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The Halophiles 2013 meeting is a multidisciplinary international congress, with a strong history of regular triennial meetings since 1978. Our mission is to bring researchers from a wide diversity of investigation interests (e.g., protein and species evolution; niche adaptation, ecology, taxonomy, genomics, metagenomics, horizontal gene transfer, gene regulation; DNA replication, repair and recombination; signal transduction; community assembly and species distribution; astrobiology; biotechnological applications; adaptation to radiation, desiccation, osmotic stress) into a single forum for the integration and synthesis of ideas and data from all three domains of life, and their viruses, yet from a single environment; salt concentrations greater than seawater. This cross-section of research informs our understanding of the microbiological world in many ways. The halophilic environment is extreme, especially above 10% NaCl, restricting life solely to microbes. The microorganisms that live there are adapted to extreme conditions, and are notable for their ability to survive high doses of radiation and desiccation. Therefore, the hypersaline environment is a model system (both the abiotic, and biologic factors) for insightful understanding regarding conditions and life in the absence of plant and animals (e.g., life on the early earth, and other solar system bodies like Mars and Europa). Lower salinity conditions (e.g., 6-10% NaCl) form luxuriant microbial mats considered modern analogues of fossilized stromatolites, which are enormous microbially produced structures fashioned during the Precambrian (and still seen today in places like Shark’s Bay, Australia). Hypersaline systems are island-like habitats spread patchily across the earth’s surface, and similar to the Galapagos Islands represent unique systems excellent for studying the evolutionary pressures that shape microbial community assembly, adaptation, and speciation. The unique adaptations to this extreme environment produce valuable proteins, enzymes and other molecules capable of remediating harsh human instigated environments, and are useful for the production of biofuels, vitamins, and retinal implants, for example. This research topic is intended to capture the breadth and depth of these topics.

Halophilic microorganisms. --- halophile evolution --- halophilic and halotolerant microorganisms --- Haloferax volcanii --- halophile biochemistry --- halophile metabolism --- halophile adaptations --- halophile molecular biology --- halophile communities

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Nowadays, we are witnessing highly dynamic research activities related to the intriguing field of biodegradable materials with plastic-like properties. These activities are stimulated by the strengthened public awareness of prevailing ecological issues connected to growing piles of plastic waste and increasing greenhouse gas emissions; this goes hand-in-hand with the ongoing depletion of fossil feedstocks, which are traditionally used to produce full carbon backbone polymers. Polyhydroxyalkanoate (PHA) biopolyesters, a family of plastic-like materials with versatile material properties, are increasing considered to be a future-oriented solution for diminishing these concerns. PHA production is based on renewable resources and occurs in a bio-mediated fashion through the action of living organisms. If accomplished in an optimized way, PHA production and the entire PHA lifecycle are embedded into nature´s closed cycles of carbon. Sustainable and efficient PHA production requires understanding and improvement of all the individual process steps. Holistic improvement of PHA production, applicable on an industrially relevant scale, calls for, inter alia, consolidated knowledge about the enzymatic and genetic particularities of PHA-accumulating organisms, an in-depth understanding of the kinetics of the bioprocess, the selection of appropriate inexpensive fermentation feedstocks, tailoring of PHA composition at the level of its monomeric constituents, optimized biotechnological engineering, and novel strategies for PHA recovery from biomass characterized by low energy and chemical requirements. This Special Issue represents a comprehensive compilation of articles in which these individual aspects have been addressed by globally recognized experts.

Cupriavidus necator --- alginate --- tissue engineering --- PAT --- simulation --- terpolyester --- high cell density cultivation --- process simulation --- selective laser sintering --- gaseous substrates --- microaerophilic --- in-line monitoring --- Pseudomonas sp. --- additive manufacturing --- fed-batch --- terpolymer --- on-line --- bubble column bioreactor --- biopolymer --- fused deposition modeling --- biomaterials --- polyhydroxyalkanoate (PHA) --- Pseudomonas putida --- fed-batch fermentation --- blends --- upstream processing --- wound healing --- activated charcoal --- downstream processing --- Archaea --- polyhydroxyalkanoates processing --- film --- bioreactor --- medium-chain-length polyhydroxyalkanoate (mcl-PHA) --- poly(3-hydroxybutyrate-co-4-hydroxybutyrate) --- Ralstonia eutropha --- hydrolysate detoxification --- extremophiles --- Poly(3-hydroxybutyrate) --- process analytical technologies --- PHA composition --- COMSOL --- non-Newtonian fluid --- tequila bagasse --- biopolyester --- biosurfactants --- Haloferax --- PHA --- phenolic compounds --- polyhydroxybutyrate --- PHB --- in-line --- Pseudomonas --- haloarchaea --- plant oil --- PHA processing --- bioeconomy --- delivery system --- P(3HB-co-3HV-co-4HB) --- productivity --- electrospinning --- cyanobacteria --- waste streams --- polyhydroxyalkanoates --- oxygen transfer --- polyhydroxyalkanoate --- biomedical application --- photon density wave spectroscopy --- carbon dioxide --- salinity --- PDW --- rheology --- halophiles --- feedstocks --- high-cell-density fed-batch --- biomedicine --- process engineering --- bioprocess design --- viscosity --- computer-aided wet-spinning --- microorganism --- Cupriavidus malaysiensis --- poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHVB)