Tyrosyl-tRNA synthetase from wheat germ

Tyrosyl-tRNA synthetase (TyrRS) was purified 5,000-fold from wheat germ extract by ultracentrifugation, precipitation with ammonium acetate, and column chromatography. Under denaturing conditions the enzyme ran as a single band on SDS-polyacrylamide electrophoresis with an apparent Mr of 55,000. The native molecular weight determined by gel filtration was 110,000, suggesting a quaternary structure of an alpha 2 type for native TyrRS. Purified enzyme activity, based on the aminoacylation reaction, was studied in terms of Mg2+, ATP, pH, and KCl dependence. Optimum concentrations were 6 mM Mg2+, 4 mM ATP, and 200 mM KCl at pH 8. The Km values for ATP, tyrosine, and tRNA were 40, 3.3, and 1.5 microM, respectively. The instability of the TyrRS activity and the methods used for stabilizing it are discussed. In wheat germ extract we found a second tyrosylating activity that works with Escherichia coli tRNA, but not with wheat germ tRNA. We believe that this enzyme is the mitochondrial tyrosyl-tRNA synthetase of wheat germ.     

Protein engineering of homodimeric tyrosyl-tRNA synthetase to produce active heterodimers

Heterodimers of tyrosyl-tRNA synthetase from Bacillus stearothermophilus have been produced by mutagenesis at the subunit interface. Oppositely charged groups have been engineered into the subunits so that they can form a complementary pair. Wild-type tyrosyl-tRNA synthetase is a symmetrical dimer in which the side chains of the 2 Phe-164 residues interact at the subunit interface. Phe-164 was mutated to Asp in tyrosyl-tRNA synthetase and to Lys in a truncated enzyme (des-(321-419)tyrosyl-tRNA synthetase) which lacks the two tRNA-binding sites, but which can catalyze pyrophosphate exchange. The size difference allows subunit association to be studied by gel filtration chromatography. These changes induce reversible dissociation from active dimers into inactive monomers at pH values which favor ionization at position 164. A mixture of the two mutants near neutral pH is apparently fully active in pyrophosphate exchange and consists of a heterodimer of [Asp164]tyrosyl-tRNA synthetase and [Lys164]des-(321-419)tyrosyl-tRNA synthetase. Despite having only one binding site for tRNA, heterodimer has full aminoacylation activity at high concentrations of tyrosine. We have therefore produced a family of dimers that differ in stability near neutral pH. This novel approach using protein engineering allows specific dimerization of subunits of the same size that have different defined mutations, each subunit being tagged by the charge. Such hybrid proteins can be used to study subunit interaction.     

Macromolecular recognition through electrostatic repulsion.

In the process of genetic translation, each aminoacyl-tRNA synthetase specifically aminoacylates its cognate tRNAs and rejects the 19 other species of tRNAs. A decrease in the specificity of this reaction can result in misincorporations of amino acids into proteins and be deleterious to the cell. In the case of tyrosyl-tRNA synthetase from Bacillus stearothermophilus, the change of residue Glu152 into Ala results in erroneous interactions with non-cognate tRNAs. To analyse how Glu152 contributes to the discrimination between tRNAs by tyrosyl-tRNA synthetase, 11 changes to this residue were created by mutagenesis. The misaminoacylations of tRNA(Phe) and tRNA(Val) with tyrosine in vitro (on a scale going from 1 to 30) and the toxicity of tyrosyl-tRNA synthetase in vivo (on a scale from 1 to 10(7)) increased in a correlated way when the nature of the side chain in position 152 varied from negatively charged to uncharged then to positively charged. The aminoacylation of tRNA(Tyr) was unaffected by the mutations. The results show that the role of Glu152 in the discrimination between tRNAs is purely negative, that it acts by electrostatic repulsion of non-cognate tRNAs and that this mechanism has been conserved throughout evolution.     

Correlating amino acid conservation with function in tyrosyl-tRNA synthetase

Sequence comparisons have been combined with mutational and kinetic analyses to elucidate how the catalytic mechanism of Bacillus stearothermophilus tyrosyl-tRNA synthetase evolved. Catalysis of tRNA(Tyr) aminoacylation by tyrosyl-tRNA synthetase involves two steps: activation of the tyrosine substrate by ATP to form an enzyme-bound tyrosyl-adenylate intermediate, and transfer of tyrosine from the tyrosyl-adenylate intermediate to tRNA(Tyr). Previous investigations indicate that the class I conserved KMSKS motif is involved in only the first step of the reaction (i.e. tyrosine activation). Here, we demonstrate that the class I conserved HIGH motif also is involved only in the tyrosine activation step. In contrast, one amino acid that is conserved in a subset of the class I aminoacyl-tRNA synthetases, Thr40, and two amino acids that are present only in tyrosyl-tRNA synthetases, Lys82 and Arg86, stabilize the transition states for both steps of the tRNA aminoacylation reaction. These results imply that stabilization of the transition state for the first step of the reaction by the class I aminoacyl-tRNA synthetases preceded stabilization of the transition state for the second step of the reaction. This is consistent with the hypothesis that the ability of aminoacyl-tRNA synthetases to catalyze the activation of amino acids with ATP preceded their ability to catalyze attachment of the amino acid to the 3' end of tRNA. We propose that the primordial aminoacyl-tRNA synthetases replaced a ribozyme whose function was to promote the reaction of amino acids and other small molecules with ATP.     

Tyrosyl-tRNA-synthetase from bovine liver. Functional role of histidine residues]

A specific chemical modification of histidyl residues in tyrosyl-tRNA synthetase by diethyl pyrocarbonate was performed. It is shown that five of sixteen histidyl residues can react with diethyl pyrocarbonate in the native conditions. Modification of two histidyl residues per dimer results in the inactivation of tyrosyl-tRNA synthetase in both steps of the tRNATyr aminoacylation. All substrates protect tyrosyl-tRNA synthetase against inactivation with diethyl pyrocarbonate, the most effective protector being combination of ATP and tyrosine. Histidyl residues of tyrosyl-tRNA synthetase are suggested to be involved in the catalytic mechanism of aminoacylation of tRNATyr.     

Expression,purification, and characterization of human tyrosyl-tRNA synthetase

Human tyrosyl-tRNA synthetase is a homodimeric enzyme and each subunit is near 58 KD. It catalyzes the aminoacylation of tRNA(Tyr) by L-tyrosine. The His(6)-tagged human TyrS gene was obtained by RT-PCR from total RNA of human lung giant-cell cancer strain 95 D. It was confirmed by sequencing and cloned into the expression vector pET-24 a (+) to yield pET-24 a (+)-HTyrRS, which was transfected into Escherichia coli BL21-CodonPlus-RIL. The induced-expression level of His(6)-tagged human TyrRS was about 24% of total cell proteins under IPTG inducing. The recombinant protein was conveniently purified in a single step by metal (Ni(2+)) chelate affinity chromatography. About 22.3mg purified enzyme could be obtained from 1L cell culture. The k(cat) value of His(6)-tagged human TyrRS in the second step of tRNA(Tyr) aminoacylation was 1.49 s(-1). The K(m) values of tyrosine and tRNA(Tyr) were 0.3 and 0.9 microM. Six His residues at the C terminus of human TyrRS have little effect on the activities of the enzyme compared with other eukaryotic TyrRSs.     

The 'KMSKS' motif in tyrosyl-tRNA synthetase participates in the initial binding of tRNA(Tyr)

Variants at each position of the 'KMSKS' signature motif in tyrosyl-tRNA synthetase have been analyzed to test the hypothesis that this motif is involved in catalysis of the second step of the aminoacylation reaction (i.e., the transfer of tyrosine from the enzyme-bound tyrosyl-adenylate intermediate to the tRNA(Tyr) substrate). Pre-steady-state kinetic studies show that while the rate constants for tyrosine transfer (k(4)) are similar to the wild-type value for all of the mobile loop variants, the K230A and K233A variants have increased dissociation constants (K(d)(tRNA)( )()= 2.4 and 1.7 microM, respectively) relative to the wild-type enzyme (K(d)(tRNA)( )()= 0.39 microM). In contrast, the K(d)(tRNA) values for the F231L, G232A, and T234A variants are similar to that of the wild-type enzyme. The K(d)(tRNA) value for a loop deletion variant, Delta(227-234), is similar to that for the K230A/K233A double mutant variant (3.4 and 3.0 microM, respectively). Double mutant free energy cycle analysis indicates there is a synergistic interaction between the side chains of K230 and K233 during the initial binding of tRNA(Tyr) (DeltaDeltaG(int) = -0.74 kcal/mol). These results suggest that while the 'KMSKS' motif is important for the initial binding of tRNA(Tyr) to tyrosyl-tRNA synthetase, it does not play a catalytic role in the second step of the reaction. These studies provide the first kinetic evidence that the 'KMSKS' motif plays a role in the initial binding of tRNA(Tyr) to tyrosyl-tRNA synthetase.     

Competition of aminoacyl-tRNA synthetases for tRNA ensures the accuracy of aminoacylation.

The accuracy of protein biosynthesis rests on the high fidelity with which aminoacyl-tRNA synthetases discriminate between tRNAs. Correct aminoacylation depends not only on identity elements (nucleotides in certain positions) in tRNA (1), but also on competition between different synthetases for a given tRNA (2). Here we describe in vivo and in vitro experiments which demonstrate how variations in the levels of synthetases and tRNA affect the accuracy of aminoacylation. We show in vivo that concurrent overexpression of Escherichia coli tyrosyl-tRNA synthetase abolishes misacylation of supF tRNA(Tyr) with glutamine in vivo by overproduced glutaminyl-tRNA synthetase. In an in vitro competition assay, we have confirmed that the overproduction mischarging phenomenon observed in vivo is due to competition between the synthetases at the level of aminoacylation. Likewise, we have been able to examine the role competition plays in the identity of a non-suppressor tRNA of ambiguous identity, tRNA(Glu). Finally, with this assay, we show that the identity of a tRNA and the accuracy with which it is recognized depend on the relative affinities of the synthetases for the tRNA. The in vitro competition assay represents a general method of obtaining qualitative information on tRNA identity in a competitive environment (usually only found in vivo) during a defined step in protein biosynthesis, aminoacylation. In addition, we show that the discriminator base (position 73) and the first base of the anticodon are important for recognition by E. coli tyrosyl-tRNA synthetase.     

A continuous tyrosyl-tRNA synthetase assay that regenerates the tRNA substrate

Tyrosyl-tRNA synthetase catalyzes the attachment of tyrosine to the 3′ end of tRNA^Tyr, releasing AMP, pyrophosphate, and l-tyrosyl-tRNA as products. Because this enzyme plays a central role in protein synthesis, it has garnered attention as a potential target for the development of novel antimicrobial agents. Although high-throughput assays that monitor tyrosyl-tRNA synthetase activity have been described, these assays generally use stoichiometric amounts of tRNA, limiting their sensitivity and increasing their cost. Here, we describe an alternate approach in which the Tyr-tRNA product is cleaved, regenerating the free tRNA substrate. We show that cyclodityrosine synthase from Mycobacterium tuberculosis can be used to cleave the l-Tyr-tRNA product, regenerating the tRNA^Tyr substrate. Because tyrosyl-tRNA synthetase can use both l- and d-tyrosine as substrates, we replaced the cyclodityrosine synthase in the assay with d-tyrosyl-tRNA deacylase, which cleaves d-Tyr-tRNA. This substitution allowed us to use the tyrosyl-tRNA synthetase assay to monitor the aminoacylation of tRNA^Tyr by d-tyrosine. Furthermore, by making Tyr-tRNA cleavage the rate-limiting step, we are able to use the assay to monitor the activities of cyclodityrosine synthetase and d-tyrosyl-tRNA deacylase. Specific methods to extend the tyrosyl-tRNA synthetase assay to monitor both the aminoacylation and post-transfer editing activities in other aminoacyl-tRNA synthetases are discussed.     

Evidence for two types of complexes formed by yeast tyrosyl-tRNA synthetase with cognate and non-cognate tRNA. Effect of ribonucleoside triphosphates

Polyacrylamide gel electrophoresis at pH 8.3 was used to detect and quantitate the formation of the yeast tyrosyl-tRNA synthetase (an alpha 2-type enzyme) complex with its cognate tRNA. Electrophoretic mobility of the complex is intermediate between the free enzyme and free tRNA; picomolar quantities can be readily detected by silver staining and quantitated by densitometry of autoradiograms when [32P]tRNA is used. Two kinds of complexes of Tyr-tRNA synthetase with yeast tRNA(Tyr) were detected. A slower-moving complex is formed at ratios of tRNA(Tyr)/enzyme less than or equal to 0.5; it is assigned the composition tRNA.(alpha 2)2. At higher ratios, a faster-moving complex is formed, approaching saturation at tRNA(Tyr)/enzyme = 1; any excess of tRNA(Tyr) remains unbound. This complex is assigned the composition tRNA.alpha 2. The slower, i.e. tRNA.(alpha 2)2 complex, but not the faster complex, can be formed even with non-cognate tRNAs. Competition experiments show that the affinity of the enzyme towards tRNA(Tyr) is at least 10-fold higher than that for the non-cognate tRNAs. ATP and GTP affect the electrophoretic mobility of the enzyme and prevent the formation of tRNA.(alpha 2)2 complexes both with cognate and non-cognate tRNAs, while neither tyrosine, as the third substrate of Tyr tRNA synthetase, nor AMP, AMP/PPi, or spermidine, have such effects. Hence, the ATP-mediated formation of the alpha 2 structure parallels the increase in specificity of the enzyme towards its cognate tRNA.     

Effects of spermine and magnesium ions on the aminoacylation of yeast tRNA(Tyr)

Stimulatory effects of Mg2+ and spermine on the kinetics of the aminoacylation of tRNA(Tyr) were examined using purified yeast tRNA(Tyr) and tyrosyl-tRNA synthetase. The apparent Km for tRNA(Tyr) was the lowest at Mg2+ concentrations between 2 and 5 mM and was not influenced by spermine. In the absence of spermine, the apparent Vmax was the highest at Mg2+ concentrations of 5 mM or higher, whereas the presence of spermine strongly stimulated the reaction at lower Mg2+ concentrations. Spermine alone could not substitute for Mg2+, nor was it able, at any Mg2+ concentration, to increase the reaction rate above the level reached at high concentrations of Mg2+ alone. Calculations of the concentration of Mg3.tRNA(Tyr) complex as a function of initial Mg2+ concentration, using the binding constants derived from physical measurements, allow the conclusion that spermine exerts its stimulatory activity by creating strong binding sites for Mg2+; this would enable the tRNA to assume the conformation required for optimal aminoacylation. The conformational requirement for the first tRNA: synthetase encounter is obviously less stringent, since the apparent Km for tRNA(Tyr) is not influenced by spermine.     

Stabilization of the transition state for the transfer of tyrosine to tRNA(Tyr) by tyrosyl-tRNA synthetase

Aminoacylation of tRNA(Tyr) involves two steps: (1) tyrosine activation to form the tyrosyl-adenylate intermediate; and (2) transfer of tyrosine from the tyrosyl-adenylate intermediate to tRNA(Tyr). In Bacillus stearothermophilus tyrosyl-tRNA synthetase, Asp78, Tyr169, and Gln173 have been shown to form hydrogen bonds with the alpha-ammonium group of the tyrosine substrate during the first step of the aminoacylation reaction. Asp194 and Gln195 stabilize the transition state complex for the first step of the reaction by hydrogen bonding with the 2'-hydroxyl group of AMP and the carboxylate oxygen atom of tyrosine, respectively. Here, the roles that Asp78, Tyr169, Gln173, Asp194, and Gln195 play in catalysis of the second step of the reaction are investigated. Pre-steady-state kinetic analyses of alanine variants at each of these positions shows that while the replacement of Gln173 by alanine does not affect the initial binding of the tRNA(Tyr) substrate, it destabilizes the transition state complex for the second step of the reaction by 2.3 kcal/mol. None of the other alanine substitutions affects either the initial binding of the tRNA(Tyr) substrate or the stability of the transition state for the second step of the aminoacylation reaction. Taken together, the results presented here and the accompanying paper are consistent with a concerted reaction mechanism for the transfer of tyrosine to tRNA(Tyr), and suggest that catalysis of the second step of tRNA(Tyr) aminoacylation involves stabilization of a transition state in which the scissile acylphosphate bond of the tyrosyl-adenylate species is strained. Cleavage of the scissile bond on the breakdown of the transition state alleviates this strain.     

Purification and some properties of rat liver tyrosyl-tRNA synthetase.

Rat liver cytoplasmic tyrosine:tRNA ligase (tyrosine:tRNA ligase, EC 6.1.1.1) was purified by ultracentrifugation, DEAE-cellulose chromatography and repeated phosphocellulose chromatography by more than 1500-fold. The molecular weight of the enzyme was approx. 150 000 as determined by Sephadex G-200 gel filtration. On the basis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the enzyme consisted of two subunits, each of 68 000 daltons. We found the following Km values for the enzyme: 13 micrometer for tyrosine and 1.7 mM for ATP in the ATP:PPi exchange reaction and 13 micrometer for tyrosine, 210 micrometer for ATP and 0.14 micrometer for tRNATyr in the aminoacylation reaction. The rate of tyrosyl-tRNA synthesis was 50-fold lower than that of ATP:PPi exchange. Addition of a saturating amount of tRNA did not affect the rate of ATP:PPi exchange.     

Domain-domain communication for tRNA aminoacylation: the importance of covalent connectivity

Aminoacyl-tRNA synthetases form complexes with tRNA to catalyze transfer of activated amino acids to the 3' end of tRNA. The tRNA synthetase complexes are roughly divided into the activation and tRNA-binding domains of synthetases, which interact with the acceptor and anticodon ends of tRNAs, respectively. Efficient aminoacylation of tRNA by Escherichia coli cysteinyl-tRNA synthetase (CysRS) requires both domains, although the pathways for the long-range domain-domain communication are not well understood. Previous studies show that dissection of tRNA(Cys) into acceptor and anticodon helices seriously reduces the efficiency of aminoacylation, suggesting that communication requires covalent continuity of the tRNA backbone. Here we tested if communication requires the continuity of the synthetase backbone. Two N-terminal fragments and one C-terminal fragment of E. coli CysRS were generated. While the N-terminal fragments were active in adenylate synthesis, they were severely defective in the catalytic efficiency and specificity of tRNA aminoacylation. Conversely, although the C-terminal fragment was not catalytically active, it was able to bind and discriminate tRNA. However, addition of the C-terminal fragment to an N-terminal fragment in trans did not improve the aminoacylation efficiency of the N-terminal fragment to the level of the full-length enzyme. These results emphasize the importance of covalent continuity of both CysRS and tRNA(Cys) for efficient tRNA aminoacylation, and highlight the energetic costs of constraining the tRNA synthetase complex for domain-domain communication. Importantly, this study also provides new insights into the existence of several natural "split" synthetases that are now identified from genomic sequencing projects.     

Dominant Intermediate Charcot-Marie-Tooth disorder is not due to a catalytic defect in tyrosyl-tRNA synthetase

Charcot-Marie-Tooth disorder (CMT) is the most common inherited peripheral neuropathy, afflicting 1 in every 2500 Americans. One form of this disease, Dominant Intermediate Charcot-Marie-Tooth disorder type C (DI-CMTC), is due to mutation of the gene encoding the cytoplasmic tyrosyl-tRNA synthetase (TyrRS). Three different TyrRS variants have been found to give rise to DI-CMTC: replacing glycine at position 41 by arginine (G41R), replacing glutamic acid at position 196 by lysine (E196K), and deleting amino acids 153-156 (Δ(153-156)). To test the hypothesis that DI-CMTC is due to a defect in the ability of tyrosyl-tRNA synthetase to catalyze the aminoacylation of tRNA(Tyr), we have expressed each of these variants as recombinant proteins and used single turnover kinetics to characterize their abilities to catalyze the activation of tyrosine and its subsequent transfer to the 3' end of tRNA(Tyr). Two of the variants, G41R and Δ(153-156), display a substantial decrease in their ability to bind tyrosine (>100-fold). In contrast, the E196K substitution does not significantly affect the kinetics for formation of the tyrosyl-adenylate intermediate and actually increases the rate at which the tyrosyl moiety is transferred to tRNA(Tyr). The observation that the E196K substitution does not decrease the rate of catalysis indicates that DI-CMTC is not due to a catalytic defect in tyrosyl-tRNA synthetase.     

Regulation of the tyrosine biosynthetic enzymes in Salmonella typhimurium: analysis of the involvement of tyrosyl-transfer ribonucleic acid and tyrosyl-transfer ribonucleic acid synthetase

Mutants of Salmonella typhimurium were isolated that require tyrosine for growth because of an altered tyrosyl-transfer ribonucleic acid (tRNA) synthetase. Extracts of one strain (JK10) contain a labile enzyme with decreased ability to transfer tyrosine to tRNA(Tyr) and a higher K(m) for tyrosine than the wild-type enzyme. Strain JK10 maintains repressed levels of the tyrosine biosynthetic enzymes when the growth rate is restricted due to limitation of charged tRNA(Tyr). Several second-site revertants of strain JK10 exhibit temperature-sensitive growth due to partially repaired, heat-labile tyrosyl-tRNA synthetase. The tyrosine biosynthetic enzymes are not derepressed in thermosensitive strains grown at the restrictive temperature. A class of tyrosine regulatory mutants, designated tyrR, contains normal levels of tyrosyl-tRNA synthetase and tRNA(Tyr). These results suggest that charging of tRNA(Tyr) is not necessary for repression. This conclusion is substantiated by the finding that 4-aminophenylalanine, a tyrosine analogue which causes repression of the tyrosine biosynthetic enzymes, is not attached to tRNA(Tyr) in vivo, nor does it inhibit the attachment reaction in vitro. A combined regulatory effect due to the simultaneous presence of tyrS and tyrR mutations in the same strain was detected. The possibility of direct participation of tyrosyl-tRNA synthetase in tyrosine regulation is discussed.     

Pyrophosphate-dependent inactivation of tyrosyl-tRNA synthetase during aminoacylation of heterologous tRNA]

It has been shown that heterologous aminoacylation of tRNA by tyrosyl-tRNA synthetase leads to inactivation of the enzyme. Inorganic pyrophosphatase prevents the inactivation and increases the enzyme activity and aminoacylation level in a heterologous system. A putative inactivation mechanism is discussed.     

Aminoacyl-tRNA synthetases from yeast: generality of chemical proofreading in the prevention of misaminoacylation of tRNA.

The specificity of valyl-, phenylalanyl-, and tyrosyl-tRNA synthetases from yeast has been examined by a series of stringent tests designed to eliminate the possibility of artefactual interference. Valyl-tRNA synthetase, as well as activating a number of amino acid analogues, will accept alanine, cysteine, isoleucine, and serine in addition to threonine as substrates for both ATP-PPi exchange and transfer to some tRNAVal species. The transfer is not observed if atempts are made to isolate the appropriate aminoacyl-tRNAVal-C-C-A but its role in the overall aminoacylation can be suspected from both the formation of a stable aminoacyl-tRNAVal-C-C-A(3'NH2) compound and from the stoichiometry of ATP hydrolysis during the aminoacylation of the native tRNA. Similar tests with phenylalanyl-tRNA synthetase indicate that this enzyme will also activate and transfer other naturally occurring amino acids, namely, leucine, methionine, and tyrosine. The tyrosine enzyme, which lacks the hydrolytic capacity of the other two enzymes (von der Haar, F., & Cramer, F (1976) Biochemistry 15, 4131--4138) is probably absolutely specific for tyrosine. It is concluded that chemical proofreading, in terms of an enzymatic hydrolysis of a misacylated tRNA, plays an important part in maintaining the specificity in the overall reaction and that this activity may be more widespread than has so far been suspected.     

Mutational switching of a yeast tRNA synthetase into a mammalian-like synthetase cytokine

Aminoacyl-tRNA synthetases catalyze the attachment of amino acids to their cognate tRNAs. A link was recently established between protein biosynthesis and cytokine signal transduction. Human tyrosyl-tRNA synthetase can be split into two fragments, each of which has a distinct cytokine function. This activity is specific to the human enzyme. It is absent in the enzymes from lower organisms such as bacteria and yeast. Here, yeast tyrosyl-tRNA synthetase (TyrRS), which lacks cytokine activity, was used as a model to explore how a human tyrosyl-tRNA synthetase during evolution acquired novel functions beyond aminoacylation. We found that a rationally designed mutant yeast TyrRS(ELR) gained cytokine function. The mutant yeast enzyme gained this function without sacrifice of aminoacylation activity. Therefore, relatively simple alteration of a basic structural motif imparts cytokine activity to a tRNA synthetase while preserving its canonical function. Further work established that mutational switching of a yeast protein to a mammalian-like cytokine was specific to this synthetase and not to just any yeast ortholog of a mammalian cytokine.