The Role of Oxophytodienoate Reductases in the Detoxification of the Explosive 2,4,6-Trinitrotoluene by Arabidopsis

The explosive 2,4,6-trinitrotoluene (TNT) is a significant environmental pollutant that is both toxic and recalcitrant to degradation. Phytoremediation is being increasingly proposed as a viable alternative to conventional remediation technologies to clean up explosives-contaminated sites. Despite the potential of this technology, relatively little is known about the innate enzymology of TNT detoxification in plants. To further elucidate this, we used microarray analysis to identify Arabidopsis (Arabidopsis thaliana) genes up-regulated by exposure to TNT and found that the expression of oxophytodienoate reductases (OPRs) increased in response to TNT. The OPRs share similarity with the Old Yellow Enzyme family, bacterial members of which have been shown to transform explosives. The three predominantly expressed forms, OPR1, OPR2, and OPR3, were recombinantly expressed and affinity purified. Subsequent biochemical characterization revealed that all three OPRs are able to transform TNT to yield nitro-reduced TNT derivatives, with OPR1 additionally producing the aromatic ring-reduced products hydride and dihydride Meisenheimer complexes. Arabidopsis plants overexpressing OPR1 removed TNT more quickly from liquid culture, produced increased levels of transformation products, and maintained higher fresh weight biomasses than wild-type plants. In contrast, OPR1,2 RNA interference lines removed less TNT, produced fewer transformation products, and had lower biomasses. When grown on solid medium, two of the three OPR1 lines and all of the OPR2-overexpressing lines exhibited significantly enhanced tolerance to TNT. These data suggest that, in concert with other detoxification mechanisms, OPRs play a physiological role in xenobiotic detoxification.Large amounts of land and water are heavily contaminated by explosives, mainly as a result of the manufacture and military use of munitions. The high financial cost associated with cleaning up these contaminated sites largely precludes the use of many existing remediation technologies, such as soil excavation and incineration or disposal to landfill. There is a great deal of work documenting the global contamination, general toxicity, and microbial metabolism of 2,4,6-trinitrotoluene (TNT) in the environment; however, relatively little is known about the enzymes mediating the detoxification of TNT in plants (for review, see Rylott and Bruce, 2009).Phytoremediation, the use of plants to remove environmental pollutants, offers a low-cost, sustainable alternative to conventional remediation technologies and is attracting considerable attention as a means to clean up sites contaminated with explosives. While TNT is a potent phytotoxin, plants are able to detoxify low levels of TNT. In an effort to determine how plant tolerance could be further improved, we are investigating the biochemistry and enzymology underlying the innate ability of plants to detoxify TNT. The detoxification of xenobiotics has been loosely categorized into three phases (Sandermann, 1992): activation, conjugation, and compartmentation. The proposed route of TNT detoxification follows these phases. The electron-withdrawing properties of the nitro groups of TNT make the aromatic ring electron deficient. This favors reductive transformation reactions in plants, and the TNT molecule is most commonly activated by the reduction of a nitro group to give hydroxylamino and then amino derivatives (Fig. 1, pathway A). Following the introduction of a functional group, more hydrophilic molecules such as Glc are conjugated to the activated TNT molecule (Gandia-Herrero et al., 2008), facilitating transport and subsequent compartmentation or sequestration.Open in a separate windowFigure 1.The transformation of TNT by pentaerythritol tetranitrate reductase. Pathway A shows the transformation of the nitro group to nitroso-dinitrotoluene (NODNT), HADNT, and then ADNT products. Pathway B shows the reduction of the aromatic ring to form hydride and dihydride Meisenheimer complexes, then chemical condensation with HADNT to form diarylamines.Data from both our microarray experiments (Gandia-Herrero et al., 2008) and other expression studies (Ekman et al., 2003; Mezzari et al., 2005) have found that members of the small gene family of oxophytodienoate reductases (OPRs) in Arabidopsis (Arabidopsis thaliana) are up-regulated following exposure to TNT. The Arabidopsis genome contains three characterized OPRs: OPR1, OPR2, and OPR3. In addition, there are three as yet uncharacterized putative OPRs, named here as OPR4, OPR5, and OPR6, with OPR4 and OPR5 being identical. The physiological functions of the OPRs remain obscure, with the exception of OPR3, which is involved in jasmonic acid biosynthesis, converting (9S,13S)-12-oxophytodienoic acid to 3-2(2′(Z)-pentyl)cyclopentane-1-octanoic acid in the peroxisome (Sanders et al., 2000; Stintzi and Browse, 2000; for review, see Wasternack, 2007). OPR3 is located on chromosome II within the Arabidopsis genome and contains a C-terminal Ser-Arg-Leu type 1 peroxisome-targeting sequence. The remaining OPRs are all located on chromosome I and do not possess any known organelle-targeting sequences. The spatial expression of OPR1 and OPR2 across root cells where TNT accumulates (Biesgen and Weiler, 1999; Baerenfaller et al., 2008) favors a role in detoxification.The OPRs share similarity with the Old Yellow Enzyme family, a group of flavoenzymes that has been repeatedly associated with the transformation of explosives (Binks et al., 1996; Schaller and Weiler, 1997; Snape et al., 1997; Basran et al., 1998; French et al., 1998; Blehert et al., 1999; Pak et al., 2000; Fitzpatrick et al., 2003; Williams et al., 2004). Studies also indicate that Old Yellow Enzyme homologs function as antioxidants, detoxifying the breakdown products of lipid peroxidation and other toxic electrophilic compounds (Kohli and Massey, 1998; Williams and Bruce, 2002; Fitzpatrick et al., 2003; Trotter et al., 2006). This oxidative stress could result from exposure to xenobiotics including TNT, wounding, or pathogen attack.Pentaerythritol tetranitrate reductase, an Old Yellow Enzyme homolog isolated from Enterobacter cloacae (Binks et al., 1996), possesses two catalytic activities toward TNT (Fig. 1): nitroreduction of TNT to form hydroxylamino-dinitrotoluene (HADNT) and then amino-dinitrotoluene (ADNT), and aromatic ring reduction of TNT to yield hydride and dihydride (2H⁻-TNT) Meisenheimer TNT adducts (French et al., 1998; Williams et al., 2004). The TNT ring-reduced compounds condense via a nonenzymatic reaction with HADNTs to form diarylamines, with the liberation of nitrite (Wittich et al., 2008). Expression of pentaerythritol tetranitrate reductase in tobacco (Nicotiana tabacum) confers both resistance to, and the ability to transform, TNT (French et al., 1999). OPR1, OPR2, and OPR3 share 43%, 44%, and 36% identity, respectively, with pentaerythritol tetranitrate reductase, and all possess the conserved active site amino acids crucial for TNT transformation by pentaerythritol tetranitrate reductase and other members of the Old Yellow Enzyme family (Snape et al., 1997; French et al., 1998; Khan et al., 2004), suggesting that they are capable of transforming TNT.The OPR4/5 protein is predicted to have reduced activity toward TNT, compared with the other OPRs, owing to a C-terminal truncation that removes residues thought to be important in binding the cofactor NADH, Thus, we investigated OPR1, -2, and -3 as likely candidates for the TNT nitroreduction activity in Arabidopsis.