Mutation Of His Research Articles

A conserved histidine in vertebrate-type ferredoxins is critical for redox-dependent dynamics.

Adrenodoxin (Adx) belongs to the family of Cys(4)Fe(2)S(2) vertebrate-type ferredoxins that shuttle electrons from NAD(P)H-dependent reductases to cytochrome P450 enzymes. The vertebrate-type ferredoxins contain a conserved basic residue, usually a histidine, adjacent to the third cysteine ligand of the Cys(4)Fe(2)S(2) cluster. In bovine Adx the side chain of this residue, His 56, is involved in a hydrogen-bonding network within the domain of Adx that interacts with redox partners. It has been proposed that this network acts as a mechanical link between the metal cluster binding site and the interaction domain, transmitting redox-dependent conformational or dynamical changes from the cluster binding loop to the interaction domain. H/D exchange studies indicate that oxidized Adx (Adx(o)) is more dynamic than reduced Adx (Adx(r)) on the kilosecond time scale in many regions of the protein, including the interaction domain. Dynamical differences on picosecond to nanosecond time scales between the oxidized (Adx(o)) and reduced (Adx(r)) adrenodoxin were probed by measurement of (15)N relaxation parameters. Significant differences between (15)N R(2) rates were observed for all residues that could be measured, with those rates being faster in Adx(o) than in Adx(r). Two mutations of His 56, H56R and H56Q, were also characterized. No systematic redox-dependent differences between (15)N R(2) rates or H/D exchange rates were observed in either mutant, indicating that His 56 is required for the redox-dependent behavior observed in WT Adx. Comparison of chemical shift differences between oxidized and reduced H56Q and H56R Adx confirms that redox-dependent changes are smaller in these mutants than in the wild-type Adx.

Identification of the essential histidine residue for high-affinity binding of AlbA protein to albicidin antibiotics.

The albA gene from Klebsiella oxytoca encodes a protein that binds albicidin phytotoxins and antibiotics with high affinity. Previously, it has been shown that shifting pH from 6 to 4 reduces binding activity of AlbA by about 30%, indicating that histidine residues might be involved in substrate binding. In this study, molecular analysis of the albA coding region revealed sequence discrepancies with the albA sequence reported previously, which were probably due to sequencing errors. The albA gene was subsequently cloned from K. oxytoca ATCC 13182(T) to establish the revised sequence. Biochemical and molecular approaches were used to determine the functional role of four histidine residues (His(78), His(125), His(141) and His(189)) in the corrected sequence for AlbA. Treatment of AlbA with diethyl pyrocarbonate (DEPC), a histidine-specific alkylating reagent, reduced binding activity by about 95 %. DEPC treatment increased absorbance at 240-244 nm by an amount indicating conversion to N-carbethoxyhistidine of a single histidine residue per AlbA molecule. Pretreatment with albicidin protected AlbA against modification by DEPC, with a 1 : 1 molar ratio of albicidin to the protected histidine residues. Based on protein secondary structure and amino acid surface probability indices, it is predicted that His(125) might be the residue required for albicidin binding. Mutation of His(125) to either alanine or leucine resulted in about 32 % loss of binding activity, and deletion of His(125) totally abolished binding activity. Mutation of His(125) to arginine and tyrosine had no effect. These results indicate that His(125) plays a key role either in an electrostatic interaction between AlbA and albicidin or in the conformational dynamics of the albicidin-binding site.

A Cholera Toxin B-subunit Variant That Binds Ganglioside GM1 but Fails to Induce Toxicity

Entry of cholera toxin (CT) into target epithelial cells and the induction of toxicity depend on CT binding to the lipid-based receptor ganglioside G(M1) and association with detergent-insoluble membrane microdomains, a function of the toxin's B-subunit. The B-subunits of CT and related Escherichia coli toxins exhibit a highly conserved exposed peptide loop (Glu(51)-Ile(58)) that faces the cell membrane upon B-subunit binding to G(M1). Mutation of His(57) to Ala in this loop resulted in a toxin (CT-H57A) that bound G(M1) with high apparent affinity, but failed to induce toxicity. CT-H57A bound to only a fraction of the cell-surface receptors available to wild-type CT. The bulk of cell-surface receptors inaccessible to CT-H57A localized to detergent-insoluble apical membrane microdomains (lipid rafts). Compared with wild-type toxin, CT-H57A exhibited slightly lower apparent binding affinity for and less stable binding to G(M1) in vitro. Rather than being transported into the Golgi apparatus, a process required for toxicity, most of CT-H57A was rapidly released from intact cells at physiologic temperatures or degraded following its internalization. These data indicate that CT action depends on the stable formation of the CT B-subunit.G(M1) complex and provide evidence that G(M1) functions as a necessary sorting motif for the retrograde trafficking of toxin into the secretory pathway of target epithelial cells.

Identification of the Collagen-binding Site of the von Willebrand Factor A3-domain

Von Willebrand factor (vWF) is a multimeric glycoprotein that mediates platelet adhesion and thrombus formation at sites of vascular injury. vWF functions as a molecular bridge between collagen and platelet receptor glycoprotein Ib. The major collagen-binding site of vWF is contained within the A3 domain, but its precise location is unknown. To localize the collagen-binding site, we determined the crystal structure of A3 in complex with an Fab fragment of antibody RU5 that inhibits collagen binding. The structure shows that RU5 recognizes a nonlinear epitope consisting of residues 962-966, 981-997, and 1022-1026. Alanine mutants were constructed of residues Arg(963), Glu(987), His(990), Arg(1016), and His(1023), located in or close to the epitope. Mutants were expressed as fully processed multimeric vWF. Mutation of His(1023) abolished collagen binding, whereas mutation of Arg(963) and Arg(1016) reduced collagen binding by 25-35%. These residues are part of loops alpha3beta4 and alpha1beta2 and alpha-helix 3, respectively, and lie near the bottom face of the domain. His(1023) and flanking residues display multiple conformations in available A3-crystal structures, suggesting that binding of A3 to collagen involves an induced-fit mechanism. The collagen-binding site of A3 is located distant from the top face of the domain where collagen-binding sites are found in homologous integrin I domains.

Identification of the histidine and aspartic acid residues essential for enzymatic activity of a family I.3 lipase by site-directed mutagenesis

A lipase from Pseudomonas sp. MIS38 (PML) is a member of the lipase family I.3. We analyzed the roles of the five histidine residues (His 30, His 274, His 291, His 313, and His 365) and five acidic amino acid residues (Glu 253, Asp 255, Asp 262, Asp 275, and Asp 290), which are fully conserved in the amino acid sequences of family I.3 lipases, by site-directed mutagenesis. We showed that the mutation of His 313 or Asp 255 to Ala almost fully inactivated the enzyme, whereas the mutations of other residues to Ala did not seriously affect the enzymatic activity. Measurement of the far- and near-UV circular dichroism spectra suggests that inactivation by the mutation of His 313 or Asp 255 is not due to marked changes in the tertiary structure. We propose that His 313 and Asp 255, together with Ser 207, form a catalytic triad in PML.

Influence of the Axial Ligands on the Spectral Properties of P700 of Photosystem I: A Study of Site-Directed Mutants

Two histidines provide the axial ligands of the two chlorophyll a (Chl a) molecules which form the primary electron donor (P700) of photosystem I (PSI). Histidine 676 in the protein subunit PsaA, His(A676), and histidine 656 in subunit PsaB, His(B656), were replaced in the green algae Chlamydomnas reinhardtii by site-directed mutagenesis with nonpolar, uncharged polar, acidic, and basic amino acid residues. Only the substitutions with uncharged polar residues led to a significant accumulation of PSI in the thylakoid membranes. These PSI complexes were isolated and the physical properties of the primary donor characterized. The midpoint potential of P700(+)(*)/P700 was increased in all mutants (up to 140 mV) and showed a dependence on size and polarizability of the residues when His(B656) was substituted. In the light-minus-dark absorbance spectra, all mutations in PsaB exhibited an additional bleaching band at 665 nm at room temperature comparable with the published spectrum for the replacement of His(B656) with asparagine [Webber, A. N., Su Hui, Bingham, S. E., Käss, H., Krabben, L., Kuhn, M., Jordan, R., Schlodder, E., and Lubitz, W. (1996) Biochemistry 35, 12857-12863]. Substitutions of His(A676) showed an additional shoulder around 680 nm. In the low-temperature absorbance difference spectra of P700(+)(*)/P700, a blue shift of the main bleaching band by 2 nm and some changes in the spectral features around 660 nm were observed for mutations of His(B656) in PsaB. The analogous substitution in PsaA showed only a shift of the main bleaching band. Similar effects of the mutations were found in the (3)P700/P700 absorbance difference spectra at low temperatures (T = 2 K). The zero-field splitting parameters of (3)P700 were not significantly changed in the mutated PSI complexes. The electron spin density distribution of P700(+)(*), determined by ENDOR spectroscopy, was only changed when His(B656) was replaced. In all measurements, two general observations were made. (i) The replacement of His(B656) had a much stronger impact on the physical properties of P700 than the mutation of His(A676). (ii) The exchange of His(B656) with glutamine induces the smallest changes in the spectra or the midpoint potential, whereas the other replacements exhibited a stronger but very similar influence on the spectroscopic features of P700. The data provide convincing evidence that the unpaired electron in the cation radical and the triplet state of P700 are mainly localized on the Chl a of the dimer which is axially coordinated by His(B656).

Functional cloning and mutational analysis of the human cDNA for phosphoacetylglucosamine mutase: identification of the amino acid residues essential for the catalysis

In Saccharomyces cerevisiae, phosphoacetylglucosamine mutase is encoded by an essential gene called AGM1. The human AGM1 cDNA ( HsAGM1) and the Candida albicans AGM1 gene ( CaAGM1) were functionally cloned and characterized by using an S. cerevisiae strain in which the endogenous phosphoacetylglucosamine mutase was depleted. When expressed in Escherichia coli as fusion proteins with glutathione S-transferase, both HsAgm1 and CaAgm1 proteins displayed phosphoacetylglucosamine mutase activities, demonstrating that they indeed specify phosphoacetylglucosamine mutase. Sequence comparison of HsAgm1p with several hexose-phosphate mutases yielded three domains that are highly conserved among phosphoacetylglucosamine mutases and phosphoglucomutases of divergent organisms. Mutations of the conserved amino acids found in these domains, which were designated region I, II, and III, respectively, demonstrated that alanine substitutions for Ser 64 and His 65 in region I, and for Asp 276, Asp 278, and Arg 281 in region II of HsAgm1p severely diminished the enzyme activity and the ability to rescue the S. cerevisiae agm1Δ null mutant. Conservative mutations of His 65 and Asp 276 restored detectable activities, whereas those of Ser 64, Asp 278, and Arg 281 did not. These results indicate that Ser 64, Asp 278, and Arg 281 of HsAgm1p are residues essential for the catalysis. Because Ser 64 corresponds to the phosphorylating serine in the E. coli phosphoglucosamine mutase, it is likely that the activation of HsAgm1p also requires phosphorylation on Ser 64. Furthermore, alanine substitution for Arg 496 in region III significantly increased the K m value for N-acetylglucosamine-6-phosphate, demonstrating that Arg 496 serves as a binding site for N-acetylglucosamine-6-phosphate.

The Chemotactic Action of Urokinase on Smooth Muscle Cells Is Dependent on Its Kringle Domain: CHARACTERIZATION OF INTERACTIONS AND CONTRIBUTION TO CHEMOTAXIS

Urokinase plasminogen activator (uPA) is thought to exert its effects on cell growth, adhesion, and migration by mechanisms involving proteolysis and interaction with its cell surface receptor (uPAR). The functional properties of uPA and the significance of its various domains for chemotactic activity were analyzed using human airway smooth muscle cells (hAWSMC). The wild-type uPA (r-uPAwt), inactive urokinase with single mutation (His(204) to Gln) (r-uPA(H/Q)), urokinase with mutation of His(204) to Gln together with a deletion of growth factor-like domain (r-uPA(H/Q)-GFD), the catalytic domain of urokinase (r-uPA(LMW)), and its kringle domain (r-KD) were expressed in Escherichia coli. We demonstrate that glycosylated uPA, r-uPAwt, r-uPA(H/Q), and r-uPA(H/Q)-GFD elicited similar chemotactic effects. Half-maximal chemotaxis (EC(50)) were apparent at approximately 2 nm with all the uPA variants. The kringle domain induced cell migration with an EC(50) of about 6 nm, whereas the denaturated r-KD and r-uPA(LMW) were without effect. R-uPAwt-induced chemotaxis was dependent on an association with uPAR and a uPA-kringle domain-binding site, determined using a monoclonal uPAR antibody to prevent the uPA-uPAR interaction, and a monoclonal antibody to the uPA-kringle domain. The binding of iodinated r-uPAwt with hAWSMC was due to interaction with a high affinity binding site on the uPAR, and a lower affinity binding site on an unidentified cell surface target, which was mediated exclusively through the kringle domain of urokinase. Specific binding of r-uPA(H/Q)-GFD to hAWSMC involved an interaction with a single site whose characteristics were similar to those of the low affinity site of r-uPAwt binding to hAWSMC. uPAR-deficient HEK 293 cells specifically bound r-uPAwt and r-uPA(H/Q)-GFD via a single, similar type of binding site. These cells migrated when stimulated by r-uPA(H/Q)-GFD and uPAwt, but not r-uPA(LMW). HEK 293 cells transfected with the uPAR cDNA expressed two classes of sites that bound r-uPAwt; however, only a single site was responsible for the binding of r-uPA(H/Q)-GFD. Together, these findings indicate that uPA-induced chemotaxis is dependent on the binding of the uPA-kringle to the membrane surface of cells and the association of uPA with uPAR.

Structure and Function of the Tryptophan Synthase α2β2 Complex: ROLES OF β SUBUNIT HISTIDINE 86

To probe the structural and functional roles of active-site residues in the tryptophan synthase alpha(2)beta(2) complex from Salmonella typhimurium, we have determined the effects of mutation of His(86) in the beta subunit. His(86) is located adjacent to beta subunit Lys(87), which forms an internal aldimine with the pyridoxal phosphate and catalyzes the abstraction of the alpha-proton of L-serine. The replacement of His(86) by leucine (H86L) weakened pyridoxal phosphate binding approximately 20-fold and abolished the circular dichroism signals of the bound coenzyme and of a reaction intermediate. Correlation of these results with previous crystal structures indicates that beta-His(86) plays a structural role in binding pyridoxal phosphate and in stabilizing the correct orientation of pyridoxal phosphate in the active site of the beta subunit. The H86L mutation also altered the pH profiles of absorbance and fluorescence signals and shifted the pH optimum for the synthesis of L-tryptophan from pH 7.5 to 8.8. We propose that the interaction of His(86) with the phosphate of pyridoxal phosphate and with Lys(87) lowers the pK(a) of Lys(87) in the wild-type alpha(2)beta(2) complex and thereby facilitates catalysis by Lys(87) in the physiological pH range.

Characterization of the block in replication of nucleocapsid protein zinc finger mutants from moloney murine leukemia virus.

Mutagenesis studies have shown that retroviral nucleocapsid (NC) protein Zn(2+) fingers (-Cys-X(2)-Cys-X(4)-His-X(4)-Cys- [CCHC]) perform multiple functions in the virus life cycle. Moloney murine leukemia virus mutants His 34-->Cys (CCCC) and Cys 39-->His (CCHH) were able to package their genomes normally but were replication defective. Thermal dissociation experiments showed that the CCHH mutant was not defective in genomic RNA dimer structure. Primer tRNA placement on the viral genome and the ability of the tRNA to function in reverse transcription initiation in vitro also appear normal. Some "full-length" DNA copies of the viral genome were synthesized in mutant virus-infected cells. The CCCC and CCHH mutants produced these DNA copies at greatly reduced levels. Circle junction fragments, amplified from two-long-terminal-repeat viral DNA (vDNA) by PCR, were cloned and characterized. Remarkably, it was discovered that vDNA isolated from cells infected with mutant virions had a wide variety of abnormalities at the site at which the two ends of the linear precursor had been ligated to form the circle (i.e., the junction between the 5' end of U3 and the 3' end of U5). In some molecules, bases were missing from regions corresponding to the U3 and U5 linear vDNA termini; in others, the viral sequences extended either beyond the U5 sequences into the primer-binding site and 5' leader or beyond the U3 sequences into the polypurine tract into the env coding region. Still other molecules contained nonviral sequences between the linear vDNA termini. Such defective genomes would certainly be unsuitable substrates for integration. Thus, strict conservation of the CCHC structure in NC is required for infection events prior to and possibly including integration.

Significance of metal ions in galactose-1-phosphate uridylyltransferase: an essential structural zinc and a nonessential structural iron.

Galactose-1-phosphate uridylyltransferase (GalT) catalyzes the reversible transformation of UDP-glucose and galactose-1-phosphate (Gal-1-P) into UDP-galactose and glucose-1-phosphate (Glc-1-P) by a double displacement mechanism, with the intermediate formation of a covalent uridylyl-enzyme (UMP-enzyme). GalT is a metalloenzyme containing 1.2 mol of zinc and 0.7 mol of iron/mol of subunits [Ruzicka, F. J., Wedekind, J. E., Kim, J., Rayment, I., and Frey, P. A. (1995) Biochemistry 34, 5610-5617]. The zinc site lies 8 A from His 166 in active site, and the iron site lies 30 A from the active site [Wedekind,J. E., Frey, P. A., & Rayment, I. (1995) Biochemistry 34, 11049-11061]. Zinc is coordinated in tetrahedral geometry by Cys 52, Cys 55, His 115, and His 164. His 164 is part of the highly conserved active-site triad His 164-Pro 165-His 166, in which His 166 is the nucleophilic catalyst. Iron is coordinated in square pyramidal geometry with His 296, His 298, and Glu 182 in bidentate coordination providing the base ligands and His 281 providing the axial ligand. In the present study, site-directed mutagenesis, kinetic, and metal analysis studies show that C52S-, C55S-, and H164N-GalT are 3000-, 600-, and 10000-fold less active than wild-type. None of the variants formed the UMP-enzyme in detectable amounts upon reaction with UDP-Glc in the absence of Gal-1-P. Their zinc content was very low, and the zinc + iron content was about 50% of that for wild-type GalT. Mutation of His 115 to Asn 115 resulted in decreased activity to 2.9% of wild-type, with retention of zinc and iron. In contrast to the zinc-binding site, Glu 182 in the iron site is not important for enzymatic activity. The variant E182A-GalT displayed about half the activity of wild-type GalT, and all of the active sites underwent uridylylation to the UMP-enzyme, similar to wild-type GalT, upon reaction with UDP-Glc. Metal analysis showed that while E182A-GalT contained 0.9 equiv of zinc/subunit, it contained no iron. The residual zinc can be removed by dialysis with 1,10-phenanthroline, with the loss in activity being proportional to the amount of residual zinc. It is concluded that the presence of zinc is essential for maintaining GalT function, whereas the presence of iron is not essential.

Evidence for a Direct Interaction between the Penultimate Aspartic Acid of Cholecystokinin and Histidine 207, Located in the Second Extracellular Loop of the Cholecystokinin B Receptor

Recently, we reported that the mutation of His(207) to Phe located in the second extracellular loop of the cholecystokinin B receptor strongly affected cholecystokinin (CCK) binding (Silvente-Poirot, S., Escrieut, C., and Wank, S. A. (1998) Mol. Pharmacol. 54, 364-371). To characterize the functional group in CCK that interacts with His(207), we first substituted His(207) to Ala. This mutation decreased the affinity and the potency of CCK to produce total inositol phosphates 302-fold and 456-fold without affecting the expression of the mutant receptor. The screening of L-alanine-modified CCK peptides to bind and activate the wild type and mutant receptors allowed the identification of the interaction of the C-terminal Asp(8) of CCK with His(207). The H207A-CCKBR mutant, unlike the wild type receptor, was insensitive to substitution of Asp(8) of CCK to other amino acid residues. This interaction was further confirmed by mutating His(207) to Asp. The affinity of CCK for the H207D-CCKBR mutant was 100-fold lower than for the H207A-CCKBR mutant, consistent with an electrostatic repulsion between the negative charges of the two interacting aspartic acids. Peptides with neutral amino acids in position eight of CCK reversed this effect and displayed a gain of affinity for the H207D mutant compared with CCK. To date, this is the first report concerning the identification of a direct contact point between the CCKB receptor and CCK.

The affinity of cholera toxin for Ni2+ ion.

Cholera toxin (CT) was shown to bind to immobilized Ni2+ ion. The affinity of CT for the complex required the presence of the Ni2+ ion, since CT was unable to bind in its absence. Binding was mediated by the B-subunit (CTB) as both CT and CTB bound to the resin, but not the A-subunit (CTA). Binding was reversible in the presence of imidazole and suggested that the affinity of CT for the Ni2+ ion was mediated by His residues. The heat-labile enterotoxin of Escherichia coli (LT), which is closely related to CT, was unable to bind to the Ni2+ ion. Comparison of amino acid sequences revealed the presence of three His residues in CT (positions 13, 57 and 94), but only one in LT (position 57). To confirm that the residues at positions 13 and 94 of CTB were responsible for the binding, they were changed to residues found in LTB. Changing His13-->Arg completely abrogated the ability of CTB to bind to Ni2+ ion. In contrast, the mutation of His 94-->Asn reduced, but did not abrogate, the ability of CTB to bind to Ni2+ ion. Based on calculated interatomic distances, it is unlikely that His13 and His94 are part of the same complex. There appear to be two separate binding sites, with the principal site involving His13 and a much weaker site involving His94. This latter site can only participate in binding if the complex involving His13 has formed.

Fluoride binding in hemoproteins: the importance of the distal cavity structure.

The electronic absorption and resonance Raman spectra of the fluoride complexes of various peroxidases and selected site-directed mutants have been studied at pH 5.0, and compared to the spectra obtained for the myoglobin-F adduct. It is shown that the electronic absorption maxima depend on the degree of conjugation between the porphyrin macrocycle and the vinyl substituents. Moreover, it is confirmed that the wavelength of the CT1 band is a sensitive probe of axial ligand polarity and of its interaction with the distal protein residues. The results highlight the different mechanism of stabilization of the fluoride ligand exerted by the distal residues in myoglobin and peroxidases. In peroxidases, the Arg is determinant in controlling the ligand binding via a strong hydrogen bond between the positively charged guanidinium group and the anion. Mutation of Arg to Leu decreases the stability of the complex by 900-fold, suggesting that this interaction stabilizes the complex by 4 kcal/mol. The distal His also contributes to the stability of the fluoride complex, presumably by accepting a proton from HF and hydrogen-bonding, through a water molecule, to the anion. Mutation of His to Leu decreases the stability of the fluoride complex by 30-fold, suggesting that this interaction is much weaker than the interaction with the distal Arg. For Mb, the distal His is solely responsible for stabilization of the exogenous ligand.

Nephrotoxic effects of bacterial ribonucleases in the isolated perfused rat kidney

Alterations of the renal function in the isolated perfused rat kidney system after application of two bacterial RNases, Bacillus intermedius RNase (binase) and ribonuclease produced by Bacillus amyloliquefaciens (barnase), were investigated with two different treatment regimens in comparison with catalytically inactive derivatives of the enzymes, photooxidated at the active site His 101 binase and inactive mutant His 102Gln barnase. For the in vitro approach the test enzymes were dissolved in the perfusion media and applied to the kidney after removal from the animal. Alternatively, the test ribonucleases were administered to rats in vivo and the renal effects were assessed in the isolated perfused rat kidney 1 and 6 h after treatment. In the in vitro regimen both active enzymes induced time- and concentration-dependent nephrotoxicity reflected in enhancement of urinary protein excretion, decline of glucose reabsorption, increase of γ-glutamyltranspeptidase and alkaline phosphatase activities in urine. In vivo administration of active binase induced functional impairment of the isolated perfused organ in a similar way. None of the inactive RNases in both regimens and at all concentrations tested altered any renal parameter. The results suggest that RNA degradation may be involved in the nephrotoxic effects of bacillar RNases.

A European family with histidine 58 transthyretin mutation in familial amyloid polyneuropathy

1. IntroductionMore than 50 mutations of the transthyretin (TTR) [1]molecule resulting in different clinical forms of amyloidosisincluding familial amyloid polyneuropathy (FAP) havebeen reported to date. Within this FAP spectrum severaltransthyretin mutations are more frequent, others are rare.One mutation, the codon 58 histidine for leucine has pre-viously been recorded only in American subjects (Mary-land/German type), originally reported in a large kinship[2,3] and in another family from Ohio [4]. In the originaldescription of the Maryland/German type of amyloidosis[2], it was stated that the early immigrants in this pedigreewere from the Rhine river area, nearly all of them from theleft Rhine side southward of (p. 15).We now report an identification of the codon 58 histidinefor leucine mutation in autosomal-dominant FAP from afamily that has always lived south of Mainz on the leftside of the Rhine river, suggesting that this family is geneti-cally related to the 58 histidine for leucine mutation patientsin the US. This paper, thus, does not give a lengthy accountof FAP type II, the Maryland/German type, because this hasbeen described exhaustively before [2] and is now commontextbook knowledge; instead, this paper aims to highlight,the somewhat historic aspect, where the US founder of thisHis 58 FAP originated from—documented by modernmolecular techniques.2. Patients’ report2.1. Patient 1This 59-year-old man had experienced stiffness andimpaired sensation in both hands and later in both legs forthe past 10 years. Clinical examination revealed bilateralimpaired hearing suspected by his clinicians to have devel-oped due to excessive noise, decreased deep tendon reflexesin both legs, mild afferent type ataxia, atrophy of small footmuscles, not hand muscles, distal hypesthesia and hypalge-sia in both hands and feet, reduced sense of vibration in bothhands and both legs. Electroneurographically (Table 1), hehad markedly reduced conduction velocities of his motormedian and tibial nerves and no potentials in his sensorymedian nerves in the carpal tunnel region. Sural nervebiopsy revealed chronic neuropathy and focal amyloiddeposits which reacted with an antibody against anti-trans-thyretin amyloid. He died suddenly, while abroad, 5 yearslater of cardiac failure.2.2. Patient 2 (son of patient 1)This 45-year-old man complained of occasional repeti-tive, later of frequent numbness of his right hand. Hedescribed mild dysesthesia in his right hand due to compres-sion of his right carpal tunnel. Data of his electrophysiolo-gical examination are listed in Table 1. Operation of bothcarpal tunnels showed deposits of amyloid within the con-nective tissue.2.3. DNA analysesDirect DNA sequencing analysis of the TTR gene ofpatient 2 showed both thymine and adenine at the secondbase of codon 58 of TTR. Thus patient 2 was heterozygouswith a normal allele and a mutant allele encoding histidinefor leucine at codon 58. Restriction fragment length poly-morphisms (RFLP) analysis based on the polymerase chainreaction [5] revealed three mutant His 58 gene carriers ofseven family members at risk that were tested. DNA haplo-type analysis of the TTR gene of this German family, i.e.patient 2, his mother but not his father who had previously

The active site histidines of creatine kinase. A critical role of His 61 situated on a flexible loop.

A histidine residue with a pKa of 7 has been inferred to act as a general acid-base catalyst for the reaction of creatine kinase (CK), catalyzing the reversible phosphorylation of creatine by ATP. The chicken sarcomeric muscle mitochondrial isoenzyme Mib-CK contains several histidine residues that are conserved throughout the family of creatine kinases. By X-ray crystal structure analysis, three of them (His 61, His 92, and His 186) were recently shown to be located close to the active site of the enzyme. These residues were exchanged against alanine or aspartate by in vitro mutagenesis, and the six mutant proteins were expressed in E. coli and purified. Structural integrity of the mutant proteins was checked by small-angle X-ray scattering. Kinetic analysis showed the mutant His 61 Asp to be completely inactive in the direction of ATP consumption while exhibiting a residual activity of 1.7% of the wild-type (wt) activity in the reverse direction. The respective His to Ala mutant of residue 61 showed approximately 1% wt activity in the forward and 10% wt activity in the reverse reaction. All other mutants showed near wt activities. Changes in the kinetic parameters K(m) or Vmax, as well as a significant loss of synergism in substrate binding, could be observed with all active mutants. These effects were most pronounced for the binding of creatine and phosphocreatine, whereas ATP or ADP binding were less severely affected. Based on our results, we assume that His 92 and His 186 are involved in the binding of creatine and ATP in the active site, whereas His 61 is of importance for the catalytic reaction but does not serve as an acid-base catalyst in the transphosphorylation of creatine and ATP. In addition, our data support the idea that the flexible loop bearing His 61 is able to move towards the active site and to participate in catalysis.

Ribonuclease A mutant His 119Asn: the role of histidine in catalysis

Bovine pancreatic ribonuclease A (RNase A) has been widely used as a convenient model for structural and functional studies. The enzyme catalyzes cleavage of phosphodiester bonds in RNA and related substrates. Three amino acid residues located at the active site of RNase A (His 12, His 119, and Lys 41) are known to be involved in catalysis. Mutation of His 119 to asparagine was generated to study the role of His 119 in RNase A catalysis. The mutant enzyme has been isolated and characterized. The mutation significantly decreases the rate of the transesterification reaction and has no effect on substrate affinity of the enzyme. An analysis of the enzymatic properties of H119N RNase A suggests that the imidazole ring of His 119 of the wild-type enzyme must be protonated in an enzyme-substrate productive complex. Thus our results indicate that a contribution of protonated His 119 into the catalysis is not restricted to protonation of oxygen atom of the substrate leaving group and that His 119 participates directly in a transition state stabilization via hydrogen bonding.

Identification of the Five Essential Histidine Residues for Peptidylglycine Monooxygenase

Peptidylglycine monooxygenase (PGM) is a copper-containing monooxygenase that plays a key role in the peptide C-terminal α-amidation. Comparative analysis of the amino acid sequences of rat, human, bovine and frog PGMs revealed that ten histidines (residues 107, 108, 172, 235, 242, 244, 279, 364, 366 and 367 in rat PGM) are conserved among the four species. We introduced site-directed mutations to the ten histidines of rat PGM and found that the mutation of His- 107 → Ala, His-108 → Ala, His-172 → Ala, His-242 → Arg or His-244 → Ala abolished the enzyme activity. The five mutant proteins lacking the enzyme activity bound to a substrate, Phe-Gly-Phe-Gly, as did the wild type PGM. These results along with available evidence indicate that the five histidine residues (His-107, 108, 172, 242 and 244) are essential for PGM activity, acting as copper ligands.

Aspartate mutation distinguishes ET A but not ET B receptor subtype-selective ligand binding while abolishing phospholipase C activation in both receptors

The endothelin receptors, ET A and ET B, are G protein-coupled receptors (GPCR) that show distinctively different binding profiles for the endothelin peptides and other ligands. We recently reported that Tyr 129 in the second transmembrane region (TM2) of the ET A receptor was critical for subtype-specific ligand binding [Krystek, S.R. et al. (1994) J. Biol. Chem. 269, 12383–12386]. Receptor models indicated that aspartic acids located one helical turn above (Asp 133) and below (Asp 126) Tyr 129 in ET A had their side chains directed toward the putative binding cavity. Similarly in ET B, Asp 147 and Asp 154 are located one turn below and above His 150, the residue that corresponds to Tyr 129. Asp 126 in ET A and Asp 147 in ET B corresponds to the highly conserved aspartate present in TM2 of many GPCR that has frequently been shown to be crucial for agonist efficacy. Mutagenesis of Asp 126 of the human ET A receptor to alanine resulted in an unaltered affinity for ET-1, a 160-fold increase in ET-3 affinity and a decrease in affinity for the ET A selective naphthalenesulfonamide, BMS-182874. ET-1 activation of phospholipase C was abolished. In addition, despite the gain in binding affinity, ET-3 failed to activate phospholipase C, suggesting that Asp 126 is required for signal transduction. Mutagenesis of Asp 133 to alanine indicated that it was critical only for the binding of BMS-182874. In the ET B receptor, mutation of His 150 to alanine or tyrosine indicated that it plays a minor role in ET B subtype-selective ligand binding; mutation of the aspartates in TM2 of ET B did not alter ligand binding. As in the Asp 126Ala ET A variant, ET-1 and ET-3 failed to increase intracellular levels of inositol phosphates in the Asp 147Ala ET B mutant. Taken together, these data support the hypothesis that Asp 126 and Asp 133 flanking Tyr 129 in TM2 of the ET A receptor play a role in defining ET A subtype-selective ligand binding but Asp 147 and Asp 154 that flank the His 150 in TM2 of the ET B receptor do not. Furthermore, these data indicate that Asp 126 in ET A and Asp 147 in ET B are important for transmembrane signaling via phospholipase C.