Alessandra Pasquo

The structure of Pyrococcus furiosus glutamate dehydrogenase reveals a key role for ion-pair networks in maintaining enzyme stability at extreme temperatures

BACKGROUND The hyperthermophile Pyrococcus furiosus is one of the most thermostable organisms known, with an optimum growth temperature of 100 degrees C. The proteins from this organism display extreme thermostability. We have undertaken the structure determination of glutamate dehydrogenase from P. furiosus in order to gain further insights into the relationship between molecular structure and thermal stability. RESULTS The structure of P. furiosus glutamate dehydrogenase, a homohexameric enzyme, has been determined at 2.2 A resolution and compared with the structure of glutamate dehydrogenase from the mesophile Clostridium symbiosum. CONCLUSIONS Comparison of the structures of these two enzymes has revealed one major difference: the structure of the hyperthermophilic enzyme contains a striking series of ion-pair networks on the surface of the protein subunits and buried at both interdomain and intersubunit interfaces. We propose that the formation of such extended networks may represent a major stabilizing feature associated with the adaptation of enzymes to extreme temperatures.

Construction of a dimeric form of glutamate dehydrogenase from Clostridium symbiosum by site-directed mutagenesis

By using site-directed mutagenesis, Phe-187, one of the amino-acid residues involved in hydrophobic interaction between the three identical dimers comprising the hexamer of Clostridium symbiosum glutamate dehydrogenase (GDH), has been replaced by an aspartic acid residue. Over-expression in Escherichia coli led to production of large amounts of a soluble protein which, though devoid of GDH activity, showed the expected subunit M(r) on SDS-PAGE, and cross-reacted with an anti-GDH antibody preparation in Western blots. The antibody was used to monitor purification of the inactive protein. F187D GDH showed altered mobility on non-denaturing electrophoresis, consistent with changed size and/or surface charge. Gel filtration on a calibrated column indicated an M(r) of 87000 +/- 3000. The mutant enzyme did not bind to the dye column routinely used in preparing wild-type GDH. Nevertheless suspicions of major misfolding were allayed by the results of chemical modification studies: as with wild-type GDH, NAD+ completely protected one-SH group against modification by DTNB, implying normal coenzyme binding. A significant difference, however, is that in the mutant enzyme both cysteine groups were modified by DTNB, rather than C320 only. The CD spectrum in the far-UV region indicated no major change in secondary structure in the mutant protein. The near-UV CD spectrum, however, was less intense and showed a pronounced Phe contribution, possibly reflecting the changed environment of Phe-199, which would be buried in the hexamer. Sedimentation velocity experiments gave corrected coefficients S20,W of 11.08 S and 5.29 S for the wild-type and mutant proteins. Sedimentation equilibrium gave weight average molar masses M(r,app) of 280000 +/- 5000 g/mol. consistent with the hexameric structure for the wild-type protein and 135000 +/- 3000 g/mol for F187D. The value for the mutant is intermediate between the values expected for a dimer (98000) and a trimer (147000). To investigate the basis of this, sedimentation equilibrium experiments were performed over a range of protein concentrations. M(r,app) showed a linear dependence on concentration and a value of 108 118 g/mol at infinite dilution. This indicates a rapid equilibrium between dimeric and hexameric forms of the mutant protein with an equilibrium constant of 0.13 l/g. An independent analysis of the radial absorption scans with Microcal Origin software indicated a threefold association constant of 0.11 l/g. Introduction of the F187D mutation thus appears to have been successful in producing a dimeric GDH species. Since this protein is inactive it is possible that activity requires subunit interaction around the 3-fold symmetry axis. On the other hand this mutation may disrupt the structure in a way that cannot be extrapolated to other dimers. This issue can only be resolved by making alternative dimeric mutants.

Glutamate dehydrogenase from the thermoacidophilic archaebacterium Sulfolobussolfataricus: studies on thermal and guanidine-dependent inactivation

The hexameric NAD(P)-dependent glutamate dehydrogenase isolated from the thermoacidophilic archaebacterium Sulfolobus solfataricus shows a remarkable thermal stability which is strictly dependent on protein concentration (half-life at 95 degrees C is 0.25 h and 0.5 h at 0.4 and 0.8 mg/ml, respectively). Temperature-dependent inactivation of the enzyme is apparently irreversible; this process is accompanied by a progressive increase in hydrophobic surface area which leads to protein precipitation. 3 M GdnHCl increases the half-life of the enzyme at 90 degrees C and 0.2 mg/ml 6-fold. The hexamer is the only soluble molecular species revealed by glutaraldehyde fixation after thermal inactivation. Lyotropic salts strongly affect the enzyme thermal stability: the half-life at 90 degrees C and 0.2 mg/ml protein concentration increases more than 6-fold in the presence of 0.4 M Na2SO4 and decreases 4-fold in the presence of 0.4 M NaSCN. The maximum protein thermal stability is observed around the isoelectric pH, between pH 5.2 and pH 6.8. Guanidine-dependent inactivation of the enzyme at 20 degrees C is irreversible above 1.5 M GdnHCl. The decline in percentage of reactivation closely parallels the structural changes detected by fluorescence and the loss of hexameric structure accompanied by the dissociation to monomers, as indicated by glutaraldehyde fixation.

Crystallization of NAD+-dependent phenylalanine dehydrogenase from Nocardia sp239

The NAD+-dependent phenylalanine dehydrogenase from Nocardia sp239 has been crystallized by the hanging-drop method of vapour diffusion using ammonium sulfate as the precipitant. Two crystal forms were obtained in the presence and absence of the enzyme substrates phenylpyruvic acid or phenylalanine and its coenzyme NADH. Crystals of the native protein belong to the hexagonal system, with the space group being one of the enantiomorphic pair P6122 or P6522. The cell dimensions are a = b = 111.0, c = 174.5 A, alpha = beta = 90 and gamma = 120 degrees. Crystals grown from the protein co-crystallized with its substrates all belong to the trigonal system, space group P3121 or P3221, with unit-cell dimensions of a = b = 88.1, c = 112.6 A, alpha = beta = 90 and gamma = 120 degrees. Preliminary protein-sequencing experiments have established that this enzyme is related to the octameric PheDHs which are members of the wider superfamily of amino-acid dehydrogenases. However, gel-filtration studies suggest that this enzyme is active as a monomer. The full determination of the three-dimensional structure of this phenylalanine dehydrogenase will add to the understanding of the molecular basis of the differential substrate specificity within this enzyme superfamily. In turn this will contribute to the rational design of an amino-acid dehydrogenase which could be used for the diagnosis of phenylketonuria and for the chiral synthesis of high-value pharmaceuticals.

Structural basis of the transactivation deficiency of the human PPARγ F360L mutant associated with familial partial lipodystrophy

The peroxisome proliferator-activated receptors (PPARs) are transcription factors that regulate glucose and lipid metabolism. The role of PPARs in several chronic diseases such as type 2 diabetes, obesity and atherosclerosis is well known and, for this reason, they are the targets of antidiabetic and hypolipidaemic drugs. In the last decade, some rare mutations in human PPARγ that might be associated with partial lipodystrophy, dyslipidaemia, insulin resistance and colon cancer have emerged. In particular, the F360L mutant of PPARγ (PPARγ2 residue 388), which is associated with familial partial lipodystrophy, significantly decreases basal transcriptional activity and impairs stimulation by synthetic ligands. To date, the structural reason for this defective behaviour is unclear. Therefore, the crystal structure of PPARγ F360L together with the partial agonist LT175 has been solved and the mutant has been characterized by circular-dichroism spectroscopy (CD) in order to compare its thermal stability with that of the wild-type receptor. The X-ray analysis showed that the mutation induces dramatic conformational changes in the C-terminal part of the receptor ligand-binding domain (LBD) owing to the loss of van der Waals interactions made by the Phe360 residue in the wild type and an important salt bridge made by Arg357, with consequent rearrangement of loop 11/12 and the activation function helix 12 (H12). The increased mobility of H12 makes the binding of co-activators in the hydrophobic cleft less efficient, thereby markedly lowering the transactivation activity. The spectroscopic analysis in solution and molecular-dynamics (MD) simulations provided results which were in agreement and consistent with the mutant conformational changes observed by X-ray analysis. Moreover, to evaluate the importance of the salt bridge made by Arg357, the crystal structure of the PPARγ R357A mutant in complex with the agonist rosiglitazone has been solved.

Crystallization of the NAD(P)-dependent glutamate dehydrogenase from the hyperthermophile Pyrococcus furiosus

The NAD(P)-dependent glutamate dehydrogenase from Pyrococcus furiosus has been crystallized by the hanging-drop method of vapour diffusion using lithium sulfate as the precipitant. The crystals belong to the tetragonal system and are in space group P4(2)2(1)2 with unit-cell dimensions of a = b = 167.2, c = 172.9 A. Consideration of the values of V(m) and possible packing of the molecules within the cell suggest that the asymmetric unit contains a trimer. P. furiosus belongs to the family of Archaea and is one of the most thermostable organisms known, having an optimal growth temperature of 376 K. The glutamate dehydrogenase isolated from this organism has a half-life of 12 h at 373 K and, therefore, the determination of the structure of this enzyme will be important in advancing our understanding of how proteins are adapted to enable them to survive at such extreme temperatures.

Single-Nucleotide Polymorphism of PPARγ, a Protein at the Crossroads of Physiological and Pathological Processes

Genome polymorphisms are responsible for phenotypic differences between humans and for individual susceptibility to genetic diseases and therapeutic responses. Non-synonymous single-nucleotide polymorphisms (nsSNPs) lead to protein variants with a change in the amino acid sequence that may affect the structure and/or function of the protein and may be utilized as efficient structural and functional markers of association to complex diseases. This study is focused on nsSNP variants of the ligand binding domain of PPARγ a nuclear receptor in the superfamily of ligand inducible transcription factors that play an important role in regulating lipid metabolism and in several processes ranging from cellular differentiation and development to carcinogenesis. Here we selected nine nsSNPs variants of the PPARγ ligand binding domain, V290M, R357A, R397C, F360L, P467L, Q286P, R288H, E324K, and E460K, expressed in cancer tissues and/or associated with partial lipodystrophy and insulin resistance. The effects of a single amino acid change on the thermodynamic stability of PPARγ, its spectral properties, and molecular dynamics have been investigated. The nsSNPs PPARγ variants show alteration of dynamics and tertiary contacts that impair the correct reciprocal positioning of helices 3 and 12, crucially important for PPARγ functioning.

Crystallization of RusA Holliday junction resolvase from Escherichia coli.

Crystals of the Escherichia coli Holliday junction resolvase RusA have been obtained using the hanging-drop method and characterized. The crystals have a primitive monoclinic form and belong to space group P2(1). The V(M) value suggests the presence of two copies of the monomer in the asymmetric unit. A full three-wavelength MAD data collection on a selenomethionine-incorporated form has been undertaken and structure determination is under way using data collected to 2.1 A resolution.

The phosphoglycerate kinase 1 variants found in carcinoma cells display different catalytic activity and conformational stability compared to the native enzyme

Cancer cells are able to survive in difficult conditions, reprogramming their metabolism according to their requirements. Under hypoxic conditions they shift from oxidative phosphorylation to aerobic glycolysis, a behavior known as Warburg effect. In the last years, glycolytic enzymes have been identified as potential targets for alternative anticancer therapies. Recently, phosphoglycerate kinase 1 (PGK1), an ubiquitous enzyme expressed in all somatic cells that catalyzes the seventh step of glycolysis which consists of the reversible phosphotransfer reaction from 1,3-bisphosphoglycerate to ADP, has been discovered to be overexpressed in many cancer types. Moreover, several somatic variants of PGK1 have been identified in tumors. In this study we analyzed the effect of the single nucleotide variants found in cancer tissues on the PGK1 structure and function. Our results clearly show that the variants display a decreased catalytic efficiency and/or thermodynamic stability and an altered local tertiary structure, as shown by the solved X-ray structures. The changes in the catalytic properties and in the stability of the PGK1 variants, mainly due to the local changes evidenced by the X-ray structures, suggest also changes in the functional role of PGK to support the biosynthetic need of the growing and proliferating tumour cells.

NAD-dependent glutamate dehydrogenase from the thermophilic eubacterium Bacillus acidocaldarius

The first thermophilic eubacterial glutamate dehydrogenase was purified to homogeneity from Bacillus acidocaldarius to compare its molecular properties with those of the glutamate dehydrogenase from thermophilic archaea. Glutamate dehydrogenase represents 2% of the total soluble proteins of B. acidocaldarius, an amount that may suggest an important role for this enzyme in nitrogen metabolism of the thermophilic eubacterium. The protein is a hexamer (subunit mass 48 kDa) and undergoes dissociation during gel filtration analysis. Isoelectric focusing of the purified enzyme indicated a pI of 4.5. The enzyme is strictly specific for NAD, 2-oxoglutarate, and l-glutamate. The thermal stability of B. acidocaldarius glutamate dehydrogenase is dependent on protein concentration.