BackgroundParaquat is one of the most effective herbicides used to control weeds in agricultural management, while the pernicious weed goosegrass (Eleusine indica) has evolved resistance to herbicides, including paraquat. Polyamines provide high-level paraquat resistance in many plants. In the present study, we selected three polyamines, namely, putrescine, spermidine, and spermine, as putative genes to investigate their correlation with paraquat resistance by using paraquat-resistant (R) and paraquat-susceptible (S) goosegrass populations.ResultsThere was no significant difference in the putrescine nor spermine content between the R and S biotypes. However, 30 and 90 min after paraquat treatment, the spermidine concentration was 346.14-fold and 421.04-fold (P < 0.001) higher in the R biotype than in the S biotype, but the spermidine concentration was drastically reduced to a marginal level after 90 min. Since the transcript level of PqE was low while the spermidine concentration showed a transient increase, the PqE gene was likely involved in the synthesis of the paraquat resistance mechanism, regulation of polyamine content, and synthesis of spermidine and spermine. PqTS1, PqTS2, and PqTS3 encode transporter proteins involved in the regulation of paraquat concentration but showed different transcription patterns with synchronous changes in polyamine content.ConclusionEndogenous polyamines (especially spermidine) play a vital role in paraquat resistance in goosegrass. PqE, PqTS1, PqTS2, and PqTS3 were speculated on the relationship between polyamine metabolism and paraquat resistance. To validate the roles of PqE, PqTS1, PqTS2, and PqTS3 in polyamine transport systems, further research is needed.
A novel and practical photoredox-catalyzed generation of sulfamyl radicals followed by radical sulfonamidation of enol silyl ether has been described. Diverse functionalized β-ketosulfonamides were prepared in modest to excellent yields under mild and economic reaction conditions through the present catalytic protocol. Furthermore, the methodology developed provides an efficient and convenient approach to the synthesis of the antiseizure drug Zonisamide.
BACKGROUND: Paraquat is used widely as one of the bipyridine herbicides, which generates reactive oxygen species to cause cell death. With a growing number of paraquat-resistant weeds, the mechanism of paraquat-resistance in plants remains unclear. This research verified the functions of a previously confirmed putative paraquat-resistant gene, EiKCS, from paraquat-resistant goosegrass by genetic engineering in a single overexpressing line in rice.RESULTS: Overexpression of EiKCS improved paraquat resistance in transgenic rice (KCSox). Pre-applied (12 h) exogenous spermidine (1.5 mmol L −1 ), alleviated the injury of paraquat in rice. Paraquat induced injury in KCSox was 19.57%, which was lower than 32.22% injury it induced in wild-type (WT) rice. The paraquat-resistant mechanism was through the increased activity of antioxidant enzymes and the overproduction of endogenous polyamines. The spermine content in KCSox was more than 30 ∼g mL −1 , while that in WT rice was less than 5 ∼g mL −1 . Quantitative proteomics showed that ⊎-ketoacyl-coenzyme A (CoA) synthase ( 51.81 folds) encoded by the transgenic EiKCS gene promoted the synthesis of the proteins involved with the polyamine pathway. The synthesized putrescine was promoted by the arginine decarboxylase (ADC) pathway. The spermidine synthase I (1.10-fold) and three eceriferum cofactors (CERs) were responsive to the paraquat stress. We validated putrescine (C 18 H 20 N 2 O 2 ) spermidine (C 28 H 31 N 3 O 3 ), and spermine (C 38 H 42 N 4 O 4 ) in this study.CONCLUSION: EiKCS encoding ⊎-ketoacyl-CoA synthase from goosegrass has been shown as an ideal candidate gene for engineering genetically modified organism (GMO) crops, as its overexpression does not only bring paraquat-resistance, but also have potential benefits without decreasing yield and rice grain quality.
CRISPR/Cas9-based cytosine base editors (CBEs) and adenine base editors (ABEs) can efficiently mediate C-to-T/G-to-A and A-to-G/T-to-C substitutions, respectively; however, achieving base transversions (C-to-G/C-to-A and A-to-T/A-to-C) is challenging and has been rarely studied in plants. Here, we constructed new plant C-to-G base editors (CGBEs) and new A-to-Y (T/C) base editors and explored their base editing characteristics in rice. First, we fused the highly active cytidine deaminase evoFENRY and the PAM-relaxed Cas9-nickase variant Cas9n-NG with rice and human uracil DNA N-glycosylase (rUNG and hUNG), respectively, to construct CGBE-rUNG and CGBE-hUNG vector tools. The analysis of five NG-PAM target sites showed that these CGBEs achieved C-to-G conversions with monoallelic editing efficiencies of up to 27.3% in T0 rice, with major byproducts being insertion/deletion mutations. Moreover, for the A-to-Y (C or T) editing test, we fused the highly active adenosine deaminase TadA8e and the Cas9-nickase variant SpGn (with NG-PAM) with Escherichia coli endonuclease V (EndoV) and human alkyladenine DNA glycosylase (hAAG), respectively, to generate ABE8e-EndoV and ABE8e-hAAG vectors. An assessment of five NG-PAM target sites showed that these two vectors could efficiently produce A-to-G substitutions in a narrow editing window; however, no A-to-Y editing was detected. Interestingly, the ABE8e-EndoV also generated precise small fragment deletions in the editing window from the 5′-deaminated A base to the SpGn cleavage site, suggesting its potential value in producing predictable small-fragment deletion mutations. Overall, we objectively evaluated the editing performance of CGBEs in rice, explored the possibility of A-to-Y editing, and developed a new ABE8e-EndoV tool, thus providing a valuable reference for improving and enriching base editing tools in plants.
20Background : Paraquat is one of the most effective herbicides used to control weeds 21 in agricultural management, while the pernicious weed goosegrass (Eleusine indica) 22 has evolved resistance to herbicides, including paraquat. Polyamines provide high-23 level paraquat resistance in many plants. In the present study, we selected three 24 polyamines, namely, putrescine, spermidine, and spermine, as putative genes to 25 investigate their correlation with paraquat resistance by using paraquat-resistant (R) 26 and paraquat-susceptible (S) goosegrass populations. 27Results: There was no significant difference in the putrescine nor spermine content 28 between the R and S biotypes. However, 30 and 90 min after paraquat treatment, the 29 spermidine concentration was 346.14-fold and 421.04-fold (P < 0.001) higher in the R 30 biotype than in the S biotype, but the spermidine concentration was drastically reduced 31 to a marginal level after 90 min. Since the transcript level of PqE was low while the 32 spermidine concentration showed a transient increase, the PqE gene was likely 33 involved in the synthesis of the paraquat resistance mechanism, regulation of 34 polyamine content, and synthesis of spermidine and spermine. PqTS1, PqTS2, and 35 PqTS3 encode transporter proteins involved in the regulation of paraquat concentration 36 but showed different transcription patterns with synchronous changes in polyamine 37 content. 38 Conclusion: Endogenous polyamines (especially spermidine) play a vital role in 39 paraquat resistance in goosegrass. PqE, PqTS1, PqTS2, and PqTS3 were speculated on 40 the relationship between polyamine metabolism and paraquat resistance. To validate 41 the roles of PqE, PqTS1, PqTS2, and PqTS3 in polyamine transport systems, further 42 research is needed. 43 3 44 45
Eleusine indica (goosegrass) is a problematic weed worldwide known for its multi-herbicide tolerance/resistance biotype. However, a genetic transformation method in goosegrass has not been successfully established, making a bottleneck for functional genomics studies in this species. Here, we report a successful Agrobacterium-mediated transformation method for goosegrass. Firstly, we optimized conditions for breaking seed dormancy and increasing seed germination rate. A higher callus induction rate from germinated seeds was obtained in N6 than in MS or B5 medium. Then the optimal transformation efficiency of the gus reporter gene was obtained by infection with Agrobacterium tumefaciens culture of OD600 = 0.5 for 30 min, followed by 3 days of co-cultivation with 300 μmol/L acetosyringone. Concentrations of 20 mg L−1 kanamycin and 100 mg L−1 timentin were used to select the transformed calli. The optimal rate of regeneration of the calli was generated by using 0.50 mg L−1 6-BA and 0.50 mg L−1 KT in the culture medium. Then, using this transformation method, we overexpressed the paraquat-resistant EiKCS gene into a paraquat-susceptible goosegrass biotype MZ04 and confirmed the stable inheritance of paraquat-resistance in the transgenic goosegrass lines. This approach may provide a potential mechanism for the evolution of paraquat-resistant goosegrass and a promising gene for the manipulation of paraquat-resistance plants. This study is novel and valuable in future research using similar methods for herbicide resistance.
Paraquat is an important bipyridine herbicide by acting on the photosynthetic system of the plants and generating reactive oxygen species leading to cell death, whereas the mechanism of the paraquat resistance remains to be explored. In this study, a putative paraquat-resistant gene EiKCS from goosegrass (Eleusine indica L.) was isolated and overexpressed in a transgenic rice (Oryza sativa L.). This transgenic rice (KCSox) was treated by exogenous spermidine and paraquat and then was analyzed by qualitative and quantitative proteomics. Overexpressing of EiKCS enhanced paraquat tolerance in KCSox by the accumulation of endogenous polyamines whose dominant presences of polyamines benzoylation derivatizations in rice were C18H20N2O2, C28H31N3O3, and C38H42N4O4. The mechanism underlying the improving tolerance enhanced antioxidant capacity of ROS systems and light-harvesting in photosynthesis in KCSox rice leaves to reducing paraquat toxicity. The protein β-Ketoacyl-CoA Synthase (EiKCS) encoded by the EiKCS gene promoted the synthesis and metabolism of proteins of the polyamine pathway. Three cofactors CERs were identified and positively correlated with the function of EiKCS on very-long-chain fatty acids (VLCFAs) biosynthesis via promoting the polyamine pathway and inhibiting the links with the TCA pathway and fatty acid pathway to responding to the paraquat tolerance in the KCSox rice, which also caused the prolongation of the overproduction of spermine and a transient increase of intracellular malondialdehyde (MDA). These results expanded the polyamines pathway manipulated in cereals using genetic engineering to clarify the mechanism of paraquat-tolerance.One Sentence SummaryA putative paraquat-resistant EiKCS gene from the goosegrass overexpressing in the rice resulted in the accumulation of polyamines, especially the spermine, and promoted the proteins in polyamine pathways by its EiKCS protein under paraquat stress.
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