Kind Discrimination and Competitive Exclusion Mediated by Contact-Dependent Growth Inhibition Systems Shape Biofilm Community Structure

Contact-Dependent Growth Inhibition (CDI) is a phenomenon in which bacteria use the toxic C-terminus of a large exoprotein (called BcpA in Burkholderia species) to inhibit the growth of neighboring bacteria upon cell-cell contact. CDI systems are present in a wide range of Gram-negative proteobacteria and a hallmark feature is polymorphism amongst the exoprotein C-termini (BcpA-CT in Burkholderia) and amongst the small immunity proteins (BcpI) that protect against CDI in an allele-specific manner. In addition to CDI, the BcpAIOB proteins of Burkholderia thailandensis mediate biofilm formation, and they do so independent of BcpA-mediated interbacterial competition, suggesting a cooperative role for CDI system proteins in this process. CDI has previously only been demonstrated between CDI⁺ and CDI⁻ bacteria, leaving the roles of CDI system-mediated interbacterial competition and of CDI system diversity in nature unknown. We constructed B. thailandensis strains that differed only in the BcpA-CT and BcpI proteins they produced. When co-cultured on agar, these strains each participated in CDI and the outcome of the competition depended on both CDI system efficiency and relative bacterial numbers initially. Strains also participated in CDI during biofilm development, resulting in pillar structures that were composed of only a single BcpA-CT/BcpI type. Moreover, a strain producing BcpA-CT/BcpI proteins of one type was prevented from joining a pre-established biofilm community composed of bacteria producing BcpA-CT/BcpI proteins of a different type, unless it also produced the BcpI protein of the established strain. Bacteria can therefore use CDI systems for kind recognition and competitive exclusion of ‘non-self’ bacteria from a pre-established biofilm. Our data indicate that CDI systems function in both cooperative and competitive behaviors to build microbial communities that are composed of only bacteria that are related via their CDI system alleles.     

Plant regeneration through somatic embryogenesis in protoplast cultures of sandalwood (Santalum album L.)

Summary Protoplasts were isolated from embryogenic cell suspension cultures derived from proliferating shoot segments of a 20-year-old sandalwood tree (Santalum album Linn.). Under appropriate conditions, isolated protoplasts divided in liquid culture medium and produced embryogenic cell aggregates and globular embryos. Plating of cell aggregates on a fresh medium facilitated the differentiation of somatic emryos which further developed into plantlets.Abbreviations BAP 6-benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid - GA₃ Gibberellic acid - IAA indoleacetic acid - IBA indolebutrytic acid - MES 2-(N-morpholino)ethane sulfonic acid - MS Murashige and Skoog's medium as modified in the text     

Elongation of Confluent Endothelial Cells in Culture: The Importance of Fields of Force in the Associated Alterations of Their Cytoskeletal Structure

Studies using either animal models or in vitro flow systems have shown that the shape of large-vessel endothelial cells (ECs) was sensitive to the amplitude of the flow imposed on them. In order to better understand the morphological changes experienced by ECs when exposed to physical forces such as shear stress, the mechanical integrity of confluent bovine aortic ECs (BAECs) was anisotropically perturbed using the five following types of experiments: (i) slicing and partial scraping of BAEC monolayers; (ii) culture of BAECs on narrow strips of adhesive plastic; (iii) incubation of confluent BAECs with media containing low Ca²⁺ concentrations; (iv) culture of ECs on top of rectangular collagen gels; and (v) exposure of BAECs to laminar steady shear stress. In all five experimental systems, BAECs exhibited an elongated morphology and aligned their major axes in specific directions. In addition, a preferential alignment of actin microfilaments, vimentin intermediate filaments, and streaks of vinculin with the major axes of the cells often occurred concomitantly with BAEC elongation. In all five systems, the elongation of ECs was analyzed in terms of a mechanical deformation borne by the cytoskeleton, and possibly caused by anisotropic distribution of the forces experienced by the cell structure. In addition, the strain-stress and stiffness-stress relationships characterizing the elongation of BAECs exposed to steady flow were qualitatively similar to those computed for the uniaxial deformation of a spherical geodesic. Our findings suggest that the cytoskeleton of ECs plays an important role in the transduction of those forces which cause an elongation of ECs.     

THE EFFECT OF A HORN SNAIL ON ULVA EXPANSA (CHLOROPHYTA): CONSUMER OR FACILITATOR OF GROWTH?1

To determine whether California horn snails are more likely to be consumers or facilitators of Ulva expansa (Setch) S. & G. growth in estuaries, we conducted manipulative experiments that evaluated algal growth and the movement of N between the water column, algal tissue, and, in the second experiment, sediments. Algae grew poorly in the absence of sediments, drawing on their own sequestered N supplies (3.5% of dry weight reduced to <2%) and N released by snails and by depleting inorganic N in the water column. There was no evidence of consumption when snail densities ranged from 0 to 900.m^?2 (0, 3, 6, and 9 per aquarium), as algal growth was similar for all snail densities, and snail lengths did not increase during the 21–d experiment. when sediment was provided, N was depleted in the sediment and enhanced in the algal tissue. As in the first experiment, the water column was depleted of inorganic N and enriched with organic N, mostly in the dissolved form. Because both snails and macroalgae often dominate the shallow waters of southern California's lagoons and estuaries, our evidence that the snails are primarily facilitators of algal growth (via transfer of N from sediments to the water column) suggests that snails may play an important role in both food web and N dynamics.     

Subnormal norepinephrine release relates to presyncope in astronauts after spaceflight

Fritsch-Yelle, Janice M., Peggy A. Whitson, Roberta L. Bondar, and Troy E. Brown. Subnormal norepinephrine release relates to presyncope in astronauts after spaceflight.J. Appl. Physiol. 81(5):2134-2141, 1996.Postflight orthostatic intolerance isexperienced by virtually all astronauts but differs greatly in degreeof severity. We studied cardiovascular responses to upright posture in40 astronauts before and after spaceflights lasting up to 16 days. Weseparated individuals according to their ability to remain standingwithout assistance for 10 min on landing day. Astronauts who could notremain standing on landing day had significantly smaller increases inplasma norepinephrine levels with standing than did those who couldremain standing (105 ± 41 vs. 340 ± 62 pg/ml;P = 0.05). In addition, they hadsignificantly lower standing peripheral vascular resistance (23 ± 3 vs. 34 ± 3 mmHg ^· l^{1 ·} min;P = 0.02) and greater decreases insystolic (28 ± 4 vs. 11 ± 3 mmHg;P = 0.002) and diastolic (14 ± 7 vs. 3 ± 2 mmHg; P = 0.0003) pressures. The presyncopal group also hadsignificantly lower supine (16 ± 1 vs. 21 ± 2 mmHg ^· l^{1 ·} min;P = 0.04) and standing (23 ± 2 vs.32 ± 2 mmHg ^· l^{1 ·} min;P = 0.038) vascular resistance, supine(66 ± 2 vs. 73 ± 2 mmHg; P = 0.008) and standing (69 ± 4 vs. 77 ± 2 mmHg;P = 0.007) diastolic pressure, andsupine (109 ± 3 vs. 114 ± 2 mmHg; P = 0.05) and standing (99 ± 4 vs. 108 ± 3 mmHg; P = 0.006) systolic pressures before flight. This is the first study toclearly document these differences among presyncopal and nonpresyncopalastronauts after spaceflight and also offer the possibility ofpreflight prediction of postflight susceptibility. These resultsclearly point to hypoadrenergic responsiveness, possibly centrallymediated, as a contributing factor in postflight orthostaticintolerance. They may provide insights into autonomic dysfunction inEarthbound patients.

     

EFFECTS OF AVIAN SEED DISPERSAL ON THE GENETIC STRUCTURE OF WHITEBARK PINE POPULATIONS

We used allozyme analysis to examine family structure, the spatial patterning of related individuals, in two populations of whitebark pine (Pinus albicaulis), a subalpine conifer that commonly displays a multistem form. The individual stems within clumps are genetically distinct individuals, having arisen from separate seeds. Individuals within a clump are genetically more similar than individuals in different clumps, but individuals in neighboring clumps do not appear to be more similar than individuals in distant clumps. This family structure appears to be a direct result of the seed-caching behavior of Clark's nutcrackers (Nucifraga columbiana), the primary dispersal agent for whitebark pine seeds.