Amino Acid Metabolism of Lemna minor L. : II. Responses to Chlorsulfuron

Chlorsulfuron, an inhibitor of acetolactate synthase (EC 4.1.3.18) (TB Ray 1984 Plant Physiol 75: 827-831), markedly inhibited the growth of Lemna minor at concentrations of 10⁻⁸ molar and above, but had no inhibitory effects on growth at 10⁻⁹ molar. At growth inhibitory concentrations, chlorsulfuron caused a pronounced increase in total free amino acid levels within 24 hours. Valine, leucine, and isoleucine, however, became smaller percentages of the total free amino acid pool as the concentration of chlorsulfuron was increased. At concentrations of chlorsulfuron of 10⁻⁸ molar and above, a new amino acid was accumulated in the free pool. This amino acid was identified as α-amino-n-butyrate by chemical ionization and electron impact gas chromatography-mass spectrometry. The amount of α-amino-n-butyrate increased from undetectable levels in untreated plants, to as high as 840 nanomoles per gram fresh weight (2.44% of the total free pool) in plants treated with 10⁻⁴ molar chlorsulfuron for 24 hours. The accumulation of this amino acid was completely inhibited by methionine sulfoximine. Chlorsulfuron did not inhibit the methionine sulfoximine induced accumulations of valine, leucine, and isoleucine, supporting the idea that the accumulation of the branched-chain amino acids in methionine sulfoximine treated plants is the result of protein turnover rather than enhanced synthesis. Protein turnover may be primarily responsible for the failure to achieve complete depletion of valine, leucine, and isoleucine even at concentrations of chlorsulfuron some 10⁴ times greater than that required to inhibit growth. Tracer studies with ¹⁵N demonstrate that chlorsulfuron inhibits the incorporation of ¹⁵N into valine, leucine, and isoleucine. The α-amino-n-butyrate accumulated in the presence of chlorsulfuron and [¹⁵N]H₄⁺ was heavily labeled with ¹⁵N at early time points and appeared to be derived by transamination from a rapidly labeled amino acid such as glutamate or alanine. We propose that chlorsulfuron inhibition of acetolactate synthase may lead to accumulation of 2-oxobutyrate in the isoleucine branch of the pathway, and transamination of 2-oxobutyrate to α-amino-n-butyrate by a constitutive transaminase utilizing either glutamate or alanine as α-amino-N donors.     

The existence of three types of acetohydroxy acid synthetase in an isoleucine-requiring mutant of Aerobacter aerogenes.

The synthesis of the three types of acetolactate synthase (EC 4.1.3.18) which are responsible for the biosynthesis os isoleucine and valine, was observed in Aerobacter aerogenes I-12, an isoleucine-requiring mutant, when grown on the four kinds of media. When the cells were grown on isoleucine-rich medium, acetolactate synthase sensitive to feedback inhibition and having an optimum pH at 8.0 was formed. By increasing the amount of potassium phosphate in the medium, the catabolite repression of the enzyme having an optimum pH at 6.0 and which is insensitive to feedback inhibition, was released. In contrast, acetolactate synthase having an optimum pH at 8.0 and insensitive to feedback inhibition was formd when isoleucine was limited, irrespective of phosphate concentrations. Two insensitive enzymes were not regulated by isoleucine, leucine and valine, although sensitive pH 8.0 enzyme was repressed by them. Thus, it may be assumed that the synthesis of insensitive pH 8.0 enzyme were repressed by limiting the amount of isoleucine is still open.     

Properties of mutant acetolactate synthases resistant to triazolopyrimidine sulfonanilide

Triazolopyrimidine sulfanilides are a class of highly active herbicides whose primary target is acetolactate synthase. Spontaneous mutants of tobacco (Nicotiana tabacum) (KS-43) and cotton (Gossypium hirsutum) (PS-3 and DO-2) resistant to triazolopyrimidine sulfonanilide were selected in tissue culture. Acetolactate synthase partially purified from the three mutants were 80- to 1000-fold less sensitive to inhibition by the compound compared with the corresponding wild-type enzyme. The mutants also varied in the cross-resistance pattern to other acetolactate synthase inhibiting herbicides in the sulfonylurea, imidazolinone, and pyrimidyl-oxy-benzoate chemical families. Thus, acetolactate synthase from KS-43, PS-3, and DO-2 cultures have different mutations. The affinities for pyruvate, thiamine pyrophosphate, as well as the activity of the mutant enzymes were found to be comparable to the corresponding wild-type enzymes. However, the enzyme from PS-3 was highly resistant to feedback inhibition by valine and leucine. In contrast, acetolactate synthase from KS-43 and DO-2 were inhibited by valine and leucine to nearly the same extent as the wild-type enzymes. Also, PS-3 cultures accumulated much higher levels of the branched chain amino acids compared to the wild-type cotton culture. The mutation in the PS-3 enzyme has therefore rendered it insensitive to feedback regulation by valine and leucine.     

The acetolactate synthase isoenzymes of Escherichia coli K-12.

Summary Strains of Escherichia coli K-12 possessing only one of the three genes coding for acetolactate synthetase activity present either in the wild type or in its ilv0603 derivative were prepared and analyzed. Extracts prepared from these strains show different values of acetolactate synthase specific activity and different sensitivity to valine inhibition. These strains show a unique pattern of growth inhibition by different substances.Temperature sensitive (ts) mutations in the ilvB and ilvG genes, have been isolated and characterized. Extracts of these strains were found to have an acetolactate synthase activity more heat labile than that of a strain containing the corresponding wild type allele. We conclude that ilvB and ilvG are the structural genes for two different forms of acetolactate synthase activity, most likely two isoenzymes. Moreover, since the strains containing a ts mutation show a temperature sensitive auxotrophy for isoleucine and valine, these two acetolactate synthases participate in isoleucine and valine biosynthesis. Similar evidence for a third acetolactate synthase, the product of the ilvHI genes, has been reported previously.We propose the following names for the acetolactate synthase isoenzymes: acetolactate synthase I (AHAS I), the product of the ilvB gene; acetolactate synthase II (AHAS II), the product of ilvG gene; and acetolactate synthase III (AHAS III), the product of the ilvHI genes.     

Sulfonylurea-resistant mutants and natural tolerance of cyanobacteria

The herbicide sulfometuron methyl (SM) inhibited the growth of the cyanobacterium Synechococcus sp. PCC7942, but not of Synechocystis sp. PCC6714. The inhibitory effect was alleviated by the simultaneous addition of valine, leucine and isoleucine. SM resistant mutants were isolated from Synechococcus 7942, two types of which were further analysed. In these mutants, SM3/20 and SM2/32, the activity of acetolactate synthase (ALS) — a key enzyme in the biosynthesis of branched-chain amino acids —appeared 2600- and 300-fold, respectively, more resistant to SM than that of their wild type. Strain SM2/32 also exhibited a low level of ALS activity. Although the growth of the latter mutant was extremely inhibited by valine, the sensitivity of its ALS activity to feed-back inhibition by the amino acid was unaltered. At high concentrations valine inhibited growth of the wild type strains and of the mutant SM3/20. Isoleucine alleviated the valine-induced growth inhibition. Unlike that of Synechococcus 7942, the ALS activity of Synechocystis was found to tolerate high concentrations (100-fold) of the herbicide. The study confirms that the SM mutations are correlated with a cyanobacterial ilv gene.Abbreviations ALS acetolactate synthase; ile, isoleucine - leu leucine - NTG N-methyl-N-nitro-N-nitrosoguanidine - SM sulfometuron methyl - SM^r sulfometuron methyl resistant - val valine     

Structural Genes for a Newly Recognized Acetolactate Synthase in Escherichia coli K-12

Evidence is reported that shows the presence in Escherichia coli K-12 of a newly found acetolactate synthase. This enzyme is the product of two genes, ilvH and ilvI, both located very close to leu. Amber mutations have been found in both genes and therefore their products are polypeptides. Mutations in the ilvH gene cause the appearance of an acetolactate synthase activity which is relatively resistant to valine inhibition and can be separated by adsorption on hydroxylapatite from another activity present in the extract and more sensitive to valine inhibition than the former. A mutant altered in the ilvI gene was isolated among the revertants sensitive to valine inhibition of an ilvH mutant. Such a mutant lacks the resistant acetolactate synthase. A temperature-sensitive revertant of the ilvI mutant contained a temperature-sensitive acetolactate synthase. Thus ilvI is the structural gene for a specific acetolactate synthase. The activity of the ilvH gene product has been measured by adding an extract containing it to a purified ilvI acetolactate synthase, which, upon incubation, became more sensitive to valine inhibition. Conversely, a valine-sensitive acetolactate synthase (the product of the ilvH and the ilvI genes) became more resistant to valine inhibition upon incubation with an extract of a strain containing a missense ilvH gene product.     

1H, 13C, 15N assignments of the dimeric regulatory subunit (ilvN) of the E. coli AHAS I

Acetohydroxyacid synthase (AHAS) is an enzyme involved in the biosynthesis of the branched chain amino acids viz, valine, leucine and isoleucine. The activity of this enzyme is regulated through feedback inhibition by the end products of the pathway. Here we report the backbone and side-chain assignments of ilvN, the 22 kDa dimeric regulatory subunit of E. coli AHAS isoenzyme I, in the valine bound form. Detailed analysis of the structure of ilvN and its interactions with the catalytic subunit of E. coli AHAS I will help in understanding the mechanism of activation and regulation of the branched chain amino acid biosynthesis.     

Leucine biosynthesis: effect of branched-chain amino acids and threonine on a-isopropylmalate synthase activity from aerobic and anaerobic microorganisms

$\text{a-}\text{Isopropylmalate}$ synthase activity was demonstrated in the Sephadex G 25 gel filtrated crude extracts of one yeast and 43 bacterial strains belonging to 14 families. The enzyme was inhibited by leucine from all strains Bacteroides fragilis, Clostridia and several phototropic bacteria. The enzyme was inhibited by leucine from all strains investigated. In crude extracts of 17 species (8 genera) the leucine-mediated inhibition could be relieved by the addition of valine or isoleucine , but not by the addition of threonine or alanine. The enzymes from 11 species (7 genera) were inhibited by 1 mM valine and isoleucine, whereas the enzyme activity from 5 bacteria (4genera) were not so affected. These results suggest that valine and isoleucine are specifically involved in the regulation of leucine biosynthesis in several bacteria. The affect of valine and isoleucine on the IPM-synthase activity from mycobacteria and Corynebacterium autotrophicum lends support to the reclassification of Mycobacterium flavum 301 to C. autotrophicum. The antagonism between 5′,5′,5′-trifluoroleucine and amino acids and $\text{a-}\text{ketoisovalerate}$ was $\text{a-}\text{isopropylmalate}$ synthase in the presence or abssence of leucine and the reversal of the 5′,5′,5′-trifluoroleucine-mediated growth inhibition by these amino acids.     

A valine-resistant mutant ofArabidopsis thaliana displays an acetolactate synthase with altered feedback control

A valine-resistant mutant line, VAL-2, ofArabidopsis thaliana (L.) Heynh. was identified by screening M 2 populations of ethylmethane-sulfonate-mutagenized seeds. The resistance was found to be due to a single, dominant, nuclear gene mutation. Assay of acetolactate synthase (ALS) indicated that the valine resistance in this mutant is caused by decreased sensitivity of ALS to the branched-chain amino acids, valine, leucine andisoleucine. A two fold decrease in apparentK _m value for pyruvate of the mutant ALS enzyme was detected compared with that of the wild type. The sensitivity of the ALS enzyme to sulfonylurea, imidazolinone and triazolopyrimidine herbicides was not altered in the mutant. At the plant growth level the mutant was also resistant to valine plus leucine, but was sensitive to leucine orisoleucine alone. The mutant gene,var1, maps, or is very closely linked, toCSR1, the gene encoding acetolactate synthase inArabidopsis.Abbreviations ALS acetolactate synthase - BCAA branched-chain amino acid - CS chlorsulfuron - IM imidazolinone - SU sulfonylurea - TP triazolopyrimidine We thank Dr. George W. Haughn for providing Arabidopsis lines MSU12, MSU15, MSU21, MSU22 and MSU23. This work was supported by a Research Grant from the Natural Sciences and Engineering Research Council of Canada to J.K., K.W. is grateful for a University of Saskatchewan Graduate Scholarship.     

Mode of action of chlorsulfuron in a sensitive wheat (Triticum aestivum) cultivar: primary and secondary effects on nitrogen assimilation

Chlorsulfuron (15 g a.i. ha^-1) inhibited growth of wheat (Triticurn aestivum L. cv. Rongotea) especially on high nitrate (NO₃) supply. Decreased growth at high NO^-₃ was associated with higher concentrations of reduced nitrogen (N) and NO^-₃ in the shoots. Seven days after spraying (DAS), shoot dry weight (dry wt) of sprayed plants was similar with NO^-₃ or branched chain amino acids as main N supply but 28 DAS, shoot dry wt was greater with the amino acid treatment. One DAS, chlorsulfuron caused substantial decreases in extension of the youngest leaf and acetolactate synthase activity and valine content of shoots of plants supplied with NO^-₃ or branched chain amino acids. Total amino acid content of shoots was greater in sprayed plants than in unsprayed plants 1 DAS. Acetolactate synthase activity of sprayed plants supplied low NO^-₃ returned to normal 14–21 DAS. For sprayed plants transferred from low to high NO^-₃ supply 7, 14 or 21 DAS, shoot dry wt 50 DAS increased with increased time of transfer to high NO^-₃ while shoot NO^-₃ content decreased. Shoot NO₃ content of sprayed plants transferred to high NO^-₃ supply 7 or 14 DAS was similar to that in unsprayed plants at applied NO^-₃ concentrations which inhibited growth. It is concluded that inhibition of acetolactate synthase is likely to be the primary mode of action of chlorsulfuron in this wheat cultivar; data are consistent with the proposal that subsequent NO^-₃ accumulation can also inhibit growth.     

New aspects on inhibition of plant acetolactate synthase by chlorsulfuron and imazaquin

The sulfonylurea herbicide chlorsulfuron and the imidazolinone herbicide imazaquin were shown to be noncompetitive and uncompetitive inhibitors, respectively, of purified acetolactate synthase from barley (Hordeum vulgare L.) with respect to pyruvate. From double-reciprocal plots of the time-dependent biphasic inhibition by chlorsulfuron, an initial apparent inhibition constant of 68 nanomolar was calculated (a 0 to 4 minute assay was used for the initial inhibition), and a final steady-state dissociation constant of 3 nanomolar was estimated. The corresponding constants for imazaquin were 10 and 0.55 micromolar. Specific binding of [¹⁴C]chlorsulfuron and [¹⁴C]imazaquin to purified acetolactate synthase from barley and partially purified enzyme from corn (Zea mays L.) could be demonstrated by gel filtration and equilibrium dialysis. Evidence is presented that the binding of the inhibitors to the enzyme follows the previously described mechanism of slow reversibility once excess inhibitor has been removed. However, after formation of the slowly reversible complex and subsequent dissociation, both chlorsulfuron and imazaquin seem to permanently inactivate acetolactate synthase. These results add a new feature to the mode of action of these herbicides with respect to their high herbicidal potency.     

Cross-Resistance to Herbicides in Annual Ryegrass (Lolium rigidum): I. Properties of the Herbicide Target Enzymes Acetyl-Coenzyme A Carboxylase and Acetolactate Synthase

Lolium rigidum biotype SR4/84 is resistant to the herbicides diclofop-methyl and chlorsulfuron when grown in the field, in pots, and in hydroponics. Similar extractable activities and affinities for acetyl-coenzyme A of carboxylase (ACCase), an enzyme inhibited by diclofop-methyl, were found for susceptible and resistant L. rigidum. ACCase activity from both biotypes was inhibited by diclofop-methyl, diclofop acid, haloxyfop acid, fluazifop acid, sethoxydim, and tralkoxydim but not by chlorsulfuron or trifluralin. Exposure of plants to diclofop-methyl did not induce any changes in either the extractable activities or the herbicide inhibition kinetics of ACCase. It is concluded that, in contrast to diclofop resistance in L. multiflorum and diclofop tolerance in many dicots, the basis of resistance to diclofop-methyl and to other aryloxyphenoxypropionate and cyclohexanedione herbicides in L. rigidum is not due to the altered inhibition characteristics or expression of the enzyme ACCase. The extractable activities and substrate affinity of acetolactate synthase (ALS), an enzyme inhibited by chlorsulfuron, from susceptible and resistant biotypes of L. rigidum were similar. ALS from susceptible and resistant plants was equally inhibited by chlorsulfuron. Prior exposure of plants to 100 millimolar chlorsulfuron did not affect the inhibition kinetics. It is concluded that resistance to chlorsulfuron is not caused by alterations in either the expression or inhibition characteristics of ALS.     

Feedback-Resistant Acetohydroxy Acid Synthase Increases Valine Production in Corynebacterium glutamicum

Acetohydroxy acid synthase (AHAS), which catalyzes the key reactions in the biosynthesis pathways of branched-chain amino acids (valine, isoleucine, and leucine), is regulated by the end products of these pathways. The whole Corynebacterium glutamicum ilvBNC operon, coding for acetohydroxy acid synthase (ilvBN) and aceto hydroxy acid isomeroreductase (ilvC), was cloned in the newly constructed Escherichia coli-C. glutamicum shuttle vector pECKA (5.4 kb, Km^r). By using site-directed mutagenesis, one to three amino acid alterations (mutations M8, M11, and M13) were introduced into the small (regulatory) AHAS subunit encoded by ilvN. The activity of AHAS and its inhibition by valine, isoleucine, and leucine were measured in strains carrying the ilvBNC operon with mutations on the plasmid or the ilvNM13 mutation within the chromosome. The enzyme containing the M13 mutation was feedback resistant to all three amino acids. Different combinations of branched-chain amino acids did not inhibit wild-type AHAS to a greater extent than was measured in the presence of 5 mM valine alone (about 57%). We infer from these results that there is a single binding (allosteric) site for all three amino acids in the enzyme molecule. The strains carrying the ilvNM13 mutation in the chromosome produced more valine than their wild-type counterparts. The plasmid-free C. glutamicum ΔilvA ΔpanB ilvNM13 strain formed 90 mM valine within 48 h of cultivation in minimal medium. The same strain harboring the plasmid pECKAilvBNC produced as much as 130 mM valine under the same conditions.     

Acetolactate Synthase Activity in Developing Maize (Zea mays L.) Kernels

Acetolactate synthase (EC 4.1.3.18) activity was examined in maize (Zea mays L.) endosperm and embryos as a function of kernel development. When assayed using unpurified homogenates, embryo acetolactate synthase activity appeared less sensitive to inhibition by leucine + valine and by the imidazolinone herbicide imazapyr than endosperm acetolactate synthase activity. Evidence is presented to show that pyruvate decarboxylase contributes to apparent acetolactate synthase activity in crude embryo extracts and a modification of the acetolactate synthase assay is proposed to correct for the presence of pyruvate decarboxylase in unpurified plant homogenates. Endosperm acetolactate synthase activity increased rapidly during early kernel development, reaching a maximum of 3 micromoles acetoin per hour per endosperm at 25 days after pollination. In contrast, embryo activity was low in young kernels and steadily increased throughout development to a maximum activity of 0.24 micromole per hour per embryo by 45 days after pollination. The sensitivity of both endosperm and embryo acetolactate synthase activities to feedback inhibition by leucine + valine did not change during kernel development. The results are compared to those found for other enzymes of nitrogen metabolism and discussed with respect to the potential roles of the embryo and endosperm in providing amino acids for storage protein synthesis.     

Amino Acid Metabolism of Lemna minor L. : III. Responses to Aminooxyacetate

Aminooxyacetate, a known inhibitor of transaminase reactions and glycine decarboxylase, promotes rapid depletion of the free pools of serine and aspartate in nitrate grown Lemna minor L. This compound markedly inhibits the methionine sulfoximine-induced accumulation of free ammonium ions and greatly restricts the methionine sulfoximine-induced depletion of amino acids such as glutamate, alanine, and asparagine. These results suggest that glutamate, alanine, and asparagine are normally catabolized to ammonia by transaminase-dependent pathways rather than via dehydrogenase or amidohydrolase reactions. Aminooxyacetate does not inhibit the methionine sulfoximine-induced irreversible deactivation of glutamine synthetase in vivo, indicating that these effects cannot be simply ascribed to inhibition of methionine sulfoximine uptake by amino-oxyacetate. This transaminase inhibitor promotes extensive accumulation of several amino acids including valine, leucine, isoleucine, alanine, glycine, threonine, proline, phenylalanine, lysine, and tyrosine. Since the aminooxyacetate induced accumulations of valine, leucine, and isoleucine are not inhibited by the branched-chain amino acid biosynthesis inhibitor, chlorsulfuron, these amino acid accumulations most probably involve protein turnover. Depletions of soluble protein bound amino acids are shown to be approximately stoichiometric with the free amino acid pool accumulations induced by aminooxyacetate. Aminooxyacetate is demonstrated to inhibit the chlorsulfuron-induced accumulation of α-amino-n-butyrate in L. minor, supporting the notion that this amino acid is derived from transamination of 2-oxobutyrate.     

Genetic analysis of pathway regulation for enhancing branched‐chain amino acid biosynthesis in plants

The branched‐chain amino acids (BCAAs) valine, leucine and isoleucine are essential amino acids that play critical roles in animal growth and development. Animals cannot synthesize these amino acids and must obtain them from their diet. Plants are the ultimate source of these essential nutrients, and they synthesize BCAAs through a conserved pathway that is inhibited by its end products. This feedback inhibition has prevented scientists from engineering plants that accumulate high levels of BCAAs by simply over‐expressing the respective biosynthetic genes. To identify components critical for this feedback regulation, we performed a genetic screen for Arabidopsis mutants that exhibit enhanced resistance to BCAAs. Multiple dominant allelic mutations in the VALINE‐TOLERANT 1 (VAT1) gene were identified that conferred plant resistance to valine inhibition. Map‐based cloning revealed that VAT1 encodes a regulatory subunit of acetohydroxy acid synthase (AHAS), the first committed enzyme in the BCAA biosynthesis pathway. The VAT1 gene is highly expressed in young, rapidly growing tissues. When reconstituted with the catalytic subunit in vitro, the vat1 mutant‐containing AHAS holoenzyme exhibits increased resistance to valine. Importantly, transgenic plants expressing the mutated vat1 gene exhibit valine tolerance and accumulate higher levels of BCAAs. Our studies not only uncovered regulatory characteristics of plant AHAS, but also identified a method to enhance BCAA accumulation in crop plants that will significantly enhance the nutritional value of food and feed.     

Reversal of chlorsulfuron-induced inhibition of mitotic entry by isoleucine and valine

Pea (Pisum sativum L. cv Alaska) root tips were excised and cultured aseptically in White's medium. Cultures were treated immediately or after a 24 hour equilibration time with 28 nanomolar chlorsulfuron plus isoleucine and valine (each 0.1 millimolar), isoleucine and valine, or untreated. The percentage of mitotic figures in untreated control roots sampled immediately after excision showed a transitory drop and recovery within 24 hours (an excision effect). In chlorsulfuron-treated roots, the percentage of mitotic figures did not recover. In roots treated with chlorsulfuron plus isoleucine and valine, a complete recovery did occur. If roots were treated with chlorsulfuron 24 hours after excision, the percentage of mitotic figures was reduced to near 0 by 8 hours. In roots treated with chlorsulfuron plus isoleucine and valine, no reduction in mitotic figures occurred. The complete reversal of chlorsulfuron-inhibited mitotic entry by isoleucine and valine implicates these amino acids, in some manner, with the control of cell cycles progression.     

In-vivo control of valine and leucine synthesis in the duckweed Spirodela polyrhiza

Duckweed colonies were grown on 1 l of nutrient solution supplied with 10 M l-[¹⁴C]leucine or with 25 M l-[¹⁴C]valine. Under these conditions the exogenously supplied amino acid did not inhibit growth, but caused in the plants a moderately increased pool of that amino acid, which remained essentially constant during the culture period. The effect of the increased pool of valine or leucine on the biosynthesis of these amino acids was determined from isotope dilution in the protein-bound valine and-or leucine. An increase in the leucine pool from 1.1 to 5.0 nmol mg^–1 dry weight resulted in a 21% reduction of metabolite flow through the common part of the valine-leucine biosynthetic pathway; leucine synthesis was reduced by 35%, but valine synthesis by only 5% and isoleucine synthesis was apparently unaffected. An increase in the valine pool from 3.2 to 6.6 nmol mg^–1 dry weight reduced the metabolite flow through the valine-leucine pathway by 48%, valine synthesis by 70%, and leucine synthesis from pyruvate by 29%, which was compensated by leucine synthesis from exogenous valine, whereas the synthesis of isoleucine was not changed. It is concluded that the biosynthesis of valine and leucine is mainly controlled by feedback inhibition of acetohydroxyacid synthetase. In vivo, the feedback inhibition can be exerted in such a way that synthesis of acetolactate (the precursor of valine and leucine) is appreciably reduced, whereas synthesis of acetohydroxybutyrate (the isoleucine precursor) is not inhibited.     

Regulation of the Pool Size of Valine in Escherichia coli K-12

Three mutations (ilvH611, ilvH612, and ilvH613) are described which make Escherichia coli K-12 resistant to valine inhibition and are located near leu. The expression of the ilv genes appears to be normal in these mutants since the isoleucine-valine biosynthetic enzymes are not derepressed relative to the wild type. The intracellular concentration of valine is, however, higher in the mutants than in the isogenic ilvH(+) strain. These mutants also excrete valine, probably because of the high intracellular concentration of this amino acid. The pool size of valine is regulated independently from that of isoleucine and leucine. The increased intracellular concentration of valine is due to a decreased feedback inhibition that valine exerts on its own biosynthetic pathway. In fact, acetolactate synthase activity assayed in extracts of ilvH612 and ilvH613 mutants is more resistant to valine inhibition than the activity assayed in the ilvH(+) isogenic strain. Two forms of acetolactate synthase activity can be separated from these extracts by adsorption and elution on hydroxylapatite. One of them is as sensitive to valine inhibition as that of the wild type, the other is more resistant to valine inhibition.     

An acetohydroxy acid synthase mutant reveals a single site involved in multiple herbicide resistance

Acetohydroxy acid synthase (AHAS) is an essential enzyme for many organisms as it catalyzes the first step in the biosynthesis of the branched-chain amino acids valine, isoleucine, and leucine. The enzyme is under allosteric control by these amino acids. It is also inhibited by several classes of herbicides, such as the sulfonylureas, imidazolinones and triazolopyrimidines, that are believed to bind to a relic quinone-binding site. In this study, a mutant allele of AHAS3 responsible for sulfonylurea resistance in a Brassica napus cell line was isolated. Sequence analyses predicted a single amino acid change (557 TrpLeu) within a conserved region of AHAS. Expression in transgenic plants conferred strong resistance to the three classes of herbicides, revealing a single site essential for the binding of all the herbicide classes. The mutation did not appear to affect feedback inhibition by the branched-chain amino acids in plants.