Activation of Phenylalanine Hydroxylase Induces Positive Cooperativity toward the Natural Cofactor

Gersting, Søren W.; Staudigl, Michael; Truger, Marietta; Messing, Dunja D.; Danecka, Marta K.; Sommerhoff, Christian P.; Kemter, Kristina; Muntau, Ania C.

doi:10.1074/jbc.m110.124016

Cited by 30 publications

(25 citation statements)

References 59 publications

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“…PAH activity determination used a continuous fluorescence assay monitoring the production of tyrosine [57] adapted to single microcuvette format for use with a Photon Technologies International fluorescence spectrophotometer equipped with a xenon flash lamp. Fluorescence was monitored at λ Ex = 275 nm and λ Em = 305 nm, with excitation and emission slit widths set to 2 nm.…”

Section: Methodsmentioning

confidence: 99%

A new model for allosteric regulation of phenylalanine hydroxylase: Implications for disease and therapeutics

Jaffe

Stith

Lawrence

et al. 2013

Archives of Biochemistry and Biophysics

118

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The structural basis for allosteric regulation of phenylalanine hydroxylase (PAH), whose dysfunction causes phenylketonuria (PKU), is poorly understood. A new morpheein model for PAH allostery is proposed to consist of a dissociative equilibrium between two architecturally different tetramers whose interconversion requires a ~90° rotation between the PAH catalytic and regulatory domains, the latter of which contains an ACT domain. This unprecedented model is supported by in vitro data on purified full length rat and human PAH. The conformational change is both predicted to and shown to render the tetramers chromatographically separable using ion exchange methods. One novel aspect of the activated tetramer model is an allosteric phenylalanine binding site at the inter-subunit interface of ACT domains. Amino acid ligand-stabilized ACT domain dimerization follows the multimerization and ligand binding behavior of ACT domains present in other proteins in the PDB. Spectroscopic, chromatographic, and electrophoretic methods demonstrate a PAH equilibrium consisting of two architecturally distinct tetramers as well as dimers. We postulate that PKU-associated mutations may shift the PAH quaternary structure equilibrium in favor of the low activity assemblies. Pharmacological chaperones that stabilize the ACT:ACT interface can potentially provide PKU patients with a novel small molecule therapeutic.

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Section: Methodsmentioning

confidence: 99%

A new model for allosteric regulation of phenylalanine hydroxylase: Implications for disease and therapeutics

Jaffe

Stith

Lawrence

et al. 2013

Archives of Biochemistry and Biophysics

118

View full text Add to dashboard Cite

show abstract

“…Here we abandon the concept of “misfolding with loss-of-function” and put a structural framework to prior proposals that disease-associated PAH variants can be defective in the allosteric response to elevated Phe in a manner that does not impair protein stability and/or promote aggregation (e.g. (21, 24)). On the basis of newly available structural information that defines the allosteric Phe binding site, we propose that there is a class of common disease-associated variants that are not defective in the ability to fold, but are defective in the ability to stabilize A-PAH.…”

Section: Regulation Of Phe In Humansmentioning

confidence: 99%

New protein structures provide an updated understanding of phenylketonuria

Jaffe

2017

Molecular Genetics and Metabolism

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Phenylketonuria (PKU) and less severe hyperphenylalaninemia (HPA) constitute the most common inborn error of amino acid metabolism, and is most often caused by defects in phenylalanine hydroxylase (PAH) function resulting in accumulation of Phe to neurotoxic levels. Despite the success of dietary intervention in preventing permanent neurological damage, individuals living with PKU clamor for additional non-dietary therapies. The bulk of disease-associated mutations are PAH missense variants, which occur throughout the entire 452 amino acid human PAH protein. While some disease-associated mutations affect protein structure (e.g. truncations) and others encode catalytically dead variants, most have been viewed as defective in protein folding/stability. Here we refine this view to address how PKU-associated missense variants can perturb the equilibrium among alternate native PAH structures (resting-state PAH and activated PAH), thus shifting the tipping point of this equilibrium to a neurotoxic Phe concentration. This refined view of PKU introduces opportunities for the design or discovery of therapeutic pharmacological chaperones that can help restore the tipping point to healthy Phe levels and how such a therapeutic might work with or without the inhibitory pharmacological chaperone BH4. Dysregulation of an equilibrium of architecturally distinct native PAH structures departs from the concept of “misfolding”, provides an updated understanding of PKU, and presents an enhanced foundation for understanding genotype/phenotype relationships.

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“…A variety of other mechanisms are known to regulate PAH activity in vivo, including its activation by phenylalanine and phosphorylation, in addition to its allosteric inhibition by BH4 cofactor (31,32). Previous reports suggest that queuine can enhance the phosphorylation of unspecified cytosolic proteins (22), whereas in other cases a decrease in phosphorylation was observed (33)(34)(35).…”

Section: Tgt Inactivation Does Not Affect Pah Expression or Activity mentioning

confidence: 84%

Queuosine Deficiency in Eukaryotes Compromises Tyrosine Production through Increased Tetrahydrobiopterin Oxidation

Rakovich

Boland

Bernstein

et al. 2011

Journal of Biological Chemistry

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Queuosine is a modified pyrrolopyrimidine nucleoside found in the anticodon loop of transfer RNA acceptors for the amino acids tyrosine, asparagine, aspartic acid, and histidine. Because it is exclusively synthesized by bacteria, higher eukaryotes must salvage queuosine or its nucleobase queuine from food and the gut microflora. Previously, animals made deficient in queuine died within 18 days of withdrawing tyrosine, a nonessential amino acid, from the diet (Marks, T., and Farkas, W. R. (1997) Biochem. Biophys. Res. Commun. 230, 233-237). Here, we show that human HepG2 cells deficient in queuine and mice made deficient in queuosine-modified transfer RNA, by disruption of the tRNA guanine transglycosylase enzyme, are compromised in their ability to produce tyrosine from phenylalanine. This has similarities to the disease phenylketonuria, which arises from mutation in the enzyme phenylalanine hydroxylase or from a decrease in the supply of its cofactor tetrahydrobiopterin (BH4). Immunoblot and kinetic analysis of liver from tRNA guanine transglycosylase-deficient animals indicates normal expression and activity of phenylalanine hydroxylase. By contrast, BH4 levels are significantly decreased in the plasma, and both plasma and urine show a clear elevation in dihydrobiopterin, an oxidation product of BH4, despite normal activity of the salvage enzyme dihydrofolate reductase. Our data suggest that queuosine modification limits BH4 oxidation in vivo and thereby potentially impacts on numerous physiological processes in eukaryotes.Bacteria and humans have co-evolved for millennia, and many examples exist of how various symbiotic and commensal partnerships contribute to human health and nutrition ranging from the metabolism of complex carbohydrates to the provision of vital micronutrients (1). Queuosine is an example of a micronutrient, synthesized exclusively by bacteria but which, for poorly defined reasons, is utilized by almost all eukaryotic species with the exception of the baker's yeast, Saccharomyces cerevisiae (2).Bacterial queuosine biosynthesis occurs in two stages. First, a series of five enzymatic steps convert guanosine triphosphate nucleoside (GTP) to the soluble 7-aminomethyl-7-deazaguanine molecule. Subsequently, 7-aminomethyl-7-deazaguanine is inserted into the wobble position of tRNA containing a GUN consensus sequence (Tyr, Asp, Asn, and His) by means of the single enzyme species, tRNA guanine transglycosylase (TGT), and is further remodeled in situ to queuosine (3). Eukaryotes must acquire queuosine or its free nucleobase, queuine, from food and the gut microflora. Curiously, both cytosolic and mitochondrial tRNA species are modified by queuosine (2). The eukaryotic enzyme that performs this reaction, queuine tRNA ribosyltransferase, has recently been identified as a heterodimeric complex, consisting of the eukaryotic homologue of the catalytic TGT subunit and a related protein called queuine tRNA ribosyltransferase domain containing 1 (QTRTD1), both of which localize to the mitochondria (4, 5).Stu...

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Activation of Phenylalanine Hydroxylase Induces Positive Cooperativity toward the Natural Cofactor

Cited by 30 publications

References 59 publications

A new model for allosteric regulation of phenylalanine hydroxylase: Implications for disease and therapeutics

A new model for allosteric regulation of phenylalanine hydroxylase: Implications for disease and therapeutics

New protein structures provide an updated understanding of phenylketonuria

Queuosine Deficiency in Eukaryotes Compromises Tyrosine Production through Increased Tetrahydrobiopterin Oxidation

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