Thermodynamic and Structural Adaptation Differences between the Mesophilic and Psychrophilic Lactate Dehydrogenases

Khrapunov, Sergei; Chang, Eric P.; Callender, Robert

doi:10.1021/acs.biochem.7b00156

Cited by 12 publications

(24 citation statements)

References 55 publications

(155 reference statements)

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“…10 Furthermore, pig heart LDH demonstrates a structural change and similar break in enzyme activity around 35°C, indicating that elevated glass transitions may not be restricted to thermophilic enzymes. 18…”

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confidence: 99%

Activity-Related Microsecond Dynamics Revealed by Temperature-Jump Förster Resonance Energy Transfer Measurements on Thermophilic Alcohol Dehydrogenase

et al. 2018

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Previous studies of a thermophilic alcohol dehydrogenase (ht-ADH) demonstrated a range of discontinuous transitions at 30 °C that include catalysis, kinetic isotope effects, protein hydrogen-deuterium exchange rates, and intrinsic fluorescence properties. Using the Förster resonance energy transfer response from a Trp-NADH donor-acceptor pair in T-jump studies of ht-ADH, we now report microsecond protein motions that can be directly related to active site chemistry. Two distinctive transients are observed: a slow, kinetic process lacking a temperature break, together with a faster transient that is only detectable above 30 °C. The latter establishes a link between enzyme activity and microsecond protein motions near the cofactor binding site, in a region distinct from a previously detected protein network that communicates with the substrate binding site. Though evidence of direct dynamical links between microsecond protein motions and active site bond cleavage events is extremely rare, these studies highlight the potential of T-jump measurements to uncover such properties.

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confidence: 99%

Activity-Related Microsecond Dynamics Revealed by Temperature-Jump Förster Resonance Energy Transfer Measurements on Thermophilic Alcohol Dehydrogenase

et al. 2018

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“…rPsLeuDH also exhibited lower Δ H , Δ S and Δ G and higher k cat at low temperature, as compared to mesophilic enzyme, which may be mainly related to the conformation of cold adapted protein [ 27 ]. On the other hand, it may also be related to increasing the efficiency of binding of the substrate to the catalytic site [ 28 ].…”

Section: Resultsmentioning

confidence: 99%

A Novel Cold-Adapted Leucine Dehydrogenase from Antarctic Sea-Ice Bacterium Pseudoalteromonas sp. ANT178

et al. 2018

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l-tert-leucine and its derivatives are useful as pharmaceutical active ingredients, in which leucine dehydrogenase (LeuDH) is the key enzyme in their enzymatic conversions. In the present study, a novel cold-adapted LeuDH, psleudh, was cloned from psychrotrophic bacteria Pseudoalteromonas sp. ANT178, which was isolated from Antarctic sea-ice. Bioinformatics analysis of the gene psleudh showed that the gene was 1209 bp in length and coded for a 42.6 kDa protein containing 402 amino acids. PsLeuDH had conserved Phe binding site and NAD+ binding site, and belonged to a member of the Glu/Leu/Phe/Val dehydrogenase family. Homology modeling analysis results suggested that PsLeuDH exhibited more glycine residues, reduced proline residues, and arginine residues, which might be responsible for its catalytic efficiency at low temperature. The recombinant PsLeuDH (rPsLeuDH) was purified a major band with the high specific activity of 275.13 U/mg using a Ni-NTA affinity chromatography. The optimum temperature and pH for rPsLeuDH activity were 30 °C and pH 9.0, respectively. Importantly, rPsLeuDH retained at least 40% of its maximum activity even at 0 °C. Moreover, the activity of rPsLeuDH was the highest in the presence of 2.0 M NaCl. Substrate specificity and kinetic studies of rPsLeuDH demonstrated that l-leucine was the most suitable substrate, and the catalytic activity at low temperatures was ensured by maintaining a high kcat value. The results of the current study would provide insight into Antarctic sea-ice bacterium LeuDH, and the unique properties of rPsLeuDH make it a promising candidate as a biocatalyst in medical and pharmaceutical industries.

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“…Rapid kinetics experiments and molecular dynamics simulations demonstrated that the LDH complex with NADH exists in quite a range of protein conformations with different degree of openness and solvation of the active site, whereby only a minority population of the enzyme is binding competent [50,51]. Once the enzyme-substrate complex is formed, its further catalytic conversion also proceeds through several different trajectories-the active site conformation of LDH is shown to exhibit important heterogeneity, so that the LDH reaction landscape branches at multiple points creating pathways with varied reactivity [51,73,75,76]. Importantly, the conformational transitions that control the rate of substrate binding and determine the partitioning between different catalytic branches are all associated with substantial changes in protein solvation and, consequently, large volume changes.…”

Section: A Newly Discovered Mode Of High-pressure Adaptation In Proteinsmentioning

confidence: 99%

“…Importantly, the conformational transitions that control the rate of substrate binding and determine the partitioning between different catalytic branches are all associated with substantial changes in protein solvation and, consequently, large volume changes. It makes the catalytic landscape of LDH particularly susceptible to hydrostatic pressure [77] and addition of osmolytes, such as TMAO [52,75].…”

Section: A Newly Discovered Mode Of High-pressure Adaptation In Proteinsmentioning

confidence: 99%

“…Increase in osmotic pressure via addition of cosolvents is known to have a profound effect on the activity and stability of LDH. Thus, addition of TMAO was shown to increase the thermal stability of LDH from the mackerel icefish (Champsocephalus gunnari L€ onnberg 1905) muscle, while simultaneously reducing its catalytic activity [75]. A study with LDH from rabbit muscle showed a displacement of P ½ of its inactivation to higher pressure by an addition of TMAO.…”

Section: A Newly Discovered Mode Of High-pressure Adaptation In Proteinsmentioning

confidence: 99%

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Pressure tolerance of deep‐sea enzymes can be evolved through increasing volume changes in protein transitions: a study with lactate dehydrogenases from abyssal and hadal fishes

et al. 2020

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We explore the principles of pressure tolerance in enzymes of deep-sea fishes using lactate dehydrogenases (LDH) as a case study. We compared the effects of pressure on the activities of LDH from hadal snailfishes Notoliparis kermadecensis and Pseudoliparis swirei with those from a shallowadapted Liparis florae and an abyssal grenadier Coryphaenoides armatus. We then quantified the LDH content in muscle homogenates using mass-spectrometric determination of the LDH-specific conserved peptide LNLVQR. Existing theory suggests that adaptation to high pressure requires a decrease in volume changes in enzymatic catalysis. Accordingly, evolved pressure tolerance must be accompanied with an important reduction in the volume change associated with pressure-promoted alteration of enzymatic activity (DV PP). Our results suggest an important revision to this paradigm. Here, we describe an opposite effect of pressure adaptation-a substantial increase in the absolute value of DV PP in deep-living species compared to shallow-water counterparts. With this change, the enzyme activities in abyssal and hadal species do not substantially decrease their activity with pressure increasing up to 1-2 kbar, well beyond full-ocean depth pressures. In contrast, the activity of the enzyme from the tidepool snailfish, L. florae, decreases nearly linearly from 1 to 2500 bar. The increased tolerance of LDH activity to pressure comes at the expense of decreased catalytic efficiency, which is compensated with increased enzyme contents in high-pressure-adapted species. The newly discovered strategy is presumably used when the enzyme mechanism involves the formation of potentially unstable excited transient states associated with substantial changes in enzyme-solvent interactions.

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Thermodynamic and Structural Adaptation Differences between the Mesophilic and Psychrophilic Lactate Dehydrogenases

Cited by 12 publications

References 55 publications

Activity-Related Microsecond Dynamics Revealed by Temperature-Jump Förster Resonance Energy Transfer Measurements on Thermophilic Alcohol Dehydrogenase

Activity-Related Microsecond Dynamics Revealed by Temperature-Jump Förster Resonance Energy Transfer Measurements on Thermophilic Alcohol Dehydrogenase

A Novel Cold-Adapted Leucine Dehydrogenase from Antarctic Sea-Ice Bacterium Pseudoalteromonas sp. ANT178

Pressure tolerance of deep‐sea enzymes can be evolved through increasing volume changes in protein transitions: a study with lactate dehydrogenases from abyssal and hadal fishes

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