Paule Claverie

Cold-adapted enzymes: from fundamentals to biotechnology

Psychrophilic enzymes produced by cold-adapted microorganisms display a high catalytic efficiency and are most often, if not always, associated with high thermosensitivity. Using X-ray crystallography, these properties are beginning to become understood, and the rules governing their adaptation to cold appear to be relatively diverse. The application of these enzymes offers considerable potential to the biotechnology industry, for example, in the detergent and food industries, for the production of fine chemicals and in bioremediation processes.

Did psychrophilic enzymes really win the challenge

Abstract. Organisms living in permanently cold environments, which actually represent the greatest proportion of our planet, display at low temperatures metabolic fluxes comparable to those exhibited by mesophilic organisms at moderate temperatures. They produce cold-evolved enzymes partially able to cope with the reduction in chemical reaction rates and the increased viscosity of the medium induced by low temperatures. In most cases, the adaptation is achieved through a reduction in the activation energy, leading to a high catalytic efficiency, which possibly originates from an increased flexibility of either a selected area of or the overall protein structure. This enhanced plasticity seems in return to be responsible for the weak thermal stability of cold enzymes. These particular properties render cold enzymes particularly useful in investigating the possible relationships existing between stability, flexibility, and specific activity and make them potentially unrivaled for numerous biotechnological tasks. In most cases, however, the adaptation appears to be far from being fully achieved.

Cold-Adapted Enzymes

In the last few years, increased attention has been focused on enzymes produced by cold-adapted micro-organisms. It has emerged that psychrophilic enzymes represent an extremely powerful tool in both protein folding investigations and for biotechnological purposes. Such enzymes are characterised by an increased thermosensitivity and, most of them, by a higher catalytic efficiency at low and moderate temperatures, when compared to their mesophilic counterparts. The high thermosensitivity probably originates from an increased flexibility of either a selected area of the molecular edifice or the overall protein structure, providing enhanced abilities to undergo conformational changes during catalysis at low temperatures. Structure modelling and recent crystallographic data have allowed to elucidate the structural parameters that could be involved in this higher resilience. It was demonstrated that each psychrophilic enzyme adopts its own adaptive strategy. It appears, moreover, that there is a continuum in the strategy of protein adaptation to temperature, as the previously mentioned structural parameters are implicated in the stability of thermophilic proteins. Additional 3D crystal structures, site-directed and random mutagenesis experiments should now be undertaken to further investigate the stability-flexibility-activity relationship.

The precursor of a psychrophilic alpha-amylase: structural characterization and insights into cold adaptation.

The alpha-amylase precursor from the bacterium Pseudoalteromonas haloplanktis possesses a propeptide at the C-terminus possibly responsible for outer membrane translocation. Unlike the predicted beta-barrel of autotransporters, this C-terminal propeptide displays a noticeable alpha-helix content. It is connected to the enzyme by a disordered linker and has no significant interaction with the catalytic domain. The microcalorimetric pattern of the precursor also demonstrates that the stability of protein domains may evolve differently.

Chapter 3 Cold-adapted enzymes: An unachieved symphony

Publisher Summary Temperature is one of the most important environmental factors for life. Cold-adapted or psychrophilic organisms are able to thrive at temperatures around 0°C. They are either prokaryotic or eukaryotic and represent a significant portion of the living world because temperatures over a considerable portion of our planet (example, polar and alpine regions, deep-sea waters) are below 5°C. Evolution has allowed these adapted organisms, named psychrophiles, to survive and grow in the restrictive conditions of these cold habitats. In these environments, psychrophiles display metabolic fluxes more or less comparable with those exhibited by mesophiles at moderate temperatures. The challenge for them is to counteract the reduction in chemical reaction rates due to low temperatures. This chapter describes the principles of enzyme cold-adaptation. It is well known that rates of chemical reactions decrease with temperature; this is described by the Arrhenius equation. The Arrhenius law also applies to psychrophiles but they have developed adaptation mechanisms enabling them to display, despite the low temperature of their environment, appropriate reaction rates contrary to non-adapted organisms, which would not survive or grow satisfactorily in such conditions of environmental stress.