Abstract
Glyphosate, the world's most used herbicide, is a massive success because it enables efficient weed control with minimal animal and environmental toxicity. The molecular target of glyphosate is 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS), which catalyzes the sixth step of the shikimate pathway in plants and microorganisms. Glyphosate-tolerant variants of EPSPS constitute the basis of genetically engineered herbicide-tolerant crops. A single-site mutation of Pro(101) in EPSPS (numbering according to the enzyme from Escherichia coli) has been implicated in glyphosate-resistant weeds, but this residue is not directly involved in glyphosate binding, and the basis for this phenomenon has remained unclear in the absence of further kinetic and structural characterization. To probe the effects of mutations at this site, E. coli EPSPS enzymes were produced with glycine, alanine, serine, or leucine substituted for Pro(101). These mutant enzymes were analyzed by steady-state kinetics, and the crystal structures of the substrate binary and substrate.glyphosate ternary complexes of P101S and P101L EPSPS were determined to between 1.5- and 1.6-A resolution. It appears that residues smaller than leucine may be substituted for Pro(101) without decreasing catalytic efficiency. Any mutation at this site results in a structural change in the glyphosate-binding site, shifting Thr(97) and Gly(96) toward the inhibitor molecule. We conclude that the decreased inhibitory potency observed for glyphosate is a result of these mutation-induced long-range structural changes. The implications of our findings concerning the development and spread of glyphosate-resistant weeds are discussed.
Highlights
Biosynthesis of aromatic compounds in plants, fungi, bacteria, and apicomplexan parasites [2,3,4,5]
C Rcryst ϭ 100 ϫ ⌺͉Fobs Ϫ Fmodel/⌺Fobs, where Fobs and Fmodel are observed and calculated structure factor amplitudes, respectively. d Rfree is Rcryst calculated for randomly chosen unique reflections, which were excluded from the refinement (1264 for P101S EPSPS1⁄7S3P, 1279 for P101S EPSPS1⁄7S3P1⁄7glyphosate, 1396 for P101L EPSPS1⁄7S3P, and 1149 for P101L EPSPS1⁄7S3P1⁄7glyphosate)
P101S and P101L enolpyruvylshikimate-3-phosphate synthase (EPSPS) enzymes were crystallized at 19 °C sate, and the crystal structures were determined to between 1.5
Summary
Structure refinement Protein atoms Average B-factor (Å2) Ligand atoms Average B-factor (Å2). R.m.s.d. bonds (Å)b r.m.s.d. angles Rcryst (%)c Rfree (%)d Cross-validated estimated coordinate error From Luzzati plot (Å) From SigmaA (Å) Ramachandran statistics Most favored regions (%) allowed regions (%) Generously allowed regions (%) Disallowed regions (%). 92.2 7.5 0.3 0.0 a Rmerge ϭ 100 ϫ ⌺h⌺iIhi Ϫ Ih/⌺hiIhi, where h and i are unique reflection indices. C Rcryst ϭ 100 ϫ ⌺͉Fobs Ϫ Fmodel/⌺Fobs, where Fobs and Fmodel are observed and calculated structure factor amplitudes, respectively. D Rfree is Rcryst calculated for randomly chosen unique reflections, which were excluded from the refinement (1264 for P101S EPSPS1⁄7S3P, 1279 for P101S EPSPS1⁄7S3P1⁄7glyphosate, 1396 for P101L EPSPS1⁄7S3P, and 1149 for P101L EPSPS1⁄7S3P1⁄7glyphosate)
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