Metabonomic analysis of hepatitis E patients shows deregulated metabolic cycles and abnormalities in amino acid metabolism.

Hepatitis E, which is endemic to resource-poor regions of the world, is largely an acute and self-limiting disease, but some patients have an increased susceptibility to develop fulminant hepatitis. The pathogenesis of hepatitis E in humans is poorly characterized. To understand the metabolic pathways involved in the pathophysiology of hepatitis E, we have used (1) H nuclear magnetic resonance spectroscopy to quantify various metabolites in the plasma and urine of the patients with hepatitis E. These were compared with specimens from patients with acute hepatitis B as disease controls and healthy volunteers. Data were analysed using chemometric statistical methods and metabolite databases. The main metabonomic changes found in patients with hepatitis E, but not in those with hepatitis B, included increased plasma levels of L-isoleucine, acetone, and glycerol, reduced plasma levels of glycine, and reduced urinary levels of imidazole, 3-aminoisobutanoic acid, 1-methylnicotinamide, biopterin, adenosine, 1-methylhistidine, and salicyluric acid. Patients with hepatitis E or B both showed increased levels of plasma and urinary L-proline and decreased levels of various other metabolites. Pathway analysis tools suggest the involvement of glycolysis, tricarboxylic acid cycle, urea cycle, and amino acid metabolism in patients with acute hepatitis E. These findings may help better understand the clinical and biochemical manifestations in this disease and the underlying pathophysiologic processes. Based on our findings, it would be worthwhile determining whether patients with hepatitis E are more prone to develop lactic acidosis and ketosis compared with other forms of viral hepatitis.

An efficient high-throughput resonance assignment procedure for structural genomics and protein folding research by NMR.

Sequence specific resonance assignment is the primary requirement for all investigations of proteins by NMR methods. In the present postgenomic era where structural genomics and protein folding have occupied the center stage of NMR research, there is a high demand on the speed of resonance assignment, whereas the presently available methods based either on NOESY or on some triple-resonance experiments are rather slow. They also have limited success with unfolded proteins because of the lack of NOEs, and poor dispersion of amide and carbon chemical shifts. This paper describes an efficient approach to rapid resonance assignment that is suitable for both folded and unfolded proteins, making use of the triple-resonance experiments described recently [HNN and HN(C)N]. It has three underlying principles. First, the experiments exploit the (15)N chemical shift dispersions which are generally very good for both folded and unfolded proteins, along two of the three dimensions; second, they directly display sequential amide and (15)N correlations along the polypeptide chain, and third, the sign patterns of the diagonal and the sequential peaks originating from any residue are dependent on the nature of the adjacent residues, especially the glycines and the prolines. These lead to so-called "triplet fixed points" which serve as starting points and/or check points during the course of sequential walks, and explicit side chains assignment becomes less crucial for unambiguous backbone assignment. These features significantly enhance the speed of data analysis, reduce the amount of experimentation required, and thus result in a substantially faster and unambiguous assignment. Following the amide and (15)N assignments, the other proton and carbon assignments can be obtained in a straightforward manner, from the well-established three-dimensional triple-resonance experiments. We have successfully tested the new approach with different proteins in the molecular mass range of 10-22 kDa, and for illustration, we present here the backbone results on the HIV-1 protease-tethered dimer (molecular mass approximately 22 kDa), both in the folded and in the unfolded forms, the two ends of the folding funnel. We believe that the new assignment approach will be of great value for both structural genomics and protein folding research by NMR.

NMR identification of local structural preferences in HIV-1 protease tethered heterodimer in 6 M guanidine hydrochloride.

Understanding protein folding requires complete characterization of all the states of the protein present along the folding pathways. For this purpose nuclear magnetic resonance (NMR) has proved to be a very powerful technique because of the great detail it can unravel regarding the structure and dynamics of protein molecules. We report here NMR identification of local structural preferences in human immunodeficiency virus-1 protease in the 'unfolded state'. Analyses of the chemical shifts revealed the presence of local structural preferences many of which are native-like, and there are also some non-native structural elements. Three-bond H(N)-H(alpha) coupling constants that could be measured for some of the N-terminal and C-terminal residues are consistent with the native-like beta-structure. Unusually shifted 15N and amide proton chemical shifts of residues adjacent to some prolines and tryptophans also indicate the presence of some structural elements. These conclusions are supported by amide proton temperature coefficients and nuclear Overhauser enhancement data. The locations of the residues exhibiting preferred structural propensities on the crystal structure of the protein, give useful insights into the folding mechanism of this protein.

Improved 3D triple resonance experiments, HNN and HN(C)N, for HN and 15N sequential correlations in (13C, 15N) labeled proteins: application to unfolded proteins.

Two triple resonance experiments, HNN and HN(C)N, are presented which correlate HN and 15N resonances sequentially along the polypeptide chain of a doubly (13C, 15N) labeled protein. These incorporate several improvements over the previously published sequences for a similar purpose and have several novel features. The spectral characteristics enable direct identification of certain triplets of residues, which provide many starting points for the sequential assignment procedure. The experiments are sensitive and their utility has been demonstrated with a 22 kDa protein under unfolding conditions where most of the standard triple resonance experiments such as HNCA, CBCANH etc. have limited success because of poor amide, Calpha and Cbeta chemical shift dispersions.

Real time NMR monitoring of local unfolding of HIV-1 protease tethered dimer driven by autolysis.

Structural studies in proteases have been hampered because of their inherent autolytic function. However, since autolysis is known to be mediated via protein unfolding, careful monitoring of the autolytic reaction has the potential to throw light on the folding-unfolding equilibria. In this paper we describe real time nuclear magnetic resonance investigations on the tethered dimer construct of the human immunodeficiency virus-1 protease, which have yielded insights into the relative stabilities of several residues in the protein. The residues lying along the active site (bottom, side and top of the active site) and those in helix have lower unfolding free energy values than the other parts of the protein. The residue level stability differences suggest that the protein is well suited to adjust itself in almost all the regions of its structure, as and when perturbations occur, either due to ligand binding or due to mutations.

Cation-dependent conformational switches in d-TGGCGGC containing two triplet repeats of Fragile X Syndrome: NMR observations.

Higher ordered structures formed by different DNA sequences have been widely investigated in recent years because of their implications in a variety of biological functions. Among these, G-quadruplexes have exhibited a great variety depending on the exact sequence, the lengths of the G-stretches, interception by other nucleotides, and environmental conditions such as pH, temperature, salt type, and its concentration. We report here interesting conformational switches observed by NMR in the sequence d-TGGCGGC containing two GGC triplet repeats related to the disease Fragile X-Syndrome. At neutral pH, the solution structure is a parallel-stranded quadruplex in presence of K(+) ions. Lowering the pH does not cause a major change in the structure; however, the chemical shift patterns of the C4 and G3 base protons suggest protonation of the C-tetrad in the center of the quadruplex. In contrast, the sequence forms an antiparallel duplex in Na(+) containing solutions. As the pH of the Na(+) sample is lowered, an equilibrium mixture of a duplex and a quadruplex appears, and at pH 2.2, the molecule exists entirely as a quadruplex. These results would be of significance from the point of view of recognition and regulation by different helicase enzymes, which have been found to discriminate between different types of quadruplex structures.

NMR observation of a novel C-tetrad in the structure of the SV40 repeat sequence GGGCGG.

We report the NMR structure of the DNA sequence d-TGGGCGGT in Na(+) solutions at neutral pH, containing a repeat sequence from SV40 viral genome. The structure is a novel quadruplex incorporating the C-tetrad formed by symmetrical pairing of four Cs via NH(2)&bond;O(2) H-bonds in a plane. The C-tetrad has a wider cavity compared to G-tetrads and stacks well over the adjacent G4-tetrad, but poorly on the G6 tetrad. The quadruplex helix is largely underwound by 8-10 degrees compared to B-DNA except at the C5-G6 step. To our knowledge this is the first report of C-tetrad formation in DNA structures, and would be of significance from the point of view of both structural diversity and specific recognition.