* Astronomy

Microbe that feeds off arsenic alters search for life

Researchers have discovered a strange microbe that can use arsenic as a nutrient, a finding they say could change how scientists search for new life forms on Earth and elsewhere.
Until now, six major elements -- carbon, hydrogen, nitrogen, oxygen, phosphorus and sulphur -- were considered essential for life. The discovery of the new bacterium throws that assumption on its head.
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Title: Did nature also choose arsenic?
Authors: Wolfe-Simon, Felisa; Davies, Paul C. W.; Anbar, Ariel D.

All known life requires phosphorus (P) in the form of inorganic phosphate (PO4 ^3- or Pi) and phosphate-containing organic molecules. Pi serves as the backbone of the nucleic acids that constitute genetic material and as the major repository of chemical energy for metabolism in polyphosphate bonds. Arsenic (As) lies directly below P on the periodic table and so the two elements share many chemical properties, although their chemistries are sufficiently dissimilar that As cannot directly replace P in modern biochemistry. Arsenic is toxic because As and P are similar enough that organisms attempt this substitution. We hypothesise that ancient biochemical systems, analogous to but distinct from those known today, could have utilised arsenate in the equivalent biological role as phosphate. Organisms utilising such 'weird life' biochemical pathways may have supported a 'shadow biosphere' at the time of the origin and early evolution of life on Earth or on other planets. Such organisms may even persist on Earth today, undetected, in unusual niches.

Source

Title: Microbial Life in a Liquid Asphalt Desert
Authors: Dirk Schulze-Makuch, Shirin Haque, Marina Resendes de Sousa Antonio, Denzil Ali, Riad Hosein, Young C. Song, Jinshu Yang, Elena Zaikova, Denise M. Beckles, Edward Guinan, Harry J. Lehto, Steven J. Hallam

An active microbiota, reaching up to 10 E+7 cells/g, was found to inhabit a naturally occurring asphalt lake characterised by low water activity and elevated temperature. Geochemical and molecular taxonomic approaches revealed novel and deeply branching microbial assemblages mediating anaerobic hydrocarbon degradation, metal respiration and C1 utilisation pathways. These results open a window into the origin and adaptive evolution of microbial life within recalcitrant hydrocarbon matrices, and establish the site as a useful analogue for the liquid hydrocarbon environments on Saturn's moon Titan.

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Microbes thrive in harsh, Mars-like lakes

Life not only survives but thrives in Australian lakes where conditions may be as harsh as those on ancient Mars, a new DNA analysis suggests.
Minerals on Mars studied by the NASA rovers suggest water once flowed on the planet's surface, but was very salty and acidic, raising doubts about whether it could have supported life.
But in 2007, Melanie Mormile of Missouri University of Science and Technology in Rolla and colleagues cultured a bacterium from water sampled from one of several salty, acidic lakes in Western Australia.
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