or mixed gangliosides led to a significant enhancement of the basal retinal sprouting activity as compared to controls, which were injected with a 0.9% NaCl solution. This ganglioside related stimulation was maximal after i.o. injection of low concentrations (3 g/eye), didn't occur at high concentration (30 g/eye) and was similar to the response obtained after i.o. injection of NGF or insulin. I.o. injected phospholipids had no or a slightly inhibitory effect on the sprouting activity as compared to NaCl controls. Daily in vivo i.o. injections of the monoclonal antibody Q211, specifically recognizing c-pathway polysialogangliosides, led to a dose dependent inhibition of the in vitro sprouting of goldfish retina explants. In summary, these data suggest an involvement of gangliosides in the complex process of induction of neuronal sprouting.Abbreviations used: Ganglioside nomenclature follows the IUPACIUB recommendations, 1977. Lipids, 12:455–468     

The Simplest Integrated Multicellular Organism Unveiled

Volvocine green algae represent the “evolutionary time machine” model lineage for studying multicellularity, because they encompass the whole range of evolutionary transition of multicellularity from unicellular Chlamydomonas to >500-celled Volvox. Multicellular volvocalean species including Gonium pectorale and Volvox carteri generally have several common morphological features to survive as integrated multicellular organisms such as “rotational asymmetry of cells” so that the cells become components of the individual and “cytoplasmic bridges between protoplasts in developing embryos” to maintain the species-specific form of the multicellular individual before secretion of new extracellular matrix (ECM). However, these morphological features have not been studied in the four-celled colonial volvocine species Tetrabaena socialis that is positioned in the most basal lineage within the colonial or multicellular volvocine greens. Here we established synchronous cultures of T. socialis and carried out immunofluorescence microscopic and ultrastructural observations to elucidate these two morphological attributes. Based on immunofluorescence microscopy, four cells of the mature T. socialis colony were identical in morphology but had rotational asymmetry in arrangement of microtubular rootlets and separation of basal bodies like G. pectorale and V. carteri. Ultrastructural observations clearly confirmed the presence of cytoplasmic bridges between protoplasts in developing embryos of T. socialis even after the formation of new flagella in each daughter protoplast within the parental ECM. Therefore, these two morphological attributes might have evolved in the common four-celled ancestor of the colonial volvocine algae and contributed to the further increase in cell number and complexity of the multicellular individuals of this model lineage. T. socialis is one of the simplest integrated multicellular organisms in which four identical cells constitute the individual.     

Multicellular cuddling in a stem cell niche

Haematopoietic stem and progenitor cells (HSPCs) can self-renew and differentiate in any blood cell type throughout life and thereby sustain the entire blood system. To do so, HSPCs had been shown to seed, in a multi-step process, intermediate haematopoietic niches before colonizing the adult marrow. While HSPC birth had been thoroughly characterized in the past, both in mammals and in zebrafish, how perivascular niches could host HSPCs and sustain their expansion was poorly understood. In an article published in the last issue of Cell, Tamplin et al.¹ elegantly exploited the many advantages provided by the zebrafish embryo to describe how endothelium remodeling in the perivascular niche, referred to as “cuddling,” favors HSPCs colonization and expansion.     

Multicellular dynamics during epithelial elongation

The reorganization of multicellular populations to produce an elongated tissue structure is a conserved mechanism for shaping the body axis and several organ systems. In the Drosophila germband epithelium, this process is accompanied by the formation of a planar polarized network of junctional and cytoskeletal proteins in response to striped patterns of gene expression. Actomyosin cables and adherens junctions are dynamically remodeled during intercalation, providing the basis for polarized cell behavior. Quantitative analysis of cell behavior in living embryos reveals unexpected cell population dynamics that include the formation of multicellular rosette structures as well as local neighbor exchange.     

Evolution of the Multicellular Animals

SYNOPSIS. Molecular sequence analysis is providing new insightsinto the study of metazoan relationships. The use of ribosomalRNA sequences is revising many of the metazoan phylogenies thathave been established traditionally with anatomical and embryologicaldata. Four new findings that seem to be well supported by moleculardata, both from the authors' laboratories and from others, aredescribed and discussed. First, the arthropods are members ofa deep primary clade within the protostomes and are not thesister taxa of either the annelids or the mollusks. Second,the lophophorate animals are clearly protostomes and are containedwithin a lophotrochozoan superclade including the mollusks,annelids, and many other phyla. Third, the arthropods togetherwith all other molting animals comprise a second monophyleticsuperclade within the protostomes, the ecdysozoa. Fourth, theplatyhelminthes are contained within the lophotrochozoan superclade.     

Erythropoietin has an antiapoptotic effect after myocardial infarction and stimulates in vitro aortic ring sprouting

Aims were to explore if darbepoietin-α in mouse can induce angiogenesis and if moderate doses after myocardial infarction stimulates periinfarct capillary and arteriolar densities, cell proliferation, and apoptosis. Myocardial infarction was induced by ligation of LAD. Mouse aortic rings (0.8 mm) were cultured in matrigel and the angiogenic sprouting was studied after addition of darbepoietin-α with and without VEGF-165. After 12 days the hemoglobin concentration was 25% higher in the darbepoietin-α treated mice than in the control group. No difference in capillary densities in the periinfarct or noninfarcted areas was seen with darbepoietin-α. Cell proliferation was about 10 times higher in the periinfarct area than in the noninfarcted wall. Darbepoietin-α treatment led to a decrease of cell proliferation (BrdU, (p < 0.02)) and apoptosis (TUNEL, p < 0.005) with about 30% in the periinfarct area. Darbepoietin-α and VEGF-165 both independently induced sprouting from aortic rings. The results suggest that darbepoietin-α can induce angiogenesis but that moderate doses after myocardial infarction are not angiogenic but antiapoptotic.     

Multicellular development and gliding motility in Myxococcus xanthus

A great deal of progress has been made in the studies of fruiting body development and social gliding in Myxocococcus xanthus in the past few years. This includes identification of the bone fide C-signal and a receptor for type IV pili, and development of a model for the mechanism of adventurous gliding motility. It is anticipated that the next few years will see even more progress as the complete genome sequence is available and genomic and proteomic tools are applied to the study of M. xanthus social behaviors.     

Integration of Single and Multicellular Wound Responses

Single cells and multicellular tissues rapidly heal wounds. These processes are considered distinct, but one mode of healing—Rho GTPase-dependent formation and closure of a purse string of actin filaments (F-actin) and myosin-2 around wounds—occurs in single cells [1] and [2] and in epithelia [3], [4], [5], [6], [7], [8], [9] and [10]. Here, we show that wounding of one cell in Xenopus embryos elicits Rho GTPase activation around the wound and at the nearest cell-cell junctions in the neighbor cells. F-actin and myosin-2 accumulate at the junctions and around the wound itself, and as the resultant actomyosin array closes over the wound site, junctional F-actin and myosin-2 become mechanically integrated with the actin and myosin-2 around the wound, forming a hybrid purse string. When cells are ablated rather than wounded, Rho GTPase activation and F-actin accumulation occur at cell-cell junctions surrounding the ablated cell, and the purse string closes the hole in the epithelium. Elevation of intracellular free calcium, an essential upstream signal for the single-cell wound response [2] and [11], also occurs at the cell-cell contacts and in neighbor cells. Thus, the single and multicellular purse string wound responses represent points on a signaling and mechanical continuum that are integrated by cell-cell junctions.