Enzymes from psychrophilic organisms

peer reviewed Psychrophilic organisms such as micro-organisms and other ectothermic species living in polar, deep- sea or any constantly low temperature environments, produce enzymes adapted to function at low temperature. These enzymes are characterized by a high catalytic efficiency at low and mod...

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Bibliographic Details
Published in:FEMS Microbiology Reviews
Main Authors: Feller, Georges, Narinx, E., Arpigny, J. L., Aittaleb, M., Baise, Etienne, Genicot, S., Gerday, Charles
Format: Article in Journal/Newspaper
Language:English
Published: Blackwell Publishing 1996
Subjects:
cold enzyme
psychrophile
Antarctic bacterium
adaptation to cold
PROTEIN STABILITY
NUCLEOTIDE-SEQUENCE
ANTARCTIC BACTERIA
HISTIDINE-RESIDUES
MORAXELLA TA144
ALPHA-AMYLASE
SUBTILISIN
CLONING
LIPASE
TEMPERATURE
Life sciences
Biochemistry
biophysics & molecular biology
Sciences du vivant
Biochimie
biophysique & biologie moléculaire
Antarc*
Antarctic
North Atlantic
Online Access:https://orbi.uliege.be/handle/2268/17417
https://doi.org/10.1111/j.1574-6976.1996.tb00236.x
Description
Summary:peer reviewed Psychrophilic organisms such as micro-organisms and other ectothermic species living in polar, deep- sea or any constantly low temperature environments, produce enzymes adapted to function at low temperature. These enzymes are characterized by a high catalytic efficiency at low and moderate temperatures but are rather thermolabile. Due to their high specific activity and their rapid inactivation at temperatures as low as 30 degrees C, they offer, along with the producing micro-organisms, a great potential in biotechnology. The molecular basis of the adaptation of cold cu-amylase, subtilisin, triose phosphate isomerase from Antarctic bacteria and of trypsin from fish living in North Atlantic and in Antarctic sea waters have been studied. The comparison of the 3D structures obtained either by protein modelling or by X-ray crystallography (North Atlantic trypsin) with those of their mesophilic counterparts indicates that the molecular changes tend to increase the flexibility of the structure by a weakening of the intramolecular interactions and by an increase of the interactions with the solvent. For each enzyme, the most appropriate strategy enabling it to accommodate the substrate at a low energy cost is selected. There is a price to pay in terms of thermosensibility because the selective pressure is essentially oriented towards the harmonization of the specific activity with ambient thermal conditions. However, as demonstrated by site-directed mutagenesis experiments carried out on the Antarctic subtilisin, the possibility remains to stabilize the structure of these enzymes without affecting their high catalytic efficiency.

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