The penultimate tyrosine residue of the K99 fibrillar subunit is essential for stability of the protein and its interaction with the periplasmic carrier protein

The role of the penultimate and conserved tyrosine residue of the K99 major fibrillar subunit (FanC) in fibrillae biosynthesis and functioning was investigated. By using oligonucleotide-directed in vitro mutagenesis the TAT codon of tyrosine-158 of fanC was changed into a TAG stop codon. The mutant fanC gene encoded a truncated major subunit lacking the two carboxyl-terminal amino acid residues. Furthermore, the tyrosine residue (position 158) was replaced by a serine residue or by a glutamic acid residue. The effect of these mutations on the expression and binding capacity of K99 fibrillae was investigated by using an ELISA, an haemagglutination assay, Escherichia coli minicells and suppressor strains. All mutations completely blocked K99 fibrillae biosynthesis and haemagglutination activity. The mature form of the truncated mutant FanC polypeptide could not be detected in minicells, but its precursor was expressed at a normal level. The results showed that the penultimate tyrosine residue is essential for the expression of mature fibrillar subunits and suggested a function in the interaction with the periplasmic transport protein FanE.     

Localization of lysine residues in the binding domain of the K99 fibrillar subunit of enterotoxigenic Escherichia coli

Modification of lysine residues with 4-chloro-3,5-dinitrobenzoate results in the loss of the binding capacity of K99 fibrillae to horse erythrocytes (Jacobs, A.A.C., van Mechelen, J.R. and de Graaf, F.K. (1985) Biochim. Biophys. Acta 832, 148-155). In the present study we used dinitrobenzoate as a spectral probe to map the modified residues. After the incorporation of 0.7 mol CDNB per mol subunit, 90% of the binding activity disappeared and the lysine residues at positions 87, 132 and 133 incorporated 20%, 27.5% and 52.2% of the totally incorporated label, respectively. In the presence of the glycolipid receptor, Lys-132 and Lys-133 were partially protected against modification, while Lys-87 was not protected. The results suggest that Lys-132 and Lys-133 are part of the receptor-binding domain of the K99 fibrillar subunit and that the positive charges on these residues are important for the interaction of the fibrillae with the negatively charged sialic acid residue of the glycolipid receptor. A striking homology was found between a six-amino-acid residue segment of K99, containing Lys-132 and Lys-133, and segments of three other sialic-acid-specific lectins; cholera toxin B subunit, heat-labile toxin B subunit of Escherichia coli and CFA1 fimbrial subunit, suggesting that these segments might also be part of the receptor-binding domain in these three proteins.     

Mutation of tryptophan-21 in mouse nerve growth factor (NGF) affects binding to the fast NGF receptor but not induction of neurites on PC12 cells.

By using in vitro DNA mutagenesis, we replaced the tryptophan residue at position 21 in mouse nerve growth factor (NGF) with either phenylalanine, leucine or serine. Yield, biological activity, immunological reactivity and receptor binding of the recombinant proteins were determined. All three mutants were produced at considerably lower yields than wild-type NGF, with the serine mutant being undetectable. The results of competitive binding assays show that tryptophan-21 is involved in recognition of the fast NGF receptor of PC12 cells. However, specific biological activity of NGF is not altered by the replacement of tryptophan-21. Our results therefore suggest that biological activity of NGF is not directly coupled to binding to the fast NGF receptor.     

Effect of chemical modifications on the K99 and K88ab fibrillar adhesins of Escherichia coli

The role of specific amino acid residues of the K88ab and K99 fibrillar adhesins in the binding to erythrocytes and antibodies has been studied by chemical modification. It appeared that: (1) The integrity of the single disulfide bridge in the K99 subunits is essential for the binding of the fibrillae to the glycolipid receptors, but not for the recognition and binding of specific anti-K99 antibodies. (2) Modification of one lysine residue per subunit with 4-chloro-3,5-dinitrobenzoate results in the loss of the adhesive capacity of K99 fibrillae. Lysine residue are not important for the adhesive activity of K88ab fibrillae. Three or five lysine residues per subunit, respectively, can be modified without an effect on the immunological properties of the K99 and K88ab fibrillae. (3) Limited reaction of K99 and K88ab fibrillae with 2,3-butanedione destroys the adhesive activity of both fibrillae. This inactivation corresponds with the loss of one (K99) or two (K88ab) arginine residues per subunit. Ultimately, in K99 three, and in K88ab four, arginine residues per subunit can be modified without affecting the binding of specific antibodies. (4) Modification of five out of the nine carboxyl groups contained in the K99 subunit suppresses the recognition of specific anti-K99 antibodies, but carboxylates are not important for the adhesive activity of K99 fibrillae. Modification of two additional carboxylates in K99 results in an insoluble product. (5) Tyrosine residues are most probably not present in the adhesive or antigenic sites of K99 fibrillae. Modification of six out of the ten tyrosine residues in the K88ab subunit results in a decrease in adhesive activity but has no effect on the reaction with anti-K88ab antibodies.     

Structure, localization and function of FanF, a minor component of K99 fibrillae of enterotoxigenic Escherichia coii

The DNA sequence of the K99 fanF gene, encoding FanF, was determined. An open reading frame of 999 bp was found. The primary structure of FanF was deduced and analysis revealed the presence of a signal sequence of 22 amino acid residues. The mature protein contains 311 amino acid residues (Mr 33,905 D). The amino acid sequence of FanF showed similarity with the K88ab major subunit FaeG. A specific mouse antiserum against FanF was prepared by constructing and purifying a hybrid Cro-LacZ-FanF protein. Minicell analysis, immunoblotting and immunoelectronmicroscopy revealed a pool of FanF in the periplasm of K99-producing cells and showed, furthermore, that FanF is a minor component of K99 fibrillae, present at the top and in or along the shaft of the K99 fibrillar structures. A fanF mutant plasmid was constructed. Cells harbouring this plasmid produced all K99-specific proteins, except FanF, but produced 0.1% of the K99 fibrillae relative to 'normal' K99-producing cells. Electron microscopic observations showed that cells defective in fanF produce only a few (apparently short) K99 fibrillae. FanF, therefore, was supposed to play a role in initiation and elongation of K99 fibrillae formation. Thin-layer chromatography experiments involving purified receptor material showed that FanF is not required for binding of K99 fibrillae to the ganglioside receptor. Fibrillae produced by an adhesion-negative strain carrying a mutation in the K99 major fibrillar subunit were shown to contain a normal amount of FanF.     

Molecular dissection of a critical specificity determinant within the amino acid editing domain of leucyl-tRNA synthetase

A highly conserved threonine residue marks the amino acid binding pocket within the editing active site of leucyl-tRNA synthetases (LeuRSs). It is essential to substrate specificity for the Escherichia coli enzyme in that it blocks the cognate leucine amino acid from binding in the hydrolytic editing active site. We combined mutagenesis and computational approaches to elucidate the molecular role of the critical side chain of this threonine residue. Removal of the terminal methyl group of the threonine side chain by replacement with serine yielded a mutant LeuRS that hydrolyzes Leu-tRNA(Leu). Substitution of valine for the conserved threonine conferred similar activities to the wild-type enzyme. However, an additional substitution within the editing active site suggested synergistic interactions with the conserved threonine site that significantly affected amino acid editing. On the basis of our combined biochemical and computational data, we propose that the threonine 252 side chain not only sterically hinders the cognate charged leucine from binding for hydrolysis but also plays a critical role in maintaining an active site geometry that is required for the fidelity of LeuRS.     

Role of phenylalanine 150 in the receptor-binding domain of the K88 fibrillar subunit.

Recently, we reported the isolation of three peptides, Ile-83-Ala-Phe-85, Ser-148-Leu-Phe-150, and Ala-156-Ile-Phe-158, derived from the K88 fibrillar subunit and found to inhibit the binding of K88 fibrillae to cavia erythrocytes or pig intestinal epithelial cells (A. A. C. Jacobs, J. Venema, R. Leeven, H. van Pelt-Heerschap, and F. K. de Graaf, J. Bacteriol. 169:735-741, 1987). The gene encoding the K88 fibrillar adhesin was modified by oligonucleotide-directed site-specific mutagenesis such that each of the phenylalanine residues at positions 85, 150, and 158 were replaced by serine. Replacement of phenylalanine 85 or 158 had no apparent effect on the biosynthesis of the fibrillae or on their adhesive capacity. In contrast, substitution of phenylalanine 150 with serine resulted in a dramatic decrease in adhesive capacity of the K88 fibrillae. Apparently, phenylalanine 150 plays an essential role in the interaction of the adhesin with receptor molecules present on eucaryotic cells.     

Probing the caveolin-1 P132L mutant: critical insights into its oligomeric behavior and structure

Caveolin-1 is the most important protein found in caveolae, which are cell surface invaginations of the plasma membrane that act as signaling platforms. A single point mutation in the transmembrane domain of caveolin-1 (proline 132 to leucine) has deleterious effects on caveolae formation in vivo and has been implicated in various disease states, particularly aggressive breast cancers. Using a combination of gel filtration chromatography and analytical ultracentrifugation, we found that a fully functional construct of caveolin-1 (Cav1(62-178)) was a monomer in dodecylphosphocholine micelles. In contrast, the P132L mutant of Cav1(62-178) was dimeric. To explore the dimerization of the P132L mutant further, various truncated constructs (Cav1(82-178), Cav1(96-178), Cav1(62-136), Cav1(82-136), Cav1(96-136)) were prepared which revealed that oligomerization occurs in the transmembrane domain (residues 96-136) of caveolin-1. To characterize the mutant structurally, solution-state NMR experiments in lyso-myristoylphosphatidylglycerol were undertaken of the Cav1(96-136) P132L mutant. Chemical shift analysis revealed that, compared to the wild-type, helix 2 in the transmembrane domain was lengthened by four residues (wild-type, residues 111-129; mutant, residues 111-133), which corresponds to an extra turn in helix 2 of the mutant. Lastly, point mutations at position 132 of Cav1(62-178) (P132A, P132I, P132V, P132G, P132W, P132F) revealed that no other hydrophobic amino acid can preserve the monomeric state of Cav1(62-178), which indicates that proline 132 is critical in supporting proper caveolin-1 behavior.     

Transport of Biosynthetic Intermediates: Homoserine and Threonine Uptake in Escherichia coli

Although amino acid transport has been extensively studied in bacteria during the past decade, little is known concerning the transport of those amino acids that are biosynthetic intermediates or have multiple fates within the cell. We have studied homoserine and threonine as examples of this phenomenon. Homoserine is transported by a single system which it shares with alanine, cysteine, isoleucine, leucine, phenylalanine, threonine, tyrosine, and valine. The evidence for this being the sole system for homoserine transport is (i) a linear double-reciprocal plot showing a homoserine K(m) of 9.6 x 10(-6) M, (ii) simultaneous reduction by 85% of homoserine and branched-chain amino acid uptake in a mutant selected for its inability to transport homoserine, and (iii) simultaneous reduction by 94% of the uptake of homoserine and the branched-chain amino acids by cells grown in millimolar leucine. Threonine, in addition to sharing the above system with homoserine, is transported by a second system shared with serine. The evidence for this second system consists of (i) incomplete inhibition of threonine uptake by any single amino acid, (ii) only 70% loss of threonine uptake in the mutant unable to transport homoserine, and (iii) only 40% reduction of threonine uptake when cells are grown in millimolar leucine. In this last case, the remaining threonine uptake can only be inhibited by serine and the inhibition is complete.     

Identification and characterisation of the catalytic triad of the alkaliphilic thermotolerant PHA depolymerase PhaZ7 of Paucimonas lemoignei

The recently discovered extracellular poly[(R)-3-hydroxybutyrate] (PHB) depolymerase PhaZ7 of Paucimonas lemoignei represents the first member of a new subgroup (EC 3.1.1.75) of serine hydrolases with no significant amino acid similarities to conventional PHB depolymerases, lipases or other hydrolases except for a potential lipase box-like motif (Ala-His-Ser136-Met-Gly) and potential candidates for catalytic triad and oxyanion pocket amino acids. In order to identify amino acids essential for activity 11 mutants of phaZ7 were generated by site-directed mutagenesis and expressed in recombinant protease-deficient Bacillus subtilis WB800. The wild-type depolymerase and 10 of the 11 mutant proteins (except for Ser136Cys) were expressed and efficiently secreted by B. subtilis as shown by Western blots of cell-free culture fluid proteins. No PHB depolymerase activity was detected in strains harbouring one of the following substitutions: His47Ala, Ser136Ala, Asp242Ala, Asp242Asn, His306Ala, indicating the importance of these amino acids for activity. Replacement of Ser136 by Thr resulted in a decrease of activity to about 20% of the wild-type level and suggested that the hydroxy group of the serine side chain is important for activity but can be partially replaced by the hydroxy function of threonine. Alterations of Asp256 to Ala or Asn or of the putative serine hydrolase pentapeptide motif (Ala-His-Ser136-Met-Gly) to a lipase box consensus sequence (Gly134-His-Ser136-Met-Gly) or to the PHB depolymerase box consensus sequence (Gly134-Leu135-Ser136-Met-Gly) had no significant effect on PHB depolymerase activity, indicating that these amino acids or sequence motifs were not essential for activity. In conclusion, the PHB depolymerase PhaZ7 is a serine hydrolase with a catalytic triad and oxyanion pocket consisting of His47, Ser136, Asp242 and His306.     

Site-directed mutagenesis at the active site of Escherichia coli TEM-1 beta-lactamase. Suicide inhibitor-resistant mutants reveal the role of arginine 244 and methionine 69 in catalysis.

Arginine 244 is a highly conserved residue in Class A beta-lactamases, while methionine 69 is not. Informational suppression experiments show that replacement of M69 by a leucine, or that of R244 by most other amino acids lead to clavulanic acid-resistant phenotypes. The arginyl 244 side chain is tightly held in a network of interactions within the active site. Its replacement by a glutamine or a threonine perturbs the enzyme kinetics but to a smaller extent than would have been predicted if it were directly involved in substrate binding. Clavulanic acid and sulbactam still interact specifically with the mutant enzymes but are much less efficiently metabolized. Substitutions at position 244 also unveil interactions between the C6 substituent of substrates and the Asn132/Glu104 region of the active site. Methionine 69 is located in a region of strong structural constraints and presents an unusual conformation. Molecular dynamics simulation showed that its replacement by a leucine does not release the strain in this area and induces only minor structural changes. Accordingly, the kinetic behavior of the mutant is only marginally perturbed, except for suicide inhibitors. Both clavulanic acid and sulbactam are well degraded by the mutant enzyme, while irreversible inactivation is dramatically decreased. The contribution of both residues to catalysis is discussed in the light of the kinetic and structural data.     

Elucidation of the role of arginine-244 in the turnover processes of class A beta-lactamases.

The highly conserved arginine-244 of beta-lactamases has been postulated to play a role in their initial recognition of substrates, presumably through ion pairing interactions [Moews, P. C., Knox, J. R., Dideberg, O., Charlier, P., & Frère, J. M. (1990) Proteins: Struct., Funct., Genet. 7, 156-171]. However, in the Michaelis enzyme-substrate complex, no direct function has been attributed to this residue. Two mutants with substitutions of this residue in the TEM-1 beta-lactamase (lysine-244 and serine-244) have been prepared to explore whether the guanidinium group of arginine-244 plays a critical role in the turnover processes. The mutant enzymes are effective catalysts for the hydrolysis of both penicillins and cephalosporins, and the lysine mutant enzyme behaves virtually identically to the wild-type beta-lactamase. Comparative kinetic characterization of the serine mutant and wild-type enzymes attributed apparent binding energies of 1.3-2.3 kcal/mol for the penicillins and 0.3-1.0 kcal/mol for the cephalosporins to the transition-state species by arginine-244. Furthermore, it was shown that arginine-244 also contributes equally well to ground-state binding stabilization. These results were interpreted to indicate the involvement of a long hydrogen bond between arginine-244 and the substrate carboxylate, both in the ground and transition states. A reassessed picture for substrate anchoring involving interactions of the substrate carboxylate with the side chains of Ser-130, Ser-235, and Arg-244 is proposed to accommodate these observations.     

Sodium Ion-Driven Serine/Threonine Transport in Porphyromonas gingivalis

Porphyromonas gingivalis is an asaccharolytic, gram-negative bacterium that relies on the fermentation of amino acids for metabolic energy. When grown in continuous culture in complex medium containing 4 mM (each) free serine, threonine, and arginine, P. gingivalis assimilated mainly glutamate/glutamine, serine, threonine, aspartate/asparagine, and leucine in free and/or peptide form. Serine and threonine were assimilated in approximately equal amounts in free and peptide form. We characterized serine transport in this bacterium by measuring uptake of the radiolabeled amino acid in washed cells of P. gingivalis energized with a tetrapeptide not containing serine. Serine was transported by a single system with an affinity constant for transport (K(t)) of 24 microM that was competitively inhibited by threonine. Serine transport was dependent on sodium ion concentration in the suspending buffer, and the addition of the ionophore gramicidin caused the inhibition of serine uptake. Together these data indicate that serine transport was sodium ion-motive force driven. A P. gingivalis gene potentially encoding a serine transporter was identified by sequence similarity to an Escherichia coli serine transporter (SstT). This P. gingivalis gene, designated sstT, was inactivated by insertion of a Bacteroides tetQ gene, producing the mutant W50ST. The mutant was unable to transport serine, confirming the presence of a single serine transporter in this bacterium under these growth conditions. The transport of serine by P. gingivalis was dependent on the presence of free cysteine in the suspension buffer. Other reducing agents were unable to stimulate serine uptake. These data show that P. gingivalis assimilates free serine and threonine from culture media via a cysteine-activated, sodium ion-motive force-driven serine/threonine transporter.     

Attachment Sites of Carbohydrate Moieties to Peptide Chain of Bovine κ-Casein from Normal Milk

The attachment site of the carbohydrate moiety to the peptide chain of normal κ-casein was investigated with κ-casein component P-6 containing the most carbohydrates. Three short glycopeptides 6-IB₁, 6-IB_{2 ? 1} and 6-IB_{2 ? 2} were prepared by cyanogen bromide cleavage and digestion of proteases (pronase P and thermolysin). Glycopeptides 6-IB₁, 6-IB_{2? 1} and 6-IB_{2 ? 2} corresponded to residues 128–139 (Gly-Glu-Pro-Thr-Ser-Thr-Pro-Thr-Thr-Glu-Ala-Val), residues 128–132 (or 127–131) and residues 135–139 of κ-casein A, respectively, and contained threonine and/or serine, but not asparagine. Glycopeptide 6-IB₁ was considered to have three carbohydrate chains because it contained three galactosamine residues. The results of alkali treatment of 6-IB, under reduction condition excluded serine residue as the binding site, and confirmed the existence of three binding sites in the carbohydrate moieties. The carbohydrate moiety was shown to attach to threonine residue No. 131 from analysis of 6-IB_{2? 1} and to threonine residue No. 135 (or 136) from analysis of 6-IB_{2 ? 2}. It was concluded that the carbohydrate chains attached to threonine residues No. 131, 133 and 135 (or 136).     

Aminolevulinate synthase: lysine 313 is not essential for binding the pyridoxal phosphate cofactor but is essential for catalysis.

5-Aminolevulinate synthase is the first enzyme of the heme biosynthetic pathway in animals and some bacteria. Lysine-313 of the mouse erythroid aminolevulinate synthase was recently identified to be linked covalently to the pyridoxal 5'-phosphate cofactor (Ferreira GC, Neame PJ, Dailey HA, 1993, Protein Sci 2:1959-1965). Here we report on the effect of replacement of aminolevulinate synthase lysine-313 by alanine, histidine, and glycine, using site-directed mutagenesis. Mutant enzymes were purified to homogeneity, and the purification yields were similar to those of the wild-type enzyme. Although their absorption spectra indicate that the mutant enzymes bind pyridoxal 5'-phosphate, they bind noncovalently. However, addition of glycine to the mutant enzymes led to the formation of external aldimines. The formation of an external aldimine between the pyridoxal 5'-phosphate cofactor and the glycine substrate is the first step in the mechanism of the aminolevulinate synthase-catalyzed reaction. In contrast, lysine-313 is an essential catalytic residue, because the K313-directed mutant enzymes have no measurable activity. In summary, site-directed mutagenesis of the aminolevulinate synthase active-site lysine-313, to alanine (K313A), histidine (K313H), or glycine (K313G) yields enzymes that bind the pyridoxal 5'-phosphate cofactor and the glycine substrate to produce external aldimines, but which are inactive. This suggests that lysine-313 has a functional role in catalysis.     

Genetic characterization of a highly efficient alternate pathway of serine biosynthesis in Escherichia coli.

There exists in Escherichia coli a known set of enzymes that were shown to function in an efficient and concerted way to convert threonine to serine. The sequence of reactions catalyzed by these enzymes is designated the Tut cycle (threonine utilization). To demonstrate that the relevant genes and their protein products play essential roles in serine biosynthesis, a number of mutants were analyzed. Strains of E. coli with lesions in serA, serB, serC, or glyA grew readily on minimal medium supplemented with elevated levels of leucine, arginine, lysine, threonine, and methionine. No growth on this medium was observed upon testing double mutants with lesions in one of the known ser genes plus a second lesion in glyA (serine hydroxymethyltransferase), gcv (the glycine cleavage system), or tdh (threonine dehydrogenase). Pseudorevertants of ser mutants capable of growth on either unsupplemented minimal medium or medium supplemented with low levels of leucine, arginine, lysine, threonine, and methionine were isolated. At least two unlinked mutations were associated with such phenotypes.     

Computational,pulse-radiolytic,and structural investigations of lysine-136 and its role in the electrostatic triad of human C u,Z n superoxide dismutase

Key charged residues in Cu,Zn superoxide dismutase (Cu,Zn SOD) promote electrostatic steering of the superoxide substrate to the active site Cu ion, resulting in dismutation of superoxide to oxygen and hydrogen peroxide. Lys-136, along with the adjacent residues Glu-132 and Glu-133, forms a proposed electrostatic triad contributing to substrate recognition. Human Cu,Zn SODs with single-site replacements of Lys-136 by Arg, Ala, Gln, or Glu or with a triple-site substitution (Glu-132 and Glu-133 to Gln and Lys-136 to Ala) were made to test hypotheses regarding contributions of these residues to Cu,Zn SOD activity. The structural effects of these mutations were modeled computationally and validated by the X-ray crystallographic structure determination of Cu,Zn SOD having the Lys-136-to-Glu replacement. Brownian dynamics simulations and multiple-site titration calculations predicted mutant reaction rates as well as ionic strength and pH effects measured by pulse-radiolytic experiments. Lys-136-to-Glu charge reversal decreased dismutation activity 50% from 2.2 × 10⁹ to 1.2 × 10⁹ M⁻¹ s⁻¹ due to repulsion of negatively charged superoxide, whereas charge-neutralizing substitutions (Lys-136 to Gln or Ala) had a less dramatic influence. In contrast, the triple-mutant Cu,Zn SOD (all three charges in the electrostatic triad neutralized) surprisingly doubled the reaction rate compared with wild-type enzyme but introduced phosphate inhibition. Computational and experimental reaction rates decreased with increasing ionic strength in all of the Lys-136 mutants, with charge reversal having a more pronounced effect than charge neutralization, implying that local electrostatic effects still govern the dismutation rates. Multiple-site titration analysis showed that deprotonation events throughout the enzyme are likely responsible for the gradual decrease in SOD activity above pH 9.5 and predicted a pK_a value of 11.7 for Lys-136. Overall, Lys-136 and Glu-132 make comparable contributions to substrate recognition but are less critical to enzyme function than Arg-143, which is both mechanistically and electrostatically essential. Thus, the sequence-conserved residues of this electrostatic triad are evidently important solely for their electrostatic properties, which maintain the high catalytic rate and turnover of Cu,Zn SOD while simultaneously providing specificity by selecting against binding by other anions. Proteins 29:103–112, 1997. © 1997 Wiley-Liss, Inc.     

Accumulation of cell-bound alpha-amylase in Bacillus subtilis cells in the presence of tunicamycin

The amino acid sequence of the N-terminal cyanogen bromide fragment of bovine lens leucine aminopeptidase has been determined. This fragment contains a total of 171 amino acid residues and has a calculated molecular weight of 18,637. The sequence data presented here represent the first report of primary structure determination of a member of the class of aminopeptidases.The single cleavage site produced by limited tryptic digestion of native leucine aminopeptidase was determined to be between arginine-137 and lysine-138 of the total amino acid sequence. The possible existence of distinct structural domains in leucine aminopeptidase is discussed.     

Primary site and second site revertants of missense mutants of the evolutionarily invariant tryptophan 64 in iso-1-cytochrome c from yeast.

The three missense mutants cyc1-132, cyc1-166 and cyc1-189 in the yeast Saccharomyces cerevisiae contain nonfunctional and thermolabile iso-1-cytochromes c and have different replacements of the tryptophan at position 64 which corresponds to the invariant tryptophan residue found in cytochromes c from all eukaryotic species. The cyc1-166 and cyc1-189 mutants contain single replacements of, respectively, serine 64 and cysteine 64, while the cyc1-132 mutant contains a double replacement of glycine 64 and alanine 65 instead of the normal tryptophan 64 and aspartic acid 65. Twenty-three intragenic revertants having at least partially functional iso-1-cytochromes c arose from these three missense mutants by single amino acid replacements of either tryptophan, phenylalanine, tyrosine or leucine at position 64, or by second-site replacements in which the mutant residues at position 64 are retained and the normal serine 45 is replaced by phenylalanine 45. Specific activities of the iso-1-cytochromes c were estimated by growth of strains on lactate medium and are as follows, in terms of the normal, for iso-1-cytochromes c altered specifically in the ways shown: 100% for phenylalanine 64; 25% for tyrosine 64; between 0 and 25% for leucine 64; 100% for phenylalanine 45, cysteine 64; 25% for phenylalanine 45, serine 64; between 0 and 25% for phenylalanine 45, glycine 64, alanine 65; and 0% for serine 64, for cysteine 64, and for glycine 64, alanine 65 iso-1-cytochromes c. The results demonstrate that small residues of glycine, serine, and cysteine at position 64 are incompatible with function; they imply that many of the 10 amino acids accessible by single base-pair substitution but not observed in primary site revertants also are incompatible with function; and they show that large hydrophobic residues of phenylalanine, leucine, and tyrosine at position 64 are capable of restoring at least partial function. The second site revertants indicate that deleterious effects of the three missense mutants can be compensated by the introduction of phenylalanine 45, which may occupy space normally filled by tryptophan 64. Altered shapes of Calpha-band spectra and at least partial instability were characteristics of all iso-1-cytochromes c found lacking tryptophan 64. Apparently, the principal role of the invariant tryptophan is stabilization of the active protein structure, by providing a large hydrophobic group at the proper location.     

Detection and identification of FaeC as a minor component of K88 fibriilae of Escherichia coli

A tribrid gene containing ompF, faeC, and lacZ sequences was constructed by subcloning a large central segment of the K88ab gene encoding the fibrillar subunit-like protein FaeC into the open reading frame expression vector pORF2. The resulting tribrid protein was isolated and used to raise antibodies against the FaeC protein. These antibodies were then used for the detection and subcellular localization of the FaeC protein in Escherichia coli harbouring the K88ab-encoding plasmid pFM205 or mutant derivatives. Immunoblotting of subcellular fractions and of purified fibrillae, and agglutination experiments using whole cells revealed that the FaeC protein is present in the periplasm and as a minor component in the K88ab fibrillae. FaeC was also detected in purified K88ac and K88ad fibrillae. Immunoelectron microscopy confirmed the presence of FaeC in K88ab fibrillae, particularly at the tips of the longer fibrillae.