Interactions of derivatives of guanidinophenylalanine and guanidinophenylglycine with Streptomyces griseus trypsin

The rates of hydrolysis of the ester, amide and anilide substrates of p-guanidino-L-phenylalanine (GPA) by Streptomyces griseus trypsin (S. griseus trypsin) were compared with those of arginine (Arg) substrates. The specificity constant (kcat/km) for the hydrolysis of GPA substrates by the enzyme was 2-3-times lower than that for arginine substrates. The kcat and Km values for the hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalanine ethyl ester (Bz-GPA-OEt) by S. griseus trypsin are in the same order of magnitude as those of N alpha-benzoyl-L-arginine ethyl ester (Bz-Arg-OEt), although both values for the former when hydrolyzed by bovine trypsin are higher by one order of magnitude than those for the latter. The specificity constant for the hydrolysis of Bz-GPA-OEt by S. griseus trypsin is much higher than that for N alpha-benzoyl-p-guanidino-L-phenylglycine ethyl ester (Bz-GPG-OEt). As with the kinetic behavior of bovine trypsin, low values in Km and kcat were observed for the hydrolysis of amide and anilide substrates of GPA by S. griseus trypsin compared with those of arginine substrates. The rates of hydrolysis of GPA and arginine substrates by S. griseus trypsin are about 2- to 62-times higher than those obtained by bovine trypsin. Substrate activation was observed with S. griseus trypsin in the hydrolysis of Bz-GPA-OEt as well as Bz-Arg-OEt, whereas substrate inhibition was observed in three kinds of N alpha-protected anilide substrates of GPA and arginine. In contrast, no activation by the amide substrate of GPA could be detected with this enzyme.     

Porphyria-induced hepatic porphyrinogen carboxy-lyase inhibitor and its interaction with the active site(s) of the enzyme.

Porphyrinogen carboxy-lyase is an enzyme that sequentially decarboxylates uroporphyrinogen III (8-COOH) to yield coproporphyrinogen III (4-COOH). In mammals this enzyme activity is impaired by hexachlorobenzene treatment, through generation of an enzyme inhibitor. The interaction of porphyrinogen carboxy-lyase inhibitor, extracted from the liver of hexachlorobenzene-treated rats, with substrate decarboxylation sites on the enzyme, was studied using four different carboxylated substrates belonging to the isomeric III series of naturally-formed porphyrinogens containing 8-,7-,6- and 5-COOH. Similar inhibitor effects were elicited against all the substrates assayed, with the exception of pentacarboxyporphyrinogen III in which decarboxylation was not inhibited to same extent. Enzyme protection assays in the presence of the different substrates, indicated that each porphyrinogen protects its own decarboxylation from inhibitor action. Preincubation of the inhibitor with normal enzyme increased its inhibitory effect. On the other hand, preincubation of both enzyme and inhibitor with superoxide dismutase or mannitol, did not alter inhibitory activity. Preincubation of the inhibitor with a number of amino acids showed that only arginine and its derivative N alpha-Benzoyl-L-Arginine ethyl ester interact with the inhibitor, noticeably reducing its ability to inhibit porphyrinogen carboxy-lyase. Albumin, histidine, serine, cysteine and imidazol, were unable to quench inhibitor activity. The present results indicate that the inhibitor acts at the binding site of each porphyrinogen. Taking into account that arginine is related to enzyme activity, and that histidine is found at the binding site of the substrates, the results suggest that the inhibitor could bind to arginine residues, blocking the access of substrates to histidine and altering the adequate orientation for decarboxylation by masking the positively charged active site necessary for porphyrinogen binding to the enzyme. In addition an indirect effect of the inhibitor mediated through free radicals could be discarded.     

l-amino acid oxidases of Proteus rettgeri.

Proteus rettgeri has been found to contain two separable 1-amino acid oxidases. Both enzymes are particulate in nature, neither being ribosomal bound. One of these enzymes appears to have broad specificity, being active toward monoaminomonocarboxylic, imino, aromatic, sulfur-containing, and beta-hydroxyamino acids. The other enzyme has more limited specificity, catalyzing the oxidative deamination of the basic amino acids and citrulline. The affinity of this oxidase for the various substrates at pH 7.6 in decreasing order is arginine, histidine, ornithine, citrulline, and lysine. This enzyme has a particularly high affinity for arginine (Km equal to 0.27 mM), and anomalous kinetics are observed with increasing substrate concentrations. When concentrations of arginine greater than 1.0mM were added to the reaction containing histidine, imidazole pyruvate formation was completely inhibited.     

Peptide thioesters and 4-nitroanilides as substrates for porcine pancreatic kallikrein

A series of 14 4-nitroanilide substrates and 17 thioester substrates have been used to measure kinetic constants with porcine pancreatic kallikrein. All of the substrates have a P1 arginine residue. The 4-nitroanilide substrates consist of seven P2-glycine and seven P2-phenylalanine tripeptides. As expected from previous results, the phenylalanine series substrates were generally 100-fold 'better' than those in the glycine series. The S3 subsite was found to 'prefer' lysine or phenylalanine, whereas glutamic acid in this position was distinctly unfavourable. The thioester substrates consisted of various thioester derivatives of arginine as well as 12 dipeptides. These substrates exhibited kcat./Km values generally 1000 times higher than the P2-phenylalanine 4-nitroanilides. With the thioesters, a P2 phenylalanine or tryptophan residue yielded the best substrates, but some of the simple derivatives of arginine were nearly as good. A comparison of the kinetic constants of the thioester substrates between the porcine enzyme and human plasma kallikrein provides further evidence that these enzymes have a similar preference for bulky P2 residues, but otherwise are quite different enzymes. The thioester substrates are nearly as reactive as oxygen ester substrates such as acetylphenylalanylarginine methyl ester for the porcine enzyme [Levison & Tomalin (1982) Biochem. J. 203, 299-302; Fiedler (1983) Adv. Exp. Med. Biol. 156A, 263-274], and owing to the greater ease in assaying with the thioesters, they should find use in routine assays for the glandular kallikreins.     

Purification and characterization of arginine kinase from the American cockroach (Periplaneta americana)

The isolation and characterization of homogeneous arginine kinase from the cockroach is reported. The purification protocol produces 6.6 mg of pure enzyme from 6.8 g of whole cockroach. The purified enzyme cross-reacts with a heterologous antibody and monoclonal antibody against arginine kinase from the shrimp. Both antibody preparations also cross-react with extracts from several species known to contain monomeric arginine kinase, but fail to react with extracts from organisms containing dimeric arginine kinase. Cockroach arginine kinase has a molecular mass of approximately 43,000 determined from measurements by gel filtration and gel electrophoresis. Compared with other arginine kinases, the enzyme from the cockroach is relatively thermostable (50% activity retained at 50 degrees C for 10 min) and has a pH optima of 8.5 and 6.5-7.5, for the forward and reverse reactions, respectively. Treatment with 5,5'dithiobis[2-nitrobenzoic acid] indicates that arginine kinase has a single reactive sulfhydryl group and, interestingly, the reaction is biphasic. The Michaelis constants for the phosphagen substrates, arginine: 0.49 mM, phosphoarginine: 0.94 mM, and nucleotide substrates MgATP: 0.14 mM, MgADP: 0.09 mM, are in the range reported for other arginine kinases. A 1% solution of pure enzyme has an absorbance of 7.0 at 280 nm. Calculations based on circular dichroic spectra indicate that arginine kinase from the cockroach has 12% alpha-helical structure. The intrinsic protein fluorescence emission maximum at 340 nm suggests that tryptophan residues are below the surface of the protein and not exposed to solvent. Arginine kinase from the cockroach and shrimp are known to be deleterious immunogens towards humans. The availability of pure protein, its characterization and potential regulation of activity, will be useful in developing agents to control the cockroach population and its destructive role in agriculture and human health.     

Characterizations of acylagmatine amidohydrolase and carboxypeptidase from Fusarium anguioides.

Previously an enzyme, named acylagmatine amidohydrolase, hydrolyzing bleomycin B2 to bleomycinic acid and agmatine was found in the mycelia of Fusarium anguioides Sherbakoff. In this work the enzyme was purified further, but not completely. The crude enzyme preparation hydrolyzed various acylagmatines and also peptidyl arginine, but the latter activity could be separated from acylagmatine amidohydrolase activity by gel filtration on Sephadex G-100. The enzyme was inhibited by PCMB and its molecular weight was estimated as 65,000 by gel filtration. It showed substrate specificity with respect to the alkyl-chain length of the amine moiety. The other hydrolase fraction with activity toward Bz-Gly-Arg was found to be of a sort of carboxypeptidase, which preferentially hydrolyzed peptides with arginine or lysine at the carboxyl terminus, including bradykinin, but liberated neutral amino acids as well from the terminus when the penultimate residue of the substrates was phenylalanine. With Bz-Gly-Arg as substrate Fusarium carboxypeptidase was sensitive to chelating agents but not to diisopropyfluorophosphate, and its molecular weight was estimated to be 145,000.     

Analysis of the importance of arginine 102 in neutral endopeptidase (enkephalinase) catalysis.

Neutral endopeptidase 24.11 contains an active site arginine believed to function in substrate binding. This arginine is thought to form an ionic interaction with the COOH-terminal carboxylate of NEP substrates. The functionality of arginine 102 has been investigated by using site-directed mutagenesis to produce mutants in which this residue was converted to a lysine, glycine, glutamine, or glutamate. All of the mutants exhibited essentially full activity as determined with a synthetic peptide amide, glutaryl-Ala-Ala-Phe-4-methoxy-2-naphthylamide. In contrast, activity was detected only with the wild-type enzyme and the lysine mutant using a synthetic substrate containing a free COOH-terminal carboxylate, dansyl-Gly-Trp-Gly. Inhibition studies with the physiologically active peptide substrates substance P, endothelin, and angiotensin I, as well as substance P free acid, [D-Ala2,Leu5]enkephalin, and [D-Ala2,Leu5]enkephalinamide indicated a lack of importance of arginine 102 in substrate binding. With [D-Ala2,Met5]enkephalin and the chemotactic peptide, N-formyl-Met-Leu-Phe, a significant decrease in affinity is observed with the arginine 102 mutants. These results suggest that the contribution of arginine 102 to substrate binding is dependent upon the strength of other subsite interactions. Examination of dipeptides as inhibitors indicates that the nature and orientation of the P'2 residue is important in determining the strength of the interaction of arginine 102 with its substrates.     

Kinetics of hydrolysis of amide and anilide substrates of p-guanidino-L-phenylalanine by bovine and porcine trypsins

The rates of hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalaninamide (Bz-GPA-NH2) and N alpha-substituted p-nitroanilides (pNA) of GPA (benzyloxycarbonyl(Z)-GPA-pNA, benzoyl(Bz)-GPA-pNA and acetyl(Ac)-GPA-pNA) by bovine and porcine trypsins were compared with those of arginine (Arg) substrates. The amide type substrates of GPA were hydrolyzed as fast as those of Arg by the two enzymes with much the same kcat/Km values, though significant differences were found between the kcat and Km values of GPA derivatives and those of Arg derivatives. The kinetic behavior of porcine trypsin toward GPA substrates was almost the same as that of the bovine enzyme. The ratio of the kcat value for Bz-GPA-OEt to that for Bz-GPA-NH2 was much larger than that for the ester to amide substrates of arginine, suggesting that the conformational change of the active site of trypsin induced by a benzene ring in the side chain of Bz-GPA-OEt specifically increases the velocity of the deacylation process of the ester substrate. Remarkably low values of both kcat and Km were found for the tryptic hydrolysis of Z-GPA-pNA and Ac-GPA-pNA, as well as on that of Bz-GPA-pNA (Tsunematsu, H., et al. (1983) J. Biochem. 94, 123-128). Z-GPA-pNA is the best substrate for the two trypsins among the three N alpha-substituted anilide substrates of GPA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the coagulant enzyme from Agkistrodon rhodostoma venom. Isolation and some properties of the enzyme

1. Arvin, a commercial preparation of the coagulant activity from the venom of Agkistrodon rhodostoma, is shown to contain a non-coagulant caseinolytic fraction. 2. A method is described for the purification of the coagulant enzyme free from any detectable contaminating protein. 3. The coagulant enzyme is identified as a glycoprotein which probably consists of a single polypeptide chain containing approx. 29% by weight of carbohydrate. Amino acid and carbohydrate analyses are reported and the N- and C-terminal amino acid residues identified. 4. Electrophoresis on polyacrylamide gel reveals the polymorphic nature of the glycoprotein. Five forms of the enzyme are observed. 5. The coagulant action is correlated with an arginine esterase activity and kinetic properties are studied with both arginine and lysine esters as substrates. The inhibitory nature of guanidine and arginine toward the esterase activity is reported.     

An amino acid at position 142 in nitrilase from Rhodococcus rhodochrous ATCC 33278 determines the substrate specificity for aliphatic and aromatic nitriles

Nitrilase from Rhodococcus rhodochrous ATCC 33278 hydrolyses both aliphatic and aromatic nitriles. Replacing Tyr-142 in the wild-type enzyme with the aromatic amino acid phenylalanine did not alter specificity for either substrate. However, the mutants containing non-polar aliphatic amino acids (alanine, valine and leucine) at position 142 were specific only for aromatic substrates such as benzonitrile, m-tolunitrile and 2-cyanopyridine, and not for aliphatic substrates. These results suggest that the hydrolysis of substrates probably involves the conjugated pi-electron system of the aromatic ring of substrate or Tyr-142 as an electron acceptor. Moreover, the mutants containing charged amino acids such as aspartate, glutamate, arginine and asparagine at position 142 displayed no activity towards any nitrile, possibly owing to the disruption of hydrophobic interactions with substrates. Thus aromaticity of substrate or amino acid at position 142 in R. rhodochrous nitrilase is required for enzyme activity.     

Evidence for an essential arginine residue at the active site of ATP citrate lyase from rat liver.

Rat liver ATP citrate lyase was inactivated by 2, 3-butanedione and phenylglyoxal. Phenylglyoxal caused the most rapid and complete inactivation of enzyme activity in 4-(2-hydroxyethyl)-1-piperazine-ethanesulphonic acid buffer, pH 8. Inactivation by both butanedione and phenylglyoxal was concentration-dependent and followed pseudo- first-order kinetics. Phenylglyoxal also decreased autophosphorylation (catalytic phosphate) of ATP citrate lyase. Inactivation by phenylglyoxal and butanedione was due to the modification of enzyme arginine residues: the modified enzyme failed to bind to CoA-agarose. The V declined as a function of inactivation, but the Km values were unaltered. The substrates, CoASH and CoASH plus citrate, protected the enzyme significantly against inactivation, but ATP provided little protection. Inactivation with excess reagent modified about eight arginine residues per monomer of enzyme. Citrate, CoASH and ATP protected two to three arginine residues from modification by phenylglyoxal. Analysis of the data by statistical methods suggested that the inactivation was due to modification of one essential arginine residue per monomer of lyase, which was modified 1.5 times more rapidly than were the other arginine residues. Our results suggest that this essential arginine residue is at the CoASH binding site.     

Interactions between Escherichia coli arginyl-tRNA synthetase and its substrates

Interactions between Escherichia coli arginyl-tRNA synthetase and its substrates were extensively studied and distinctly demonstrated. Various approaches such as equilibrium dialysis, fluorescence titration, and substrate protection against heat inactivation of the enzyme were used for these studies. In the absence of other substrates, the equilibrium dissociation constants for arginine, ATP, and the cognate tRNA were about 70 microM, 0.85 mM, and 0.45 microM, respectively, at pH 7.5, in Tris buffer. The binding of arginine to the enzyme was affected neither by the presence of tRNA nor by the presence of ATP but was considerably enhanced when ATP and tRNA were both present at saturating concentrations. The dissociation constant in this case (about 16 microM) was very close to the Km (12 microM) for arginine during aminoacylation. The binding of ATP (the equilibrium dissociation constant KD approximately 0.85 mM) was not affected by the presence of arginine but was depressed in the presence of tRNA (KD became 3 mM). Arginyl-tRNA showed a dissociation constant of (4-5) X 10(-7) M which was not affected by the presence of a single other substrate. Possible explanations for the high Km for tRNA in the aminoacylation are discussed. Our results indicated pronounced interactions between substrates mediated by the enzyme under catalytic conditions. Periodate oxidation did not alter the tRNA binding to the enzyme. The oxidized tRNA still afforded protection against heat inactivation of the enzyme.     

An Arginine Specific Protease from Spirulina platensis

An arginine specific protease, Sp-protease, was purified by column chromatography from freeze-dried Spirulina platensis using a five-step process. Purified Sp-protease has a molecular weight of 80 kDa. It hydrolyzed the synthetic substrates containing arginine residue in the P1 position but did not hydrolyze synthetic substrates containing other amino acid residues, including lysine residue in the P1 position. Among the synthetic substrates tested, a substrate of plasminogen activator (Pyr-Gly-Arg-MCA) was hydrolyzed most effectively with the enzyme (K_m = 5.5 × 10⁻⁶ M), and fibrin gel was solubilized via activation of intrinsic plasminogen to plasmin with the enzyme. Activity was inhibited completely with camostat mesilate (K_i = 1.1 × 10⁻⁸ M) and leupeptin (K_i = 3.9 × 10⁻⁸ M) but was not inhibited with N^α-tosyl-L-lysine chloromethyl ketone (TLCK). The optimum pH of the enzyme has a range of pH 9.0 to pH 11.0. The optimum temperature was 50°C; the enzyme was stable at 0–50°C.     

Identification of the active-site arginine in rat neutral endopeptidase 24.11 (enkephalinase) as arginine 102 and analysis of a glutamine 102 mutant

Neutral endopeptidase 24.11 contains an active-site arginine residue involved in binding the free carboxylate of substrate peptides and inhibitors. This arginine reacts rapidly with [14C]phenylglyoxal, and its reaction is selectively blocked by the presence of either the substrate Met5-enkephalin, the competitive inhibitor phenylalanylalanine, or the transition state analog phosphoramidon. The phenylglyoxal-modified peptide was isolated by a procedure involving limited digestion by trypsin, separation of the tryptic peptides by high pressure liquid chromatography (HPLC), further digestion of the modified peptide by pepsin, and a final purification by HPLC. By this procedure arginine 102 was identified as the active-site arginine. Verification of this finding came from the use of site-directed mutagenesis in which this arginine was replaced by glutamine. Both the mutant and wild-type enzyme reacted equally well with an amide containing substrate, glutaryl-Ala-Ala-Phe-4-methoxy-2-naphthylamide. However, reaction of the mutant enzyme with a substrate containing a free COOH-terminal carboxylate, 5-dimethylaminonaphthalene-1-sulfonyl-D-Ala-Gly-(NO2)Phe-Gly, was barely detectable with the mutant enzyme. Similarly the mutant enzyme showed a loss of selectivity in inhibition by D-Ala2-Met5-enkephalin compared to the corresponding amide but exhibited no difference in the maximal velocity for hydrolysis of D-Ala2-Met5-enkephalin and its amide.     

Induction of differentiation of cultured mouse myeloid leukemic cells by arginase.

Mouse myeloid leukemic cells (Ml) could be induced by a factor in ascitic fluid to phagocytize, migrate in agar, and change into forms that were morphologically similar to macrophages and granulocytes. Arginase also induced these differentiation-associated properties of the cells. The Ml cells did not differentiate in culture medium containing arginine, but they differentiated into macrophages and granulocytes during culture in arginine-deficient culture medium. Therefore, the effect of arginase may be attribute to arginase-mediated arginine depletion.     

An aminopeptidase activity in bovine pituitary secretory vesicles that cleaves the N-terminal arginine from beta-lipotropin60-65

Secretory vesicles isolated from the neural and intermediate lobes of the bovine pituitary contained a membrane-bound aminopeptidase activity which cleaved arginine from beta-LPH60-65 (Arg-Tyr-Gly-Gly-Phe-Met) and Arg-MCA. Neither methionine enkephalin (Tyr-Gly-Gly-Phe-Met) nor Substance P, which has an N-terminal arginine followed by a proline, could serve as substrates for this aminopeptidase activity; nor could cathepsin B-like or chymotrypsin-like enzyme activities be detected in the vesicle preparations. Maximal enzyme activity was at pH 6.0, and the activity was inhibited by EDTA, stimulated by Co2+ and Zn2+, but was unaffected by leupeptin, pepstatin A, phenylmethylsulfonyl fluoride and p-chloromercuribenzenesulfonate, suggesting that the enzyme is a metalloaminopeptidase. The presence of this aminopeptidase activity in secretory vesicles suggests that it may be involved in peptide prohormone processing.     

A new latent arginine esteropeptidase from human submaxillary gland

One of the arginine esteropeptidases in human submaxillary gland was purified from microsomal membranes. The enzyme is inactive in membranes and requires trypsin treatment for its full activation. The trypsin-activated enzyme was purified to homogeneity. Its molecular weight was determined to be 94,000 by SDS-polyacrylamide gel electrophoresis. Among various substrates examined, the obtained enzyme exhibited high specific activities toward Tos-Arg-OMe (esterolysis) and D-Ile-Pro-Arg-pNA (amidolysis). The enzyme was inhibited by some serine proteinase inhibitors, whereas inhibitors of other types of proteinases did not affect or only scarcely affected it. The enzyme appears to be distinct from other arginine esteropeptidases previously described.     

Acetylhistidine as substrate for acetylornithinase: a new system for the selection of arginine regulation mutants in Escherichia coli

Summary The utilisation of acetylhistidine by histidine auxotrophs of E. coli K-12 was found to require a functioning acetylornithinase. The growth, on acetylhistidine-containing media, of his mutants possessing this enzyme was inhibited by arginine or its precursors acetylornithine, ornithine and citrulline. Mutants able to overcome this inhibition belonged to two classes: those (selected on acetylhistidine+acetylornithine or arginine) in which the arginine biosynthetic enzymes were repressible, as in the parent strains; and those (selected on acetylhistidine+acetylornithine, ornithine, citrulline or arginine) in which these enzymes were formed at high, non-repressible levels. The altered properties of the first class were shown genetically not to result from mutation in the argR or argECBH regions; the data are consistent with the second class carrying mutations at the argR locus.It is supposed that arginine, ornithine or citrulline, by repressing the formation of acetylornithinase, diminish the rate at which acetylhistidine can be utilised (although an acetylhistidine uptake system under arginine control would equally explain the results); non-repressible mutants would escape this effect. The kinetic properties, in crude extracts, of acetylornithinase from the parent strains and from members of each mutant class, with acetylornithine and acetylhistidine as substrates, were investigated. It was tentatively concluded that, in accord with the genetic results, the first class do not possess an acetylornithinase altered to make it function better with acetylhistidine as substrate. It is suggested that arginine may affect acetylhistidine utilisation by affecting its uptake in a manner not shared with ornithine or citrulline, as well as by repressing proteins of the arginine system, and that this arginine-specific effect is inoperative in the first class of mutants. The nature of the changes leading to ability to grow on acetylhistidine+acetylornithine remains unknown. Possible applications of these findings to the selection of hitherto undiscovered but potentially informative mutant types are discussed.     

Studies on (K+ + H+)-ATPase. I. Essential arginine residue in its substrate binding center

1. A membrane vesicle fraction containing a high (K+ + H+)-ATPase activity was isolated from porcine gastric mucosa. The enzyme has a pH optimum of 7.0 and is stimulated by T1+, K+, Rb+ and NH4+ with KA values of 0.13, 2.7, 7.6 and 26 mM, respectively, at this pH. 2. Incubation of the isolated membrane fraction with butanedione leads to inactivation of the (K+ + H+)-ATPase activity. The pH-dependence of the (K+ + H+)-ATPase activity. The pH-dependence of the inactivation and the reversibility of the reaction, observed after removal of excess butanedione and borate, indicate that modification of arginine is involved. 3. The inactivation of (K+ + H+)-ATPase activity by butanedione is time-dependent and follows second-order kinetics. From the dependence of the inactivation rate on the reagent concentration it appears that a single arginine residue is involved in the inactivation of the (K+ + H+)-ATPase activity. 4. ATP, deoxy-ATP, ADP and adenylyl imidodiphosphate (AMPPNP), but not CTP, GTP and ITP which are poor substrates, protect the enzyme against butanedione inactivation, suggesting that the essential arginine residue is located in the ATP binding centre. 5. In the presence of Mg2+ the butanedione inactivation is increased, and the protection by ATP, deoxy-ATP and ADP (but not that by AMPPNP) is less pronounced. This suggests that Mg2+ induces a conformational change in the enzyme, exposing the arginine group and coinciding with phosphorylation and subsequent release of ADP from its binding site.     

Unique Features of Human Protein Arginine Methyltransferase 9 (PRMT9) and Its Substrate RNA Splicing Factor SF3B2

Human protein arginine methyltransferase (PRMT) 9 symmetrically dimethylates arginine residues on splicing factor SF3B2 (SAP145) and has been functionally linked to the regulation of alternative splicing of pre-mRNA. Site-directed mutagenesis studies on this enzyme and its substrate had revealed essential unique residues in the double E loop and the importance of the C-terminal duplicated methyltransferase domain. In contrast to what had been observed with other PRMTs and their physiological substrates, a peptide containing the methylatable Arg-508 of SF3B2 was not recognized by PRMT9 in vitro. Although amino acid substitutions of residues surrounding Arg-508 had no great effect on PRMT9 recognition of SF3B2, moving the arginine residue within this sequence abolished methylation. PRMT9 and PRMT5 are the only known mammalian enzymes capable of forming symmetric dimethylarginine (SDMA) residues as type II PRMTs. We demonstrate here that the specificity of these enzymes for their substrates is distinct and not redundant. The loss of PRMT5 activity in mouse embryo fibroblasts results in almost complete loss of SDMA, suggesting that PRMT5 is the primary SDMA-forming enzyme in these cells. PRMT9, with its duplicated methyltransferase domain and conserved sequence in the double E loop, appears to have a unique structure and specificity among PRMTs for methylating SF3B2 and potentially other polypeptides.