Mode of substrate binding and specificity for ketohexokinase across isozymes implies an induced-fit mechanism

Bae, So Young

14 June 2023

Ketohexokinase (KHK), in an adenosine triphosphate (ATP) dependent reaction, catalyzes the first reaction in fructose metabolism, which converts the furanose form of D-fructose into fructose-1-phosphate. This enzyme has become a target for pharmacological development against fatty liver and metabolic syndrome. KHK exists in two isoforms, A and C, which differs by alternative splicing of exon 3 which encodes 45 out of 298 amino acids. Normally KHK exists as a homodimer and is comprised of an alpha/beta domain interlocking with a β-clasp domain. For KHK-C, there appear to be at least two conformations of the β-clasp domain. Previous work on KHK-A reveals it does not adopt the same conformations. A structure of the mouse KHK-A in its unliganded form is solved and shows that these two conformations also exist for KHK-A. Furthermore, this property is conserved across species. While crystals of human KHK-A in its unliganded form were grown, a structure was not achieved. However, unpublished structures of human KHK-A in its unliganded form also shows different conformations in β-clasp domain when in juxtaposition with the same enzyme complex with ligands. Defining the role of conformational changes in KHK-A is important, because this isozyme has been reported to have a role in cancer metastasis.

Biochemistry

Carbohydrate kinase

Fructokinase

Induced-fit mode of binding

Ketohexokinase

PfkB family

Structure and function

Étude structurale de la fructoselysine 6-kinase d’Escherichia coli : reconnaissance de substrats et mécanisme enzymatique

Arthus-Cartier, Guillaume

12 1900

Quelques enzymes sont connus pour déglyquer les kétoamines résultants de la réaction de Maillard entre des sucres et des amines primaires. Il a été démontré qu’Escherichia coli possède un opéron afin de métaboliser la fructoselysine. La fructoselysine 6-kinase, de la famille des PfkB, initie le processus de déglycation permettant l’utilisation ultérieure du glucose-6-P par la bactérie. La résolution de la structure de la FL6K par cristallographie et diffraction des rayons X a permis d’identifier son site actif en présence d’ATP, d’ADP et d’AMP-PNP. La modélisation de la fructoselysine au site actif de la kinase a permis d’identifier des résidus pouvant être importants pour sa liaison et son mécanisme enzymatique. De plus, les résultats de cinétique suggèrent que le mécanisme utilisé par la FL6K semble passer par un état ternaire de type SN2. Des modifications structurales à la FL6K pourraient permettre d’augmenter la taille des substrats afin de permettre ultimement la déglycation de protéines. / Some enzymes have been found to deglycate the products of the Maillard reaction between sugars and primary amines: ketoamines. An operon is found in Escherichia coli that allows the growth on fructoselysine media. The deglycation process is done by a kinase and a “deglycase”. The fructoselysine 6-kinase, a member of the PfkB family, phosphorylates its substrate on the sixth carbon to initiate the metabolism of fructoselysine. Here are presented x-ray crystallography structures obtained for the fructoselysine 6-kinase in its native form and bound with ATP, ADP and AMP-PNP. The active site of the kinase has been determined, and modelisation of fructoselysine allowed identification of some residues that might be important for the specific binding of the substrate and the enzymatic mechanism. Kinetic results tend to suggest a SN2 mechanism for the phosphorylation catalyzed by the enzyme. Structural modifications of the FL6K could help to increase the size of the substrates recognized by the enzyme until it binds glycated proteins.

Déglycation

Fructoselysine 6-kinase

Fructoselysine

PfkB

Métabolisme

Mécanisme enzymatique

Deglycation

Metabolism

Enzymatic mechanism

Étude structurale de la fructoselysine 6-kinase d’Escherichia coli : reconnaissance de substrats et mécanisme enzymatique

Arthus-Cartier, Guillaume

12 1900

Quelques enzymes sont connus pour déglyquer les kétoamines résultants de la réaction de Maillard entre des sucres et des amines primaires. Il a été démontré qu’Escherichia coli possède un opéron afin de métaboliser la fructoselysine. La fructoselysine 6-kinase, de la famille des PfkB, initie le processus de déglycation permettant l’utilisation ultérieure du glucose-6-P par la bactérie. La résolution de la structure de la FL6K par cristallographie et diffraction des rayons X a permis d’identifier son site actif en présence d’ATP, d’ADP et d’AMP-PNP. La modélisation de la fructoselysine au site actif de la kinase a permis d’identifier des résidus pouvant être importants pour sa liaison et son mécanisme enzymatique. De plus, les résultats de cinétique suggèrent que le mécanisme utilisé par la FL6K semble passer par un état ternaire de type SN2. Des modifications structurales à la FL6K pourraient permettre d’augmenter la taille des substrats afin de permettre ultimement la déglycation de protéines. / Some enzymes have been found to deglycate the products of the Maillard reaction between sugars and primary amines: ketoamines. An operon is found in Escherichia coli that allows the growth on fructoselysine media. The deglycation process is done by a kinase and a “deglycase”. The fructoselysine 6-kinase, a member of the PfkB family, phosphorylates its substrate on the sixth carbon to initiate the metabolism of fructoselysine. Here are presented x-ray crystallography structures obtained for the fructoselysine 6-kinase in its native form and bound with ATP, ADP and AMP-PNP. The active site of the kinase has been determined, and modelisation of fructoselysine allowed identification of some residues that might be important for the specific binding of the substrate and the enzymatic mechanism. Kinetic results tend to suggest a SN2 mechanism for the phosphorylation catalyzed by the enzyme. Structural modifications of the FL6K could help to increase the size of the substrates recognized by the enzyme until it binds glycated proteins.

Déglycation

Fructoselysine 6-kinase

Fructoselysine

PfkB

Métabolisme

Mécanisme enzymatique

Deglycation

Metabolism

Enzymatic mechanism

Structural analysis of the potential therapeutic targets from specific genes in Methicillin-resistant Staphylococcus aureus (MRSA)

Yan, Xuan

January 2011

The thesis describes over-expression, purification and crystallization of three proteins from Staphylococcus aureus (S. aureus). S. aureus is an important human pathogen and methicillin-resistant S. aureus (MRSA) is a serious problem in hospitals nowadays. The crystal structure of 3-Methyladenine DNA glycosylase I (TAG) was determined by single-wavelength anomalous diffraction (SAD) method. TAG is responsible for DNA repair and is an essential gene for both MRSA and methicilin-susceptible S. aureus (MSSA). The structure was also determined in complex with 3-methyladenine (3-MeA) and was solved using molecular replacement (MR) method. An assay was carried out and the molecular basis of discrimination between 3-MeA and adenosine was determined. The native crystal structure of fructose 1-phosphate kinase (PFK) from S. aureus was determined to 2.30 Å and solved using molecular replacement method. PFK is an essential enzyme involved in the central metabolism of MRSA. Despite extensive efforts no co-complex was determined, although crystals were obtained they diffracted poorly. An assay which can be used to test for inhibitors has been developed. Mevalonate Kinase (MK) is another essential enzyme in MRSA and is a key drug target in the mevalonate pathway. Native data diffracting to 2.2 Å was collected. The structure was solved using multiple isomorphorus replacement (MIR) method. A citrate molecule was bound at the MK active site, arising from the crystallization condition. The citrate molecule indicates how substrate might bind. The protein was kinetically characterized. A thermodynamic analysis using fluorescence-based method was carried out on each protein to investigate binding interactions of potential fragments and thus a drug design starting point.

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