2009
DOI: 10.1111/j.1529-8817.2009.00667.x
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NITZSCHIA OVALIS(BACILLARIOPHYCEAE) MONO LAKE STRAIN ACCUMULATES 1,4/2,5 CYCLOHEXANETETROL IN RESPONSE TO INCREASED SALINITY1

Abstract: The growth of microalgae in hypersaline conditions requires that cells accumulate osmoprotectants. In many instances, these are polyols. We isolated the diatom Nitzschia ovalis H. J. Arn. from the saline and alkaline water body Mono Lake (CA, USA). This isolate can grow in salinities ranging from 5 to 120 parts per thousand (ppt) of salt but normally at 90 ppt salinity. In this report, we identified the major polyol osmoprotectant as 1,4/2,5 cyclohexanetetrol by electron ionization-mass spectrometry (EI-MS), (… Show more

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Cited by 15 publications
(11 citation statements)
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“…First, lower-molecular-weight fixed carbon secreted by the MPB would be used quickly by bacteria (Cook et al, 2007;Hofmann et al, 2009); however, reductions in enzyme activity would cause a net increase in sediment concentrations if 'new' carbohydrate production remained constant. Second, bacteria and diatoms are likely to synthesize organic compatible solutes to protect from desiccation and increased salinity (van Bergeijk et al, 2003;Garza-Sanchez et al, 2009); such compounds can be secreted or leak from cells, and may be liberated by cell lysis of those microbes that are unable to tolerate the increasing osmotic stress. Third, total bacterial mortality in intertidal sediments, potentially from many sources (for example grazing, viral lysis, thermal and salinity stress), has been shown to be the primary fate (up to 65%) of bacterial production (van Oevelen et al, 2006), with the released carbon being recycled back to the DOC pool.…”
Section: Desiccation Stress Causes Microbial Behavioural Changes and mentioning
confidence: 99%
“…First, lower-molecular-weight fixed carbon secreted by the MPB would be used quickly by bacteria (Cook et al, 2007;Hofmann et al, 2009); however, reductions in enzyme activity would cause a net increase in sediment concentrations if 'new' carbohydrate production remained constant. Second, bacteria and diatoms are likely to synthesize organic compatible solutes to protect from desiccation and increased salinity (van Bergeijk et al, 2003;Garza-Sanchez et al, 2009); such compounds can be secreted or leak from cells, and may be liberated by cell lysis of those microbes that are unable to tolerate the increasing osmotic stress. Third, total bacterial mortality in intertidal sediments, potentially from many sources (for example grazing, viral lysis, thermal and salinity stress), has been shown to be the primary fate (up to 65%) of bacterial production (van Oevelen et al, 2006), with the released carbon being recycled back to the DOC pool.…”
Section: Desiccation Stress Causes Microbial Behavioural Changes and mentioning
confidence: 99%
“…Organic osmolytes include polyols [2,3], amino acids [4,5] and zwitterionic substances [6,7,8]. Certain zwitterionic metabolites may fulfill multiple physiological roles in algae e.g., as osmolytes, antioxidants and cryoprotectants [9,10,11].…”
Section: Introductionmentioning
confidence: 99%
“…Besides the free amino acids, several other organic osmolytes have been detected in marine and estuarine diatoms, such as glycine betaine (Dickson & Kirst, 1987b), homarine (Dickson & Kirst, 1987b;Nothnagel, 1995), cyclohexanetetrol (Fujii et al, 1995;Garza-Sa´nchez et al, 2009), glycerol (Dickson & Kirst, 1987b), and finally, mannose (Paul, 1979). While glycerol and mannose are direct products of photosynthesis, like sugars (e.g.…”
Section: Importance Of Polyols Quaternary Ammonium and Tertiary Sulfmentioning
confidence: 99%