<i>Moritella</i>
            Cold-Active Dihydrofolate Reductase: Are There Natural Limits to Optimization of Catalytic Efficiency at Low Temperature?

Xu, Ying; Feller, Georges; Gerday, Charles; Glansdorff, Nicolas

doi:10.1128/jb.185.18.5519-5526.2003

Cited by 50 publications

(55 citation statements)

References 44 publications

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“…values and lower k cat /K m ratios (27,28). Whether CHA3 fits with this theory is the subject of subsequent studies.…”

Section: Fig 2 Effect Of Ph On Activity Of Cha3 Toward P-np Decanoatementioning

confidence: 99%

Identification of a Novel Alkaliphilic Esterase Active at Low Temperatures by Screening a Metagenomic Library from Antarctic Desert Soil

Heath

Cary

et al. 2009

Appl Environ Microbiol

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“…values and lower k cat /K m ratios (27,28). Whether CHA3 fits with this theory is the subject of subsequent studies.…”

Section: Fig 2 Effect Of Ph On Activity Of Cha3 Toward P-np Decanoatementioning

confidence: 99%

Identification of a Novel Alkaliphilic Esterase Active at Low Temperatures by Screening a Metagenomic Library from Antarctic Desert Soil

Heath

Cary

et al. 2009

Appl Environ Microbiol

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“…More recently, recombinant DHFR from Moritella profunda (MpDHFR), a psychropiezophilic bacterium isolated from Atlantic Ocean sediments at a depth of 2815 m, [2] has been examined with respect to its structural and kinetic adaptation to high pressure and low temperature. [3][4][5] In DHFR from E. coli (EcDHFR), as with many other enzymes, physical processes rather than the actual chemical step limit the reaction rate under steady-state conditions at pH 7. [6] EcDHFR cycles through five key intermediates during catalysis [6] that vary in the movement and coordination of various loops, subdomains and bound ligands [7][8][9] and solvent access.…”

Section: Introductionmentioning

confidence: 99%

Catalysis by Dihydrofolate Reductase from the Psychropiezophile Moritella profunda

et al. 2010

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The influence of temperature and pH on the stability and catalytic activity of dihydrofolate reductase (MpDHFR) from the cold-adapted deep-sea bacterium Moritella profunda was studied. The thermal melting temperature was found to be ∼38 °C and was not affected by pH, while activity measurements demonstrated that its stability was maximal at pH 7 and was reduced dramatically below pH 6 or above pH 8. The steady-state rate constant (k(cat)) was maximal at neutral pH and higher temperatures, while the Michaelis constants (K(M)) for both substrate and cofactor were optimal at lower temperatures and at elevated or reduced pH. For both temperature and pH, any change in k(cat) was therefore offset by a similar change in K(M). Both the activation enthalpy and entropy of the MpDHFR-catalysed reaction were lower than those of DHFR from E. coli leading overall to a very small difference in activation free energy and therefore similar steady-state rate constants at the same temperature. The chemical step of the reaction is not rate limiting at pH 7, but becomes progressively more rate limiting as the pH increases. These results demonstrate adaptation of MpDHFR to its environment and show compromises between enthalpic and entropic contributions to the reaction, and between k(cat) and K(M).

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“…nov. (52) and the ornithine carbamoyltransferase from the psychrophilic Moritella abyssi (52) do not optimize the catalytic efficiency k cat /K m . Both heat-labile enzymes appear to be suboptimal in their physiological temperature range as far as the k cat /K m ratio is concerned, supporting the concept that complete metabolic adaptation to cold may remain elusive (52). However, it should be noted that the improvement of the catalytic efficiency k cat /K m could be related to the global or localized decrease in the stability of psychrophilic enzymes.…”

Section: Oligomeric Enzymesmentioning

confidence: 91%

“…The hydrophobic core and ion-pair network at the subunit interface are the major stabilizing factors which stabilize the intersubunit interface (50). Moreover, oligomerization can be a significant stabilization mechanism for hyperthermophilic enzymes (50)(51)(52)(53). On the basis of stability studies of dimeric globular proteins, it was calculated that quaternary interactions could provide 25% to 100% of the conformational stability in protein dimers (54).…”

Section: Oligomeric Enzymesmentioning

confidence: 99%

Extreme Catalysts from Low-Temperature Environments

et al. 2004

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Cold-loving or psychrophilic organisms are widely distributed in nature as a large part of the earth's surface is at temperatures around 0°C. To maintain metabolic rates and to prosper in cold environments, these extremophilic organisms have developed a vast array of adaptations. One main adaptive strategy developed in order to cope with the reduction of chemical reaction rates induced by low temperatures is the synthesis of cold-adapted or psychrophilic enzymes. These enzymes are characterized by a high catalytic activity at low temperatures associated with a low thermal stability. A study of protein adaptation strategies suggests that the high activity of psychrophilic enzymes could be achieved by the destabilization of the active site, allowing the catalytic center to be more flexible at low temperatures, whereas other protein regions may be destabilized or as rigid as their mesophilic counterparts. Due to these particular properties, psychrophilic enzymes offer a high potential not only for fundamental research but also for biotechnological applications.[Key words: psychrophile, extremophiles, cold adaptation, enzyme kinetics, flexibility strategy]Life under low-temperature conditions was identified as early as 1840 by Hooker, who observed that algae were associated with sea ice. In 1887, Forster was the first who reported that microorganisms isolated from fish could grow well at 0°C (1). The term "psychrophilic" was first used in 1902 by Schmidt-Nielsen to describe such cold-adapted organisms (2). Psychrophile is defined as an organism, prokaryotic or eukaryotic, living permanently at temperatures close to the freezing point of water in thermal equilibrium with the medium. Thus psychrophiles are numerous, including a large range of species of gram-positive and gram-negative bacteria, yeast, algae, marine invertebrates, insects and polar fish, and are widely distributed (3). Psychrophiles have developed mechanisms of adaptation to temperature including a huge range of structural and physiological adjustments in order to cope with the deleterious effect of low temperatures. Indeed, they display metabolic fluxes at low temperatures that are more or less comparable to those exhibited by closely related mesophiles living at moderate temperatures (4-6). This is explained by the capability of these psychrophilic organisms to produce "cold-adapted" enzymes which are able to cope with the reduction of chemical reaction rates induced by low temperatures. However, most cellular adaptations to low temperatures and the underlying molecular mechanisms are not fully understood and are still being investigated. Moreover, a study of proteins and enzymes from cold-adapted organisms is not only useful in the understanding of some general processes related to the protein structure and function but also in protein folding investigations. In addition, cold-active and heat-labile psychrophilic enzymes possess an interesting biotechnological potential.

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Moritella Cold-Active Dihydrofolate Reductase: Are There Natural Limits to Optimization of Catalytic Efficiency at Low Temperature?

Cited by 50 publications

References 44 publications

Identification of a Novel Alkaliphilic Esterase Active at Low Temperatures by Screening a Metagenomic Library from Antarctic Desert Soil

Identification of a Novel Alkaliphilic Esterase Active at Low Temperatures by Screening a Metagenomic Library from Antarctic Desert Soil

Catalysis by Dihydrofolate Reductase from the Psychropiezophile Moritella profunda

Extreme Catalysts from Low-Temperature Environments

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