A hybrid approach reveals the allosteric regulation of GTP cyclohydrolase I

Ebenhoch, R.; Prinz, Simone; Kaltwasser, Susann; Mills, Deryck J.; Meinecke, Robert; Rübbelke, Martin; Reinert, D.J.; Bauer, Margit; Weixler, Lisa; Zeeb, Markus; Vonck, Janet; Nar, Herbert

doi:10.1073/pnas.2013473117

Cited by 12 publications

(17 citation statements)

References 69 publications

(80 reference statements)

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“…Previous attempts to obtain a 3D structure of a mammalian GCH1 could not define the structure of the first 47 N-terminal amino acids of the R. norvegicus GCH1 and the first 67 N-terminal amino acids of the human GCH1, probable due to their high mobility. 4,72 Furthermore, deletions in the N-terminal region resulted in increased catalytic activity relative to the full-length region. 73 As a result, it was proposed that the N-terminal domain does not contribute directly to catalysis but may exert an allosteric effect on GCH1 activity.…”

Section: Journal Of Chemical Information and Modelingmentioning

confidence: 99%

“…Notably, in their singleparticle electron cryo-electron microscopy (cryo-EM) derived structures of the GCH1−GFRP inhibitory and stimulatory complexes, Ebenhoch and colleagues reported the movement of the GCH1 helices to approach each other by 1 Å. 72 This finding was deduced by an observed increase in the density of the electron microscopy map at the GCH1 core of the inhibitory complex. The atomic MSF is related to the experimentally determined fluctuation, the so-called B-factor.…”

Section: Journal Of Chemical Information and Modelingmentioning

confidence: 99%

“…4 Furthermore, it was suggested that the binding of Phe induces the association of the GFRP with GCH1 by filling the surface space between the two proteins, hence increasing the contact. 4 Based on recent experimental studies, Ebenhoch and colleagues reported drastic changes at the GCH1 central five-helix bundle and its barrel, 72 in which the barrel/tunnel was found to be more contracted in the inhibitory form.…”

Section: Mechanical Stiffness Analysis Explains the Mechanical Respon...mentioning

confidence: 99%

“…D118 and E119 showed a relatively higher fluctuation in the inhibitory form than the stimulatory one; these residues were reported to trigger structural changes of residues located on the path to the active site. 72 In a study by Ebenhoch and colleagues, two key residues of the human GCH1 homolog, R235 and R241, were reported to change position to enable the binding of BH4, resulting in the shrinking of the central five-helix bundle and conformational rearrangement of the GCH1 β-barrel curvature. 72 The two residues corresponded to R226 and R232 of the R. norvegicus GCH1 and exhibited a slight fluctuation in the inhibitory form (Figure 8C).…”

Section: Mechanical Stiffness Analysis Explains the Mechanical Respon...mentioning

confidence: 99%

“…72 In a study by Ebenhoch and colleagues, two key residues of the human GCH1 homolog, R235 and R241, were reported to change position to enable the binding of BH4, resulting in the shrinking of the central five-helix bundle and conformational rearrangement of the GCH1 β-barrel curvature. 72 The two residues corresponded to R226 and R232 of the R. norvegicus GCH1 and exhibited a slight fluctuation in the inhibitory form (Figure 8C). Furthermore, site-directed mutagenesis involving BH4 inhibitor-binding residues H126, D127, E128, corresponding to H117, D118, E119 in the R. norvegicus structure as well as R235, and R241, showed that all GCH1 mutants except for R235 and R241 were still functional or with a slight reduction in activity relative to the wild type.…”

Section: Mechanical Stiffness Analysis Explains the Mechanical Respon...mentioning

confidence: 99%

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GTP Cyclohydrolase I as a Potential Drug Target: New Insights into Its Allosteric Modulation via Normal Mode Analysis

Khairallah

Ross

Bishop

2021

J. Chem. Inf. Model.

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Guanosine triphosphate (GTP) cyclohydrolase I (GCH1) catalyzes the conversion of GTP into dihydroneopterin triphosphate (DHNP). DHNP is the first intermediate of the folate de novo biosynthesis pathway in prokaryotic and lower eukaryotic microorganisms and the tetrahydrobiopterin (BH4) biosynthesis pathway in higher eukaryotes. The de novo folate biosynthesis provides essential cofactors for DNA replication, cell division, and synthesis of key amino acids in rapidly replicating pathogen cells, such as Plasmodium falciparum (P. falciparum), a causative agent of malaria. In eukaryotes, the product of the BH4 biosynthesis pathway is essential for the production of nitric oxide and several neurotransmitter precursors. An increased copy number of the malaria parasite P. falciparum GCH1 gene has been reported to influence antimalarial antifolate drug resistance evolution, whereas mutations in the human GCH1 are associated with neuropathic and inflammatory pain disorders. Thus, GCH1 stands as an important and attractive drug target for developing therapeutics. The GCH1 intrinsic dynamics that modulate its activity remains unclear, and key sites that exert allosteric effects across the structure are yet to be elucidated. This study employed the anisotropic network model to analyze the intrinsic motions of the GCH1 structure alone and in complex with its regulatory partner protein. We showed that the GCH1 tunnel-gating mechanism is regulated by a global shear motion and an outward expansion of the central five-helix bundle. We further identified hotspot residues within sites of structural significance for the GCH1 intrinsic allosteric modulation. The obtained results can provide a solid starting point to design novel antineuropathic treatments for humans and novel antimalarial drugs against the malaria parasite P. falciparum GCH1 enzyme.

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Section: Journal Of Chemical Information and Modelingmentioning

confidence: 99%

Section: Journal Of Chemical Information and Modelingmentioning

confidence: 99%