Impact of Lipidomics on the Microbial World of Hypersaline Environments

2011 ◽  
pp. 123-135 ◽  
Author(s):  
Patrizia Lopalco ◽  
Simona Lobasso ◽  
Maristella Baronio ◽  
Roberto Angelini ◽  
Angela Corcelli
Keyword(s):  
Hypersaline Environments ◽  
Microbial World

scholarly journals The microbial world in a changing environment

2021 ◽  
Vol 94 (1) ◽  
Author(s):  
Rafael Vicuña ◽  
Bernardo González
Keyword(s):  
Climate Change ◽  
Microbial Communities ◽  
Recent Literature ◽  
Public Awareness ◽  
Complete Evaluation ◽  
Microbial World ◽  
Sustainable Environment ◽  
Entire Planet ◽  
New Strategies

Abstract Background In this article we would like to touch on the key role played by the microbiota in the maintenance of a sustainable environment in the entire planet. For obvious reasons, this article does not intend to review thoroughly this extremely complex topic, but rather to focus on the main threats that this natural scenario is presently facing. Methods Recent literature survey. Results Despite the relevance of microorganisms have in our planet, the effects of climate change on microbial communities have been scarcely and not systematically addressed in literature. Although the role of microorganisms in emissions of greenhouse gases has received some attention, there are several microbial processes that are affected by climate change with consequences that are presently under assessment. Among them, host-pathogen interactions, the microbiome of built environment, or relations among plants and beneficial microbes. Conclusions Further research is required to advance in knowledge of the effect of climate change on microbial communities. One of the main targets should be a complete evaluation of the global microbial functional diversity and the design of new strategies to cope with limitations in methods to grow microorganisms in the laboratory. These efforts should contribute to raise a general public awareness on the major role played by the microbiota on the various Earth ecosystems.

Corrigendum to “Recovering microbial genomes from metagenomes in hypersaline environments: The Good, the Bad and the Ugly” [Syst. Appl. Microbiol. 42 (2019) 30–40]

2020 ◽  
Vol 43 (4) ◽  
pp. 126100
Author(s):  
María Dolores Ramos-Barbero ◽  
Ana-B. Martin-Cuadrado ◽  
Tomeu Viver ◽  
Fernando Santos ◽  
Manuel Martinez-Garcia ◽  
...  
Keyword(s):  
Hypersaline Environments ◽  
Microbial Genomes

scholarly journals Molecular and phylogenetic analysis reveals new diversity of Dunaliella salina from hypersaline environments

2021 ◽  
pp. 1-11
Author(s):  
Andrea Highfield ◽  
Angela Ward ◽  
Richard Pipe ◽  
Declan C. Schroeder
Keyword(s):  
Genetic Diversity ◽  
Phylogenetic Analysis ◽  
Dunaliella Salina ◽  
Phylogenetic Analyses ◽  
Ssu Rdna ◽  
Lsu Rdna ◽  
Hypersaline Environments ◽  
Rdna Its ◽  
Β Carotene ◽  
Selection Of

Abstract Twelve hyper-β carotene-producing strains of algae assigned to the genus Dunaliella salina have been isolated from various hypersaline environments in Israel, South Africa, Namibia and Spain. Intron-sizing of the SSU rDNA and phylogenetic analysis of these isolates were undertaken using four commonly employed markers for genotyping, LSU rDNA, ITS, rbcL and tufA and their application to the study of Dunaliella evaluated. Novel isolates have been identified and phylogenetic analyses have shown the need for clarification on the taxonomy of Dunaliella salina. We propose the division of D. salina into four sub-clades as defined by a robust phylogeny based on the concatenation of four genes. This study further demonstrates the considerable genetic diversity within D. salina and the potential of genetic analyses for aiding in the selection of prospective economically important strains.

scholarly journals Protein Nanowires: the Electrification of the Microbial World and Maybe Our Own

2020 ◽  
Vol 202 (20) ◽  
Author(s):  
Derek R. Lovley ◽  
Dawn E. Holmes
Keyword(s):  
Electron Transport ◽  
Long Range ◽  
Electronic Devices ◽  
Electricity Production ◽  
Microbial World ◽  
Electrically Conductive ◽  
Anaerobic Digesters ◽  
Content Type ◽  
Type Iv ◽  
Type Iv Pilin

ABSTRACT Electrically conductive protein nanowires appear to be widespread in the microbial world and are a revolutionary “green” material for the fabrication of electronic devices. Electrically conductive pili (e-pili) assembled from type IV pilin monomers have independently evolved multiple times in microbial history as have electrically conductive archaella (e-archaella) assembled from homologous archaellin monomers. A role for e-pili in long-range (micrometer) extracellular electron transport has been demonstrated in some microbes. The surprising finding of e-pili in syntrophic bacteria and the role of e-pili as conduits for direct interspecies electron transfer have necessitated a reassessment of routes for electron flux in important methanogenic environments, such as anaerobic digesters and terrestrial wetlands. Pilin monomers similar to those found in e-pili may also be a major building block of the conductive “cables” that transport electrons over centimeter distances through continuous filaments of cable bacteria consisting of a thousand cells or more. Protein nanowires harvested from microbes have many functional and sustainability advantages over traditional nanowire materials and have already yielded novel electronic devices for sustainable electricity production, neuromorphic memory, and sensing. e-pili can be mass produced with an Escherichia coli chassis, providing a ready source of material for electronics as well as for studies on the basic mechanisms for long-range electron transport along protein nanowires. Continued exploration is required to better understand the electrification of microbial communities with microbial nanowires and to expand the “green toolbox” of sustainable materials for wiring and powering the emerging “Internet of things.”

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