Effect of dextran on protein stability and conformation attributed to macromolecular crowding

Thermally induced transition curves of hen egg-white lysozyme were measured in the presence of several concentrations of dextran at pH 2.0 by near-UV and far-UV CD. The transition curves were fitted to a two-state model by a non-linear, least-squares method to obtain the transition temperature (T(m)), enthalpy change (deltaH(u)(T(m))), and free energy change (deltaG(u)(T)) of the unfolding transition. An increase in T(m) and almost constant deltaH(u)(T(m)) values were observed in the presence of added dextran at concentrations exceeding ca 100 g l(-1). In addition, dextran-induced conformational changes of fully unfolded protein were investigated by CD spectroscopy. Addition of high concentrations of dextran to solutions of acid-unfolded cytochrome c at pH 2.0 results in a shift of the CD spectrum from that characteristic of the fully unfolded polypeptide to that characteristic of the more compact, salt-induced molten globule state, a result suggesting that the molten globule-like state is stabilized relative to the fully unfolded form in crowded environments. Both observations are in qualitative accord with predictions of a previously proposed model for the effect of intermolecular excluded volume (macromolecular crowding) on protein stability and conformation.

Role for phospholipid interactions in the trafficking defect of Delta F508-CFTR

Cystic fibrosis commonly occurs as a consequence of the DeltaF508 mutation in the first nucleotide binding fold domain (NBF-1) of CFTR. The mutation causes retention of the mutant CFTR molecule in the endoplasmic reticulum, and this aberrant trafficking event is believed to be due to defective interactions between the mutant NBF-1 domain and other cellular factors in the endoplasmic reticulum. Since the NBF-1 domain has been shown to interact with membranes, we wanted to investigate whether NBF-1 and CFTR interactions with specific phospholipid chaperones might play a role in trafficking. We have found that the recombinant wild-type NBF-1 interacts selectively with phosphatidylserine (PS) rather than phosphatidylcholine (PC). By contrast, NBF-1 carrying the DeltaF508 mutation loses the ability to discriminate between these two phospholipids. In cells expressing DeltaF508-CFTR, replacement of PC by noncharged analogues results in an absolute increase in CFTR expression. In addition, we detected progressive expression of higher molecular weight CFTR forms. Thus, phospholipid chaperones may be important for CFTR trafficking, and contribute to the pathology of cystic fibrosis.

Differential expression of thyroid hormone receptor isoforms dictates the dominant negative activity of mutant Beta receptor

Mutations in the thyroid hormone receptor beta gene (TRbeta) cause resistance to thyroid hormone (RTH). Genetic analyses indicate that phenotypic manifestation of RTH is due to the dominant negative action of mutant TRbeta. However, the molecular mechanisms underlying the dominant negative action of mutants and how the same mutation results in marked variability of resistance in different tissues in vivo are not clear. Here we used a knock-in mouse (TRbetaPV mouse) that faithfully reproduces human RTH to address these questions. We demonstrated directly that TRbeta1 protein was approximately 3-fold higher than TRalpha1 in the liver of TRbeta(+/+) mice but was not detectable in the heart of wild-type and TRbetaPV mice. The abundance of PV in the liver of TRbeta(PV/PV) was more than TRbeta(PV/+) mice but not detectable in the heart. TRalpha1 in the liver was approximately 6-fold higher than that in the heart of wild-type and TRbetaPV mice. Using TR isoforms and PV-specific antibodies in gel shift assays, we found that in vivo, PV competed not only with TR isoforms for binding to thyroid hormone response elements (TRE) but also competed with TR for the retinoid X receptors in binding to TRE. These competitions led to the inhibition of the thyroid hormone (T(3))-positive regulated genes in the liver. In the heart, however, PV was significantly lower and thus could not effectively compete with TRalpha1 for binding to TRE, resulting in activation of the T(3)-target genes by higher levels of circulating thyroid hormones. These results indicate that in vivo, differential expression of TR isoforms in tissues dictates the dominant negative activity of mutant beta receptor, thereby resulting in variable phenotypic expression in RTH.

Yeast cystathionine beta-synthase reacts with L-allothreonine, a non-natural substrate, and L-homocysteine to form a new amino acid, 3-methyl-L-cystathionine

Our studies of the reaction mechanism of cystathionine beta-synthase from yeast (Saccharomyces cerevisiae) are facilitated by the spectroscopic properties of the pyridoxal phosphate coenzyme. The enzyme catalyzes the reaction of L-serine with L-homocysteine to form L-cystathionine through a series of pyridoxal phosphate intermediates. In this work, we explore the substrate specificity of the enzyme by use of substrate analogues combined with kinetic measurements under pre-steady-state conditions and with circular dichroism and fluorescence spectroscopy under steady-state conditions. Our results show that L-allothreonine, but not L-threonine, serves as an effective substrate. L-Allothreonine reacts with the pyridoxal phosphate cofactor to form a stable 3-methyl aminoacrylate intermediate that absorbs maximally at 446 nm. The rapid-scanning stopped-flow results show that the binding of L-allothreonine as the external aldimine is faster than formation of the 3-methyl aminoacrylate intermediate. The 3-methyl aminoacrylate intermediate reacts with L-homocysteine to form a new amino acid, 3-methyl-L-cystathionine, which was characterized by nuclear magnetic resonance spectroscopy. This new amino acid may be a useful analogue of L-cystathionine.

Expression of mutant thyroid hormone nuclear receptors is associated with human renal clear cell carcinoma

Thyroid hormone (T(3)) regulates proliferation and differentiation of cells, via its nuclear receptors (TRs). These processes have been shown to be abnormally regulated during carcinogenesis. We have previously found aberrant expression of TRalpha and TRbeta mRNAs in renal clear cell carcinoma (RCCC), suggesting possible involvement of TRs in the carcinogenesis of RCCC. To understand the molecular actions of TRs in RCCC, cDNAs for TRbeta1 and TRalpha1 were cloned from 22 RCCC tissues and 20 surrounding normal tissues. Mutations were found in seven TRbeta1 and three TRalpha1 cDNAs. Two TRbeta1 cDNAs had a single mutation, while five TRbeta1 and three TRalpha1 had two or three mutations. Most of the mutations were localized in the hormone-binding domain. Using the TRs prepared by in vitro transcription/translation, we found that these mutations led to a loss of T(3) binding activity and/or impairment in binding to thyroid hormone response elements (TREs). Furthermore, nuclear extracts from RCCC tissues also exhibited impairment in binding to TREs. These results indicate that the normal functions of TRs in RCCC tissues were impaired. Together with the aberrant expression patterns, these mutated TRs could contribute to the carcinogenesis of RCCC.

The reaction of yeast cystathionine beta-synthase is rate-limited by the conversion of aminoacrylate to cystathionine

Our studies of the reaction mechanism of cystathionine beta-synthase from Saccharomyces cerevisiae (yeast) are facilitated by the spectroscopic properties of the pyridoxal phosphate coenzyme that forms a series of intermediates in the reaction of L-serine and L-homocysteine to form L-cystathionine. To characterize these reaction intermediates, we have carried out rapid-scanning stopped-flow and single-wavelength stopped-flow kinetic measurements under pre-steady-state conditions, as well as circular dichroism and fluorescence spectroscopy under steady-state conditions. We find that the gem-diamine and external aldimine of aminoacrylate are the primary intermediates in the forward half-reaction with L-serine and that the external aldimine of aminoacrylate or its complex with L-homocysteine is the primary intermediate in the reverse half-reaction with L-cystathionine. The second forward half-reaction of aminoacrylate with L-homocysteine is rapid. No primary kinetic isotope effect was obtained in the forward half-reaction with L-serine. The results provide evidence (1) that the formation of the external aldimine of L-serine is faster than the formation of the aminoacrylate intermediate, (2) that aminoacrylate is formed by the concerted removal of the alpha-proton and the hydroxyl group of L-serine, and (3) that the rate of the overall reaction is rate-limited by the conversion of aminoacrylate to L-cystathionine. We compare our results with cystathionine beta-synthase with those of related investigations of tryptophan synthase and O-acetylserine sulfhydrylase.

Circular dichroism studies on proteins in films and in solution: estimation of secondary structure by g-factor analysis

Estimates of the secondary structure of a protein in solution are made by mathematical analyses of its circular dichroism (CD) spectrum below 240 nm. All current procedures require accurate determination of the concentration of the protein sample. Insoluble proteins, such as prions or amyloid, are examined as thin films or gels, but concentrations cannot be precisely defined. The ratio of a sample's CD and absorbance signals is the g-factor, an intensive property. The g-factor spectra of 19 soluble, unconjugated proteins of known structures were measured and used to derive basis spectra, characteristic of the four major structural elements, helix, sheet, turn, and remainder. Using these, the g-factor spectra of other unconjugated proteins, measured in solution or as films, can be analyzed by linear regression to give good estimates of their secondary structures when protein concentration cannot be determined.

Enzymatic aspects of the phenol (aryl) sulfotransferases

The sulfotransferases that are active in the metabolism of xenobiotics represent a large family of enzymes that catalyze the transfer of the sulfuryl group from 3'-phosphoadenosine 5'-phosphosulfate to phenols, to primary and secondary alcohols, to several additional oxygen-containing functional groups, and to amines. Restriction of this review to the catalytic processes of phenol or aryl sulfotransferases does not really narrow the field, because these enzymes have overlapping specificity, not only for specific compounds, but also for multiple functional groups. The presentation aims to provide an overview of the wealth of phenol sulfotransferases that are available for study but concentrates on the enzymology of rat and human enzymes, particularly on the predominant phenol sulfotransferase from rat liver. The kinetics and catalytic mechanism of the rat enzyme is extensively reviewed and is compared with observations from other sulfotransferases.

Human IFN-alpha protein engineering: the amino acid residues at positions 86 and 90 are important for antiproliferative activity

Human IFN-alpha is a family of structurally related proteins that exhibit a wide range of antiproliferative activities. To understand the structural basis for these different antiproliferative activities, eight recombinant human IFN-alpha hybrids (HY) of alpha21a/alpha2c (HY-4, HY-5) and mutants (site-directed mutagenesis (SDM)-1, 2 and cassette mutagenesis (CM)-1, 2, 3, and 4) have been expressed, purified, and characterized. The data showed that the amino acid region 81-95 is important for antiproliferative activity. Site-directed mutagenesis and cassette mutagenesis studies showed that if serine (S) 86 and asparagine (N) 90 were replaced by tyrosine (Y), the antiproliferative activity was increased. We have also observed that if Y86 was replaced by isoleucine (I), the antiproliferative activity was comparable. However, if Y86 was replaced by aspartic acid (D), lysine (K), or alanine (A), the antiproliferative activity was substantially decreased. Our results indicate that Y and/or I at position 86 and Y at position 90 are very important in antiproliferative activity of human IFN-alpha. Circular dichroism spectra showed that the amino acid replacements at position 86 did not change the secondary structure. Thus the biological activity changes among those mutants do not appear to be due to conformational changes. The results also suggest that hydrophobic residue(s) at position 86 may be important for the interaction of the molecule with its receptor. The competitive binding data correlated with the antiproliferative activity. The N-terminal region of the molecule and the hydrophobic residues (including Y and I) on the C-helix region at positions 86 and/or 90 are important for binding and antiproliferative activities of human IFN-alphas.

Evidence that NADP+ is the physiological cofactor of ADP-L-glycero-D-mannoheptose 6-epimerase

ADP-L-glycero-D-mannoheptose 6-epimerase is required for lipopolysaccharide inner core biosynthesis in several genera of Gram-negative bacteria. The enzyme contains both fingerprint sequences Gly-X-Gly-X-X-Gly and Gly-X-X-Gly-X-X-Gly near its N terminus, which is indicative of an ADP binding fold. Previous studies of this ADP-l-glycero-D-mannoheptose 6-epimerase (ADP-hep 6-epimerase) were consistent with an NAD(+) cofactor. However, the crystal structure of this ADP-hep 6-epimerase showed bound NADP (Deacon, A. M., Ni, Y. S., Coleman, W. G., Jr., and Ealick, S. E. (2000) Structure 5, 453-462). In present studies, apo-ADP-hep 6-epimerase was reconstituted with NAD(+), NADP(+), and FAD. In this report we provide data that shows NAD(+) and NADP(+) both restored enzymatic activity, but FAD could not. Furthermore, ADP-hep 6-epimerase exhibited a preference for binding of NADP(+) over NAD(+). The K(d) value for NADP(+) was 26 microm whereas that for NAD(+) was 45 microm. Ultraviolet circular dichroism spectra showed that apo-ADP-hep 6-epimerase reconstituted with NADP(+) had more secondary structure than apo-ADP-hep 6-epimerase reconstituted with NAD(+). Perchloric acid extracts of the purified enzyme were assayed with NAD(+)-specific alcohol dehydrogenase and NADP(+)-specific isocitric dehydrogenase. A sample of the same perchloric acid extract was analyzed in chromatographic studies, which demonstrated that ADP-hep 6-epimerase binds NADP(+) in vivo. A structural comparison of ADP-hep 6-epimerase with UDP-galactose 4-epimerase, which utilizes an NAD(+) cofactor, has identified the regions of ADP-hep 6-epimerase, which defines its specificity for NADP(+).

Rotavirus nonstructural protein NSP2 self-assembles into octamers that undergo ligand-induced conformational changes

The nonstructural protein NSP2 is a component of the rotavirus replication machinery and binds single-stranded RNA cooperatively, with high affinity, and independent of sequence. Recently, NSP2 has been shown to form multimers and to possess an NTPase activity, but its precise function remains unclear. In the present study, we have characterized the solution structure of recombinant NSP2 by velocity and equilibrium ultracentrifugation, dynamic light scattering, and circular dichroism spectroscopy. We found that NSP2 exists as an octamer, which is functional in the binding of RNA and ADP. In the presence of magnesium, a partial dissociation of the octamer into smaller oligomers was observed. This was reversed by binding of ADP and RNA. We observed an increased sedimentation rate in the presence of ADP and a nonhydrolyzable ATP analogue, which suggests a change toward a significantly more compact octameric conformation. The secondary structure of NSP2 showed a high fraction of beta-sheet, with small changes induced by magnesium that were reversed in the presence of RNA. That NSP2 can exist in different conformations lends support to the previously proposed hypothesis (Taraporewala, Z., Chen, D., and Patton, J. T. (1999) J. Virol. 73, 9934-9943) of its function as a molecular motor involved in the packaging of viral mRNA.

Purification and Recognition of Recombinant Mouse P2X(1) Receptors Expressed in a Baculovirus System

Strategy, Management and Health Policy Venture Capital Enabling TechnologyPreclinical ResearchPreclinical Development Toxicology, Formulation Drug Delivery, PharmacokineticsClinical Development Phases I-III Regulatory, Quality, ManufacturingPostmarketing Phase IVThe hexahistidine-tagged mouse P2X(1) receptor (H-mP2X(1)R), an ATP-gated ion channel receptor, was expressed in a baculovirus system using the pAcHLT-B transfer vector containing a hexahistidine tag. Both widely used denaturing (8M urea) and nondenaturing (such as 1% Triton X-100) solubilization conditions were compared, resulting in about 30% of the P2X(1) receptors being solubilized (S1). However, at pH 13 most of the H-mP2X(1)R from the initially insoluble pellet fraction was solubilized (S2) and remained in the soluble fraction (S3) after dialyzing against a nondenaturing buffer. H-mP2X(1)Rs were purified sequentially through cobalt and ATP affinity columns. Receptors purified from S3 had higher purity than those from S1 (i.e., ~90% vs. ~75%). Circular dichroism spectra indicated identical protein secondary structures of the receptors from both sources. Autoradiographic data showed that the purified receptors from S3 had higher affinity for 8-azido-ATP-γ-(32)P than the receptors from S1. The binding of 8-azido-ATP-γ-(32)P to H-mP2X(1)R was inhibited by ATP-γ-S, α,β-me-ATP, and PPADS, but not by a nucleoside analog (N(6)-methyl-2'-deoxy-adenosine). In the presence of 2 mM Ca(2+) or Mg(2+) the binding was increased, but not when using a partially purified receptor fraction, in which unidentified proteins bound 8-azido-ATP-γ-(32)P or were phosphorylated at 4°C in the presence of 2 mM Mg(2+). These data suggest that the decrease in potency of ATP in the presence of Ca(2+) and Mg(2+), as observed in functional studies, is not due to a direct effect of the cations on the binding of ATP to the receptor. Both cyanogen bromide and hydroxylamine cleavage further confirmed the peptide structure of the purified H-mP2X(1)R. Autoradiographic analysis of the cleavage products showed that 8-azido-ATP-γ-(32)P was crosslinked to the carboxyl side of the extracellular domain of the receptor.

Redox control of aryl sulfotransferase specificity

Aryl sulfotransferase IV from rat liver has the very broad substrate range that is characteristic of the enzymes of detoxication. With the conventional assay substrates, 4-nitrophenol and PAPS, sulfation was considered optimal at pH 5.5 whereas the enzyme in the physiological pH range was curiously ineffective. These properties would seem to preclude a physiological function for this cytosolic enzyme. Partial oxidation of the enzyme, however, results not only in a substantial increase in the rate of sulfation of 4-nitrophenol at physiological pH but also in a shift of the pH optimum to this range and radically altered overall substrate specificity. The mechanism for this dependence on redox environment involves oxidation at Cys66, a process previously shown to occur by formation of a mixed disulfide with glutathione or by the formation of an internal disulfide with Cys232. Oxidation at Cys66 acts only as a molecular redox switch and is not directly part of the catalytic mechanism. Underlying the activation process is a change in the nature of the ternary complex formed between enzyme, phenol, and the reaction product, adenosine 3',5'-bisphosphate. The reduced enzyme gives rise to an inhibitory, dead-end ternary complex, the stability of which is dictated by the ionization of the specific phenol substrate. Ternary complex formation impedes the binding of PAPS that is necessary to initiate a further round of the reaction and is manifest as profound, substrate-dependent inhibition. In contrast, the ternary complex formed when the enzyme is in the partially oxidized state allows binding of PAPS and the unhindered completion of the reaction cycle.

Domain architecture of the heme-independent yeast cystathionine beta-synthase provides insights into mechanisms of catalysis and regulation

Cystathionine beta-synthase from yeast (Saccharomyces cerevisiae) provides a model system for understanding some of the effects of disease-causing mutations in the human enzyme. The mutations, which lead to accumulation of L-homocysteine, are linked to homocystinuria and cardiovascular diseases. Here we characterize the domain architecture of the heme-independent yeast cystathionine beta-synthase. Our finding that the homogeneous recombinant truncated enzyme (residues 1-353) is catalytically active and binds pyridoxal phosphate stoichiometrically establishes that the N-terminal residues 1-353 compose a catalytic domain. Removal of the C-terminal residues 354-507 increases the specific activity and alters the steady-state kinetic parameters including the K(d) for pyridoxal phosphate, suggesting that the C-terminal residues 354-507 compose a regulatory domain. The yeast enzyme, unlike the human enzyme, is not activated by S-adenosyl-L-methionine. The truncated yeast enzyme is a dimer, whereas the full-length enzyme is a mixture of tetramer and octamer, suggesting that the C-terminal domain plays a role in the interaction of the subunits to form higher oligomeric structures. The N-terminal catalytic domain is more stable and less prone to aggregate than full-length enzyme and is thus potentially more suitable for structure determination by X-ray crystallography. Comparisons of the yeast and human enzymes reveal significant differences in catalytic and regulatory properties.

Determination of transport kinetics of chick MCT3 monocarboxylate transporter from retinal pigment epithelium by expression in genetically modified yeast

Monocarboxylate transporters (MCTs) comprise a group of highly homologous proteins that reside in the plasma membrane of almost all cells and which mediate the 1:1 electroneutral transport of a proton and a lactate ion. The isoform MCT3 is restricted to the basal membrane of the retinal pigment epithelium where it regulates lactate levels in the neural retina. Kinetic analysis of this transporter poses formidable difficulties due to the presence of multiple lactate transporters and their complex interaction with MCTs in adjacent cells. To circumvent these problems, we expressed both the MCT3 gene and a green fluorescent protein-tagged MCT3 construct in Saccharomyces cerevisiae. Since L-lactate metabolism in yeast depends on the CYB2 gene, we disrupted CYB2 to study the MCT3 transporter activity free from the complications of metabolism. Under these conditions L-lactate uptake varied inversely with pH, greater uptake being associated with lower pH. Whereas the V(max) was invariant, the K(m) increased severalfold as the pH rose from 6 to 8. In addition, MCT3 was highly resistant to a number of "classical" inhibitors of lactate transport. Last, studies with diethyl pyrocarbonate and p-chloromercuribenzenesulfonate set limitations on the locus of potential residues involved in the critical site of lactate translocation.

Thermal repair of tryptophan synthase mutations in a regulatory intersubunit salt bridge. Evidence from arrhenius plots, absorption spectra, and primary kinetic isotope effects

This work is aimed at understanding how protein structure and conformation regulate activity and allosteric communication in the tryptophan synthase alpha(2)beta(2) complex from Salmonella typhimurium. Previous crystallographic and kinetic results suggest that both monovalent cations and a salt bridge between alpha subunit Asp(56) and beta subunit Lys(167) play allosteric roles. Here we show that mutation of either of these salt bridging residues produced deleterious effects that could be repaired by increased temperature in combination with CsCl or with NaCl plus an alpha subunit ligand, alpha-glycerol 3-phosphate. Arrhenius plots of the activity data under these conditions were nonlinear. The same conditions yielded temperature-dependent changes in the equilibrium distribution of enzyme-substrate intermediates and in primary kinetic isotope effects. We correlate the results with a model in which the mutant enzymes are converted by increased temperature from a low activity, "open" conformation to a high activity, "closed" conformation under certain conditions. The allosteric ligand and different monovalent cations affected the equilibrium between the open and closed forms. The results suggest that alpha subunit Asp(56) and beta subunit Lys(167) are not essential for catalysis and for allosteric communication between the alpha and beta subunits but that their mutual interaction is important in stabilization of the active, closed form of the alpha(2)beta(2) complex.

Calcium-sensitive interaction between calmodulin and modified forms of rat brain neurogranin/RC3

Neurogranin (NG) binding of calmodulin (CaM) at its IQ domain is sensitive to Ca(2+) concentration and to modifications by protein kinase C (PKC) and oxidants. The PKC phosphorylation site of NG is within the IQ domain whereas the four oxidant-sensitive Cys residues are outside this region. These Cys residues were oxidized forming two pairs of intramolecular disulfides, and could also be glutathiolated by S-nitrosoglutathione resulting in the incorporation of four glutathiones per NG. Circular dichroism (CD) showed that modification of NG by phosphorylation, oxidation forming intramolecular disulfides, or glutathiolation did not affect the alpha-helical content of this protein. Mutation of the four Cys residues [Cys(-)-NG] to Gly and Ser did not affect the alpha-helical content either. Interaction of CaM with the reduced (red)-, glutathiolated (GS)-, or Cys(-)-NG in the Ca(2+)-free solution resulted in an increase in the alpha-helicity determined by their CD spectra, but relatively little change was seen with the oxidized NG (ox-NG) or phosphorylated NG (PO(4)-NG). The binding affinities between the various modified forms of NG and CaM were determined by CD spectrometry and sedimentation equilibrium: their affinities were Cys(-)-NG > red-NG, GS-NG > ox-NG > PO(4)-NG. Unlike Cys(-)-, red-, and GS-NG, neither ox- nor PO(4)-NG bound to a CaM-affinity column. Thus, both oxidation of NG to form intramolecular disulfides and phosphorylation of NG by PKC are effective in modulating the intracellular level of CaM. These results indicate that modification of NG to form intramolecular disulfides outside the IQ domain provides an alternative mechanism for regulation of its binding affinity to CaM.

Regulation of tryptophan synthase by temperature, monovalent cations, and an allosteric ligand. Evidence from Arrhenius plots, absorption spectra, and primary kinetic isotope effects

To investigate the linkage between enzyme conformation and catalysis, we have determined the effects of temperature on catalytic properties of the tryptophan synthase alpha(2)beta(2) complex and beta(2) subunit in the absence or presence of different monovalent cations (Cs(+), Na(+), and GuH(+)) and of an allosteric ligand, alpha-glycerol 3-phosphate. Arrhenius plots of the activity data between 5 and 50 degrees C are nonlinear in the presence of certain ligands but not others. The conditions that yield nonlinear Arrhenius plots also yield temperature-dependent changes in the equilibrium distribution of enzyme-substrate intermediates and in primary kinetic isotope effects. The results provide evidence that the nonlinear Arrhenius plots are caused by a temperature-dependent conformational change that precedes the rate-limiting step in catalysis. Thermodynamic analysis of the data associated with the conformational change shows that the activation energies are much higher at low temperatures than at high temperatures. We correlate the results with a model in which the enzyme is converted by increased temperature under certain conditions from a low-activity "open" conformation to a high-activity "closed" conformation. The allosteric ligand and different monovalent cations, including GuH(+), which also acts as a chaotropic agent, affect the equilibrium between the open and closed forms. The large positive entropy changes in the conformational conversion suggest that the closed conformation results from tightened hydrophobic interactions that exclude water from the active site of the beta subunit.

Yeast cystathionine beta-synthase is a pyridoxal phosphate enzyme but, unlike the human enzyme, is not a heme protein

Our studies of cystathionine beta-synthase from Saccharomyces cerevisiae (yeast) are aimed at clarifying the cofactor dependence and catalytic mechanism and obtaining a system for future investigations of the effects of mutations that cause human disease (homocystinuria or coronary heart disease). We report methods that yielded high expression of the yeast gene in Escherichia coli and of purified yeast cystathionine beta-synthase. The absorption and circular dichroism spectra of the homogeneous enzyme were characteristic of a pyridoxal phosphate enzyme and showed the absence of heme, which is found in human and rat cystathionine beta-synthase. The absence of heme in the yeast enzyme facilitates spectroscopic studies to probe the catalytic mechanism. The reaction of the enzyme with L-serine in the absence of L-homocysteine produced the aldimine of aminoacrylate, which absorbed at 460 nm and had a strong negative circular dichroism band at 460 nm. The formation of this intermediate from the product, L-cystathionine, demonstrates the partial reversibility of the reaction. Our results establish the overall catalytic mechanism of yeast cystathionine beta-synthase and provide a useful system for future studies of structure and function. The absence of heme in the functional yeast enzyme suggests that heme does not play an essential catalytic role in the rat and human enzymes. The results are consistent with the absence of heme in the closely related enzymes O-acetylserine sulfhydrylase, threonine deaminase, and tryptophan synthase.

The orphan nuclear receptor Ear-2 is a negative coregulator for thyroid hormone nuclear receptor function

Thyroid hormone (T3) nuclear receptors (TR) are ligand-dependent transcription factors which regulate growth, differentiation, and development. One emerging hypothesis suggests that TR mediate these diverse effects via a large network of coregulators. Recently, we found that TR-mediated transcriptional responses varied in six cell lines derived from different tissues. We therefore used human TR subtype beta1 (TRbeta1) as bait to search for coregulators in human colon carcinoma RKO cells with a yeast two-hybrid system. RKO cells exhibited T3-dependent and -independent transcriptional activation. One of the three positive clones was identified as Ear-2, which is a distant member of the chick ovalbumin upstream promoter-transcription factors of the orphan nuclear receptor family. The physical interaction between Ear-2 and TRbeta1 was further confirmed by specific binding of Ear-2 to glutathione S-transferase-TRbeta1. In addition, Ear-2 was found to associate with TRbeta1 in cells. As a result of this physical interaction, binding of TRbeta1 to the T3 response elements was inhibited. Using reporter systems, we found that both the basal activation and the T3-dependent activation mediated by TRbeta1 were repressed by Ear-2 in CV1 cells. In RKO cells, however, the T3-independent transcriptional activity was more sensitive to the repression effect of Ear-2 than the T3-dependent transcriptional activity. The repression effect of Ear-2 was reversed by steroid hormone receptor coactivator 1. These results suggest that TR-mediated responses reflect a balance of corepressors and coactivators in cells. These findings further strengthen the hypothesis that the diverse activities of TR are achieved via a large network of coregulators that includes Ear-2.

Guanidine hydrochloride exerts dual effects on the tryptophan synthase alpha 2 beta 2 complex as a cation activator and as a modulator of the active site conformation

To characterize the conformational transitions that regulate the activity and specificity of the tryptophan synthase alpha 2 beta 2 complex, we have determined some effects of low concentrations of guanidine hydrochloride (GuHCl) and of urea on functional properties. We report the novel finding that GuHCl at low concentrations (0. 02-0.08 M) is a cation activator of the tryptophan synthase alpha 2 beta 2 complex. Molecular modeling studies show that GuH+ could bind at a previously identified cation binding site in the tryptophan synthase beta subunit. Addition of increasing concentrations of GuHCl has strikingly different effects on the rates of different reactions with L-serine or beta-chloro-L-alanine in the presence or absence of indole. Spectroscopic studies demonstrate that GuHCl alters the equilibrium distribution of pyridoxal 5'-phosphate intermediates formed in reactions at the active site of the beta subunit. Data analysis shows that GuHCl binds preferentially with the conformer of the enzyme that predominates when the aldimine of L-serine is formed and shifts the equilibrium in favor of this conformer. These results provide evidence that GuHCl exerts dual effects on tryptophan synthase as a cation, stimulating activity, and as a chaotropic agent, altering the distribution of conformational states that exhibit different reaction specificities. Our finding that the nonionic urea stabilizes the aldimine of L-serine in the presence, but not in the absence, of NaCl shows that cation binding plays an important role in the conformational transitions that regulate activity and the transmission of allosteric signals between the alpha and beta sites.

Expression, purification, and biochemical characterization of the amino-terminal extracellular domain of the human calcium receptor

We purified the extracellular domain (ECD) of the human calcium receptor (hCaR) from the medium of HEK-293 cells stably transfected with a hCaR cDNA containing an isoleucine 599 nonsense mutation. A combination of lectin, anion exchange, and gel permeation chromatography yielded milligram quantities of >95% pure protein from 15 liters of starting culture medium. The purified ECD ran as an approximately 78-kDa protein on SDS-polyacrylamide gel electrophoresis and was found to be a disulfide-linked dimer. Its NH2-terminal sequence, carbohydrate content, and CD spectrum were defined. Tryptic proteolysis studies showed two major sites accessible to cleavage. These studies provide new insights into the structure of the hCaR ECD. Availability of purified ECD protein should permit further structural studies to help define the mechanism of Ca2+ activation of this G protein-coupled receptor.

Estimation of secondary/tertiary structure

A protein has three types of structure: primary, its covalent sequence; secondary, the local arrangement of the polypeptide chain; tertiary, the mutual three-dimensional arrangement of the chain. Two spectroscopic techniques allow convenient estimation of the amount and type of secondary structure in a pure protein. Analysis of the Fourier Transform Infra Red Spectrum of the Amide I band of a protein (1650 cm(-1)) allows direct evaluation of the relative amounts of the peptide groups in various secondary structures. The Circular Dichroism Spectrum of the peptide chromophore (below 240 nm) can yield similar information and may allow assignment of the protein in one of five general structural classes.

Tryptophan synthase mutations that alter cofactor chemistry lead to mechanism-based inactivation

Mutations in the pyridoxal phosphate binding site of the tryptophan synthase beta subunit (S377D and S377E) alter cofactor chemistry [Jhee, K.-H., et al. (1998) J. Biol. Chem. 273, 11417-11422]. We now report that the S377D, S377E, and S377A beta2 subunits form alpha2 beta2 complexes with the alpha subunit and activate the alpha subunit-catalyzed cleavage of indole 3-glycerol phosphate. The apparent Kd for dissociation of the alpha and beta subunits is unaffected by the S377A mutation but is increased up to 500-fold by the S377D and S377E mutations. Although the three mutant alpha2 beta2 complexes exhibit very low activities in beta elimination and beta replacement reactions catalyzed at the beta site in the presence of Na+, the activities and spectroscopic properties of the S377A alpha2 beta2 complex are partially repaired by addition of Cs+. The S377D and S377E alpha2 beta2 complexes, unlike the wild-type and S377A alpha2 beta2 complexes and the mutant beta2 subunits, undergo irreversible substrate-induced inactivation by L-serine or by beta-chloro-L-alanine. The rates of inactivation (kinact) are similar to the rates of catalysis (kcat). The partition ratios are very low (kcat/kinact = 0.25-3) and are affected by alpha subunit ligands and monovalent cations. The inactivation product released by alkali was shown by HPLC and by fluorescence, absorption, and mass spectroscopy to be identical to a compound previously synthesized from pyridoxal phosphate and pyruvate. We suggest that alterations in the cofactor chemistry that result from the engineered Asp377 in the active site of the beta subunit may promote the mechanism-based inactivation.

Colocalization of heparin and receptor binding sites on keratinocyte growth factor

Keratinocyte growth factor (KGF) is a member of the fibroblast growth factor (FGF) family. FGFs are also known as heparin-binding growth factors because they bind to heparin and their physical and biological properties are modulated by heparin. Consistent with a role as a paracrine effector, KGF is produced by cells of mesenchymal origin but is active primarily, if not exclusively, on epithelial cells. KGF is involved in a variety of physiological processes, including proliferation, differentiation, wound healing, and cytoprotection. To identify regions in KGF that contribute to heparin and tyrosine kinase receptor interactions, nine peptides spanning defined motifs in the predicted structure of KGF were synthesized, and their heparin and receptor binding properties were analyzed. Peptides at the amino and carboxyl termini bound heparin, and one peptide showed relative binding comparable to that of KGF. Competitive binding studies showed that this peptide along with two other overlapping peptides specifically displaced KGF bound to the KGF receptor. These three peptides were also selectively recognized by a neutralizing monoclonal antibody against KGF, though only in the presence of heparin. Together, these data suggest that the sites for heparin and receptor binding both reside in the amino and carboxyl termini of KGF, which are spatially juxtaposed in the predicted three-dimensional structure of this molecule.