Escherichia coli dimethylallyl diphosphate:tRNA dimethylallyltransferase: pre-steady-state kinetic studies

Escherichia coli dimethylallyl diphosphate:tRNA dimethylallyltransferase (DMAPP-tRNA transferase) catalyzes the first step in the biosynthesis of the hypermodified A37 residue in tRNAs that read codons beginning with uridine. The mechanism of the enzyme-catalyzed reaction was studied by isotope trapping, pre-steady-state rapid quench, and single turnover experiments. Isotope trapping indicated that the enzyme.tRNA complex is catalytically competent, whereas the enzyme.DMAPP complex is not. The results are consistent with an ordered sequential mechanism for substrate binding where tRNA binds first. The association and dissociation rate constants for the enzyme.tRNA binary complex are 1. 15+/-0.33x10(7) M(-1) s(-1) and 0.06+/-0.01 s(-1), respectively. Addition of DMAPP gives an enzyme.tRNA.DMAPP ternary complex in rapid equilibrium with the binary complex and DMAPP. Rapid quench studies yielded a linear profile (k(cat)=0.36+/-0.01 s(-1)) with no evidence for buildup of enzyme-bound product. Product release from DMAPP-tRNA transferase is therefore not rate-limiting. The Michaelis constant for tRNA and the equilibrium dissociation constant for DMAPP calculated from the individual rate constants determined here are consistent with values obtained from a steady-state kinetic analysis.     

Escherichia coli dimethylallyl diphosphate:tRNA dimethylallyltransferase: essential elements for recognition of tRNA substrates within the anticodon stem-loop

Escherichia coli dimethylallyl diphosphate:tRNA dimethylallyltransferase (DMAPP-tRNA transferase) catalyzes the alkylation of the exocyclic amine of A37 by a dimethylallyl unit in tRNAs with an adenosine in the third anticodon position (position 36). By use of purified recombinant enzyme, steady- state kinetic studies were conducted with chemically synthesized RNA oligoribonucleotides to determine the essential elements within the tRNA anticodon stem-loop structure required for recognition by the enzyme. A 17-base oligoribonucleotide corresponding to the anticodon stem-loop of E. coli tRNA(Phe) formed a stem-loop minihelix (minihelix(Phe)) when annealed rapidly on ice, while the same molecule formed a duplex structure with a central loop when annealed slowly at higher concentrations. Both the minihelix and duplex structures gave k(cat)s similar to that for the normal substrate (full-length tRNA(Phe) unmodified at A37), although the K(m) for minihelix(Phe) was approximately 180-fold higher than full-length tRNA. The A36-A37-A38 motif, which is completely conserved in tRNAs modified by the enzyme, was found to be important for modification. Changing A36 to G in the minihelix resulted in a 260-fold reduction in k(cat) compared to minihelix(Phe) and a 13-fold increase in K(m). An A38G variant was modified with a 9-fold reduction in k(cat) and a 5-fold increase in K(m). A random coil 17-base oligoribonucleotide in which the loop sequence of E. coli tRNA(Phe) was preserved, but the 5 base pair helix stem was completely disrupted and showed no measurable activity, indicating that a helix-loop structure is essential for recognition. Finally, altering the identity of several base pairs in the helical stem did not have a major effect on catalytic efficiency, suggesting that the enzyme does not make base-specific contacts important for binding or catalysis in this region.     

Significance of Asn-77 and Trp-78 in the catalytic function of undecaprenyl diphosphate synthase of Micrococcus luteus B-P 26

The primary structures of cis-prenyltransferases are completely different from those of trans-prenyltransferases. To obtain information about amino acid residues relating to catalytic function, random mutation of the undecaprenyl diphosphate synthase gene of Micrococcus luteus B-P 26 was carried out to construct a mutated gene library using an error-prone polymerase chain reaction. From the library, the mutants showing poor enzymatic activity were selected by the colony autoradiography method. Among 31 negative clones selected from 3,000 mutants, two clones were found to contain only one amino acid substitution at either Asn-77 or Trp-78. To determine the functional roles of these interesting residues, we prepared six mutated enzymes with substitutions at residues Asn-77 or Trp-78 by site-directed mutagenesis. Substitution of Asn-77 with Ala, Asp, or Gln resulted in a dramatic decrease in catalytic activity, but the K(m) values for both allylic and homoallylic substrates of these mutant enzymes were comparable to those of the wild-type. On the other hand, three Trp-78 mutants, W78I, W78R, and W78D, showed 5-20-fold increased K(m) values for farnesyl diphosphate but not for Z-geranylgeranyl diphosphate. However, these mutants showed moderate levels of enzymatic activity and comparable K(m) values for isopentenyl diphosphate to that of the wild-type. These results suggest that the Asn-Trp motif is involved in the binding of farnesyl diphosphate and enzymatic catalysis.     

Misacylation and editing by Escherichia coli valyl-tRNA synthetase: evidence for two tRNA binding sites.

Valyl-tRNA synthetase (ValRS) has difficulty discriminating between its cognate amino acid, valine, and structurally similar amino acids. To minimize translational errors, the enzyme catalyzes a tRNA-dependent editing reaction that prevents accumulation of misacylated tRNA(Val). Editing occurs with threonine, alanine, serine, and cysteine, as well as with several nonprotein amino acids. The 3'-end of tRNA plays a vital role in promoting the tRNA-dependent editing reaction. Valine tRNA having the universally conserved 3'-terminal adenosine replaced by any other nucleoside does not stimulate the editing activity of ValRS. As a result 3'-end tRNA(Val) mutants, particularly those with 3'-terminal pyrimidines, are stably misacylated with threonine, alanine, serine, and cysteine. Valyl-tRNA synthetase is unable to hydrolytically deacylate misacylated tRNA(Val) terminating in 3'-pyrimidines but does deacylate mischarged tRNA(Val) terminating in adenosine or guanosine. Evidently, a purine at position 76 of tRNA(Val) is essential for translational editing by ValRS. We also observe misacylation of wild-type and 3'-end mutants of tRNA(Val) with isoleucine. Valyl-tRNA synthetase does not edit wild-type tRNA(Val)(A76) mischarged with isoleucine, presumably because isoleucine is only poorly accommodated at the editing site of the enzyme. Misacylated mutant tRNAs as well as 3'-end-truncated tRNA(Val) are mixed noncompetitive inhibitors of the aminoacylation reaction, suggesting that ValRS, a monomeric enzyme, may bind more than one tRNA(Val) molecule. Gel-mobility-shift experiments to characterize the interaction of tRNA(Val) with the enzyme provide evidence for two tRNA binding sites on ValRS.     

Farnesyl diphosphate synthase. Altering the catalytic site to select for geranyl diphosphate activity

Farnesyl diphosphate synthase (FPPase) catalyzes chain elongation of the C(5) substrate dimethylallyl diphosphate (DMAPP) to the C(15) product farnesyl diphosphate (FPP) by addition of two molecules of isopentenyl diphosphate (IPP). The synthesis of FPP proceeds in two steps, where the C(10) product of the first addition, geranyl diphosphate (GPP), is the substrate for the second addition. The product selectivity of avian FPPase was altered to favor synthesis of GPP by site-directed mutagenesis of residues that form the binding pocket for the hydrocarbon residue of the allylic substrate. Amino acid substitutions that reduced the size of the binding pocket were identified by molecular modeling. FPPase mutants containing seven promising modifications were constructed. Initial screens using DMAPP and GPP as substrates indicated that two of the substitutions, A116W and N144'W, strongly discriminated against binding of GPP to the allylic site. These observations were confirmed by an analysis of the products from reactions with DMAPP in the presence of excess IPP and by comparing the steady-state kinetic constants for the wild-type enzyme and the A116W and N114W mutants.     

Yeast mitochondrial initiator tRNA is methylated at guanosine 37 by the Trm5-encoded tRNA (guanine-N1-)-methyltransferase

The TRM5 gene encodes a tRNA (guanine-N1-)-methyltransferase (Trm5p) that methylates guanosine at position 37 (m(1)G37) in cytoplasmic tRNAs in Saccharomyces cerevisiae. Here we show that Trm5p is also responsible for m(1)G37 methylation of mitochondrial tRNAs. The TRM5 open reading frame encodes 499 amino acids containing four potential initiator codons within the first 48 codons. Full-length Trm5p, purified as a fusion protein with maltose-binding protein, exhibited robust methyltransferase activity with tRNA isolated from a Delta trm5 mutant strain, as well as with a synthetic mitochondrial initiator tRNA (tRNA(Met)(f)). Primer extension demonstrated that the site of methylation was guanosine 37 in both mitochondrial tRNA(Met)(f) and tRNA(Phe). High pressure liquid chromatography analysis showed the methylated product to be m(1)G. Subcellular fractionation and immunoblotting of a strain expressing a green fluorescent protein-tagged version of the TRM5 gene revealed that the enzyme was localized to both cytoplasm and mitochondria. The slightly larger mitochondrial form was protected from protease digestion, indicating a matrix localization. Analysis of N-terminal truncation mutants revealed that a Trm5p active in the cytoplasm could be obtained with a construct lacking amino acids 1-33 (Delta1-33), whereas production of a Trm5p active in the mitochondria required these first 33 amino acids. Yeast expressing the Delta1-33 construct exhibited a significantly lower rate of oxygen consumption, indicating that efficiency or accuracy of mitochondrial protein synthesis is decreased in cells lacking m(1)G37 methylation of mitochondrial tRNAs. These data suggest that this tRNA modification plays an important role in reading frame maintenance in mitochondrial protein synthesis.     

Membrane topology of loop 13-14 of the Na+/glucose cotransporter (SGLT1): a SCAM and fluorescent labelling study

The accessibility of the hydrophilic loop between putative transmembrane segments XIII and XIV of the Na+/glucose cotransporter (SGLT1) was studied in Xenopus oocytes, using the substituted cysteine accessibility method (SCAM) and fluorescent labelling. Fifteen cysteine mutants between positions 565 and 664 yielded cotransport currents of similar amplitude than the wild-type SGLT1 (wtSGLT1). Extracellular, membrane-impermeant MTSES(-) and MTSET(+) had no effect on either cotransport or Na+ leak currents of wtSGLT1 but 9 mutants were affected by MTSES and/or MTSET. We also performed fluorescent labelling on SGLT1 mutants, using tetramethylrhodamine-5-maleimide and showed that positions 586, 588 and 624 were accessible. As amino acids 604 to 610 in SGLT1 have been proposed to form part of a phlorizin (Pz) binding site, we measured the K(i)(Pz) and K(m)(alphaMG) for wtSGLT1 and for cysteine mutants at positions 588, 605-608 and 625. Although mutants A605C, Y606C and D607C had slightly higher K(i)(Pz) values than wtSGLT1 with minimal changes in K(m)((alpha)MG), the effects were modest and do not support the original hypothesis. We conclude that the large, hydrophilic loop near the carboxyl terminus of SGLT1 is thus accessible to the external solution but does not appear to play a major part in the binding of phlorizin.     

Structure of tRNA dimethylallyltransferase: RNA modification through a channel

Dimethylallyltransferase (DMATase) transfers a five-carbon isoprenoid moiety from dimethylallyl pyrophosphate (DMAPP) to the amino group of adenosine at position 37 of certain tRNAs. Reported here are the crystal structures of Pseudomonas aeruginosa DMATase alone and in complex with pyrophosphate at 1.9 A resolution. Surprisingly, the enzyme possesses a central channel spanning the entire width of the enzyme. Both the accepting substrate tRNA and the donating substrate DMAPP appear to enter the channel from opposite sides in an ordered sequence, with tRNA first and DMAPP second, and the RNA modification reaction occurs in the middle of the channel once the two substrates have met. The structure of DMATase is homologous to a class of small soluble kinases involved in biosynthesis of nucleotide precursors for nucleic acids, indicating its possibly evolutionary origin. Furthermore, specific recognition of the pyrophosphate by a conserved loop in DMATase, similar to the P-loop commonly seen in diverse nucleotide-binding proteins, demonstrates that DMATase is structurally and mechanistically distinct from farnesyltransferase, another family of prenyltransferases involved in protein modification.     

Identity elements for specific aminoacylation of a tRNA by mammalian lysyl-tRNA synthetase bearing a nonspecific tRNA-interacting factor

Mammalian lysyl-tRNA synthetase (LysRS) has an N-terminal polypeptide chain extension appended to a prokaryotic-like synthetase domain. This extension, termed a tRNA-interacting factor (tIF), possesses a RNA-binding motif [KxxxK(K/R)xxK] that binds nonspecifically the acceptor TPsiC stem-loop domain of tRNA and provides a potent tRNA binding capacity to this enzyme. Consequently, native LysRS aminoacylates a RNA minihelix mimicking the amino acid acceptor stem-loop domain of tRNA(3)(Lys). Here, examination of minihelix recognition showed that mammalian LysRS aminoacylates RNA minihelices without specificity of sequence, revealing that none of the nucleotides from the acceptor TPsiC stem-loop domain are essential determinants of tRNA(Lys) acceptor identity. To test whether the tIF domain reduces the specificity of the synthetase with regard to complete tRNA molecules, aminoacylation of wild-type and mutant noncognate tRNAs by wild-type or N-terminally truncated LysRS was examined. The presence of the UUU anticodon of tRNA(Lys) appeared to be necessary and sufficient to transform yeast tRNA(Asp) or tRNA(i)(Met) into potent lysine acceptor tRNAs. Thus, nonspecific RNA-protein interactions between the acceptor stem of tRNA and the tIF domain do not relax the tRNA specificity of mammalian LysRS. The possibility that interaction of the full-length cognate tRNA with the synthetase is required to induce the catalytic center of the enzyme into a productive conformation is discussed.     

Mutagenesis of isopentenyl phosphate kinase to enhance geranyl phosphate kinase activity

Isopentenyl phosphate kinase (IPK) catalyzes the ATP-dependent phosphorylation of isopentenyl phosphate (IP) to form isopentenyl diphosphate (IPP) during biosynthesis of isoprenoid metabolites in Archaea. The structure of IPK from the archeaon Thermoplasma acidophilum (THA) was recently reported and guided the reconstruction of the IP binding site to accommodate the longer chain isoprenoid monophosphates geranyl phosphate (GP) and farnesyl phosphate (FP). We created four mutants of THA IPK with different combinations of alanine substitutions for Tyr70, Val73, Val130, and Ile140, amino acids with bulky side chains that limited the size of the side chain of the isoprenoid phosphate substrate that could be accommodated in the active site. The mutants had substantially increased GP kinase activity, with 20-200-fold increases in k(cat)(GP) and 30-130-fold increases in k(cat)(GP)/K(M)(GP) relative to those of wild-type THA IPK. The mutations also resulted in a 10(6)-fold decrease in k(cat)(IP)/K(M)(IP) compared to that of wild-type IPK. No significant change in the kinetic parameters for the cosubstrate ATP was observed, signifying that binding between the nucleotide binding site and the IP binding site was not cooperative. The shift in substrate selectivity from IP to GP, and to a lesser extent, FP, in the mutants could act as a starting point for the creation of more efficient GP or FP kinases whose products could be exploited for the chemoenzymatic synthesis of radiolabeled isoprenoid diphosphates.     

Distinct isoprenoid origins of cis- and trans-zeatin biosyntheses in Arabidopsis

Plants produce the common isoprenoid precursors isopentenyl diphosphate and dimethylallyl diphosphate (DMAPP) through the methylerythritol phosphate (MEP) pathway in plastids and the mevalonate (MVA) pathway in the cytosol. To assess which pathways contribute DMAPP for cytokinin biosynthesis, metabolites from each isoprenoid pathway were selectively labeled with (13)C in Arabidopsis seedlings. Efficient (13)C labeling was achieved by blocking the endogenous pathway genetically or chemically during the feed of a (13)C labeled precursor specific to the MEP or MVA pathways. Liquid chromatography-mass spectrometry analysis demonstrated that the prenyl group of trans-zeatin (tZ) and isopentenyladenine is mainly produced through the MEP pathway. In comparison, a large fraction of the prenyl group of cis-zeatin (cZ) derivatives was provided by the MVA pathway. When expressed as fusion proteins with green fluorescent protein in Arabidopsis cells, four adenosine phosphate-isopentenyltransferases (AtIPT1, AtIPT3, AtIPT5, and AtIPT8) were found in plastids, in agreement with the idea that the MEP pathway primarily provides DMAPP to tZ and isopentenyladenine. On the other hand, AtIPT2, a tRNA isopentenyltransferase, was detected in the cytosol. Because the prenylated adenine moiety of tRNA is usually of the cZ type, the formation of cZ in Arabidopsis seedlings might involve the transfer of DMAPP from the MVA pathway to tRNA. Distinct origins of large proportions of DMAPP for tZ and cZ biosynthesis suggest that plants are able to separately modulate the level of these cytokinin species.     

Peptidase specificity characterization of C- and N-terminal catalytic sites of angiotensin I-converting enzyme

Quenched fluorescence peptides were used to investigate the substrate specificity requirements for recombinant wild-type angiotensin I-converting enzyme (ACE) and two full-length mutants bearing a single functional active site (N- or C-domain). We assayed two series of bradykinin-related peptides flanked by o-aminobenzoic acid (Abz) and N-(2,4-dinitrophenyl)ethylenediamine (EDDnp), namely, Abz-GFSPFXQ-EDDnp and Abz-GFSPFRX-EDDnp (X = natural amino acids), in which the fluorescence appeared when Abz/EDDnp are separated by substrate hydrolysis. Abz-GFSPFFQ-EDDnp was preferentially hydrolyzed by the C-domain while Abz-GFSPFQQ-EDDnp exhibits higher N-domain specificity. Internally quenched fluorescent analogues of N-acetyl-SDKP-OH were also synthesized and assayed. Abz-SDK(Dnp)P-OH, in which Abz and Dnp (2,4-dinitrophenyl) are the fluorescent donor-acceptor pair, was cleaved at the D-K(Dnp) bond with high specificity by the ACE N-domain (k(cat)/K(m) = 1.1 microM(-)(1) s(-)(1)) being practically resistant to hydrolysis by the C-domain. The importance of hydroxyl-containing amino acids at the P(2) position for N-domain specificity was shown by performing the kinetics of hydrolysis of Abz-TDK(Dnp)P-OH and Abz-YDK(Dnp)P-OH. The peptides Abz-YRK(Dnp)P-OH and Abz-FRK(Dnp)P-OH which were hydrolyzed by wild-type ACE with K(m) values of 5.1 and 4.0 microM and k(cat) values of 246 and 210 s(-)(1), respectively, have been shown to be excellent substrates for ACE. The differentiation of the catalytic specificity of the C- and N-domains of ACE seems to depend on very subtle variations on substrate-specific amino acids. The presence of a free C-terminal carboxyl group or an aromatic moiety at the same substrate position determines specific interactions with the ACE active site which is regulated by chloride and seems to distinguish the activities of both domains.     

The RNA-binding PUA domain of archaeal tRNA-guanine transglycosylase is not required for archaeosine formation

Bacterial tRNA-guanine transglycosylase (TGT) replaces the G in position 34 of tRNA with preQ(1), the precursor to the modified nucleoside queuosine. Archaeal TGT, in contrast, substitutes preQ(0) for the G in position 15 of tRNA as the first step in archaeosine formation. The archaeal enzyme is about 60% larger than the bacterial protein; a carboxyl-terminal extension of 230 amino acids contains the PUA domain known to contact the four 3'-terminal nucleotides of tRNA. Here we show that the C-terminal extension of the enzyme is not required for the selection of G15 as the site of base exchange; truncated forms of Pyrococcus furiosus TGT retain their specificity for guanine exchange at position 15. Deletion of the PUA domain causes a 4-fold drop in the observed k(cat) (2.8 x 10(-3) s(-1)) and results in a 75-fold increased K(m) for tRNA(Asp)(1.2 x 10(-5) m) compared with full-length TGT. Mutations in tRNA(Asp) altering or abolishing interactions with the PUA domain can compete with wild-type tRNA(Asp) for binding to full-length and truncated TGT enzymes. Whereas the C-terminal domains do not appear to play a role in selection of the modification site, their relevance for enzyme function and their role in vivo remains to be discovered.     

Genetic evidence for the role of isopentenyl diphosphate isomerases in the mevalonate pathway and plant development in Arabidopsis

Isopentenyl/dimethylallyl diphosphate isomerase (IPI) catalyzes the interconversion of isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP), which are the universal C(5) units of isoprenoids. In plants, IPP and DMAPP are synthesized via the cytosolic mevalonate (MVA) and plastidic methylerythritol phosphate (MEP) pathways, respectively. However, the role of IPI in each pathway and in plant development is unknown due to a lack of genetic studies using IPI-defective mutants. Here, we show that the atipi1atipi2 double mutant, which is defective in two Arabidopsis IPI isozymes, exhibits dwarfism and male sterility under long-day conditions and decreased pigmentation under continuous light, whereas the atipi1 and atipi2 single mutants are phenotypically normal. We also show that the sterol and ubiquinone levels in the double mutant are <50% of those in wild-type plants, and that the male-sterile phenotype is chemically complemented by squalene, a sterol precursor. In vivo isotope labeling experiments using the atipi1atipi2 double mutant revealed a decrease in the incorporation of MVA (in its lactone form) into sterols, with no decrease in the incorporation of MEP pathway intermediates into tocopherol. These results demonstrate a critical role for IPI in isoprenoid biosynthesis via the MVA pathway, and they imply that IPI is essential for the maintenance of appropriate levels of IPP and DMAPP in different subcellular compartments in plants.     

The Kluyveromyces lactis gamma-toxin targets tRNA anticodons

Kluyveromyces lactis killer strains secrete a heterotrimeric toxin (zymocin), which causes an irreversible growth arrest of sensitive yeast cells. Despite many efforts, the target(s) of the cytotoxic gamma-subunit of zymocin has remained elusive. Here we show that three tRNA species tRNA(Glu)(mcm(5)s(2)UUC), tRNA(Lys)(mcm(5)s(2)UUU), and tRNA(Gln)(mcm(5)s(2)UUG) are the targets of gamma-toxin. The toxin inhibits growth by cleaving these tRNAs at the 3' side of the modified wobble nucleoside 5-methoxycarbonylmethyl-2-thiouridine (mcm(5)s(2)U). Transfer RNA lacking a part of or the entire mcm(5) group is inefficiently cleaved by gamma-toxin, explaining the gamma-toxin resistance of the modification-deficient trm9, elp1-elp6, and kti11-kti13 mutants. The K. lactis gamma-toxin is the first eukaryotic toxin shown to target tRNA.     

Mutants of Salmonella typhimurium with an Altered Leucyl-Transfer Ribonucleic Acid Synthetase

Two trifluoroleucine-resistant mutants of Salmonella typhimurium, strains CV69 and CV117, had an altered leucyl-transfer ribonucleic acid (tRNA) synthetase. The mutant enzymes had higher apparent K(m) values for leucine (ca. 10-fold) and lower specific activities (ca. twofold) than the parent enzyme when tested in crude extracts. Preparations of synthetase purified ca. 60-fold from the parent and strain CV117 differed sixfold in their leucine K(m) values. In addition, the mutant enzyme was inactivated faster than the parent enzyme at 50 C. The growth rates of strains CV69 and CV117 at 37 C were not significantly different from that of the parent, whereas at 42 C strain CV69 grew more slowly than the parent. Leucine-, valine-, and isoleucine-forming enzymes were partially derepressed when the mutants were grown in minimal medium; the addition of leucine repressed these enzymes to wild-type levels. During growth in minimal medium, the proportion of leucine tRNA that was charged in the mutants was about 75% of that in the parent. The properties of strain CV117 were shown to result from a single mutation located near gal at minute 18 on the genetic map. These studies suggest that leucyl-tRNA synthetase is involved in repression of the enzymes required for the synthesis of branched-chain amino acids.     

Sequence specificity and role of proximal amino acids of the histone H3 tail on catalysis of murine G9A lysine 9 histone H3 methyltransferase

The activity of recombinant murine G9a toward lysine 9 of histone H3 was investigated. GST fusion proteins containing various lengths of the histone H3 amino-terminal tail were used as substrates in the presence of recombinant G9a enzyme and AdoMet cosubstrate. The minimal substrate methylated by G9a contained seven amino acids (TARKSTG) of the histone H3 tail. Furthermore, mutational analysis of the minimal substrate was performed to identify the amino acids essential for G9a-mediated methylation. All amino acids except Thr-11 were indispensable for the methylation reaction. Steady-state kinetic analysis of the wild-type and histone H3 point mutants, lysine 4 changed to alanine (K4A) or lysine 27 changed to alanine (K27A), with purified G9a revealed similar catalytic efficiency but a reduction in turnover number (k(cat)) from 78 to 58 h(-)(1). G9a methylated synthetic peptide substrates containing the first 13 amino acids of histone H3 efficiently, although methylation, acetylation, or mutation of proximal Lys-4 amino acids reduced Lys-9 methylation. The k(cat) for wild-type peptide substrate vs Lys-4 acetyl- or trimethyl-modified peptide were 88 and 32 h(-)(1), respectively, and the K(m) for the peptides varied from 0.6 to 2.2 muM, resulting in a large difference (15-91) in catalytic efficiency. Ser-10 or Thr-11 phosphorylation resulted in poor methylation by G9a. Immunoprecipitation of unmodified and Ser-10 and Thr-11 phosphorylated histone H3 displayed mostly Lys-4 dimethylation. Dimethylated Lys-9 was reduced in Ser-10 and Thr-11 immunoprecipitated phosphorylated histones as compared to nonphosphorylated H3. In an immunocytochemical assay, GFP fusion SUV39H1 or G9a did not colocalize with phosphorylated histone H3. Thus, Ser-10/Thr-11 phosphorylation impairs Lys-9 methylation. These data suggest that the sequence context of the modified residue affects G9a activity and the modification in the proximal amino acids influences methylation.