A path from primary protein sequence to ligand recognition

Kho, Richard; Baker, Brian L.; Newman, Joseph V.; Jack, R M; Sem, Daniel S.; Villar, Hugo O.; Hansen, Mark

doi:10.1002/prot.10316

Cited by 15 publications

(22 citation statements)

References 47 publications

(59 reference statements)

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“…10 Comparing clusters of sequences of NAD(P)-utilising enzymes from the SWISS-PROT database 11 with the conformations of bound cofactors, the main result reported is that each sequence family binds NAD(P) molecules in conformations which cluster together. This is not surprising, since the identification of protein relationships from sequence alone implies that more than 30% of their residues are identical, which in turn implies that function is conserved, and hence the cofactor should be expected to bind in the same way.…”

Section: Introductionmentioning

confidence: 95%

Conformational Diversity of Ligands Bound to Proteins

Stockwell

Thornton

2006

Journal of Molecular Biology

112

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Section: Introductionmentioning

confidence: 95%

Conformational Diversity of Ligands Bound to Proteins

Stockwell

Thornton

2006

Journal of Molecular Biology

112

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“…NAD(P)(H)‐dependent enzymes are ubiquitous, and, from a large number of X‐ray structures, more than 10 different NAD(P)(H) binding folds can be identified, of which the Rossmann‐fold is the most common [3]. A recent study of enzyme–NAD(P)(H) complexes showed that the binding fold also correlates with the conformation of the NAD(P)(H) ligand [4]. The affinity for NAD(P)(H) can range from very tight binding, as in nicotinoproteins, which use the nucleotides as a cofactor [5], to weak binding, as is the case for p ‐hydroxybenzoate hydroxylase, an enzyme that does not have a recognizable NAD(P)H‐binding domain [6].…”

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confidence: 99%

Identifying determinants of NADPH specificity in Baeyer–Villiger monooxygenases

Kamerbeek

Fraaije

Janssen

2004

European Journal of Biochemistry

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The Baeyer-Villiger monooxygenase (BVMO), 4-hydroxyacetophenone monooxygenase (HAPMO), uses NADPH and O 2 to oxidize a variety of aromatic ketones and sulfides. The FAD-containing enzyme has a 700-fold preference for NADPH over NADH. Sequence alignment with other BVMOs, which are all known to be selective for NADPH, revealed three conserved basic residues, which could account for the observed coenzyme specificity. The corresponding residues in HAPMO (Arg339, Lys439 and Arg440) were mutated and the properties of the purified mutant enzymes were studied. For Arg440 no involvement in coenzyme recognition could be shown as mutant R440A was totally inactive. Although this mutant could still be fully reduced by NADPH, no oxygenation occurred, indicating that this residue is crucial for completing the catalytic cycle of HAPMO. Characterization of several Arg339 and Lys439 mutants revealed that these residues are indeed both involved in coenzyme recognition. Mutant R339A showed a largely decreased affinity for NADPH, as judged from kinetic analysis and binding experiments. Replacing Arg339 also resulted in a decreased catalytic efficiency with NADH.Mutant K439A displayed a 100-fold decrease in catalytic efficiency with NADPH, mainly caused by an increased K m . However, the efficiency with NADH increased fourfold. Saturation mutagenesis at position 439 showed that the presence of an asparagine or a phenylalanine improves the catalytic efficiency with NADH by a factor of 6 to 7. All Lys439 mutants displayed a lower affinity for AADP + , confirming a role of the lysine in recognizing the 2¢-phosphate of NADPH. The results obtained could be extrapolated to the sequence-related cyclohexanone monooxygenase. Replacing Lys326 in this BVMO, which is analogous to Lys439 in HAPMO, again changed the coenzyme specificity towards NADH. These results indicate that the strict NADPH dependency of this class of monooxygenases is based upon recognition of the coenzyme by several basic residues.

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“…Application of cofactor fingerprinting with STD NMR to dehydrogenases We initially applied the cofactor fingerprinting with STD NMR approach to well-characterized proteins (dehydrogenases), then to a protein of unknown function, as part of a lar- ger functional proteomics project [12][13][14][15]. Dehydrogenases are an excellent gene family for applying functional proteomic methods, since they represent 3-6% of most proteomes, and are easily identified using bioinformatics tools [16,17]. But, it is often difficult to predict based on sequence whether there will be preference for NADH or for its 2 0 -phosphorylated form (NADPH).…”

Section: Resultsmentioning

confidence: 99%

“…Dehydrogenases are an excellent gene family for applying functional proteomic methods, since they represent 3-6% of most proteomes, and are easily identified using bioinformatics tools [16,17]. But, it is often difficult to predict based on sequence whether there will be preference for NADH or for its 2 0 -phosphorylated form (NADPH).…”

Section: Application Of Cofactor Fingerprinting With Std Nmr Tomentioning

confidence: 99%

Cofactor fingerprinting with STD NMR to characterize proteins of unknown function: identification of a rare cCMP cofactor preference

Yao

Sem

2004

FEBS Letters

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Proteomics efforts have created a need for better strategies to functionally categorize newly discovered proteins. To this end, we have employed saturation transfer difference NMR with pools of closely related cofactors, to determine cofactor preferences. This approach works well for dehydrogenases and has also been applied to cyclic nucleotide-binding proteins. In the latter application, a protein (radial spoke protein-2, RSP2) that plays a central role in forming the radial spoke of Chlamydomonas reinhardtii flagella was shown to bind cCMP. cCMP-binding proteins are rare, although previous reports of their presence in sperm and flagella suggest that cCMP may have a more general role in flagellar function. 31 P NMR was used to monitor the preferential hydrolysis of ATP versus GTP, suggesting that RSP2 is a kinase.

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A path from primary protein sequence to ligand recognition

Cited by 15 publications

References 47 publications

Conformational Diversity of Ligands Bound to Proteins

Conformational Diversity of Ligands Bound to Proteins

Identifying determinants of NADPH specificity in Baeyer–Villiger monooxygenases

Cofactor fingerprinting with STD NMR to characterize proteins of unknown function: identification of a rare cCMP cofactor preference

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