Role of tryptophanyl residues in tobacco acetolactate synthase.

Acetolactate synthase (ALS) catalyzes the first common step in the biosynthesis of valine, leucine, and isoleucine. ALS is the target of three classes of herbicides, the sulfonylureas, the imidazolinones, and the triazolopyrimidines. Five mutants (W266F, W439F, W490F, W503F, and W573F) of the ALS gene from Nicotiana tabacum were constructed and expressed in Escherichia coli, and the enzymes were purified. The W490F mutation abolished the binding affinity for cofactor FAD and inactivated the enzyme. The replacement of Trp573 by Phe yielded a mutant ALS resistant to the three classes of herbicides. The other three mutations, W266F, W439F, and W503F, did not significantly affect the enzymatic properties and the sensitivity to the herbicides. These results indicate that the Trp490 residue is essential for the binding of FAD and that Trp573 is located at the herbicide binding site. The data also suggest that the three classes of herbicides bind ALS competitively.     

Roles of conserved methionine residues in tobacco acetolactate synthase

Acetolactate synthase (ALS) catalyzes the first common step in the biosynthesis of valine, leucine, and isoleucine. ALS is the target of several classes of herbicides, including the sulfonylureas, the imidazolinones, and the triazolopyrimidines. The conserved methionine residues of ALS from plants were identified by multiple sequence alignment using ClustalW. The alignment of 17 ALS sequences from plants revealed 149 identical residues, seven of which were methionine residues. The roles of three well-conserved methionine residues (M350, M512, and M569) in tobacco ALS were determined using site-directed mutagenesis. The mutation of M350V, M512V, and M569V inactivated the enzyme and abolished the binding affinity for cofactor FAD. Nevertheless, the secondary structure of each of the mutants determined by CD spectrum was not affected significantly by the mutation. Both M350C and M569C mutants were strongly resistant to three classes of herbicides, Londax (a sulfonylurea), Cadre (an imidazolinone), and TP (a triazolopyrimidine), while M512C mutant did not show a significant resistance to the herbicides. The mutant M350C was more sensitive to pH change, while the mutant M569C showed a profile for pH dependence activity similar to that of wild type. These results suggest that M512 residue is likely located at or near the active site, and that M350 and M569 residues are probably located at the overlapping region between the active site and a common herbicide binding site.     

Roles of lysine 219 and 255 residues in tobacco acetolactate synthase

Acetolactate synthase (ALS) catalyzes the first common step in the biosynthesis of valine, leucine, and isoleucine. The ALS is the target of several classes of herbicides, including the sulfonylureas, the imidazolinones, and the triazolopyrimidines. The roles of three well-conserved lysine residues (K219, K255, K299) in tobacco ALS were determined using site-directed mutagenesis. The mutation of K219Q inactivated the enzyme and abolished the binding affinity for cofactor FAD. However, the secondary structure of the enzyme was not changed significantly by the mutation. Both mutants, K255F and K255Q, showed strong resistance to three classes of herbicides Londax (a sulfonylurea), Cadre (an imidazolinone), and TP (a triazolopyrimidine). In addition, there was no difference in the secondary structures of wALS and K255F. On the other hand, the mutation of K299Q did not show any significant effect on the kinetic properties or any sensitivity to the herbicides. These results suggest that Lys219 is located at the active site and is likely involved in the binding of FAD, and that Lys255 is located at a binding site common for the three herbicides in tobacco ALS.     

Amino acid residues conferring herbicide tolerance in tobacco acetolactate synthase

Acetolactate synthase (ALS) is the common enzyme in the biosynthetic pathways leading to valine, leucine, and isoleucine in plants and microorganisms. ALS is the target site of several classes of structurally unrelated herbicides including sulfonylureas, imidazolinones, and triazolopyrimidines. To identify the residues conferring herbicide tolerance in tobacco ALS, site-directed mutagenesis for three residues, Ala121, Pro187 and Ser652, was performed. Mutant A121T showed strong resistance to Londax (a sulfonylurea) and Cadre (an imidazolinone), while mutant S652T was resistant only to Cadre. The S652N mutation abolished the binding affinity of FAD, and inactivated the enzyme. Double mutation of Ala121 and Ser652 with Thr yielded a mutant highly tolerant to Londax, Cadre, and TP (a triazolopyrimidine sulfonamide), but has enzymatic properties similar to those of wild-type. Substitution of Pro187 with Ser resulted in the enzyme highly susceptible to oxidation and fragmentation. These results suggest that two residues Ala121 and Ser652 are potent residues conferring herbicide resistance in tobacco ALS, and that double mutation of Ala121 and Ser652 by Thr can confer stronger tolerance to Londax, Cadre, and TP.     

Structural and functional evaluation of three well-conserved serine residues in tobacco acetohydroxyacid synthase

The first step in the common pathway for the biosynthesis of branched-chain amino acids (BCAAs) is catalyzed by acetohydroxyacid synthase (AHAS). The roles of three well-conserved serine residues (S167, S506, and S539) in tobacco AHAS were determined using site-directed mutagenesis. The mutations S167F and S506F were found to be inactive and abolished the binding affinity for cofactor FAD. The Far-UV CD spectrum of the inactive mutants was similar to that of wild-type enzyme, indicating no major conformational changes in the secondary structure. However, the active mutants, S167R, S506A, S506R, S539A, S539F and S539R, showed lower specific activities. Further, a homology model of tobacco AHAS was generated based on the crystal structure of yeast AHAS. In the model, the S167 and S506 residues were identified near the FAD binding site, while the S539 residue was found to near the ThDP binding site. The S539 mutants, S539A and S539R, showed strong resistance to three classes of herbicides, NC-311 (a sulfonylurea), Cadre (an imidazolinone), and TP (a triazolopyrimidine). In contrast, the active S167 and S506 mutants did not show any significant resistance to the herbicides, with the exception of S506R, which showed strong resistance to all herbicides. Thus, our results suggest that the S167 and S506 residues are essential for catalytic activity by playing a role in the FAD binding site. The S539 residue was found to be near the ThDP with an essential role in the catalytic activity and specific mutants of this residue (S539A and S539R) showed strong herbicide resistance as well.     

Functional role of cysteinyl residues in tryptophanase

Holotryptophanase inactivated by oxidation of cysteinyl residues showed a different absorption spectrum from the native enzyme. At pH 8.0, the native enzyme preferentially existed as a 337-nm species (active form), whereas in the inactive enzyme a 420-nm species (inactive form) was dominant. During the reactivation of the enzyme by reduction with dithiothreitol, an increase at 337 nm and a decrease at 420 nm were observed with concomitant increase in enzymatic activity, which was accompanied by the appearance of two cysteinyl residues per monomer. Specific S-cyanylation of cysteinyl residues by nitrothiocyanobenzoic-acid-inactivated apotryptophanase with the modification of one cysteinyl residue per monomer, whereas holotryptophanase was highly resistant to inactivation with nitrothiocyanobenzoic acid. The essential role of the active-site-bound pyridoxal 5'-phosphate in protection against inactivation was confirmed by the agreement of the K1/2 (protection) of 5.0 microM for pyridoxal 5'-phosphate with Km of 2.0 microM in enzyme catalysis. The inactivation by nitrothiocyanobenzoic acid caused a similar shift in the equilibrium between the 337-nm species and 420-nm species, i.e. decrease of the 337-nm species and increase of the 420-nm species. From the pH dependence of the equilibrium between these two species, pKa of 7.9 and 7.4 was obtained for the inactive and the dithiothreitol-activated enzyme, respectively, indicating that cysteinyl residue(s) participated in lowering the pKa of the interconversion between the 337-nm species (active form) and 420-nm species (inactive form). The possible role of cysteinyl residues in the function of tryptophanase is discussed.     

Structural and functional role of leucine residues in proteins

Circular dichroism and potentiometric titration studies of leucine random copolymers in aqueous solutions, as well as a comparison of the conformational stability in poly-α-amino acids, indicate that leucine may possibly be the amino acid with the highest propensity for forming α-helical structures. This suggests that leucine might be found most frequently in the helical regions of proteins. A survey was made on 15 different proteins containing 2473 residues with known sequence and conformation determined by X-ray crystallography: carboxy-peptidase A, α-chymotrypsin, cytochrome b₅, elastase, ferricytochrome c, α- and β-hemoglobin, insulin, lysozyme, myogen, myoglobin, papain, ribonuclease A, staphylococcal nuclease, and subtilisin BPN′. It was found that 888 residues in these proteins are in helices, and 422 of them reside in the internal turns of helical regions. While Glu, Ala, Leu and His were found to be present with the highest percentages in helical regions, Leu was clearly the most abundant residue in the inner helical cores of proteins. Polar residues are found preferentially at the helix-coil boundary regions; Asp and Glu at the N-terminal and His, Lys and Arg at the C-terminal helical ends. These findings agree with Ptitsyn's (1969) analysis on seven proteins containing 1132 residues. A more comprehensive analysis in the present survey showed that Ile, Met and Val occur with the greatest frequency in the β-regions of proteins. Leu was also found as the strongest structure-forming residue in proteins (total helical and β-regions). The functional-structural role of leucine was established by showing that it occurs most frequently among residues surrounding the heme in five of the heme proteins. In addition, the greater abundance of leucine as neighbors to active-site residues in enzymes provides strong evidence that hydrophobic residues create a non-aqueous environment, aiding the polar residues in substrate binding and enzymic catalysis. Examples of conservative and non-conservative mutations of leucine in heme proteins are given to illustrate the structure—function relation of proteins, and explain why most leucine residues in the insulin, hemoglobin, and cytochrome c homologs are invariant. Finally, the strong helical-forming power of leucine, as demonstrated experimentally in synthetic copolypeptides and its high occurrence in the inner helical cores of proteins, suggests that it could have a major role as nucleation centers in the folding and evolution of large protein molecules.     

A single amino acid change in acetolactate synthase confers resistance to valine in tobacco

The metabolic control of branched chain amino acid (BCAA) biosynthesis involves allosteric regulation of acetolactate synthase (ALS) by the end-products of the pathway, valine, leucine and isoleucine. We describe here the molecular basis of valine resistance. We cloned and sequenced an ALS gene from the tobacco mutant Val^r-1 and found a single basepair substitution relative to the wild-type allele. This mutation causes a serine to leucine change in the amino acid sequence of ALS at position 214. We then mutagenized the wild-type allele of the ALS gene ofArabidopsis and found that it confers valine resistance when introduced into tobacco plants. Taken together, these results suggest that the serine to leucine change at position 214 of ALS is responsible for valine resistance in tobacco.This paper is dedicated to the memory of Jean-Pierre Bourgin, who died on October 29, 1994, at the age of 50     

Cloning and functional expression of the small subunit of acetolactate synthase from Nicotiana plumbaginifolia

Acetolactate synthase (ALS) is the first committed step of branched-chain amino acid biosynthesis in plants and bacteria. The bacterial holoenzyme has been well characterized and is a tetramer of two identical large subunits (LSUs) of 60 kDa and two identical small subunits (SSUs) ranging in molecular mass from 9 to 17 kDa depending on the isozyme. The enzyme from plants is much less well characterized. Attempts to purify the protein have yielded an enzyme which appears to be an oligomer of LSUs, with the potential existence of a SSU for the plant enzyme remaining a matter of considerable speculation. We report here the discovery of a cDNA clone that encodes a SSU of plant ALS based upon the homology of the encoded peptide with various bacterial ALS SSUs. The plant ALS SSU is more than twice as large as any of its prokaryotic homologues and contains two domains that each encode a full-length copy of the prokaryotic SSU polypeptide. The cDNA clone was used to express Nicotiana plumbaginifolia SSU in Escherichia coli. Mixing a partially purified preparation of this SSU with the LSU of ALS from either N. plumbaginifolia or Arabidopsis thaliana results in both increased specific activity and increased stability of the enzymic activity. These results are consistent with those observed for the bacterial enzyme in similar experiments and represent the first functional demonstration of the existence of a SSU for plant ALS.     

Synthesis of the quinoline-linked triazolopyrimidine analogues and their interactions with the recombinant tobacco acetolactate synthase.

Acetolactate synthase (ALS) is the first common enzyme in the biosynthesis of L-leucine, L-isoleucine, and L-valine. Triazolopyrimidine sulfonamide (TP) is a mixed-type inhibitor of ALS with respect to both pyruvate and thiamine pyrophosphate. In this study, we synthesized new substituted quinoline-linked TP analogues and several TP analogues which contained either unsubstituted aminoquinolines or amino isoquinolines. In addition, we examined the interactions of both the wild-type and the sulfonylurea-resistant recombinant tobacco ALS enzymes in a highly pure and active form with the quinoline-linked TP analogues, respectively. The wild-type tobacco ALS was extremely sensitive to inhibition by the quinoline-linked TP analogues. In contrast, the mutant tobacco ALS was insensitive to both the quinoline-linked triazolopyrimidine and the sulfonylurea herbicides. The results indicate that the ability of the quinoline-linked TP analogues to inhibit ALS is highly sensitive to substitution at the ortho position (C-7) and to the position of the ring nitrogen around the sulfonamide functionality (C-8).     

乙酰乳酸合成酶基因的克隆与高效表达

【目的】乙酰乳酸合成酶(ALS)是异丁醇生物合成中的关键酶,实现ALS的高效表达对调控异丁醇代谢途径有重要意义。【方法】根据GenBank中ALS的基因序列(alsS)设计引物,以枯草芽孢杆菌168基因组DNA为模板通过PCR扩增技术得到目标酶基因,目的片段全长为1 713 bp。将alsS连接到pET-30a(+)上,得到重组质粒pET-30a(+)-alsS,并在Escherichia coli BL2l(DE3)中实现表达。【结果】对表达条件进行了优化,获得最佳表达条件为:诱导温度30°C,诱导起始菌体OD600为0.6 0.8,诱导剂IPTG浓度为1 mmol/L,诱导时间为6 h。表达的乙酰乳酸合成酶大部分以可溶性形式存在于菌体内,优化后酶活可达到24.4 U/mL,比优化前提高了7.13倍。经HisTrapTMFF亲和层析后获得电泳纯的ALS,比活为95.2 U/mg。【结论】ALS的有效表达为在大肠杆菌体内构建异丁醇代谢途径打下了基础。     

Expression and functional characterization of mutant human CXCR4 in insect cells: role of cysteinyl and negatively charged residues in ligand binding

Human CXCR4 was expressed in Sf9 insect cells using the Bac-to-Bac baculovirus expression system. The recombinant receptor exhibited ligand binding activities with a K(d) value (3.3 nM) comparable to that of the native receptor. The role of four conserved cysteinyl residues was explored by site-directed mutagenesis. Each cysteine was individually changed to an alanine residue. All of the four mutants showed decreased ligand binding activity with increased K(d) values although comparable levels of receptor expression were observed. These results suggest that each of these four cysteinyl residues may be important for the ligand binding of the receptor. Evidence suggests that the ionic interaction may be involved in ligand binding. Point mutation of several relatively conserved acidic residues (Asp-10, Asp-262, Glu-275, and Glu-277) to an alanine residue greatly decreased the ligand binding activity and affinity. Since SDF-1alpha is a highly basic protein, these acidic residues may interact with the basic residues of SDF-1alpha by ionic pairing in addition to other molecular interactions and play an important role in ligand binding.     

Isolation and purification of acetolactate synthase and acetolactate decarboxylase from the culture ofLactococcus lactis

Enzymes catalyzing the synthesis and subsequent transformation of α-acetolactate (AcL)—acetolactate synthase (AcLS) and acetolactate decarboxylase (AcLDC)—were isolated and partially purified from the cells of lactic acid bacteriaLactococcus lactis ssp.lactis biovar.diacetylactis, strain 4. The preparation of AcLS, purified 560-fold, had a specific activity of 358 300 U/mg protein (9% yield). The preparation of AcLDC., purified 4828-fold, had a specific activity of 140 U/mg protein (4.8% yield). The enzymes exhibited optimum activity at pH 6.5 and 6.0, respectively (medium, phosphate buffer). The values of apparentK _m, determined for AcLS and AcLDC with pyruvate and AcL, respectively, were equal to 70 mM and 20 mM. AcLS appeared as an allosteric enzyme with low affinity for the substrate and a sigmoid dependence of the activity on the substrate concentration. In the case of AcLDC, this dependence was hyperbolic and the affinity of the enzyme for its substrate was high (K _m = 20 mM). Leucine, valine, and isoleucine were shown to be activators of AcDLC.     

Isolation and purification of acetolactate synthase and acetolactate decarboxylase from a Lactococcus lactis culture

Enzymes catalyzing the synthesis and subsequent transformation of alpha-acetolactate (AcL)--acetolactate synthase (AcLS) and acetolactate decarboxylase (AcLDC)--were isolated and partially purified from the cells of lactic acid bacteria Lactococcus lactis ssp. lactis biovar. diacetylactis strain 4. The preparation of AcLS, purified 560-fold, had a specific activity of 358,300 U/mg protein (9% yield). The preparation of AcLDC, purified 4828-fold, had a specific activity of 140 U/mg protein (4.8% yield). The enzymes exhibited optimum activity at pH 6.5 and 6.0, respectively (medium, phosphate buffer). The values of apparent Km, determined for AcLS and AcLDC with pyruvate and AcL, respectively, were equal to 70 mM and 20 mM. AcLS appeared as an allosteric enzyme with low affinity for the substrate and a sigmoid dependence of the activity on the substrate concentration. In the case of AcLDC, this dependence was hyperbolic, and the affinity of the enzyme for its substrate was high (Km = 20 mM). Leucine, valine, and isoleucine were shown to be activators of AcDLC.     

Selectable tolerance to herbicides by mutated acetolactate synthase genes integrated into the chloroplast genome of tobacco

Strategies employed for the production of genetically modified (GM) crops are premised on (1) the avoidance of gene transfer in the field; (2) the use of genes derived from edible organisms such as plants; (3) preventing the appearance of herbicide-resistant weeds; and (4) maintaining transgenes without obstructing plant cell propagation. To this end, we developed a novel vector system for chloroplast transformation with acetolactate synthase (ALS). ALS catalyzes the first step in the biosynthesis of the branched amino acids, and its enzymatic activity is inhibited by certain classes of herbicides. We generated a series of Arabidopsis (Arabidopsis thaliana) mutated ALS (mALS) genes and introduced constructs with mALS and the aminoglycoside 3'-adenyltransferase gene (aadA) into the tobacco (Nicotiana tabacum) chloroplast genome by particle bombardment. Transplastomic plants were selected using their resistance to spectinomycin. The effects of herbicides on transplastomic mALS activity were examined by a colorimetric assay using the leaves of transplastomic plants. We found that transplastomic G121A, A122V, and P197S plants were specifically tolerant to pyrimidinylcarboxylate, imidazolinon, and sulfonylurea/pyrimidinylcarboxylate herbicides, respectively. Transplastomic plants possessing mALSs were able to grow in the presence of various herbicides, thus affirming the relationship between mALSs and the associated resistance to herbicides. Our results show that mALS genes integrated into the chloroplast genome are useful sustainable markers that function to exclude plants other than those that are GM while maintaining transplastomic crops. This investigation suggests that the resistance management of weeds in the field amid growing GM crops is possible using (1) a series of mALSs that confer specific resistance to herbicides and (2) a strategy that employs herbicide rotation.     

pCMB treatment reveals the essential role of cysteinyl residues in conferring functional competence to the regulatory subunit of protein kinase CK2

To assess the functional role of the four conserved cysteinyl residues in the regulatory beta-subunit of protein kinase CK2, the effect of pCMB and other reagents of sulfhydryl groups has been investigated. The pCMB-treated beta-subunit has lost its ability to form either homodimers or regular alpha(2)beta(2) heterotetramers with the catalytic subunit. It also fails to increase catalytic activity toward peptide substrates and to mediate the stimulatory effect of polylysine. The pCMB-treated beta-subunit, however, is still able to prevent calmodulin phosphorylation and to physically interact with the alpha-subunit to form inactive complexes whose sedimentation coefficient is lower than that of CK2 holoenzyme. These inactive complexes upon treatment with reducing agents like DTT are converted into a fully active heterotetrameric holoenzyme.     

Transformation with a mutant Arabidopsis acetolactate synthase gene renders tobacco resistant to sulfonylurea herbicides

Summary A gene encoding acetolactate synthase was cloned from a chlorsulfuron-resistant mutant of Arabidopsis. The DNA sequence of the mutant gene differed from that of the wild type by a single base pair substitution. When introduced into tobacco by Ti plasmid-mediated transformation the gene conferred a high level of herbicide resistance. These results suggest that the cloned gene may confer agronomically useful levels of herbicide resistnace in other crop species, and that it may be useful as a selectable marker for plant transformation experiments.