Abstract
One of the central issues of evolutionary genomics is to find out the adaptive strategies of microorganisms to stabilize nucleic acid molecules under high temperature. Thermal adaptation hypothesis gives a link between G+C content and growth temperature if there is a considerable variation of guanine and cytosine content between species. However, there has been a long-standing debate regarding the correlations between genomic GC content and optimal growth temperature (Topt). We urged that adaptation to growth at high temperature requires a coordinated set of evolutionary changes affecting: (i) nucleic acid thermostability and (ii) stability of codon-anticodon interactions. Moreover, in Bacillaceae family we have demonstrated that a higher genomic GC level do not have any role in stabilizing mRNA secondary structure at high growth temperature. Comparative analysis between homologous sequences of thermophilic Thermus thermophilus and mesophilic Deinococcus radiodurans suggests that increased levels of GC contents in the coding sequence corresponding to strand structure of Thermus thermophilus genes have stabilizing effect on the mRNA secondary structure, whereas increased levels of GC contents in coding sequences corresponding to aperiodic structure have destabilizing effect on the mRNA secondary structure. In this perspective, a critical review of thermal adaptation hypothesis is further advocated.
Highlights
For a long time, the central issue of evolutionary genomics was to find out the adaptive strategy of nucleic acid molecules towards different optimal growth temperatures (Topt)
Implications of higher GC-level towards genomic thermal adaptation To investigate whether a higher GC-level of thermophilic prokaryotes increases the thermodynamic stability of mRNA secondary structure, we analyzed the Bacillaceae family where highest correlation coefficient in the regression analysis between genomic G+C content and optimal growth temperature has been observed by Musto et al [4]
The decrease in stability of mRNA secondary structure at high growth temperature might be related to an increase in translation rates
Summary
The central issue of evolutionary genomics was to find out the adaptive strategy of nucleic acid molecules towards different optimal growth temperatures (Topt). They are the most studied extremophiles and are generally found in hot springs and deep sea vents. Thermophiles thrive at temperatures that would scald or kill most other types of life. Regular thermophiles are those that thrive at temperatures greater than 55° C. Hyperthermophiles grow optimally at above 80° C. Microorganisms grow below 55° C are known as mesophiles
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