Probing local environments of tryptophan residues in proteins: comparison of 19F nuclear magnetic resonance results with the intrinsic fluorescence of soluble human tissue factor

19F nuclear magnetic resonance (19F NMR) of 5-fluorotryptophan (5F-Trp) and tryptophan (Trp) fluorescence both provide information about local environment and solvent exposure of Trp residues. To compare the information provided by these spectroscopies, the four Trp residues in recombinant soluble human tissue factor (sTF) were replaced with 5F-Trp. 19F NMR assignments for the 5F-Trp residues (14, 25, 45, and 158) were based on comparison of the wild-type protein spectrum with the spectra of three single Trp-to-Phe replacement mutants. Previously we showed from fluorescence and absorption difference spectra of mutant versus wild-type sTF that the side chains of Trpl4 and Trp25 are buried, whereas those of Trp45 and Trp158 are partially exposed to bulk solvent (Hasselbacher et al., Biophys J 1995;69:20-29). 19F NMR paramagnetic broadening and solvent-induced isotope-shift experiments show that position 5 of the indole ring of 5F-Trp158 is exposed, whereas that of 5F-Trp45 is essentially inaccessible. Although 5F-Trp incorporation had no discernable effect on the procoagulant cofactor activity of either the wild-type or mutant proteins, 19F NMR chemical shifts showed that the single-Trp mutations are accompanied by subtle changes in the local environments of 5F-Trp residues residing in the same structural domain.     

19F NMR studies of the D-galactose chemosensory receptor. 2. Ca(II) binding yields a local structural change.

The Escherichia coli D-galactose and D-glucose receptor possesses a Ca(II)-binding site closely related in structure and metal-binding characteristics to the eukaryotic EF-hand sites. Only the structure of the Ca(II)-occupied site is known. To investigate the structural change triggered by Ca(II) and Sr(II) binding, we have used 19F NMR to probe five 5-fluorotryptophan (5F-Trp) and seven 3-fluorophenylalanine (3F-Phe) positions in the structure, extending the approach described in the preceding article. Of particular interest were two 5F-Trp residues near the N terminus of the Ca(II) site at positions 127 and 133. Substitution of the larger Sr(II) for Ca(II) triggered 19F NMR frequency shifts of the 5F-Trp127 and -133 resonances, indicating a detectable structural change in the Ca(II) site. In contrast, the three 5F-Trp resonances from distant regions of the structure exhibited no detectable frequency shifts. When the metal was removed from the Ca(II) site, the 5F-Trp127 and -133 frequencies shifted to a new value similar to that observed for free 5F-Trp in aqueous solvent, and this new frequency was a function of the H2O to D2O ratio, indicating that the residues had become solvent exposed. Metal removal yielded small or undetectable frequency shifts for the three distant 5F-Trp resonances and for four of the five resolved 3F-Phe resonances. The allosteric coupling of the metal and sugar binding sites was observed to be slight: depletion of metal ions was observed to reduce the D-galactose affinity of the receptor by 2-fold. Together the results indicate that the structural changes in the Ca(II) site are primarily localized in the region of the site. Removal of the metal ion from the site exposes the nearby 5F-Trp127 and -133 residues to the solvent, suggesting that the empty site has a more open structure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermal denaturation of engineered tet repressor proteins and their complexes with tet operator and tetracycline studied by temperature gradient gel electrophoresis

The effects of Trp to Phe exchanges in the Tet repressor on the thermal stability of the proteins and their complexes with operator DNA and inducer have been studied by temperature gradient polyacrylamide gel electrophoresis. The denaturation temperatures obtained by this method are compared with the results from temperature-dependent fluorescence and binding activities of the proteins. It is established that exchanging the interior Trp75 to Phe reduces the thermal stability of the Tet repressor by 8 degrees C while exchanging the exterior Trp43 to Phe has no effect on the stability of the protein. Binding of the inducer tetracycline increases the thermal stability of wild-type and Trp43 to Phe mutant Tet repressors by 5 degrees C, while the ones with the Trp75 to Phe mutation are stabilized by 10 degrees C. The stabilizing effect of operator binding is 20 degrees C in the Trp75 to Phe mutant and only 9 degrees C in the ones with the Trp43 to Phe exchange. In addition to the denaturation temperatures, the gel mobility shifts observed in temperature gradient gel electrophoresis reveal also information about the intermediates of the denaturation reaction. The free proteins and their complexes with the inducer tetracycline exhibit monophasic transitions upon denaturation. The operator complexes of wild-type and Trp75 to Phe mutant repressors denature in more complex reactions. At low temperature they exhibit a stoichiometry of two repressor dimers per tandem tet operator DNA. Upon elevating the temperature they form complexes with only one repressor dimer per DNA fragment. When the temperature is further increased the double-stranded DNA begins to melt from one end resulting in a complex with partially single-stranded DNA which exists only in a narrow temperature range. Finally, the denatured protein and single-stranded DNA are formed at high temperature. The associated mobility shifts are analyzed by changing the ionic strength and characterizing multiphasic melting of a pure DNA fragment by temperature gradient gel electrophoresis.     

Membrane interaction and cellular internalization of penetratin peptides.

Penetratin is a 16-residue peptide [RQIKIWFQNRRMKWKK(43-58)] derived from the Antennapedia homeodomain, which is used as a vector for cellular internalization of hydrophilic molecules. In order to unravel the membrane translocation mechanism, we synthesized new penetratin variants. The contribution of the positively charged residues was studied by double substitutions of Lys and/or Arg residues to Ala, while the specific contribution of Trp48 and Trp56 was studied by individual substitution of these residues to Phe. Trp fluorescence titrations demonstrated the importance of the positively charged residues for the initial electrostatic interaction of the peptide with negatively charged vesicles. In contrast, none of the Trp residues seemed critical for this initial interaction. Trp fluorescence quenching experiments showed that penetratin lies close to the water-lipid interface in a tilted orientation, while circular dichroism indicated that lipid binding increased the alpha-helical structure of the peptides. The R53A/K57A and R52A/K55A substitutions increased calcein leakage and decreased vesicle aggregation compared to wild-type penetratin. These variants insert deeper into the lipid bilayer, due to an increased hydrophobic environment of Trp56. The W48F and W56F substitutions had a minor effect on membrane insertion and destabilization. Cellular internalization of the R53A/K57A, R52A/K55A and K46A/K57A variants by MDCK cells was similar to wild-type penetratin, as shown by flow cytometry. Moreover, residue Trp48 specifically contributed to endocytosis-independent internalization by MDCK cells, as demonstrated by the lower uptake of the W48F variant compared to wild-type penetratin and to the W56F variant. None of the penetratin variants was haemolytic or cytotoxic.     

Mutagenesis of uracil-DNA glycosylase deficient mutants of the extremely thermophilic eubacterium Thermus thermophilus

Thermus thermophilus is an extremely thermophilic, aerobic, and gram-negative eubacterium that grows optimally at 70-75 degrees C, pH 7.5. In extremely high temperature environment, DNA damages in cells occur at a much higher frequency in thermophiles than mesophiles such as E. coli. When temperature rises, the deamination of cytosine residues in double-strand DNA is expected to increase greatly. T. thermophilus HB27 has two putative uracil-DNA glycosylase genes (udgA and udgB). Expression level of udgA gene was 2-3 times higher than that of udgB at 70, 74, and 78 degrees C when it was monitored by beta-glucosidase reporter assay. We developed hisD(3110), hisD(3113), hisD(3115), and hisD(174) marker allele that can specifically detect G:C-->A:T, C:G-->A:T, T:A-->A:T, and A:T-->G:C base-substitutions, respectively, by His(+) reverse mutations. We then disrupted udgA and udgB by thermostable kanamycin-resistant gene (htk) or pyrE gene insertion in each hisD background, and their spontaneous His(+) reversion frequencies were compared. A udgA,B double mutant showed a pronounced increase in G:C-->A:T reversion frequency compared with each single udg mutant, udgA or udgB. Estimated mutation rates of the udgA,B mutant cultured at 60, 70, and 78 degrees C were about 2, 12, and 117 His(+)/10(8)/generation, respectively. At 70 degrees C culture, increased ratio of the mutation rate compared with the udg(+) strain was 12-fold in udgA, 3-fold in udgB, and 56-fold in udgA,B mutant. On the other hand, no difference was observed in other mutations of C:G-->A:T, T:A-->A:T, and A:T-->G:C between udgA,B double mutant and the parent udg(+) strain. The present results indicated that gene products of udgB as well as udgA functioned in vivo to remove uracil in DNA and prevent G:C-->A:T transition mutations.     

U1A protein-stem loop 2 RNA recognition: prediction of structural differences from protein mutations

Molecular dynamics (MD) simulations were carried out to compare the free and bound structures of wild type U1A protein with several Phe56 mutant U1A proteins that bind the target stem loop 2 (SL2) RNA with a range of affinities. The simulations indicate the free U1A protein is more flexible than the U1A-RNA complex for both wild type and Phe56 mutant systems. A complete analysis of the hydrogen-bonding (HB) and non-bonded (VDW) interactions over the course of the MD simulations suggested that changes in the interactions in the free U1A protein caused by the Phe56Ala and Phe56Leu mutations may stabilize the helical character in loop 3, and contribute to the weak binding of these proteins to SL2 RNA. Compared with wild type, changes in HB and VDW interactions in Phe56 mutants of the free U1A protein are global, and include differences in β-sheet, loop 1 and loop 3 interactions. In the U1A-RNA complex, the Phe56Ala mutation leads to a series of differences in interactions that resonate through the complex, while the Phe56Leu and Phe56Trp mutations cause local differences around the site of mutation. The long-range networks of interactions identified in the simulations suggest that direct interactions and dynamic processes in both the free and bound forms contribute to complex stability.     

Residues Leu261, Trp264, and Phe265 account for apolipoprotein E-induced dyslipidemia and affect the formation of apolipoprotein E-containing high-density lipoprotein

Overexpression of apolipoprotein E (apoE) induces hypertriglyceridemia in apoE-deficient mice, which is abrogated by deletion of the carboxy-terminal segment of residues 260-299. We have used adenovirus-mediated gene transfer in apoE-/- and apoA-I-/- mice to test the effect of three sets of apoE mutations within the region of residues 261-265 on the induction of hypertriglyceridemia, the esterification of cholesterol of very low-density lipoprotein (VLDL) and high-density lipoprotein (HDL), and the formation of spherical or discoidal apoE-containing HDL. A single-amino acid substitution (apoE4[Phe265Ala]) induced hypertriglyceridemia in apoE-/- or apoA-I-/- mice, promoted the accumulation of free cholesterol in the very low-density lipoprotein (VLDL) and HDL region, and decreased HDL cholesterol levels. A double substitution (apoE4[Leu261Ala/Trp264Ala]) induced milder hypertriglyceridemia and increased HDL cholesterol levels. A triple substitution (apoE4[Leu261Ala/Trp264Ala/Phe265Ala] or apoE2[Leu261Ala/Trp264Ala/Phe265Ala]) did not induce hypertriglyceridemia and increased greatly the HDL cholesterol levels. Electron microscopy (EM) analysis of the HDL fractions showed that apoE4[Leu261Ala/Trp264Ala/Phe265Ala] and apoE2[Leu261Ala/Trp264Ala/Phe265Ala] contained spherical HDL, apoE4[Leu261Ala/Trp264Ala] contained mostly spherical and few discoidal HDL particles, and apoE4[Phe265Ala] contained discoidal HDL. We conclude that residues Leu261, Trp264, and Phe265 play an important role in apoE-induced hypertriglyceridemia, the accumulation of free cholesterol in VLDL and HDL, and the formation of discoidal HDL. Substitution of these residues with Ala improves the apoE functions by preventing hypertriglyceridemia and promoting formation of spherical apoE-containing HDL.     

Characterization of rat and mouse NAD+-dependent 3alpha/17beta/20alpha-hydroxysteroid dehydrogenases and identification of substrate specificity determinants by site-directed mutagenesis

In this study, we characterized rat and mouse aldo-keto reductases (AKR1C16 and AKR1C13, respectively) with 92% sequence identity. The recombinant enzymes oxidized non-steroidal alcohols using NAD⁺ as the preferred coenzyme, and showed low 3α/17β/20α-hydroxysteroid dehydrogenase (HSD) activities. The substrate specificity differs from that of rat NAD⁺-dependent 3α-HSD (AKR1C17) that shares 95% sequence identity with AKR1C16. To elucidate the residues determining the substrate specificity of the enzymes, we performed site-directed mutagenesis of Tyr24, Asp128 and Phe129 of AKR1C16 with the corresponding residues (Ser, Tyr and Leu, respectively) of AKR1C17. The double mutation (Asp128/Tyr-Phe129/Leu) had few effects on the substrate specificity, while the Tyr24/Ser mutant showed only 3α-HSD activity, and the triple mutation of the three residues produced an enzyme that had almost the same properties as AKR1C17. The importance of the residue 24 for substrate recognition was verified by the mutagenesis of Ser24/Tyr of AKR1C17 which resulted in a decrease in 3α-HSD activity and appearance of 17β- and 20α-HSD activities. AKR1C16 is also 92% identical with rat NAD⁺-dependent 17β-HSD (AKR1C24), which possesses Tyr24. The replacement of Asp128, Phe129 and Ser137 of AKR1C16 with the corresponding residues (Glu, Ser and Phe, respectively) of AKR1C24 increased the catalytic efficiency for 17β- and 20α-hydroxysteroids.     

Engineering the properties of a cold active enzyme through rational redesign of the active site.

In an effort to explore the effects of local flexibility on the cold adaptation of enzymes, we designed point mutations aiming to modify side-chain flexibility at the active site of the psychrophilic alkaline phosphatase from the Antarctic strain TAB5. The mutagenesis targets were residues Trp260 and Ala219 of the catalytic site and His135 of the Mg2+ binding site. The replacement of Trp260 by Lys in mutant W260K, resulted in an enzyme less active than the wild-type in the temperature range 5-25 degrees C. The additional replacement of Ala219 by Asn in the double mutant W260K/A219N, resulted in a drastic increase in the energy of activation, which was reflected in a considerably decreased activity at temperatures of 5-15 degrees C and a significantly increased activity at 20-25 degrees C. Further substitution of His135 by Asp in the triple mutant W260K/A219N/H135D restored a low energy of activation. In addition, the His135-->Asp replacement in mutants H135D and W260K/A219N/H135D resulted in considerable stabilization. These results suggest that the psychrophilic character of mutants can be established or masked by very slight variations of the wild-type sequence, which may affect active site flexibility through changes in various conformational constraints.     

Substrate binding and reactivity are not linked: grafting a proton-transfer network into a Class 1A dihydroorotate dehydrogenase

Adding the two residues comprising the conserved proton-transfer network of Class 2 dihydroorotate dehydrogenase (DHOD) to the Cys130Ser Class 1A DHOD did not restore the function of the active site base or rapid flavin reduction. Studies of triple, double, and single mutant Class 1A enzymes showed that the network actually prevents cysteine from acting as a base and that the network residues act independently. Our data show that residue 71 is an important determinant of ligand binding specificity. The Leu71Phe mutation tightens dihydrooroate binding but weakens the binding of benzoate inhibitors of Class 1A enzymes.     

A 19F-NMR study of the membrane-binding region of D-lactate dehydrogenase of Escherichia coli.

D-Lactate dehydrogenase (D-LDH) is a membrane-associated respiratory enzyme of Escherichia coli. The protein is composed of 571 amino acid residues with a flavin adenine dinucleotide (FAD) cofactor, has a molecular weight of approximately 65,000, and requires lipids or detergents for full activity. We used NMR spectroscopy to investigate the structure of D-LDH and its interaction with phospholipids. We incorporated 5-fluorotryptophan (5F-Trp) into the native enzyme, which contains five tryptophan residues, and into mutant enzymes, where a sixth tryptophan is substituted into a specific site by oligonucleotide-directed mutagenesis, and studied the 5F-Trp-labeled enzymes using 19F-NMR spectroscopy. In this way, information was obtained about the local environment at each native and substituted tryptophan site. Using a nitroxide spin-labeled fatty acid, which broadens the resonance from any residue within 15 A, we have established that the membrane-binding area of the protein includes the region between Tyr 228 and Phe 369, but is not continuous within this region. This conclusion is strengthened by the results of 19F-NMR spectroscopy of wild-type enzyme labeled with fluorotyrosine or fluorophenylalanine in the presence and absence of a nitroxide spin-labeled fatty acid. These experiments indicate that 9-10 Phe and 3-4 Tyr residues are located near the lipid phase.     

Investigation of a conserved stacking interaction in target site recognition by the U1A protein

Three highly conserved aromatic residues in RNA recognition motifs (RRM) participate in stacking interactions with RNA bases upon binding RNA. We have investigated the contribution of one of these aromatic residues, Phe56, to the complex formed between the N-terminal RRM of the spliceosomal protein U1A and stem–loop 2 of U1 snRNA. Previous work showed that the aromatic group is important for high affinity binding. Here we probe how mutation of Phe56 affects the kinetics of complex dissociation, the strength of the hydrogen bonds formed between U1A and the base that stacks with Phe56 (A6) and specific target site recognition. Substitution of Phe56 with Trp or Tyr increased the rate of dissociation of the complex, consistent with previously reported results. However, substitution of Phe56 with His decreased the rate of complex association, implying a change in the initial formation of the complex. Simultaneous modification of residue 56 and A6 revealed energetic coupling between the aromatic group and the functional groups of A6 that hydrogen bond to U1A. Finally, mutation of Phe56 to Leu reduced the ability of U1A to recognize stem–loop 2 correctly. Taken together, these experiments suggest that Phe56 contributes to binding affinity by stacking with A6 and participating in networks of energetically coupled interactions that enable this conserved aromatic amino acid to play a complex role in target site recognition.     

The intrinsic fluorescence of the recombinant human leukocyte interferon-alpha A and fibroblast interferon-beta 1

The environment of Trp residues of the recombinant human interferons has been studied by the analysis of the emission spectra of native and denatured proteins at pH 1.5-8.5 and temperature 10-65 degrees C in the presence and absence of the anionic, cationic and neutral to charge contact quenchers--KI, CsCl and acrylamide, respectively. The obtained data allow to suppose that in IFN-alpha A and IFN-beta 1 Trp141 interacts with Arg145 and one or several from the following residues--Phe124, Ile127, Tyr130, Leu131, whereas Trp77--with Arg33 and Phe36, Phe78, Leu81 or Leu82 (Ile81 or Val82 for IFN-beta 1).     

Determinants of substrate specificity of a second non-neuronal secreted acetylcholinesterase from the parasitic nematode Nippostrongylus brasiliensis.

We recently reported on a non-neuronal secreted acetylcholinesterase (AChE B) from the nematode parasite Nippostrongylus brasiliensis. Here we describe the primary structure and enzymatic properties of a second secreted variant, termed AChE C after the designation of native AChE isoforms from this parasite. As for the former enzyme, AChE C is truncated at the carboxyl terminus in comparison with the Torpedo AChE, and three of the 14 aromatic residues that line the active site gorge are substituted by nonaromatic residues, corresponding to Tyr70 (Ser), Trp279 (Asn) and Phe288 (Met). A recombinant form of AChE C was highly expressed by Pichia pastoris. The enzyme was monomeric and hydrophilic, and displayed a marked preference for acetylthiocholine as substrate. A double mutation (W302F/W345F, corresponding to positions 290 and 331 in Torpedo) rendered the enzyme 10-fold less sensitive to excess substrate inhibition and two times less susceptible to the bis quaternary inhibitor BW284C51, but did not radically affect substrate specificity or sensitivity to the 'peripheral site' inhibitor propidium iodide. In contrast, a triple mutant (M300G/W302F/W345F) efficiently hydrolysed propionylthiocholine and butyrylthiocholine in addition to acetylthiocholine, while remaining insensitive to the butyrylcholinesterase-specific inhibitor iso-OMPA and displaying a similar profile of excess substrate inhibition as the double mutant. These data highlight a conserved pattern of active site architecture for nematode secreted AChEs characterized to date, and provide an explanation for the substrate specificity that might otherwise appear inconsistent with the primary structure in comparison to other invertebrate AChEs.     

Urea-dependent unfolding of murine adenosine deaminase: sequential destabilization as measured by 19F NMR

Murine adenosine deaminase (mADA) is a 40 kDa (beta/alpha)(8)-barrel protein consisting of eight central beta-strands and eight peripheral alpha-helices containing four tryptophan residues. In this study, we investigated the urea-dependent behavior of the protein labeled with 6-fluorotryptophan (6-(19)F-Trp). The (19)F NMR spectrum of 6-(19)F-Trp-labeled mADA reveals four distinct resonances in the native state and three partly overlapped resonances in the unfolded state. The resonances were assigned unambiguously by site-directed mutagenesis. Equilibrium unfolding of 6-(19)F-Trp-labeled mADA was monitored using (19)F NMR based on these assignments. The changes in intensity of folded and unfolded resonances as a function of urea concentration show transition midpoints consistent with data observed by far-UV CD and fluorescence spectroscopy, indicating that conformational changes in mADA during urea unfolding can be followed by (19)F NMR. Chemical shifts of the (19)F resonances exhibited different changes between 1.0 and 6.0 M urea, indicating that local structures around 6-(19)F-Trp residues change differently. The urea-induced changes in local structure around four 6-(19)F-Trp residues of mADA were analyzed on the basis of the tertiary structure and chemical shifts of folded resonances. The results reveal that different local regions in mADA have different urea-dependent behavior, and that local regions of mADA change sequentially from native to intermediate topologies on the unfolding pathway.     

(19)F NMR studies of the leucine-isoleucine-valine binding protein: evidence that a closed conformation exists in solution

The leucine-isoleucine-valine binding protein (LIV) found in the periplasmic space of E. coli has been used as a structural model for a number of neuronal receptors. This "venus fly trap" type protein has been characterized by crystallography in only the open form. Herein we have labeled LIV with 5-fluorotryptophan (5F-Trp) and difluoromethionine (DFM) in order to explore the structural dynamics of this protein and the application of DFM as a potential (19)F NMR structural probe for this family of proteins. Based on mass spectrometric analysis of the protein overproduced in the presence of DFM, approximately 30% of the five LIV methionine residues were randomly substituted with the fluorinated analog. Urea denaturation experiments imply a slight decrease in protein stability when DFM is incorporated into LIV. However, the fluorinated methionine did not alter leucine-binding activity upon its incorporation into the protein. Binding of L-leucine stabilizes both the unlabeled and DFM-labeled LIV, and induces the protein to adopt a three-state unfolding model in place of the two-state process observed for the free protein. The (19)F NMR spectrum of DFM-labeled LIV gave distinct resonances for the five Met residues found in LIV. 5F-Trp labeled LIV gave a well resolved spectrum for the three Trp residues. Trp to Phe mutants defined the resonances in the spectrum. The distinct narrowing in line width of the resonances when ligand was added identified the closed form of the protein.     

Conserved aromatic residues of the C-terminus of human butyrylcholinesterase mediate the association of tetramers.

Human butyrylcholinesterase (BChE) in serum is composed predominantly of tetramers. The tetramerization domain of each subunit is contained within 40 C-terminal residues. To identify key residues within this domain participating in tetramer stabilization, the interaction between C-terminal 46 residue peptides was quantitated in the yeast two-hybrid system. The wild-type peptide interacted strongly with another wild-type peptide in the yeast two-hybrid system. The C571A mutant peptides interacted to a similar degree as the wild-type. However, the mutant in which seven conserved aromatic residues (Trp 543, Phe 547, Trp 550, Tyr 553, Trp 557, Phe 561, and Tyr 564) and C571 were altered to alanines showed only 12% of the interaction seen with the wild-type peptide. The seven mutations (aromatics-off) were incorporated into the complete BChE molecule, with or without the C571A mutation, and expressed in 293T and CHO-K1 cells. Expression of wild-type BChE in these cell lines yielded 10% tetramers. The aromatics-off mutant formed dimers and monomers but no tetramers. The aromatics-off/C571A mutant yielded only monomers. Addition of poly-L-proline to culture medium, or coexpression with the N-terminus of COLQ including the proline-rich attachment domain (Q(N)PRAD), increased the amount of tetrameric wild-type BChE from 10 to 70%, but had no effect on the G534stop (lacking 41 C-terminal residues) and the aromatics-off mutants. Recombinant BChE produced by coexpression with Q(N)PRAD was purified by column chromatography. The purified tetramers contained the FLAG-tagged Q(N)PRAD peptide. These observations suggest that the stabilization of BChE tetramers is mediated through the interaction of the seven conserved aromatic residues and that poly-L-proline and PRAD act through these aromatic residues to induce tetramerization.     

Role of tyrosine-80 in the stability of kanamycin nucleotidyltransferase analyzed by site-directed mutagenesis

A thermostable mutant of kanamycin nucleotidyltransferase (KNTase) with a single amino acid replacement of Asp at position 80 by Tyr has been isolated by a novel screening method in a previous study [Matsumura, M. & Aiba, S. (1985) J. Biol. Chem. 260, 15298-15303]. To elucidate the role of Tyr80 in stabilizing the enzyme, the KNTase gene was modified by site-directed mutagenesis so that the codon for Asp80 of the wild type was replaced by that for Ser, Thr, Ala, Val, Leu, Phe and Trp, respectively. The eight mutant KNTases including Tyr80 were all purified, as well as the wild-type enzyme. The heat-inactivation rate constants were determined at 58 degrees C and the half-life values were found to be correlated with the hydrophobicity of the amino acid residues replaced at the unique position. The Gibbs energy change of unfolding in water of KNTase assessed from urea denaturation (25 degrees C, pH 7.0) was also found to be correlated with hydrophobicity. The results suggest that different amino acids at position 80 of KNTase contribute to the stability of the protein by hydrophobic interactions. In the case of tyrosine at position 80 the unusually high stability of the enzyme compared to the Phe80 enzyme suggests that the hydroxyl group also contributes to the conformational stability.     

Functional relevance of aromatic residues in the first transmembrane domain of P2X receptors

The functional relevance of aromatic residues in the upper part of the transmembrane domain-1 of purinergic P2X receptors (P2XRs) was examined. Replacement of the conserved Tyr residue with Ala had a receptor-specific effect: the P2X1R was non-functional, the P2X2R, P2X4R, and P2X3R exhibited enhanced sensitivity to ATP and αβ-meATP accompanied by prolonged decay of current after washout of agonists, and the P2X7R sensitivity for agonists was not affected, though decay of current was delayed. The replacement of the P2X4R-Tyr42 with other amino acids revealed the relevance of an aromatic residue at this position. Mutation of the neighboring Phe and ipsilateral Tyr/Trp residues, but not the contralateral Phe residue, also affected the P2X2R, P2X3R, and P2X4R function. Double mutation of ipsilateral Tyr42 and Trp46 P2X4R residues restored receptor function, whereas the corresponding P2X2R double mutant was not functional. In contrast, mutation of the contralateral Phe48 residue in the P2X4R-Y42A mutant had no effect. These results indicate that aromatic residues in the upper part of TM1 play important roles in the three-dimensional structure of the P2XRs and that they are required not only for ion conductivity but also for specificity of agonist binding and/or channel gating.