Vinod Bhakuni

Membrane skeleton-bilayer interaction is not the major determinant of membrane phospholipid asymmetry in human erythrocytes☆

Transbilayer phospholipid distribution, membrane skeleton dissociation/association, and spectrin structure have been analysed in human erythrocytes after subjecting them to heating at 50 degrees C for 15 min. The membrane skeleton dissociation/association was determined by measuring the Tris-induced dissociation of Triton-insoluble membrane skeletons (Triton shells), the spectrin-actin extractability under low ionic conditions, and the binding of spectrin-actin with normal erythrocyte membrane inside-out vesicles (IOVs). The spectrin structure was ascertained by measuring the spectrin dimer-to-tetramer ratio as well as the spectrin tryptophan fluorescence. Both the Tris-induced Triton shell dissociation and the spectrin-actin extractability under low ionic conditions were considerably reduced by the heat treatment. Also, the binding of heated erythrocyte spectrin-actin to IOVs was significantly smaller than that observed with the normal cell spectrin-actin. Further, the quantity of spectrin dimers was appreciably increased in heat-treated erythrocytes as compared to the normal cells. This change in the spectrin dimer-to-tetramer ratio was accompanied by marked changes in the spectrin tryptophan fluorescence. In spite of these heat-induced alterations in structure and bilayer interactions of the membrane skeleton, the inside-outside glycerophospholipid distribution remained virtually unaffected in the heat-treated cells, as judged by employing bee venom and pancreatic phospholipase A2, fluorescamine and Merocyanine 540 as the external membrane probes. These results strongly indicate that membrane bilayer-skeleton interaction is not the major factor in determining the transbilayer phospholipid asymmetry in human erythrocyte membrane.

Unique oligomeric intermediates of bovine liver catalase

Catalases, although synthesized from single genes and built up from only one type of subunit, exist in heterogeneous form with respect to their conformations and association states in biological systems. This heterogeneity is not of genetic origin, but rather reflects the instability of this oligomeric heme enzyme. To understand better the factors that stabilize the various association states of catalase, we performed studies on the multimeric intermediates that are stabilized during guanidine‐hydrochloride‐ and urea‐induced unfolding of bovine liver catalase (BLC). For the first time, we have observed an enzymatically active, folded dimer of native BLC. This dimer has slightly higher enzymatic activity and altered structural properties compared to the native tetramer. Comparative studies of the effect of NaCl, GdmCl, and urea on BLC show that cation binding to negatively charged groups present in amino acid side chains of the enzyme leads to stabilization of an enzymatically active, folded dimer of BLC. Besides the folded dimer, an enzymatically active expanded tetramer and a partially unfolded, enzymatically inactive dimer of BLC were also observed. A complete recovery of native enzyme was observed on refolding of expanded tetramers and folded dimers; however, a very low recovery (maximum of ∼5%) of native enzyme was observed on refolding of partially unfolded dimers and fully unfolded monomers.

Unusual structural, functional, and stability properties of serine hydroxymethyltransferase from Mycobacterium tuberculosis

From the genome analysis of the Mycobacterium tuberculosis two putative genes namely GlyA and GlyA2 have been proposed to encode for the enzyme serine hydroxymethyltransferase. We have cloned, overexpressed, and purified to homogeneity their respective protein products, serine hydroxymethyltransferase, SHM1 and SHM2. The recombinant SHM1 and SHM2 exist as homodimers of molecular mass about 90 kDa under physiological conditions, however, SHM2 has more compact conformation and higher thermal stability than SHM1. The most interesting structural observation was that the SHM1 contains 1 mol of pyridoxal 5′-phosphate (PLP)/mol of enzyme dimer. This is the first report of such a unique stoichiometry of PLP and enzyme dimer for SHMT. The SHM2 contains 2 mol of PLP/mol of enzyme dimer, which is the usual stoichiometry reported for SHMT. Functionally both the recombinant enzymes showed catalysis of reversible interconversion of serine and glycine and aldol cleavage of a 3-hydroxyamino acid. However, unlike SHMT from other sources both SHM1 and SHM2 do not undergo half-transamination reaction with d-alanine resulting in formation of apoenzyme but l-cysteine removed the prosthetic group, PLP, from both the recombinant enzymes leaving the respective inactive apoenzymes. Comparative structural studies on the two enzymes showed that the SHM1 is resistant to alkaline denaturation up to pH 10.5, whereas the native SHM2 dimer dissociates into monomer at pH 9. Urea- and guanidinium chloride-induced two-step unfolding of SHM1 and SHM2 with the first step being dissociation of dimer into apomonomer at low denaturant concentrations followed by unfolding of the stabilized monomer at higher denaturant concentrations.

Guanidinium chloride- and urea-induced unfolding of FprA, a mycobacterium NADPH-ferredoxin reductase stabilization of an apo-protein by GdmCl

The guanidinium chloride‐ and urea‐induced unfolding of FprA, a mycobacterium NADPH‐ferredoxin reductase, was examined in detail using multiple spectroscopic techniques, enzyme activity measurements and size exclusion chromatography. The equilibrium unfolding of FprA by urea is a cooperative process where no stabilization of any partially folded intermediate of protein is observed. In comparison, the unfolding of FprA by guanidinium chloride proceeds through intermediates that are stabilized by interaction of protein with guanidinium chloride. In the presence of low concentrations of guanidinium chloride the protein undergoes compaction of the native conformation; this is due to optimization of charge in the native protein caused by electrostatic shielding by the guanidinium cation of charges on the polar groups located on the protein side chains. At a guanidinium chloride concentration of about 0.8 m, stabilization of apo‐protein was observed. The stabilization of apo‐FprA by guanidinium chloride is probably the result of direct binding of the Gdm+ cation to protein. The results presented here suggest that the difference between the urea‐ and guanidinium chloride‐induced unfolding of FprA could be due to electrostatic interactions stabilizating the native conformation of this protein.

Mycobacterium tuberculosis isocitrate lyase (MtbIcl): Role of divalent cations in modulation of functional and structural properties

Isocitrate lyase (Icl), an enzyme that plays an important role in the regulation of isocitrate flux and anaplerotic replenishment of pool of substrate required for biosynthetic process in Mycobacterium tuberculosis is a potential drug target for the antituberculosis drugs. Divalent cations induce differential effect of activation and inhibition of MtbIcl functional activity. The study for the first time demonstrates that interaction of cations with MtbIcl results in differential modulation of the enzyme structure which is probably the underlying mechanism for differential modulation of functional activity of enzyme by divalent cations. The Mg2+ and Mn2+ ions act as activators of the enzyme and in their absence no enzymatic activity was observed. These cations do not induce any significant structural alteration in the enzyme as observed by far‐UV CD and solvent denaturation studies using chaotropic salts. However, the thermal denaturation studies demonstrate that they do interact with the noncatalytic α/β barrel core domain of the enzyme and destabilize it. The inhibitors Zn2+ and Cd2+ interact directly with the catalytic domain of the enzyme and unfold it as a result of which complete loss of the enzymatic activity is observed in their presence. The results obtained from the studies provide intriguing insight into the possible mechanism of divalent cation‐induced changes in structure, function, and stability of MtbIcl. Proteins 2008.

Characterization of intracellular metabolites of axenic amastigotes of Leishmania donovani by 1H NMR spectroscopy.

The intracellular metabolites of long-term in vitro cultured axenic amastigotes of Leishmania donovani (strain Dd8) were determined and compared with those of promastigotes and intracellular amastigotes, employing proton NMR spectroscopy. The presence of two new metabolites, i.e. betaine and beta-hydroxybutyrate were reported. Betaine was detected in all the three stages being highest in the promastigotes while beta-hydroxybutyrate could be detected only in promastigotes and axenic amastigotes. Among other metabolites, succinate and valine were found in higher quantities in intracellular amastigotes and axenic amastigotes than in promastigotes. Acetoacetate was present only in axenic and intracellular amastigotes. The comparative metabolite profile of different parasite forms reveals that axenic amastigotes seem to represent an intermediate stage between promastigotes and intracellular amastigotes in spite of their strong resemblance to intracellular amastigotes in morphology, infectivity, biochemical studies and even in the manifestation of amastigote specific A2 protein.

Polysaccharide binding sites in hyaluronate lyase – crystal structures of native phage–encoded hyaluronate lyase and its complexes with ascorbic acid and lactose

Hyaluronate lyases are a class of endoglycosaminidase enzymes with a high level of complexity and heterogeneity. The main function of the Streptococcus pyogenes bacteriophage protein hyaluronate lyase, HylP2, is to degrade hyaluronan into unsaturated disaccharide units. HylP2 was cloned, over‐expressed and purified to homogeneity. The recombinant HylP2 exists as a homotrimer with a molecular mass of approximately 110 kDa under physiological conditions. The HylP2 was crystallized and the crystals were soaked in two separate reservoir solutions containing ascorbic acid and lactose, respectively. The crystal structures of native HylP2 and its two complexes with ascorbic acid and lactose have been determined. HylP2 folds into four distinct domains with a central core consisting of 16 antiparallel β‐strands forming an irregular triangular tube designated as triple‐stranded β‐helix. The structures of complexes show that three molecules each of ascorbic acid and lactose bind to protein at the sugar binding groove in the triple‐stranded β‐helix domain. Both ascorbic acid and lactose molecules occupy almost identical subsites in the long saccharide binding groove. Both ligands are involved in several hydrogen bonded interactions at each subsite. The binding characteristics and stereochemical properties indicate that Tyr264 may be involved in the catalytic activity of HylP2. The mutation of Tyr264 to Phe264 supports this observation.

Trichloroacetic acid and trifluoroacetic acid-induced unfolding of cytochrome c: stabilization of a native-like folded intermediate

A systematic investigation of trichloroacetic acid (TCA) and trifluoroacetic acid (TFA)-induced equilibrium unfolding of native horse cytochrome c has been carried out using a combination of optical spectroscopy and electrospray ionization mass spectroscopy (ESI MS). In the presence of an increasing concentration of TCA the native cytochrome c does not undergo significant unfolding but stabilization of a partially folded intermediate is observed. This TCA-induced partially folding intermediate of cytochrome c had an enhanced secondary structure and slightly disrupted tertiary structure compared to native protein and undergoes extensive unfolding in the presence of TFA. However, in the presence of an increasing concentration of TFA, cytochrome c was found to undergo extensive unfolding characterized by a significant breakdown of the secondary and tertiary structure of protein. The TFA-unfolded cytochrome c was found to undergo folding in the presence of TCA and low guanidine hydrochloride (GdmCl) resulting in the stabilization of the partially folded intermediate. The effectiveness of TCA as compared to TFA in the stabilization of intermediates was further supported by the observation that low concentrations of TCA were found to induce refolding of HCl-denatured cytochrome c whereas, under similar concentrations of acid, no significant effect on the unfolded structure of protein was observed in the presence of TFA. ESI MS studies indicated that the trichloroacetate anion has a greater affinity for cytochrome c compared to trifluoroacetate anion, which might be the reason for the stabilization of the native-like folded intermediate during TCA-induced denaturation of cytochrome c as compared to extensive unfolding observed in the presence of TFA.

Glutathione mediated regulation of oligomeric structure and functional activity of Plasmodium falciparum glutathione S-transferase

BackgroundIn contrast to many other organisms, the malarial parasite Plasmodium falciparum possesses only one typical glutathione S-transferase. This enzyme, Pf GST, cannot be assigned to any of the known GST classes and represents a most interesting target for antimalarial drug development. The Pf GST under native conditions forms non-covalently linked higher aggregates with major population (~98%) being tetramer. However, in the presence of 2 mM GSH, a dimer of Pf GST is observed. Recently reported study on binding and catalytic properties of Pf GST indicated a GSH dependent low-high affinity transition with simultaneous binding of two GSH molecules to Pf GST dimer suggesting that GSH binds to low affinity inactive enzyme dimer converting it to high affinity functionally active dimer. In order to understand the role of GSH in tetramer-dimer transition of Pf GST as well as in modulation of functional activity of the enzyme, detailed structural, functional and stability studies on recombinant Pf GST in the presence and absence of GSH were carried out.ResultsOur data indicate that the dimer – and not the tetramer – is the active form of Pf GST, and that substrate saturation is directly paralleled by dissociation of the tetramer. Furthermore, this dissociation is a reversible process indicating that the tetramer-dimer equilibrium of Pf GST is defined by the surrounding GSH concentration. Equilibrium denaturation studies show that the Pf GST tetramer has significantly higher stability compared to the dimer. The enhanced stability of the tetramer is likely to be due to stronger ionic interactions existing in it.ConclusionThis is the first report for any GST where an alteration in oligomeric structure and not just small conformational change is observed upon GSH binding to the enzyme. Furthermore we also demonstrate a reversible mechanism of regulation of functional activity of Plasmodium falciparum glutathione S-transferase via GSH induced dissociation of functionally inactive tetramer into active dimers.

Heat-induced alterations in monkey erythrocyte membrane phospholipid organization and skeletal protein structure and interactions

Rhesus monkey erythrocytes were subjected to heating at 50 degrees C for 5-15 min, and the heat-induced effects on the membrane structure were ascertained by analysing the membrane phospholipid organization and membrane skeleton dynamics and interactions in the heated cells. Membrane skeleton dynamics and interactions were determined by measuring the Tris-induced dissociation of the Triton-insoluble membrane skeleton (Triton shells), the spectrin-actin extractability at low ionic strength, spectrin self-association and spectrin binding to normal monkey erythrocyte membrane inside-out vesicles (IOVs). The Tris-induced Triton shell dissociation and spectrin-actin extractability were markedly decreased by the erythrocyte heating. Also, the binding of the heated erythrocyte membrane spectrin-actin with the IOVs was much smaller than that observed with the normal erythrocyte spectrin-actin. Further, the spectrin structure was extensively modified in the heated cells, as compared to the normal erythrocytes. Transbilayer phospholipid organization was ascertained by employing bee venom and pancreatic phospholipases A2, fluorescamine, and Merocyanine 540 as the external membrane probes. The amounts of aminophospholipids hydrolysed by phospholipases A2 or labeled by fluorescamine in intact erythrocytes considerably increased after subjecting them to heating at 50 degrees C for 15 min. Also, the fluorescent dye Merocyanine 540 readily stained the 15-min-heated cells but not the fresh erythrocytes. Unlike these findings, the extent of aminophospholipid hydrolysis in 5-min-heated cells by phospholipases A2 depended on the incubation time. While no change in the membrane phospholipid organization could be detected in 10 min, prolonged incubations led to the increased aminophospholipid hydrolysis. Similarly, fluorescamine failed to detect any change in the transbilayer phospholipid distribution soon after the 5 min heating, but it labeled greater amounts of aminophospholipids in the 5-min-heated cells, as compared to normal cells, after incubating them for 4 h at 37 degrees C. These results have been discussed to analyse the role of membrane skeleton in maintaining the erythrocyte membrane phospholipid asymmetry. It has been concluded that both the ATP-dependent aminophospholipid pump and membrane bilayer-skeleton interactions are required to maintain the transbilayer phospholipid asymmetry in native erythrocyte membrane.