Alleviation of intrasteric inhibition by the pathogenic activation domain mutation,D444N,in human cystathionine beta-synthase

Human cystathionine beta-synthase is a heme protein that catalyzes the condensation of serine and homocysteine to form cystathionine in a pyridoxal phosphate-dependent reaction. Mutations in this enzyme are the leading cause of hereditary hyperhomocysteinemia with attendant cardiovascular and other complications. The enzyme is activated approximately 2-fold by the allosteric regulator S-adenosylmethionine (AdoMet), which is presumed to bind to the C-terminal regulatory domain. The regulatory domain exerts an inhibitory effect on the enzyme, and its deletion is correlated with a 2-fold increase in catalytic activity and loss of responsiveness to AdoMet. A mutation in the C-terminal regulatory domain, D444N, displays high levels of enzyme activity, yet is pathogenic. In this study, we have characterized the biochemical penalties associated with this mutation and demonstrate that it is associated with a 4-fold lower steady-state level of cystathionine beta-synthase in a fibroblast cell line that is homozygous for the D444N mutation. The activity of the recombinant D444N enzyme mimics the activity of the wild-type enzyme seen in the presence of AdoMet and can be further activated approximately 2-fold in the presence of supraphysiolgical concentrations of the allosteric regulator. The mutation increases the K(act) for AdoMet from 7.4 +/- 0.2 to 460 +/- 130 microM, thus rendering the enzyme functionally unresponsive to AdoMet under physiological concentrations. These results indicate that the D444N mutation partially abrogates the intrasteric inhibition imposed by the C-terminal domain. We propose a model that takes into account the three kinetically distinguishable states that are observed with human cystathionine beta-synthase: "basal" (i.e., wild-type enzyme as isolated), "activated" (wild-type enzyme + AdoMet or the D444N mutant as isolated), and superactivated (D444N mutant + AdoMet or wild-type enzyme lacking the C-terminal regulatory domain).     

Assignment of enzymatic functions to specific regions of the PLP-dependent heme protein cystathionine beta-synthase.

Cystathionine beta-synthase is a unique heme protein that catalyzes a pyridoxal phosphate (or PLP)-dependent beta-replacement reaction. The reaction involves the condensation of serine and homocysteine and constitutes one of the two major avenues for detoxification of homocysteine in mammals. The enzyme is allosterically regulated by S-adenosylmethionine (AdoMet). In this study, we have characterized the kinetic, spectroscopic, and ligand binding properties of a truncated catalytic core of cystathionine beta-synthase extending from residues 1 through 408 in which the C-terminal 143 residues have been deleted. This is similar to a natural variant of the protein that has been described in a homocystinuric patient in which the predicted peptide is 419 amino acids in length. Truncation leads to the formation of a dimeric enzyme in contrast to the tetrameric organization of the native enzyme. Some of the kinetic properties of the truncated enzyme are different from the full-length form, most notably, significantly higher K(m)s for the two substrates, and loss of activation by AdoMet. This is paralleled by the absence of AdoMet binding to the truncated form, whereas four AdoMet molecules bind cooperatively to the full-length tetrameric enzyme with a K(d) of 7. 4 microM. Steady-state kinetic analysis indicates that the order of substrate addition is important. Thus, preincubation of the enzyme with homocysteine leads to a 2-fold increase in V(max) relative to preincubation of the enzyme with serine. Since the intracellular concentration of serine is significantly greater than that of homocysteine, the physiological significance of this phenomenon needs to be considered. Based on ligand binding studies and homology searches with protein sequences in the database, we assign residues 68-209 as being important for PLP binding, residues 241-341 for heme binding, and residues 421-469 for AdoMet binding.     

Stopped-flow kinetic analysis of the reaction catalyzed by the full-length yeast cystathionine beta-synthase

Cystathionine beta-synthase found in yeast catalyzes a pyridoxal phosphate-dependent condensation of homocysteine and serine to form cystathionine. Unlike the homologous mammalian enzymes, yeast cystathionine beta-synthase lacks a second cofactor, heme, which facilitates detailed kinetic studies of the enzyme because the different pyridoxal phosphate-bound intermediates can be followed by their characteristic absorption spectra. We conducted a rapid reaction kinetic analysis of the full-length yeast enzyme in the forward and reverse directions. In the forward direction, we observed formation of the external aldimine of serine (14 mm(-1) s(-1)) and the aminoacrylate intermediate (15 s(-1)). Homocysteine binds to the aminoacrylate with a bimolecular rate constant of 35 mm(-1) s(-1) and rapidly converts to cystathionine (180 s(-1)), leading to the accumulation of a 420 nm absorbing species, which has been assigned as the external aldimine of cystathionine. Release of cystathionine is slow (k = 2.3 s(-1)), which is similar to k(cat) (1.7 s(-1)) at 15 degrees C, consistent with this being a rate-determining step. In the reverse direction, cystathionine binds to the enzyme with a bimolecular rate constant of 1.5 mm(-1) s(-1) and is rapidly converted to the aminoacrylate without accumulation of the external aldimine. The kinetic behavior of the full-length enzyme shows notable differences from that reported for a truncated form of the enzyme lacking the C-terminal third of the protein (Jhee, K. H., Niks, D., McPhie, P., Dunn, M. F., and Miles, E. W. (2001) Biochemistry 40, 10873-10880).     

Solvent-accessible cysteines in human cystathionine beta-synthase: crucial role of cysteine 431 in S-adenosyl-L-methionine binding

Cystathionine beta-synthase (CBS) is a tetrameric heme protein that catalyzes the PLP-dependent condensation of serine and homocysteine to cystathionine. CBS occupies a crucial regulatory position between the methionine cycle and transsulfuration. Human CBS contains 11 cysteine residues that are highly conserved in mammals but completely absent in the yeast enzyme, which catalyzes an identical reaction, suggesting a possible regulatory role for some of these residues. In this report, we demonstrate that in both the presence and absence of the CBS allosteric regulator S-adenosyl-l-methionine (AdoMet), only C15 and C431 of human CBS are solvent accessible. Mutagenesis of C15 to serine did not affect catalysis or AdoMet activation but significantly reduced aggregation of the purified enzyme in vitro. Mutagenesis of C431 resulted in a constitutively activated form of CBS that could not be further activated by either AdoMet or thermal activation. We and others have previously reported a number of C-terminal CBS point mutations that result in a decreased or abolished response to AdoMet. In contrast to all of these previously investigated CBS mutants, the C431 mutant form of CBS was unable to bind AdoMet, indicating that either this residue is directly involved in AdoMet binding or its absence induces a conformational change that destroys the integrity of the binding site for this regulatory ligand.     

Complementation between kinase-defective and activation-defective TGF-beta receptors reveals a novel form of receptor cooperativity essential for signaling.

Transforming growth factor-beta (TGF-beta) signals through two transmembrane serine/threonine kinases, T beta R-I and T beta R-II. TGF-beta binds to T beta R-II, allowing this receptor to associate with and phosphorylate T beta R-I which then propagates the signal. T beta R-I is phosphorylated within its GS domain, a region immediately preceding the kinase domain. To further understand the function of T beta R-I in this complex, we analyzed T beta R-I-inactivating mutations identified in cell lines that are defective in TGF-beta signaling yet retain ligand binding ability. The three mutations identified here all fall in the kinase domain of T beta R-I. One mutation disrupts the kinase activity of T beta R-I, whereas the other two mutations prevent ligand-induced T beta R-I phosphorylation, and thus activation, by T beta R-II. Unexpectedly, a kinase-defective T beta R-I mutant can functionally complement an activation- defective T beta R-I mutant, by rescuing its T beta R-II- dependent phosphorylation. Together with evidence that the ligand-induced receptor complex contains two or more T beta R-I molecules, these results support a model in which the kinase domain of one T beta R-I molecule interacts with the GS domain of another, enabling its phosphorylation and activation by T beta R-II. This cooperative interaction between T beta R-I molecules appears essential for TGF-beta signal transduction.     

Visualization of PLP-bound intermediates in hemeless variants of human cystathionine beta-synthase: evidence that lysine 119 is a general base

Cystathionine beta-synthase catalyzes the condensation of serine and homocysteine to give cystathionine in a pyridoxal phosphate (PLP)-dependent reaction. The human enzyme contains a single heme per monomer that is bound in an N-terminal 69 amino acid extension that is missing from the otherwise highly homologous yeast enzyme. The heme dominates the UV-visible spectrum and obscures kinetic characterization of the PLP-bound reaction intermediates. In this study, we have engineered a hemeless mutant of human cystathionine beta-synthase by deletion of the N-terminal 69 amino acids. The resulting variant displays approximately 40% of the activity seen with the wild type enzyme, binds stoichiometric amounts of PLP, and permits spectral characterization of PLP-based intermediates. The enzyme as isolated exhibits an absorption maximum at 412nm corresponding to a protonated internal aldimine. Addition of serine shifts the lambdamax to 420nm (assigned as the external aldimine) with a broad shoulder between 450 and 500nm (assigned as the aminoacrylate intermediate). Addition of the product, cystathionine, also leads to formation of an external aldimine (420nm). Homocysteine elicits a red shift (and a decrease in absorption) in the spectrum from 412 to 424nm and an increase in absorption at 330nm, presumably due to formation of a dead-end complex. Mutation of K119, the residue that forms the Schiff base, to alanine results in a approximately 10(3)-fold decrease in activity, which increases approximately 2-fold in the presence of an exogenous base, ethylamine. Spectral shifts (412 --> 420nm) consistent with the formation of external aldimines are observed in the presence of serine or cystathionine, but an aminoacrylate intermediate is not formed at detectable levels. These results are consistent with an additional role for K119 as a general base in the reaction catalyzed by human cystathionine beta-synthase.     

Deletion of the regulatory domain in the pyridoxal phosphate-dependent heme protein cystathionine beta-synthase alleviates the defect observed in a catalytic site mutant.

The most common cause of severely elevated homocysteine or homocystinuria is inherited disorders in cystathionine beta-synthase. The latter enzyme is a unique hemeprotein that catalyzes pyridoxal phosphate (PLP)-dependent condensation of serine and homocysteine to give cystathionine, thus committing homocysteine to catabolism. A point mutation, V168M, has been described in a homocystinuric cell line and is associated with a B(6)-responsive phenotype. In this study, we have examined the kinetic properties of this mutant and demonstrate that the mutation affects the PLP but not the heme content. The approximately 13-fold diminution in activity because of the mutation corresponds to an approximately 7-fold decrease in the level of bound PLP. This may be explained by half of the sites activity associated with cystathionine beta-synthase. The addition of PLP results in partial but not full restoration of activity to wild type levels. Elimination of the C-terminal quarter of the mutant protein results in alleviation of the catalytic penalty imposed by the V168M mutation. The resulting truncated protein is very similar to the corresponding truncated enzyme with wild type sequence and is now able to bind the full complement of both heme and PLP cofactors. These results indicate that the V168M mutation per se does not affect binding of PLP directly and that interactions between the regulatory C terminus and the catalytic N terminus are important in modulating the cofactor content and therefore the activity of the full-length enzyme. These studies provide the first biochemical explanation for the B(6)-responsive phenotype associated with a cystathionine beta-synthase-impaired homocystinuric genotype.     

Reaction mechanism and regulation of cystathionine beta-synthase

In mammals, cystathionine beta-synthase catalyzes the first step in the transsulfuration pathway which provides an avenue for the conversion of the essential amino acid, methionine, to cysteine. Cystathionine beta-synthase catalyzes a PLP-dependent condensation of serine and homocysteine to cystathionine and is unique in also having a heme cofactor. In this review, recent advances in our understanding of the kinetic mechanism of the yeast and human enzymes as well as pathogenic mutants of the human enzyme and insights into the role of heme in redox sensing are discussed from the perspective of the crystal structure of the catalytic core of the human enzyme.     

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.     

Kinetic properties of polymorphic variants and pathogenic mutants in human cystathionine gamma-lyase

Human cystathionine-gamma-lyase (CGL) is a pyridoxal-5'-phosphate (PLP)-dependent enzyme, which functions in the transsulfuration pathway that converts homocysteine to cysteine. In addition, CGL is one of two major enzymes that can catalyze the formation of hydrogen sulfide, an important gaseous signaling molecule. Recently, several mutations in CGL have been described in patients with cystathioninuria, a rare but poorly understood genetic disease. Moreover, a common single nucleotide polymorphism in CGL, c.1364G>T that converts serine at position 403 to isoleucine, has been linked to elevated plasma homocysteine levels. In this study, we have characterized the pathogenic T67I and Q240E missense mutations and the polymorphic variants at amino acid residues 403 using kinetic and spectrophotometric methods. We report that the polymorphism does not influence the cofactor content of the enzyme or its steady-state kinetic properties. In contrast, the T67I mutant exhibits a 3.5-fold decrease in V max compared to that of wild-type CGL, while the Q240E mutant exhibits a 70-fold decrease in V max. The K Ms for cystathionine for both pathogenic mutants are comparable to that of wild type CGL. The PLP content of the T67I and Q240E mutants were about 4-fold and 80-fold lower than that of wild-type enzyme, respectively. Preincubation of the T67I mutant with PLP restored activity to wild-type levels while the same treatment resulted in only partial restoration of activity of the Q240E mutant. These results reveal that both mutations weaken the affinity for PLP and suggest that cystathionuric patients with these mutations should be responsive to pyridoxine therapy.     

Characterization of the heme and pyridoxal phosphate cofactors of human cystathionine beta-synthase reveals nonequivalent active sites

Cystathionine beta-synthase is an unusual enzyme that requires the cofactors heme and pyridoxal phosphate (PLP) to catalyze the condensation of homocysteine and serine to generate cystathionine. This transsulfuration reaction represents one of two major cellular routes for detoxification of homocysteine, which is a risk factor for atherosclerosis. While the beta-replacement reaction catalyzed by this enzyme suggests a role for the pyridoxal phosphate, the role of the heme is uncertain. In this study we have examined the effect of changing one of the ligands to the heme on the activity of the enzyme. Binding of carbon monooxide results in the displacement of a thiolate ligand to the ferrous heme, and is accompanied by complete loss of cystathionine beta-synthase activity. Furthermore, inhibition by CO is competitive with respect to homocysteine, providing the first indication that the homocysteine binding site is in the proximity of heme. Binding of both CO and cyanide to ferrous cystathionine beta-synthase occurs in two distinct isotherms and indicates that the hemes are nonequivalent. We have employed fluorescence spectroscopy to characterize the bound PLP and its interaction with serine. PLP bound to cystathionine beta-synthase is weakly fluorescent and exists as a mixture of the protonated and unprotonated tautomers. Reaction with hydroxylamine releases the oxime and greatly enhances the associated fluorescence. Binding of serine is accompanied by a shift to the unprotonated tautomer of the external aldimine as well as the appearance of a new fluorescent species at approximately 400 nm that could be due to the aminoacrylate or to a gemdiamine intermediate. These data provide the first characterization of the PLP bound to cystathionine beta-synthase. Treatment of cystathionine beta-synthase with hydroxylamine releases two PLPs after 1 day and results in complete loss of activity. Incubation for an additional 3-4 days results in the release of two more PLPs. These data lead us to revise the PLP stoichiometry to 4 per tetramer, and to the conclusion that the heme and PLP sites in cystathionine beta-synthase are nonequivalent.     

Structural insights into mutations of cystathionine beta-synthase

Cystathionine beta-synthase (CBS) is a unique heme-containing enzyme that catalyses a pyridoxal 5'-phosphate (PLP)-dependent condensation of serine and homocysteine to give cystathionine. Deficiency of CBS leads to homocystinuria, an inherited disease of sulfur amino acid metabolism characterised by increased levels of homocysteine and methionine and decreased levels of cysteine. Presently, more than 100 CBS mutations have been described which lead to homocystinuria with different degrees of severity in the patients. We have recently solved the crystal structure of a truncated form of this enzyme, which enables us to correlate some of these mutations with the structure.     

Cystathionine Metabolism in Methionine Auxotrophic and Wild-Type Strains of Saccharomyces cerevisiae

The role of cystathionine in methionine biosynthesis in wild-type and auxotrophic strains of Saccharomyces cerevisiae was studied. Homocysteine and cysteinerequiring mutants were selected for detailed study. Exogenously supplied cystathionine, although actively transported by all strains tested, could not satisfy the organic sulfur requirements of the mutants. Cell-free extracts of the wild-type, homocysteine, and cysteine auxotrophs were shown to cleave cystathionine. Pyruvic acid and homocysteine were identified as teh products of this cleavage. A mutant containing an enzyme which could cleave cystathionine to homocysteine in cell-free experiments was unable to use cystathionine as a methionine precursor in the intact organisms. The significance of this finding is discussed.     

Mapping peptides correlated with transmission of intrasteric inhibition and allosteric activation in human cystathionine beta-synthase

Cystathionine beta-synthase plays a key role in the intracellular disposal of homocysteine and is the single most common locus of mutations associated with homocystinuria. Elevated levels of homocysteine are correlated with heart disease, Alzheimer's and Parkinson's diseases, and neural tube defects. Cystathionine beta-synthase is modular and subjected to complex regulation, but insights into the structural basis of this regulation are lacking. We have employed hydrogen exchange mass spectrometry to map peptides whose motions are correlated with transmission of intrasteric inhibition and allosteric activation. The mass spectrometric data provide an excellent correlation between kinetically and conformationally distinguishable states of the enzyme. We also demonstrate that a pathogenic regulatory domain mutant, D444N, is conformationally locked in one of two states sampled by the wild type enzyme. Our hydrogen exchange data identify surfaces that are potentially involved in the juxtaposition of the regulatory and catalytic domains and form the basis of a docked structural model for the full-length enzyme.     

Characterization of the heme in human cystathionine beta-synthase by X-ray absorption and electron paramagnetic resonance spectroscopies

Human cystathionine beta-synthase is one of two key enzymes involved in intracellular metabolism of homocysteine. It catalyzes a beta-replacement reaction in which the thiolate of homocysteine replaces the hydroxyl group of serine to give the product, cystathionine. The enzyme is unusual in its dependence on two cofactors: pyridoxal phosphate and heme. The requirement for pyridoxal phosphate is expected on the basis of the nature of the condensation reaction that is catalyzed; however the function of the heme in this protein is unknown. We have examined the spectroscopic properties of the heme in order to assign the axial ligands provided by the protein. The heme Soret peak of ferric cystathionine beta-synthase is at 428 nm and shifts to approximately 395 nm upon addition of the thiol chelator, mercuric chloride. This is indicative of 6-coordinate low-spin heme converting to a 5-coordinate high-spin heme. The enzyme as isolated exhibits a rhombic EPR signal with g values of 2.5, 2.3, and 1.86, which are similar to those of heme proteins and model complexes with imidazole/thiolate ligands. Mercuric chloride treatment of the enzyme results in conversion of the rhombic EPR signal to a g = 6 signal, consistent with formation of the high-spin ferric heme. The X-ray absorption data reveal that iron in ferric cystathionine beta-synthase is 6-coordinate, with 1 high-Z scatterer and 5 low-Z scatterers. This is consistent with the presence of 5 nitrogens and 1 sulfur ligand. Together, these data support assignment of the axial ligands as cysteinate and imidazole in ferric cystathionine beta-synthase.     

Age-associated perturbations in glutathione synthesis in mouse liver

The nature of the mechanisms underlying the age-related decline in glutathione (GSH) synthetic capacity is at present unclear. Steady-state kinetic parameters of mouse liver GCL (glutamate-cysteine ligase), the rate-limiting enzyme in GSH synthesis, and levels of hepatic GSH synthesis precursors from the trans-sulfuration pathway, such as homocysteine, cystathionine and cysteine, were compared between young and old C57BL/6 mice (6- and 24-month-old respectively). There were no agerelated differences in GCL V(max), but the apparent K(m) for its substrates, cysteine and glutamate, was higher in the old mice compared with the young mice (approximately 800 compared with approximately 300 microM, and approximately 710 compared with 450 microM, P<0.05 for cysteine and glutamate in young and old mice respectively). Amounts of cysteine, cystathionine and Cys-Gly increased with age by 91, 24 and 28% respectively. Glutathione (GSH) levels remained unchanged with age, whereas GSSG content showed an 84% increase, suggesting a significant pro-oxidizing shift in the 2GSH/GSSG ratio. The amount of the toxic trans-sulfuration/glutathione biosynthetic pathway intermediate, homocysteine, was 154% higher (P<0.005) in the liver of old mice compared with young mice. The conversion of homocysteine into cystathionine, a rate-limiting step in trans-sulfuration catalysed by cystathionine beta-synthase, was comparatively less efficient in the old mice, as indicated by cystathionine/homocysteine ratios. Incubation of tissue homogenates with physiological concentrations of homocysteine caused an up to 4.4-fold increase in the apparent K(m) of GCL for its glutamate substrate, but had no effect on V(max). The results suggest that perturbation of the catalytic efficiency of GCL and accumulation of homocysteine from the trans-sulfuration pathway may adversely affect de novo GSH synthesis during aging.     

Regulation of human cystathionine beta-synthase by S-adenosyl-L-methionine: evidence for two catalytically active conformations involving an autoinhibitory domain in the C-terminal region

Cystathionine beta-synthase (CBS), condensing homocysteine and serine, represents a key regulatory point in the biosynthesis of cysteine via the transsulfuration pathway. Inherited deficiency of CBS causes homocystinuria. CBS is activated by S-adenosyl-L-methionine (AdoMet) by inducing a conformational change involving a noncatalytic C-terminal region spanning residues 414-551. We report the purification of two patient-derived C-terminal mutant forms of CBS, S466L and I435T, that provide new insight into the mechanism of CBS regulation and indicate a regulatory function for the "CBS domain". Both of these point mutations confer catalytically active proteins. The I435T protein is AdoMet inducible but is 10-fold less responsive than wild-type (WT) CBS to physiologically relevant concentrations of this compound. The S466L form does not respond to AdoMet but is constitutively activated to a level intermediate between those of WT CBS in the presence and absence of AdoMet. Both mutant proteins are able to bind AdoMet, indicating that their impairment is related to their ability to assume the fully activated conformation that AdoMet induces in WT CBS. We found that I435T and WT CBS can be activated by partial thermal denaturation but that the AdoMet-stimulated WT, S466L, and a truncated form of CBS lacking the C-terminal region cannot be further activated by this treatment. Tryptophan and PLP fluorescence data for these different forms of CBS indicate that activation by AdoMet, limited proteolysis, and thermal denaturation share a common mechanism involving the displacement of an autoinhibitory domain located in the C-terminal region of the protein.     

Functional properties of the active core of human cystathionine beta-synthase crystals

Human cystathionine beta-synthase is a pyridoxal 5'-phosphate enzyme containing a heme binding domain and an S-adenosyl-l-methionine regulatory site. We have investigated by single crystal microspectrophotometry the functional properties of a mutant lacking the S-adenosylmethionine binding domain. Polarized absorption spectra indicate that oxidized and reduced hemes are reversibly formed. Exposure of the reduced form of enzyme crystals to carbon monoxide led to the complete release of the heme moiety. This process, which takes place reversibly and without apparent crystal damage, facilitates the preparation of a heme-free human enzyme. The heme-free enzyme crystals exhibited polarized absorption spectra typical of a pyridoxal 5'-phosphate-dependent protein. The exposure of these crystals to increasing concentrations of the natural substrate l-serine readily led to the formation of the key catalytic intermediate alpha-aminoacrylate. The dissociation constant of l-serine was found to be 6 mm, close to that determined in solution. The amount of the alpha-aminoacrylate Schiff base formed in the presence of l-serine was pH independent between 6 and 9. However, the rate of the disappearance of the alpha-aminoacrylate, likely forming pyruvate and ammonia, was found to increase at pH values higher than 8. Finally, in the presence of homocysteine the alpha-aminoacrylate-enzyme absorption band readily disappears with the concomitant formation of the absorption band of the internal aldimine, indicating that cystathionine beta-synthase crystals catalyze both beta-elimination and beta-replacement reactions. Taken together, these findings demonstrate that the heme moiety is not directly involved in the condensation reaction catalyzed by cystathionine beta-synthase.     

Modulation of cystathionine beta-synthase activity by the Arg-51 and Arg-224 mutations

Human cystathionine beta-synthase (CBS) catalyzes a pyridoxal 5'-phosphate (PLP) dependent beta-replacement reaction to synthesize cystathionine from serine and homocysteine. The enzyme is unique in bearing not only a catalytically important PLP but also heme. In order to study a regulatory process mediated by heme, we performed mutagenesis of Arg-51 and Arg-224, which have hydrogen-bonding interactions with propionate side chains of the prosthetic group. It was found that the arginine mutations decrease CBS activity by approximately 50%. The results indicate that structural changes in the heme vicinity are transmitted to PLP existing 20 A away from heme. A possible explanation of our results is discussed on the basis of CBS structure.     

Deletion mutagenesis of human cystathionine beta-synthase. Impact on activity,oligomeric status,and S-adenosylmethionine regulation

Cystathionine beta-synthase is a tetrameric hemeprotein that catalyzes the pyridoxal 5'-phosphate-dependent condensation of serine and homocysteine to cystathionine. We have used deletion mutagenesis of both the N and C termini to investigate the functional organization of the catalytic and regulatory regions of this enzyme. Western blot analysis of these mutants expressed in Escherichia coli indicated that residues 497-543 are involved in tetramer formation. Deletion of the 70 N-terminal residues resulted in a heme-free protein retaining 20% of wild type activity. Additional deletion of 151 C-terminal residues from this mutant resulted in an inactive enzyme. Expression of this double-deletion mutant as a glutathione S-transferase fusion protein generated catalytically active protein (15% of wild type activity) that was unaffected by subsequent removal of the fusion partner. The function of the N-terminal region appears to be primarily steric in nature and involved in the correct folding of the enzyme. The C-terminal region of human cystathionine beta-synthase contains two hydrophobic motifs designated "CBS domains." Partial deletion of the most C-terminal of these domains decreased activity and caused enzyme aggregation and instability. Removal of both of these domains resulted in stable constitutively activated enzyme. Deletion of as few as 8 C-terminal residues increased enzyme activity and abolished any further activation by S-adenosylmethionine indicating that the autoinhibitory role of the C-terminal region is not exclusively a function of the CBS domains.