Site-directed mutagenesis of glutamate 317 of bovine α-1,3Galactosyltransferase and its effect on enzyme activity: Implications for reaction mechanism

Bovine α1,3galactosyltransferase (α1,3GalT) transfers galactose from UDP-α-galactose to terminal β-linked galactosyl residues with retention of configuration of the incoming galactose residue. The epitope synthesized has been shown to be critical for xenotransplantation. According to a proposed double-displacement reaction mechanism, glutamate-317 (E317) is thought to be the catalytic nucleophile. The proposed catalytic role of E317 involves an initial nucleophilic attack with inversion of configuration and formation of a covalent sugar–enzyme intermediate between E317 and galactose from the donor substrate, followed by a second nucleophilic attack performed by the acceptor substrate with a second inversion of configuration. To determine whether E317 of α1,3GalT is critical for enzyme activity, site-directed mutagenesis was used to substitute alanine, aspartic acid, cysteine and histidine for E317. If the proposed reaction mechanism for the α1,3GalT enzyme is correct, E317D and E317H would produce active enzymes since they can act as nucleophiles. The non-conservative mutation E317A and conservative mutation E317C are predicted to produce inactive or very low activity enzymes since the E317A mutant cannot engage in a nucleophilic attack, and the E317C mutant would trap the galactose residue. The results obtained demonstrate that E317D and E317H mutants retained activity, albeit significantly less than the wild-type enzyme. Additionally, both E317A and E317C mutant also retained enzyme activity, suggesting that E317 is not the catalytic nucleophile proposed in the double-displacement mechanism. Therefore, either a different amino acid may act as the catalytic nucleophile or the reaction must proceed by a different mechanism.     

Site-directed mutagenesis of ricin A-chain and implications for the mechanism of action

Ricin A-chain is an N-glycosidase that attacks ribosomal RNA at a highly conserved adenine residue. The enzyme is representative of a large family of medically significant proteins used in the design of anticancer agents and in the treatment of HIV infection. The x-ray structure has been used as a guide to create several active site mutations by directed mutagenesis of the cloned gene. Glu177 is a key catalytic residue, and conversion to Gln reduces activity 180-fold. Asn209 is shown to participate in substrate binding by kinetic analysis. Conversion to Ser increases Km sixfold but has no effect on kcat. Conversion of Tyr80 and Tyr123 to Phe decreases activity by 15- and 7-fold respectively. A mechanism of action is proposed that involves binding of the substrate adenine in a syn configuration that resembles the transition state; the putative oxycarbonium ion is probably stabilized by interaction with Glu177.     

Site-directed mutagenesis of epoxide hydrolase to probe catalytic amino acid residues and reaction mechanism

Epoxide hydrolase from Rhodococcus opacus catalyzes the stereospecific hydrolysis of cis-epoxysuccinate to L(+)-tartrate. It shows low but significant similarity to haloacid dehalogenase and haloacetate dehalogenase (16–23% identity). To identify catalytically important residues, we mutated 29 highly conserved charged and polar amino acid residues (except for one alanine). The replacement of D18, D193, R55, K164, H190, T22, Y170, N134 and A188 led to a significant loss in the enzyme activity, indicating their involvement in the catalysis. Single and multiple turnover reaction studies show that the enzyme reaction proceeded through the two-step mechanism involving the formation of a covalent intermediate. We discuss the roles of these residues and propose its possible reaction mechanism.     

Site-directed mutagenesis of human endothelial cell ecto-ADPase/soluble CD39: requirement of glutamate 174 and serine 218 for enzyme activity and inhibition of platelet recruitment

Endothelial cell CD39/ecto-ADPase plays a major role in vascular homeostasis. It rapidly metabolizes ADP released from stimulated platelets, thereby preventing further platelet activation and recruitment. We recently developed a recombinant, soluble form of human CD39, solCD39, with enzymatic and biological properties identical to CD39. To identify amino acids essential for enzymatic/biological activity, we performed site-directed mutagenesis within the four highly conserved apyrase regions of solCD39. Mutation of glutamate 174 to alanine (E174A) and serine 218 to alanine (S218A) resulted in complete and approximately 90% loss of solCD39 enzymatic activity, respectively. Furthermore, compared to wild-type, S57A exhibited a 2-fold increase in ADPase activity without change in ATPase activity, while the tyrosine 127 to alanine (Y127A) mutant lost 50-60% of both ADPase and ATPase activity. The ADPase activity of wild-type solCD39 and each mutant, except for R135A, was greater with calcium as the required divalent cation than with magnesium, but for ATPase activity generally no such preference was observed. Y127A demonstrated the highest calcium/magnesium ADPase activity ratio, 2.8-fold higher than that of wild-type, even though its enzyme activity was greatly reduced. SolCD39 mutants were further characterized by correlating enzymatic with biological activity in an in vitro platelet aggregation system. Each solCD39 mutant was similar to wild-type in reversing platelet aggregation, except for E174A and S218A. E174A, completely devoid of enzymatic activity, failed to inhibit platelet responsiveness, as anticipated. S218A, with 91% loss of ADPase activity, could still reverse platelet aggregation, albeit much less effectively than wild-type solCD39. Thus, glutamate 174 and serine 218 are essential for both the enzymatic and biological activity of solCD39.     

Site-directed mutagenesis of the FAD-binding histidine of 6-hydroxy-D-nicotine oxidase. Consequences on flavinylation and enzyme activity

In 6-hydroxy-D-nicotine oxidase (6-HDNO) FAD is covalently bound to His71 of the polypeptide chain by an 8 alpha-(N3-histidyl)-riboflavin linkage. The FAD-binding histidine was exchanged by site-directed mutagenesis to either a Cys- or Tyr-residue, two amino acids known to be involved in covalent binding of FAD in other enzymes, or to a Ser-residue. None of the amino acid replacements for His71 allowed covalent FAD incorporation into the 6-HDNO polypeptide. Thus, the amino acid residues involved in covalent FAD-binding require a specific polypeptide surrounding in order for this modification to proceed and cannot be replaced with each other. Enzyme activity was completely abolished with Tyr in place of His71. 6-HDNO activity with non-covalently bound FAD was found with 6-HDNO-Cys and to a lesser extent also with 6-HDNO-Ser. However, the Km values for 6-HDNO-Cys and 6-HDNO-Ser were increased approximately 20-fold as compared to 6-HDNO-His. Both mutant enzymes, in contrast to the wild-type enzyme, needed additional FAD in the enzymatic assay (50 microM for 6-HDNO-Ser and 10 microM for 6-HDNO-Cys) for maximal enzyme activity.     

Site-directed mutagenesis study of yeast peptide:N-glycanase. Insight into the reaction mechanism of deglycosylation.

Yeast peptide:N-glycanase (Png1p; PNGase), a deglycosylation enzyme involved in the proteasome dependent degradation of proteins, has been reported to be a member of the transglutaminase superfamily based on sequence alignment. In this study we have investigated the structure-function relationship of Png1p by site-directed mutagenesis. Cys-191, His-218, and Asp-235 of Png1p are conserved in the sequence of factor XIIIa, where these amino acids constitute a catalytic triad. Point mutations of these residues in Png1p resulted in complete loss in activity, consistent with a role for each in catalyzing deglycosylation of glycoproteins. Other conserved amino acid residues, Trp-220, Trp-231, Arg-210, and Glu-222, were also vitally important for folding and structure stability of the enzyme as revealed by circular dichroism analysis. The potential effects of the mutations were predicted by mapping the conserved amino acids of Png1p within the known three-dimensional structure of factor XIIIa. Our data suggest that the lack in enzyme activity when any of the catalytic triad residues is mutated is either due to the absence of charge relay in the case of the triad or due to the disruption of the native fold of the enzyme. These findings strongly suggest a common evolutionary lineage for the PNGases and transglutaminases.     

Site-directed mutagenesis of cysteine to threonine in Proteus vulgaris urease active site increases enzyme activity and stability

Cysteine-319 belongs to the flexible flap at the active site of Proteus vulgaris urease. Replacing this cysteine by threonine resulted in a 20-fold increase of specific activity. Temperature stability increased, susceptibility to inhibition by dipyridyl disulfide decreased, and pH optimum shifted from 8 to 6.9. K _m (35 to 12 mM) and V_max (47.4 to 1.8 mol min^–1) were substancially altered. Both variants of the enzyme were irreversibly inhibited by phenylmethanesulfonyl fluoride.     

Site-directed mutagenesis of glutamate-190 in the hinge region of yeast 3-phosphoglycerate kinase: implications for the mechanism of domain movement

In order to evaluate a possible contribution of glutamate-190, situated in the hinge region of yeast 3-phosphoglycerate kinase (PGK), to the mechanism of the substrate- and sulfate-induced domain movement, we have constructed two point mutants, Gln-190 and Asp-190, using oligonucleotide-directed in vitro mutagenesis. The Michaelis constants of the mutants for ATP and 3-phosphoglycerate were not significantly altered, whereas the catalytic activities were decreased, both in the absence and in the presence of sulfate ions. In the absence of sulfate, the Gln-190 and Asp-190 mutants exhibited 26% and 36% of the activity of the native enzyme. In the presence of 30 mM Na2SO4, a concentration at which native PGK exhibits maximum activation, the relative activities of the Gln-190 and Asp-190 mutants were 6% and 9%, respectively. In contrast to the native enzyme, which undergoes activation at low sulfate concentrations and inhibition at high concentrations, both mutants showed a complete loss of the salt activation effect. These results suggest that Glu-190 is not directly involved in the binding of substrates but might be important for conformational flexibility. We have also demonstrated that, similarly to native PGK, both mutants are completely inactivated by the incorporation of 1 mol of glycine ethyl ester/mol of enzyme. Appreciable protection against inactivation is observed in the presence of both substrates, MgATP and 3-phosphoglycerate. Only limited protection is observed in the presence of the individual substrates, suggesting that the modification does not occur at the substrate binding sites.(ABSTRACT TRUNCATED AT 250 WORDS)     

Site-directed mutagenesis of serine 40 of rat tyrosine hydroxylase. Effects of dopamine and cAMP-dependent phosphorylation on enzyme activity.

Rat tyrosine hydroxylase expressed with a baculovirus expression system contains covalent phosphate and has kinetic parameters consistent with those expected of phosphorylated enzyme (Fitzpatrick, P. F., Chlumsky, L. J., Daubner, S. C., and O'Malley, K. L. (1990) J. Biol. Chem. 265, 2042-2047). The phosphorylation site was identified as serine 40, by purifying the enzyme from cells grown in the presence of [32P]phosphate. Replacement of serine 40 with alanine by site-directed mutagenesis prevented phosphorylation but had little effect on the steady-state kinetic parameters at pH 7. Both wild type and S40A tyrosine hydroxylase were expressed in Escherichia coli; the kinetic parameters of the enzymes purified from bacteria were nearly identical to those of the enzymes expressed with the baculovirus system, although the bacterially expressed enzyme contained no covalent phosphate. Treatment of this wild type enzyme with cAMP-dependent protein kinase decreased the KBH4 value about 2-fold but had no effect on the Vmax value at pH 7. Treatment with a stoichiometric amount of dopamine decreased the Vmax value 15-fold and increased the KBH4 value 2-3-fold. Phosphorylation of the dopamine-bound enzyme increased the Vmax value 10-fold and decreased the KBH4 value 2-fold. The kinetic parameters of the dopamine-bound recombinant enzyme were identical to those of enzyme purified from PC12 cells. In contrast, the S40A enzyme was converted to a less active form by treatment with dopamine but was not affected by phosphorylating conditions. These results are consistent with a model in which the major effect of phosphorylation of serine 40 is to relieve tyrosine hydroxylase from the inhibitory effects of catecholamines.     

Site-directed mutagenesis of the human DNA repair enzyme HAP1: identification of residues important for AP endonuclease and RNase H activity.

HAP1 protein, the major apurinic/apyrimidinic (AP) endonuclease in human cells, is a member of a homologous family of multifunctional DNA repair enzymes including the Escherichia coli exonuclease III and Drosophila Rrp1 proteins. The most extensively characterised member of this family, exonuclease III, exhibits both DNA- and RNA-specific nuclease activities. Here, we show that the RNase H activity characteristic of exonuclease III has been conserved in the human homologue, although the products resulting from RNA cleavage are dissimilar. To identify residues important for enzymatic activity, five mutant HAP1 proteins containing single amino acid substitutions were purified and analysed in vitro. The substitutions were made at sites of conserved amino acids and targeted either acidic or histidine residues because of their known participation in the active sites of hydrolytic nucleases. One of the mutant proteins (replacement of Asp-219 by alanine) showed a markedly reduced enzymatic activity, consistent with a greatly diminished capacity to bind DNA and RNA. In contrast, replacement of Asp-90, Asp-308 or Glu-96 by alanine led to a reduction in enzymatic activity without significantly compromising nucleic acid binding. Replacement of His-255 by alanine led to only a very small reduction in enzymatic activity. Our data are consistent with the presence of a single catalytic active site for the DNA- and RNA-specific nuclease activities of the HAP1 protein.     

Site-directed mutagenesis establishes aspartic acids-227 and -342 as essential for enzyme activity in an isomalto-dextranase from Arthrobacter globiformis

Isomalto-dextranase, from Arthrobacter globiformis T6, is a member of the glycoside hydrolase family 27. However, the alignments of the whole amino acid sequence are distinct from other members of this family. The enzymes cleave the glycosidic bond of the substrate in two different manners: either retaining or inverting the anomeric configuration. We believe that a retaining enzyme is involved in a two-step, double-displacement mechanism utilizing active site carboxylic acids as the nucleophile and general acid/base catalysts in the hydrolytic reaction. The critical amino acid residues at the isomalto-dextranase active site that catalyzes the hydrolysis reaction of dextran have been identified and the roles of nine amino acid residues (D107, D163, D227, D295, D340, D342, D373, D396, and E420) in the isomalto-dextranase from A. globiformis analyzed by site-directed mutagenesis. Of 15 mutant enzymes that were prepared, eight had reduced activities for dextran hydrolysis. Aspartic acids-227 and -342, which are part of the apparent catalytic dyad, were essential for hydrolase activity toward dextran.     

Insights into the reaction mechanism of glycosyl hydrolase family 49. Site-directed mutagenesis and substrate preference of isopullulanase.

Aspergillus niger isopullulanase (IPU) is the only pullulan-hydrolase in glycosyl hydrolase (GH) family 49 and does not hydrolyse dextran at all, while all other GH family 49 enzymes are dextran-hydrolysing enzymes. To investigate the common catalytic mechanism of GH family 49 enzymes, nine mutants were prepared to replace residues conserved among GH family 49 (four Trp, three Asp and two Glu). Homology modelling of IPU was also carried out based on the structure of Penicillium minioluteum dextranase, and the result showed that Asp353, Glu356, Asp372, Asp373 and Trp402, whose substitutions resulted in the reduction of activity for both pullulan and panose, were predicted to be located in the negatively numbered subsites. Three Asp-mutated enzymes, D353N, D372N and D373N, lost their activities, indicating that these residues are candidates for the catalytic residues of IPU. The W402F enzyme significantly reduced IPU activity, and the Km value was sixfold higher and the k0 value was 500-fold lower than those for the wild-type enzyme, suggesting that Trp402 is a residue participating in subsite -1. Trp31 and Glu273, whose substitutions caused a decrease in the activity for pullulan but not for panose, were predicted to be located in the interface between N-terminal and beta-helical domains. The substrate preference of the negatively numbered subsites of IPU resembles that of GH family 49 dextranases. These findings suggest that IPU and the GH family 49 dextranases have a similar catalytic mechanism in their negatively numbered subsites in spite of the difference of their substrate specificities.     

Site-directed mutagenesis of the T4 endonuclease V gene: mutations which enhance enzyme specific activity at low salt concentrations

Previous structure/function analyses of the DNA repair enzyme, T4 endonuclease V, have suggested that the extreme carboxyl portion of the enzyme is associated with pyrimidine dimer-specific binding (Recinos and Lloyd, and Stump and Lloyd, Biochemistry 27:1832-1838 and 1839-1843, 1988, respectively). Within the final 11 amino acids there are 5 aromatic, 2 basic, and no acidic residues and it has been proposed that these residues stack with and electrostatically interact with the kinked DNA at the site of a pyrimidine dimer. The role of the tyrosine residue at position 129 has been investigated by oligonucleotide site-directed mutagenesis in which the codon for Tyr-129 has been altered to reflect conservative changes of Trp and Phe and more dramatic changes of Ser, a stop codon, deletion of the codon or introduction of a frameshift. Both changes to the aromatic amino acids resulted in proteins which accumulated well in E. coli and not only significantly enhanced the UV survival of repair-deficient cells but also complemented a defective denV gene within UV-irradiated T4 phage. Partially purified preparations of the Tyr-129----Trp and Tyr-129----Phe mutants were assayed for their ability to processively incise UV-irradiated plasmid DNA (a nicking reaction carried out at low 25 mM salt concentrations). The mutant enzymes Tyr-129----Phe and Tyr-129----Trp displayed a 1000% and 500% enhanced specific nicking activity, respectively. These reactions were also shown to be completely processive. Assays performed at higher (100 mM) salt concentrations reduced the specific activities of the mutant enzymes approximately to that of wild type for the Tyr-129----Phe mutant and to 20% that of wild type for the Tyr-129----Trp mutant.     

Structure of bovine alpha-1,3-galactosyltransferase and its complexes with UDP and DPGal inferred from molecular modeling

A homology model of alpha-1,3-galactosyltransferase (alpha-1,3-GalT), the retaining enzyme responsible for the formation of alpha-galactosyl epitopes, has been developed by means of molecular modeling using the SpsA glycosyltransferase structure. A protein-ligand docking approach was used to model alpha-1,3-GalT complexed with UDP and UDP-Gal. The comparison of structural features found in the alpha-1,3-GalT homology model with available structural data on this class of enzymes revealed similarities in the UDP-binding pocket. In the predicted structure of the complexes, the pyrophosphate interacts with the DVD motif (Asp-225, Val-226, and Asp-227) of alpha-1,3-GalT through the Mn(2+) cation. The uridine part of the UDP binds into the well-defined cavity that consists of Phe-134, Tyr-139, Ile-140, Val-136, Arg-194, Arg-202, Lys-209, Asp-173, His-218, and Thr-137 in a conformation that is generally observed in the crystal structures of other glycosyltransferase complexes.     

Measuring solution viscosity and its effect on enzyme activity

In proteins, some processes require conformational changes involving structural domain diffusion. Among these processes are protein folding, unfolding and enzyme catalysis. During catalysis some enzymes undergo large conformational changes as they progress through the catalytic cycle. According to Kramers theory, solvent viscosity results in friction against proteins in solution, and this should result in decreased motion, inhibiting catalysis in motile enzymes. Solution viscosity was increased by adding increasing concentrations of glycerol, sucrose and trehalose, resulting in a decrease in the reaction rate of the H⁺-ATPase from the plasma membrane ofKluyveromyces lactis. A direct correlation was found between viscosity (η) and the inhibition of the maximum rate of catalysis (V _max). The protocol used to measure viscosity by means of a falling ball type viscometer is described, together with the determination of enzyme kinetics and the application of Kramers’ equation to evaluate the effect of viscosity on the rate of ATP hydrolysis by the H⁺-ATPase. Published: May 1, 2003     

Site-directed mutagenesis of the ionizable groups in the active site of Zymomonas mobilis pyruvate decarboxylase: effect on activity and pH dependence.

Pyruvate decarboxylase (PDC, EC 4.1.1.1) is a thiamin diphosphate-dependent enzyme about which there is a large body of structural and functional information. The active site contains several absolutely conserved ionizable groups and all of these appear to be important, as judged by the fact that mutation diminishes or abolishes catalytic activity. Previously we have shown [Schenk, G., Leeper, F.J., England, R., Nixon, P.F. & Duggleby, R.G. (1997) Eur. J. Biochem. 248, 63-71] that the activity is pH-dependent due to changes in kcat/Km while kcat itself is unaffected by pH. The effect on kcat/Km is determined by a group with a pKa of 6.45; the identity of this group has not been determined, although H113 is a possible candidate. Here we mutate five crucial residues in the active site with ionizable side-chains (D27, E50, H113, H114 and E473) in turn, to residues that are nonionizable or should have a substantially altered pKa. Each protein was purified and characterized kinetically. Unexpectedly, the pH-dependence of kcat/Km is largely unaffected in all mutants, ruling out the possibility that any of these five residues is responsible for the observed pKa of 6.45. We conjecture that the kcat/Km profile reflects the protonation of an alcoholate anion intermediate of the catalytic cycle.     

Human peroxisomal multifunctional enzyme type 2. Site-directed mutagenesis studies show the importance of two protic residues for 2-enoyl-CoA hydratase 2 activity

Beta-oxidation of acyl-CoAs in mammalian peroxisomes can occur via either multifunctional enzyme type 1 (MFE-1) or type 2 (MFE-2), both of which catalyze the hydration of trans-2-enoyl-CoA and the dehydrogenation of 3-hydroxyacyl-CoA, but with opposite chiral specificity. Amino acid sequence alignment of the 2-enoyl-CoA hydratase 2 domain in human MFE-2 with other MFE-2s reveals conserved protic residues: Tyr-347, Glu-366, Asp-370, His-406, Glu-408, Tyr-410, Asp-490, Tyr-505, Asp-510, His-515, Asp-517, and His-532. To investigate their potential roles in catalysis, each residue was replaced by alanine in site-directed mutagenesis, and the resulting constructs were tested for complementation in a yeast. After additional screening, the wild type and noncomplementing E366A and D510A variants were expressed and characterized. The purified proteins have similar secondary structural elements, with the same subunit composition. The E366A variant had a k(cat)/K(m) value 100 times lower than that of the wild type MFE-2 at pH 5, whereas the D510A variant was inactive. Asp-510 was imbedded in a novel hydratase 2 motif found in the hydratase 2 proteins. The data show that the hydratase 2 reaction catalyzed by MFE-2 requires two protic residues, Glu-366 and Asp-510, suggesting that their catalytic role may be equivalent to that of the two catalytic residues of hydratase 1.     

Site-directed mutagenesis of an alkaline phytase: influencing specificity, activity and stability in acidic milieu

Site-directed mutagenesis of a thermostable alkaline phytase from Bacillus sp. MD2 was performed with an aim to increase its specific activity and activity and stability in an acidic environment. The mutation sites are distributed on the catalytic surface of the enzyme (P257R, E180N, E229V and S283R) and in the active site (K77R, K179R and E227S). Selection of the residues was based on the idea that acid active phytases are more positively charged around their catalytic surfaces. Thus, a decrease in the content of negatively charged residues or an increase in the positive charges in the catalytic region of an alkaline phytase was assumed to influence the enzyme activity and stability at low pH. Moreover, widening of the substrate-binding pocket is expected to improve the hydrolysis of substrates that are not efficiently hydrolysed by wild type alkaline phytase. Analysis of the phytase variants revealed that E229V and S283R mutants increased the specific activity by about 19% and 13%, respectively. Mutation of the active site residues K77R and K179R led to severe reduction in the specific activity of the enzyme. Analysis of the phytase mutant-phytate complexes revealed increase in hydrogen bonding between the enzyme and the substrate, which might retard the release of the product, resulting in decreased activity. On the other hand, the double mutant (K77R-K179R) phytase showed higher stability at low pH (pH 2.6-3.0). The E227S variant was optimally active at pH 5.5 (in contrast to the wild type enzyme that had an optimum pH of 6) and it exhibited higher stability in acidic condition. This mutant phytase, displayed over 80% of its initial activity after 3 h incubation at pH 2.6 while the wild type phytase retained only about 40% of its original activity. Moreover, the relative activity of this mutant phytase on calcium phytate, sodium pyrophosphate and p-nitro phenyl phosphate was higher than that of the wild type phytase.     

Site-directed mutagenesis of glutamate residues in the large extrinsic loop of the photosystem II protein CP 43 affects oxygen-evolving activity and PS II assembly

The psbC gene encodes the intrinsic chlorophyll protein CP 43, a component of photosystem II in higher plants, green algae, and cyanobacteria. Oligonucleotide-directed mutagenesis was used to introduce mutations into the portion of psbC that encodes the large extrinsic loop E of CP 43 in the cyanobacterium Synechocystis 6803. Three mutations, E293Q, E339Q, and E352Q, each produced a strain with impaired photosystem II activity. The E293Q mutant strain grew photoautotrophically at rates comparable to the control strain. Immunological analyses of several PS II components indicated that this mutant accumulated normal quantities of PS II proteins. However, this mutant evolved oxygen to only 56% of control rates at saturating light intensities. Measurements of total variable fluorescence yield indicated that this mutant assembled approximately 60% of the fully functional PS II centers found in the control strain. The E339Q mutant grew photoautotrophically at a severely reduced rate. Both immunological analysis and variable fluorescence yield experiments indicated that E339Q assembled a normal complement of PS II centers. However, this mutant was capable of evolving oxygen to only 20% of control rates. Variable fluorescence yield experiments demonstrated that this mutant was inefficient at using water as an electron donor. Both E293Q and E339Q strains exhibited an increased (approximately 2-fold) sensitivity to photoinactivation. The E352Q mutant was the most severely affected. This mutant failed to grow photoautotrophically and exhibited essentially no capacity for oxygen evolution. Measurements of total variable fluorescence yield indicated that this mutant assembled no functional PS II centers. Immunological analysis of isolated thylakoid membranes from E352Q revealed a complete absence of CP 43 and reduced levels of both the D1 and manganese-stabilizing proteins. These results suggest that the mutations E293Q and E339Q each produce a defect associated with the oxygen-evolving complex of photosystem II. The E352Q mutation appears to affect the stability of the PS II complex. This is the first report showing that alteration of negatively charged residues in the CP 43 large extrinsic loop results in mutations affecting PS II assembly/function.