Identification and molecular characterization of the beta-ketoacyl-[acyl carrier protein] synthase component of the Arabidopsis mitochondrial fatty acid synthase

Substrate specificity of condensing enzymes is a predominant factor determining the nature of fatty acyl chains synthesized by type II fatty acid synthase (FAS) enzyme complexes composed of discrete enzymes. The gene (mtKAS) encoding the condensing enzyme, beta-ketoacyl-[acyl carrier protein] (ACP) synthase (KAS), constituent of the mitochondrial FAS was cloned from Arabidopsis thaliana, and its product was purified and characterized. The mtKAS cDNA complemented the KAS II defect in the E. coli CY244 strain mutated in both fabB and fabF encoding KAS I and KAS II, respectively, demonstrating its ability to catalyze the condensation reaction in fatty acid synthesis. In vitro assays using extracts of CY244 containing all E. coli FAS components, except that KAS I and II were replaced by mtKAS, gave C(4)-C(18) fatty acids exhibiting a bimodal distribution with peaks at C(8) and C(14)-C(16). Previously observed bimodal distributions obtained using mitochondrial extracts appear attributable to the mtKAS enzyme in the extracts. Although the mtKAS sequence is most similar to that of bacterial KAS IIs, sensitivity of mtKAS to the antibiotic cerulenin resembles that of E. coli KAS I. In the first or priming condensation reaction of de novo fatty acid synthesis, purified His-tagged mtKAS efficiently utilized malonyl-ACP, but not acetyl-CoA as primer substrate. Intracellular targeting using green fluorescent protein, Western blot, and deletion analyses identified an N-terminal signal conveying mtKAS into mitochondria. Thus, mtKAS with its broad chain length specificity accomplishes all condensation steps in mitochondrial fatty acid synthesis, whereas in plastids three KAS enzymes are required.     

Beta-ketoacyl-acyl carrier protein synthase III (FabH) is essential for bacterial fatty acid synthesis

beta-Ketoacyl-acyl carrier protein (ACP) synthase III (KAS III, also called acetoacetyl-ACP synthase) encoded by the fabH gene is thought to catalyze the first elongation reaction (Claisen condensation) of type II fatty acid synthesis in bacteria and plant plastids. However, direct in vivo evidence that KAS III catalyzes an essential reaction is lacking, because no mutant organism deficient in this activity has been isolated. We report the first bacterial strain lacking KAS III, a fabH mutant constructed in the Gram-positive bacterium Lactococcus lactis subspecies lactis IL1403. The mutant strain carries an in-frame deletion of the KAS III active site region and was isolated by gene replacement using a medium supplemented with a source of saturated and unsaturated long-chain fatty acids. The mutant strain is devoid of KAS III activity and fails to grow in the absence of supplementation with exogenous long-chain fatty acids demonstrating that KAS III plays an essential role in cellular metabolism. However, the L. lactis fabH deletion mutant requires only long-chain unsaturated fatty acids for growth, a source of long-chain saturated fatty acids is not required. Because both saturated and unsaturated fatty acids are required for growth when fatty acid synthesis is blocked by biotin starvation (which prevents the synthesis of malonyl-CoA), another pathway for saturated fatty acid synthesis must remain in the fabH deletion strain. Indeed, incorporation of [1-14C]acetate into fatty acids in vivo showed that the fabH mutant retained about 10% of the fatty acid synthetic ability of the wild-type strain and that this residual synthetic capacity was preferentially diverted to the saturated branch of the pathway. Moreover, mass spectrometry showed that the fabH mutant retained low levels of palmitic acid upon fatty acid starvation. Derivatives of the fabH deletion mutant strain were isolated that were octanoic acid auxotrophs consistent with biochemical studies indicating that the major role of FabH is production of short-chain fatty acid primers. We also confirmed the essentiality of FabH in Escherichia coli by use of a plasmid-based gene insertion/deletion system. Together these results provide the first genetic evidence demonstrating that FabH conducts the major condensation reaction in the initiation of type II fatty acid biosynthesis in both Gram-positive and Gram-negative bacteria.     

Bacillus subtilis acyl carrier protein is encoded in a cluster of lipid biosynthesis genes.

A cluster of Bacillus subtilis fatty acid synthetic genes was isolated by complementation of an Escherichia coli fabD mutant encoding a thermosensitive malonyl coenzyme A-acyl carrier protein transacylase. The B. subtilis genomic segment contains genes that encode three fatty acid synthetic proteins, malonyl coenzyme A-acyl carrier protein transacylase (fabD), 3-ketoacyl-acyl carrier protein reductase (fabG), and the N-terminal 14 amino acid residues of acyl carrier protein (acpP). Also present is a sequence that encodes a homolog of E. coli plsX, a gene that plays a poorly understood role in phospholipid synthesis. The B. subtilis plsX gene weakly complemented an E. coli plsX mutant. The order of genes in the cluster is plsX fabD fabG acpP, the same order found in E. coli, except that in E. coli the fabH gene lies between plsX and fabD. The absence of fabH in the B. subtilis cluster is consistent with the different fatty acid compositions of the two organisms. The amino acid sequence of B. subtilis acyl carrier protein was obtained by sequencing the purified protein, and the sequence obtained strongly resembled that of E. coli acyl carrier protein, except that most of the protein retained the initiating methionine residue. The B. subtilis fab cluster was mapped to the 135 to 145 degrees region of the chromosome.     

Molecular aspects of beta-ketoacyl synthase (KAS) catalysis

Crystal structure data for Escherichia coli beta-ketoacyl synthase (KAS) I with C(10) and C(12) fatty acid substrates bound in conjunction with results from mutagenizing residues in the active site leads to a model for catalysis. Differences from and similarities to the other Claisen enzymes carrying out decarboxylations reveal two catalytic mechanisms, one for KAS I and KAS II, the other for KAS III and chalcone synthase. A comparison of the structures of KAS I and KAS II does not reveal the basis of chain-length specificity. The structures of the Arabidopsis thaliana KAS family are compared.     

大肠杆菌3-酮基脂酰ACP还原酶110位天冬酰胺突变后的结构与功能

3-酮基脂酰ACP还原酶催化3-酮基脂酰ACP还原为3-羟基脂酰ACP,是细菌脂肪酸合成反应的关键酶之一.为了明确该酶中110位的保守天冬酰胺残基在酶催化活性和酶结构中的作用,本研究采用基因定点突变和蛋白质表达纯化技术,获得了大肠杆菌3-酮基脂酰ACP还原酶FabG的两个突变蛋白：FabG N110Q和FabG N110L.圆二色谱结果显示,天冬酰胺残基的突变改变了FabG的空间结构,使突变蛋白的α螺旋结构明显增加.以3-酮脂酰ACP为底物的酶活性测定表明,突变蛋白的酶活性均有下降,但残存的酶活性达到了FabG的75%以上.突变蛋白FabG N110Q和FabG N110L具有3-酮基脂酰ACP还原酶的活性,能在体外重建细菌脂肪酸合成反应.对fabG温度敏感突变株的遗传互补分析表明,FabG蛋白110位天冬酰胺突变为谷氨酰胺或亮氨酸后,在一定的条件下仍能互补大肠杆菌的生长.本研究结果提示,FabG 110位的天冬酰胺残基不是参与3-酮基脂酰ACP还原酶催化反应的必需氨基酸,它只是作为结构氨基酸,在维持FabG的空间结构的稳定性方面起作用.     

A Mutant of Arabidopsis Deficient in the Elongation of Palmitic Acid

The overall fatty acid composition of leaf lipids in a mutant of Arabidopsis thaliana was characterized by an increased level of 16:0 and a concomitant decrease of 18-carbon fatty acids as a consequence of a single recessive nuclear mutation at the fab1 locus. Quantitative analysis of the fatty acid composition of individual lipids established that lipids synthesized by both the prokaryotic and eukaryotic pathways were affected by the mutation. Direct enzyme assays demonstrated that the mutant plants were deficient in the activity of 3-ketoacyl-acyl carrier protein synthase II; therefore, it is inferred that fab1 may encode this enzyme. Labeling experiments with [14C]acetate and lipase positional analysis indicated that the mutation results in a small shift in the partitioning of lipid synthesis between the prokaryotic and eukaryotic pathways. Synthesis of chloroplast lipids by the prokaryotic pathway was increased with a corresponding reduction in the eukaryotic pathway.     

Determination of the genetic, molecular, and biochemical basis of the Arabidopsis thaliana thiamin auxotroph th1

2-methyl-4-amino-5-hydroxymethylpyrimidine phosphate kinase/thiamin monophosphate pyrophosphorylase (HMPPK/TMPPase) is a key enzyme involved in thiamin biosynthesis. A candidate HMPPK/TMPPase gene identified in the Arabidopsis genome complemented the thiamin auxotrophy of the th1 mutant, thus proving that the th1 locus corresponds to the structural gene for the HMPPK/TMPPase. Sequence comparisons between the wild-type HMPPK/TMPPase gene and the th1-201 mutant allele identified a single point mutation that caused the substitution of a phenylalanine for a conserved serine residue in the HMPPK domain. Functional analyses of the mutant HMPPK/TMPPase in Escherichia coli revealed that the amino acid substitution in the HMPPK domain of mutant enzyme resulted in a conformational change that severely compromised both activities of the bifunctional enzyme. Studies were also performed to identify the chloroplast as the specific subcellular locale of the Arabidopsis HMPPK/TMPPase.     

Fatty Acid Biosynthesis in Pseudomonas aeruginosa Is Initiated by the FabY Class of β-Ketoacyl Acyl Carrier Protein Synthases

The prototypical type II fatty acid synthesis (FAS) pathway in bacteria utilizes two distinct classes of β-ketoacyl synthase (KAS) domains to assemble long-chain fatty acids, the KASIII domain for initiation and the KASI/II domain for elongation. The central role of FAS in bacterial viability and virulence has stimulated significant effort toward developing KAS inhibitors, particularly against the KASIII domain of the β-acetoacetyl-acyl carrier protein (ACP) synthase FabH. Herein, we show that the opportunistic pathogen Pseudomonas aeruginosa does not utilize a FabH ortholog but rather a new class of divergent KAS I/II enzymes to initiate the FAS pathway. When a P. aeruginosa cosmid library was used to rescue growth in a fabH downregulated strain of Escherichia coli, a single unannotated open reading frame, PA5174, complemented fabH depletion. While deletion of all four KASIII domain-encoding genes in the same P. aeruginosa strain resulted in a wild-type growth phenotype, deletion of PA5174 alone specifically attenuated growth due to a defect in de novo FAS. Siderophore secretion and quorum-sensing signaling, particularly in the rhl and Pseudomonas quinolone signal (PQS) systems, was significantly muted in the absence of PA5174. The defect could be repaired by intergeneric complementation with E. coli fabH. Characterization of recombinant PA5174 confirmed a preference for short-chain acyl coenzyme A (acyl-CoA) substrates, supporting the identification of PA5174 as the predominant enzyme catalyzing the condensation of acetyl coenzyme A with malonyl-ACP in P. aeruginosa. The identification of the functional role for PA5174 in FAS defines the new FabY class of β-ketoacyl synthase KASI/II domain condensation enzymes.     

Crystal structures of leucyl/phenylalanyl-tRNA-protein transferase and its complex with an aminoacyl-tRNA analog

Eubacterial leucyl/phenylalanyl-tRNA protein transferase (L/F-transferase), encoded by the aat gene, conjugates leucine or phenylalanine to the N-terminal Arg or Lys residue of proteins, using Leu-tRNA(Leu) or Phe-tRNA(Phe) as a substrate. The resulting N-terminal Leu or Phe acts as a degradation signal for the ClpS-ClpAP-mediated N-end rule protein degradation pathway. Here, we present the crystal structures of Escherichia coli L/F-transferase and its complex with an aminoacyl-tRNA analog, puromycin. The C-terminal domain of L/F-transferase consists of the GCN5-related N-acetyltransferase fold, commonly observed in the acetyltransferase superfamily. The p-methoxybenzyl group of puromycin, corresponding to the side chain of Leu or Phe of Leu-tRNA(Leu) or Phe-tRNA(Phe), is accommodated in a highly hydrophobic pocket, with a shape and size suitable for hydrophobic amino-acid residues lacking a branched beta-carbon, such as leucine and phenylalanine. Structure-based mutagenesis of L/F-transferase revealed its substrate specificity. Furthermore, we present a model of the L/F-transferase complex with tRNA and substrate proteins bearing an N-terminal Arg or Lys.     

A suppressor of fab1 challenges hypotheses on the role of thylakoid unsaturation in photosynthetic function

Leaf membrane lipids of the Arabidopsis (Arabidopsis thaliana) fatty acid biosynthesis 1 (fab1) mutant contain a 35% to 40% increase in the predominant saturated fatty acid 16:0, relative to wild type. This increase in membrane saturation is associated with loss of photosynthetic function and death of mutant plants at low temperatures. We have initiated a suppressor screen for mutations that allow survival of fab1 plants at 2 degrees C. Five suppressor mutants identified in this screen all rescued the collapse of photosynthetic function observed in fab1 plants. While fab1 plants died after 5 to 7 weeks at 2 degrees C, the suppressors remained viable after 16 weeks in the cold, as judged by their ability to resume growth following a return to 22 degrees C and to subsequently produce viable seed. Three of the suppressors had changes in leaf fatty acid composition when compared to fab1, indicating that one mechanism of suppression may involve compensating changes in thylakoid lipid composition. Surprisingly, the suppressor phenotype in one line, S31, was associated with a further substantial increase in lipid saturation. The overall leaf fatty acid composition of S31 plants contained 31% 16:0 compared with 23% in fab1 and 17% in wild type. Biochemical and genetic analysis showed that S31 plants contain a new allele of fatty acid desaturation 5 (fad5), fad5-2, and are therefore partially deficient in activity of the chloroplast 16:0 Delta7 desaturase. A double mutant produced by crossing fab1 to the original fad5-1 allele also remained alive at 2 degrees C, indicating that the fad5-2 mutation is the suppressor in the S31 (fab1 fad5-2) line. Based on the biophysical characteristics of saturated and unsaturated fatty acids, the increased 16:0 in fab1 fad5-2 plants would be expected to exacerbate, rather than ameliorate, low-temperature damage. We propose instead that a change in shape of the major thylakoid lipid, monogalactosyldiacylglycerol, mediated by the fad5-2 mutation, may compensate for changes in lipid structure resulting from the original fab1 mutation. Our identification of mutants that suppress the low-temperature phenotype of fab1 provides new tools to understand the relationship between thylakoid lipid structure and photosynthetic function.     

Modulation of the affinity of the single-stranded DNA-binding protein of Escherichia coli (E. coli SSB) to poly(dT) by site-directed mutagenesis

A vector for site-directed mutagenesis and overproduction of the Escherichia coli single-stranded-DNA-binding protein (E. coli SSB) was constructed. An E. coli strain carrying this vector produces up to 400 mg pure protein from 25 g wet cells. The vector was used to mutate specifically the Phe60 residue of E. coli SSB. Phe60 had been proposed to be located near the single-stranded-DNA-binding site. Substitution of the Phe60 residue by Val, Ser, Leu, His, Tyr and Trp gave proteins with no or only minor conformational changes, as detected by NMR spectroscopy. The affinity of the mutant E. coli SSB proteins for single-stranded DNA decreased in the order Trp greater than Phe (wild-type) greater than Tyr greater than Leu greater than His greater than Val greater than Ser, leading to the conclusion that position 60 is a site of hydrophobic interaction of the protein with DNA.     

Cloning and sequencing of clustered genes involved in fatty acid biosynthesis from the docosahexaenoic acid-producing bacterium, Vibrio marinus strain MP-1

A cluster of genes involved in fatty acid biosynthesis (fab) was isolated from docosahexaenoic acid (DHA)-producing Vibrio marinus strain MP-1. This fab gene cluster included five genes highly homologous to the Escherichia coli counterparts, and their order in the cluster was the same with that of the E. coli fab gene cluster except that the latter included the additional fabH gene. These fab genes should be involved in early steps of DHA biosynthesis in V. marinus strain MP-1.     

Cloning, nucleotide sequence, and expression of the Escherichia coli fabD gene, encoding malonyl coenzyme A-acyl carrier protein transacylase.

The Escherichia coli fabD gene encoding malonyl coenzyme A-acyl carrier protein transacylase (MCT) was cloned by complementation of a thermosensitive E. coli fabD mutant (fabD89). Expression of the fabD gene in an appropriate E. coli expression vector resulted in an accumulation of the MCT protein of up to 10% of total soluble protein, which was accompanied by an approximately 1,000-fold increase in the MCT activity. DNA sequence analysis and expression studies revealed that the fabD gene is part of an operon consisting of at least three genes involved in fatty acid biosynthesis. Comparison with available DNA and protein data bases suggest that a 3-ketoacyl-acyl carrier protein synthase and a ketoacyl-acyl carrier protein reductase gene are located immediately upstream and downstream, respectively, of fabD within this fab operon. Western immunoblot analysis with antiserum raised against wild-type E. coli MCT showed that the fabD89 allele encodes a polypeptide with an apparent molecular weight of 27,000 in addition to the normal MCT protein of 32,000. The nature of the temperature-sensitive fabD89 gene product is discussed.     

Molecular characterization of three mutations in katG affecting the activity of hydroperoxidase I of Escherichia coli

Hydroperoxidase I (HPI) of Escherichia coli is a bifunctional enzyme exhibiting both catalase and peroxidase activities. Mutants lacking appreciable HPI have been generated using nitrosoguanidine and the gene encoding HPI, katG, has been cloned from three of these mutants using either classical probing methods or polymerase chain reaction amplification. The mutant genes were sequenced and the changes from wild-type sequence identified. Two mutants contained G to A changes in the coding strand, resulting in glycine to aspartate changes at residues 119 (katG15) and 314 (katG16) in the deduced amino acid sequence of the protein. A third mutant contained a C to T change resulting in a leucine to phenylalanine change at residue 139 (katG14). The Phe139-, Asp119-, and Asp314-containing mutants exhibited 13, less than 1, and 18%, respectively, of the wild-type catalase specific activity and 43, 4, and 45% of the wild-type peroxidase specific activity. All mutant enzymes bound less protoheme IX than the wild-type enzyme. The sensitivities of the mutant enzymes to the inhibitors hydroxylamine, azide, and cyanide and the activators imidazole and Tris were similar to those of the wild-type enzyme. The mutant enzymes were more sensitive to high temperature and to beta-mercaptoethanol than the wild-type enzyme. The pH profiles of the mutant catalases were unchanged from the wild-type enzyme.     

Forced Ambiguity of the Leucine Codons for Multiple-Site-Specific Incorporation of a Noncanonical Amino Acid

Multiple-site-specific incorporation of a noncanonical amino acid into a recombinant protein would be a very useful technique to generate multiple chemical handles for bioconjugation and multivalent binding sites for the enhanced interaction. Previously combination of a mutant yeast phenylalanyl-tRNA synthetase variant and the yeast phenylalanyl-tRNA containing the AAA anticodon was used to incorporate a noncanonical amino acid into multiple UUU phenylalanine (Phe) codons in a site-specific manner. However, due to the less selective codon recognition of the AAA anticodon, there was significant misincorporation of a noncanonical amino acid into unwanted UUC Phe codons. To enhance codon selectivity, we explored degenerate leucine (Leu) codons instead of Phe degenerate codons. Combined use of the mutant yeast phenylalanyl-tRNA containing the CAA anticodon and the yPheRS_naph variant allowed incorporation of a phenylalanine analog, 2-naphthylalanine, into murine dihydrofolate reductase in response to multiple UUG Leu codons, but not to other Leu codon sites. Despite the moderate UUG codon occupancy by 2-naphthylalaine, these results successfully demonstrated that the concept of forced ambiguity of the genetic code can be achieved for the Leu codons, available for multiple-site-specific incorporation.     

Characterization of a KCS-like KASII from <Emphasis Type="Italic">Jessenia bataua</Emphasis> that Elongates Saturated and Monounsaturated Stearic Acids in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

As the world population grows, the demand for food increases. Although vegetable oils provide an affordable and rich source of energy, the supply of vegetable oils available for human consumption is limited by the "fuel vs food" debate. To increase the nutritional value of vegetable oil, metabolic engineering may be used to produce oil crops of desirable fatty acid composition. We have isolated and characterized β-ketoacyl ACP-synthase II (KASII) cDNA from a high-oleic acid palm, Jessenia bataua. Jessenia KASII (JbKASII) encodes a 488-amino acid polypeptide that possesses conserved domains that are necessary for condensing activities. When overexpressed in E. coli, recombinant His-tagged JbKASII was insoluble and non-functional. However, Arabidopsis plants expressing GFP-JbKASII fusions had elevated levels of arachidic acid (C20:0) and erucic acid (C22:1) at the expense of stearic acid (C18:0) and oleic acid (C18:1). Furthermore, JbKASII failed to complement the Arabidopsis KASII mutant, fab1-2. This suggests that the substrate specificity of JbKASII is similar to that of ketoacyl-CoA synthase (KCS), which preferentially elongates stearic and oleic acids, and not palmitic acid. Our results suggest that the KCS-like JbKASII may elongate C18:0 and C18:1 to yield C20:0 and C22:1, respectively. JbKASII may, therefore, be an interesting candidate gene for promoting the production of very long chain fatty acids in transgenic oil crops.     

Altered body morphology is caused by increased stearate levels in a mutant of Arabidopsis

A mutant of Arabidopsis thaliana, fab2 , in which a profound developmental phenotype, miniature growth, is caused by an increase in the level of the membrane fatty acid, stearate has been characterized. Miniature growth in fab2 results from changes in cell expansion and maturation processes. Leaf anatomy of fab2 is characterized by cell-specific changes in expansion growth, by a lack of differentiation in the cells of the leaf blade, and by the absence of air spaces. Leaves of fab2 lack the basipetal gradient in cellular development which is ubiquitous in higher plants. These cellular changes occur without distorting the chronology of development, or destroying the biological integrity of the organism. A second site suppressor mutation, shs , substantially restores both normal fatty acid composition and normal body size, causally linking the two phenotypes. Growth of the fab2 mutant at high temperature substantially corrects the miniature phenotype without altering the fatty acid composition, suggesting a role for membrane structure in the production of the aberrant morphology.     

Amino acid substrate specificity of Escherichia coli phenylalanyl-tRNA synthetase altered by distinct mutations

Neither the tertiary structure nor the location of active sites are known for phenylalanyl-tRNA synthetase (PheRS; alpha 2 beta 2 structure), a member of class II aminoacyl-tRNA synthetases. In an attempt to detect the phenylalanine (Phe) binding site, two Escherichia coli PheRS mutant strains (pheS), which were resistant to p-fluorophenylalanine (p-F-Phe) were analysed genetically. The pheS mutations were found to cause Ala294 to Ser294 exchanges in the alpha subunits from both independent strains. This alteration (S294) resided in the well-conserved C-terminal part of the alpha subunit, precisely within motif 3, a typical class II tRNA synthetase sequence. We thus propose that motif 3 participates in the formation of the Phe binding site of PheRS. Mutation S294 was also the key for proposing a mechanism by which the substrate analogue p-F-Phe is excluded from the enzymatic reaction; this may be achieved by steric interactions between the para-position of the aromatic ring and the amino acid residue at position 294. The Phe binding site model was then tested by replacing the alanine at position 294 as well as the two flanking phenylalanines (positions 293 and 295) by a number of selected other amino acids. In vivo and in vitro results demonstrated that Phe293 and Phe295 are not directly involved in substrate binding, but replacements of those residues affected PheRS stability. However, exchanges at position 294 altered the binding of Phe, and certain mutants showed pronounced changes in specificity towards Phe analogues. Of particular interest was the Gly294 PheRS in which presumably an enlarged cavity for the para position of the aromatic ring allowed an increased aminoacylation of tRNA with p-F-Phe. Moreover, the larger para-chloro and para-bromo derivatives of Phe could interact with this enzyme in vitro and became highly toxic in vivo. The possible exploitation of the Gly294 mutant PheRS for the incorporation of non-proteinogenic amino acids into proteins is discussed.     

A novel site-directed mutant of myoglobin with an unusually high O2 affinity and low autooxidation rate.

Mutants of sperm whale myoglobin were constructed at position 29 (B10 in helix notation) to examine the effects of distal pocket size on the rates of ligand binding and autooxidation. Leu29 was replaced with Ala, Val, and Phe using the synthetic gene and Escherichia coli expression system of Springer and Sligar (Springer, B. A., and Sligar, S. G. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 8961-8965). Structures of the ferric forms of Val29 and Phe29, and the oxy form of Phe29 myoglobin were determined to 1.7 A by x-ray crystallography. The ferric mutant proteins are remarkably isomorphous with the wild type protein except in the immediate vicinity of residue 29. Thus, the protein structure in the distal pocket of myoglobin can accommodate either a large "hole" (i.e. Ala or Val) or a large side chain (i.e. Phe) at position 29 without perturbation of tertiary structure. Phe29 oxymyoglobin is also identical to the native oxy protein in terms of overall structure and interactions between the bound O2 and His64, Val68, Phe43, and Ile107. The distance between the nearest side chain atom of residue 29 and the second atom of the bound oxygen molecule is 3.2 A in the Phe29 protein and 4.9 A in native myoglobin. The equilibrium constants for O2 binding to Ala29, Val29, and Leu29 (native) myoglobin are the same, approximately 1.0 x 10(6) M-1 at 20 degrees C, whereas that for the Phe29 protein is markedly greater, 15 x 10(6) M-1. This increase in affinity is due primarily to a 10-fold decrease in the O2 dissociation rate constant for the Phe29 mutant and appears to be the result of stabilizing interactions between the negative portion of the bound O2 dipole and the partially positive edge of the phenyl ring. Increasing the size of residue 29 causes large decreases in the rate of autooxidation of myoglobin: k(ox) = 0.24, 0.23, 0.055, and 0.005 h-1 for Ala29, Val29, Leu29 (native), and Phe29 myoglobin, respectively, in air at 37 degrees C. Thus, the Leu29----Phe mutation produces a reduced protein that is remarkably stable and is expressed in E. coli as 100% MbO2. The selective pressure to conserve Leu29 at the B10 position probably represents a compromise between reducing the rate of autooxidation and maintaining a large enough O2 dissociation rate constant to allow rapid oxygen release during respiration.