158 research outputs found
Expression of fatty-acid-modifying enzymes in the halotolerant black yeast Aureobasidium pullulans (de Bary) G. Arnaud under salt stress
AbstractMultiple tolerance to stressful environmental conditions of the black, yeast-like fungus Aureobasidium pullulans is achieved through different adaptations, among which there is the restructuring of the lipid composition of their membranes. Here, we describe three novel genes encoding fatty-acid-modifying enzymes in A. pullulans, along with the levels of their mRNAs under different salinity conditions. High levels of Δ 9−desaturase and Δ12−desaturase mRNAs were seen at high salinities, which were consistent with an increased desaturation of the fatty acids in the cell membranes. Elevated levels of elongase mRNA were also detected. Surprisingly, increases in the levels of these mRNAs were also seen following hypo-osmotic shock, while hyperosmotic shock had exactly the opposite effect, demonstrating that data that are obtained from up-shift and down-shift salinity studies should be interpreted with caution
HMG-CoA reductase is regulated by environmental salinity and its activity is essential for halotolerance in halophilic fungi
The activity and level of HMG-CoA reductase (HMGR) were addressed in
halophilic fungi isolated from solar saltpans. Representative fungi belonging
to the orders Dothideales, Eurotiales and Wallemiales have a
specific pattern of HMGR regulation, which differs from salt-sensitive and
moderately salt-tolerant yeasts. In all of the halophilic fungi studied, HMGR
amounts and activities were the lowest at optimal growth salinity and
increased under hyposaline and hypersaline conditions. This profile paralleled
isoprenylation of cellular proteins in H. werneckii. Inhibition of
HMGR in vivo by lovastatin impaired the halotolerant character. HMGR
may thus serve as an important molecular marker of halotolerance
Adaptation of extremely halotolerant black yeast Hortaea werneckii to increased osmolarity: a molecular perspective at a glance
Halophilic adaptations have been studied almost exclusively on prokaryotic
microorganisms. Discovery of the black yeast Hortaea werneckii as the
dominant fungal species in hypersaline waters enabled the introduction of a
new model organism to study the mechanisms of salt tolerance in eukaryotes.
Its strategies of cellular osmotic adaptations on the physiological and
molecular level revealed novel, intricate mechanisms to combat fluctuating
salinity. H. werneckii is an extremely halotolerant eukaryotic
microorganism and thus a promising source of transgenes for osmotolerance
improvement of industrially important yeasts, as well as in crops
A novel c.-22T>C mutation in GALK1 promoter is associated with elevated galactokinase phenotype
<p>Abstract</p> <p>Background</p> <p>Many genetic variations of <it>GALK1 </it>have been identified in the patients with galactokinase (GALK1) deficiency. However, the molecular characteristics of <it>GALK1 </it>in individuals with elevated GALK1 activity are relatively unknown.</p> <p>Methods</p> <p>We investigated the relationship between elevated GALK1 activity and the molecular <it>GALK1 </it>gene variations, and the molecular mechanism underlying elevated GALK1 activity. PCR products from 63 subjects, without any attenuation of galactose degradation enzymes, were sequenced to screen for nucleotide alterations in the <it>GALK1 </it>promoter.</p> <p>Results</p> <p>Three nucleotide substitutions were identified: c.-179A>G, c.-27A>C, and c.-22T>C. With respect to the c.-22T>C mutation, GALK1 activity in 13 subjects with the T/C or C/C genotype was significantly higher than those in 50 subjects with the T/T genotype (p < 0.001). The dual luciferase reporter assay in Hep3B cells showed that the luciferase activity with the <it>GALK1 </it>promoter with the c.-22C mutant allele increased approximately 2.5-fold, compared to that with the c.-22T. A specific DNA-protein complex was observed in an electrophoretic mobility shift assay, with slightly higher affinity to c.-22C than to c.-22T.</p> <p>Conclusion</p> <p>The c.-22T>C mutation, which was observed frequently in individuals with elevated GALK1 activity, increased the expression of a reporter gene through enhanced binding of a currently unidentified nuclear protein. These results suggest that the elevated GALK1 activity resulted from enhanced gene expression, due to nucleotide variation within <it>GALK1 </it>promoter.</p
Possible interactions between bacterial diversity, microbial activity and supraglacial hydrology of cryoconite holes in Svalbard
The diversity of highly active bacterial communities in cryoconite holes on three Arctic glaciers in Svalbard was investigated using terminal restriction fragment length polymorphism (T-RFLP) of the 16S rRNA locus. Construction and sequencing of clone libraries allowed several members of these communities to be identified, with Proteobacteria being the dominant one, followed by Cyanobacteria and Bacteroidetes. T-RFLP data revealed significantly different communities in holes on the (cold) valley glacier Austre Brøggerbreen relative to two adjacent (polythermal) valley glaciers, Midtre Lovénbreen and Vestre Brøggerbreen. These population compositions correlate with differences in organic matter content, temperature and the metabolic activity of microbial communities concerned. No within-glacier spatial patterns were observed in the communities identified over the 2-year period and with the 1 km-spaced sampling. We infer that surface hydrology is an important factor in the development of cryoconite bacterial communities
The relevance of fungi in astrobiology research – Astromycology
Since the very first steps of space exploration, fungi have been recorded as contaminants,
hitchhikers, or as part of missions’ crews and payloads. Because fungi can cause human disease and
are highly active decomposers, their presence in a space-linked context has been a source of major
concern given their possible detrimental effects on crews and space structures. However, fungi can
also be beneficial and be used for many space applications. The exact effects on fungi are not
always clear as they possess high adaptability and plasticity, and their phenotypes and genotypes
can undergo several changes under the extreme conditions found in space, thus leading to different
results than those we would have on Earth. Understanding and analysing these aspects is the subject
of astromycology, a research field within astrobiology. The impending situation of a resurgent space race is expected to boost astromycology’s
visibility and importance. However, researchers lack both a framework and a solid base of
knowledge from which to contextualise their work. This critical review addresses this gap by
conceptualising the field of astromycology, covering key research and current questions pertaining
to the field, and providing a relevant research instrument for future work
Grain refinement of magnesium alloys: a review of recent research, theoretical developments and their application
This paper builds on the ‘‘Grain Refinement of Mg Alloys’’ published in 2005 and reviews the grain refinement research onMg alloys that has been undertaken since then with an emphasis on the theoretical and analytical methods that have been developed. Consideration of recent research results and current theoretical knowledge has highlighted two important factors that affect an alloy’s as-cast grain size. The first factor applies to commercial Mg-Al alloys where it is concluded that impurity and minor elements such as Fe and Mn have a substantially negative impact on grain size because, in combination with Al, intermetallic phases can be formed that tend to poison the more potent native or deliberately added nucleant particles present in the melt. This factor appears to explain the contradictory experimental outcomes reported in the literature and suggests that the search for a more potent and reliable grain refining technology may need to take a different approach. The second factor applies to all alloys and is related to the role of constitutional supercooling which, on the one hand, promotes grain nucleation and, on the other hand, forms a nucleation-free zone preventing further nucleation within this zone, consequently limiting the grain refinement achievable, particularly in low solute-containing alloys. Strategies to reduce the negative impact of these two factors are discussed. Further, the Interdependence model has been shown to apply to a broad range of casting methods from slow cooling gravity die casting to fast cooling high pressure die casting and dynamic methods such as ultrasonic treatment
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