Application of filamentous phages in environment: A tectonic shift in the science and practice of ecorestoration

Theories in soil biology, such as plant–microbe interactions and microbial cooperation and antagonism, have guided the practice of ecological restoration (ecorestoration). Below‐ground biodiversity (bacteria, fungi, invertebrates, etc.) influences the development of above‐ground biodiversity (vegetation structure). The role of rhizosphere bacteria in plant growth has been largely investigated but the role of phages (bacterial viruses) has received a little attention. Below the ground, phages govern the ecology and evolution of microbial communities by affecting genetic diversity, host fitness, population dynamics, community composition, and nutrient cycling. However, few restoration efforts take into account the interactions between bacteria and phages. Unlike other phages, filamentous phages are highly specific, nonlethal, and influence host fitness in several ways, which make them useful as target bacterial inocula. Also, the ease with which filamentous phages can be genetically manipulated to express a desired peptide to track and control pathogens and contaminants makes them useful in biosensing. Based on ecology and biology of filamentous phages, we developed a hypothesis on the application of phages in environment to derive benefits at different levels of biological organization ranging from individual bacteria to ecosystem for ecorestoration. We examined the potential applications of filamentous phages in improving bacterial inocula to restore vegetation and to monitor changes in habitat during ecorestoration and, based on our results, recommend a reorientation of the existing framework of using microbial inocula for such restoration and monitoring. Because bacterial inocula and biomonitoring tools based on filamentous phages are likely to prove useful in developing cost‐effective methods of restoring vegetation, we propose that filamentous phages be incorporated into nature‐based restoration efforts and that the tripartite relationship between phages, bacteria, and plants be explored further. Possible impacts of filamentous phages on native microflora are discussed and future areas of research are suggested to preclude any potential risks associated with such an approach.     

Levels of circumsporozoite protein in the Plasmodium oocyst determine sporozoite morphology

The sporozoite stage of the Plasmodium parasite is formed by budding from a multinucleate oocyst in the mosquito midgut. During their life, sporozoites must infect the salivary glands of the mosquito vector and the liver of the mammalian host; both events depend on the major sporozoite surface protein, the circumsporozoite protein (CS). We previously reported that Plasmodium berghei oocysts in which the CS gene is inactivated do not form sporozoites. Here, we analyzed the ultrastructure of P.berghei oocyst differentiation in the wild type, recombinants that do not produce or produce reduced amounts of CS, and corresponding complemented clones. The results indicate that CS is essential for establishing polarity in the oocyst. The amounts of CS protein correlate with the extent of development of the inner membranes and associated microtubules underneath the oocyst outer membrane, which normally demarcate focal budding sites. This is a first example of a protein controlling both morphogenesis and infectivity of a parasite stage.     

Variations in Outer-membrane Characteristics of Two Stem-nodulating Bacteria of <Emphasis Type="Italic">Sesbania rostrata</Emphasis> and its Role in Tolerance Towards Diverse Stress

Outer-membrane characteristics may determine the survivability of rhizobia under diverse abiotic and biotic stresses. Therefore, the role of lipopolysaccharides (LPS) and membrane proteins of two stem-nodulating bacteria of Sesbania rostrata (Azorhizobium caulinodans ORS571 and Rhizobium sp. WE7) in determining tolerance towards abiotic and biotic stresses (hydrophobics and phages) was investigated. Outer-membrane characteristics (LPS and membrane–protein profiles) of ORS571, WE7 and thirteen standard strains were distinct. ORS571 and WE7 also showed susceptibility towards morphologically distinct phages, i.e., ACSR16 (short-tailed) and WESR29 (long-tailed), respectively. ORS571 and WE7 were tolerant to hydrophobic compounds (triton X-100, rifampicin, crystal violet and deoxycholate). To ascertain the role of outer membrane characteristics in stress tolerance, phage-resistant transconjugant mutants of ORS571 (ORS571-M8 and ORS571-M20) and WE7 (WE7-M9) were developed. LPS- and membrane–protein profiles of mutants differed from that of respective wild types (ORS571 and WE7). In in vitro assay, phages got adsorbed onto purified LPS-membrane protein fractions of wild types. Phages did not adsorb onto membrane fraction of mutants and standard strains. Mutant with reduced expression of LPS (ORS571-M20 and WE7-M9) showed reduced tolerance towards hydrophobics. However, the tolerance was unaffected in mutant (ORS571-M8) where expression of LPS was not reduced but pattern was different. The tolerance level of mutants towards hydrophobics varied with the expression of LPS, whereas the specificity towards phages is correlated with the specific LPS pattern.