دورية أكاديمية
أعرض في EDS

Genome-wide study of glutathione transferases and their regulation in flufenacet susceptible and resistant black-grass (Alopecurus myosuroides Huds.).

التفاصيل البيبلوغرافية
العنوان: Genome-wide study of glutathione transferases and their regulation in flufenacet susceptible and resistant black-grass (Alopecurus myosuroides Huds.).
المؤلفون: Parcharidou E; Division of Plant Pathology and Crop Protection, Georg-August University Göttingen, Göttingen, Germany., Dücker R; Division of Plant Pathology and Crop Protection, Georg-August University Göttingen, Göttingen, Germany., Beffa R; Senior Scientist Consultant, Liederbach am Taunus, Germany.
المصدر: Pest management science [Pest Manag Sci] 2024 Jun; Vol. 80 (6), pp. 3035-3046. Date of Electronic Publication: 2024 Feb 19.
نوع المنشور: Journal Article
اللغة: English
بيانات الدورية: Publisher: Published for SCI by Wiley Country of Publication: England NLM ID: 100898744 Publication Model: Print-Electronic Cited Medium: Internet ISSN: 1526-4998 (Electronic) Linking ISSN: 1526498X NLM ISO Abbreviation: Pest Manag Sci Subsets: MEDLINE
أسماء مطبوعة: Original Publication: West Sussex, UK : Published for SCI by Wiley, c2000-
مواضيع طبية MeSH: Glutathione Transferase*/genetics , Glutathione Transferase*/metabolism , Herbicide Resistance*/genetics , Poaceae*/genetics , Poaceae*/enzymology , Herbicides*/pharmacology , Gene Expression Regulation, Plant* , Acetamides*/pharmacology, Plant Proteins/genetics ; Plant Proteins/metabolism ; Genome, Plant ; Genome-Wide Association Study ; Thiadiazoles
مستخلص: Background: Glutathione transferases (GSTs) are enzymes with a wide range of functions, including herbicide detoxification. Up-regulation of GSTs and their detoxification activity enables the grass weed black-grass (Alopecurus myosuroides Huds.) to metabolize the very-long-chain fatty acid synthesis inhibitor flufenacet and other herbicides leading to multiple herbicide resistance. However, the genomic organization and regulation of GSTs genes is still poorly understood.
Results: In this genome-wide study the location and expression of 115 GSTs were investigated using a recently published black-grass genome. Particularly, the most abundant GSTs of class tau and phi were typically clustered and often followed similar expression patterns but possessed divergent upstream regulatory regions. Similarities were found in the promoters of the most up-regulated GSTs, which are located next to each other in a cluster. The binding motif of the E2F/DP transcription factor complex in the promoter of an up-regulated GST was identical in susceptible and resistant plants, however, adjacent sequences differed. This led to a stronger binding of proteins to the motif of the susceptible plant, indicating repressor activity.
Conclusions: This study constitutes the first analysis dealing with the genomic investigation of GST genes found in black-grass and their transcriptional regulation. It highlights the complexity of the evolution of GSTs in black-grass, their duplication and divergence over time. The large number of GSTs allows weeds to detoxify a broad spectrum of herbicides. Ultimately, more research is needed to fully elucidate the regulatory mechanisms of GST expression. © 2024 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.
(© 2024 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.)
References: Labrou NE, Papageorgiou AC, Pavli O and Flemetakis E, Plant GSTome: structure and functional role in xenome network and plant stress response. Curr Opin Biotechnol 32:186–194 (2015).
Frova C, Glutathione transferases in the genomics era: new insights and perspectives. Biomol Eng 23:149–169 (2006).
Rigon CAG, Gaines TA, Küpper A and Dayan FE, Metabolism‐based herbicide resistance, the major threat among the non‐target site resistance mechanisms. Outlooks Pest Manage 31:162–168 (2020).
Martin JL, Thioredoxin—a fold for all reasons. Structure 3:245–250 (1995).
Nianiou‐Obeidat I, Madesis P, Kissoudis C, Voulgari G, Chronopoulou E, Tsaftaris A et al., Plant glutathione transferase‐mediated stress tolerance: functions and biotechnological applications. Plant Cell Rep 36:791–805 (2017).
Lallement P‐A, Brouwer B, Keech O, Hecker A and Rouhier N, The still mysterious roles of cysteine‐containing glutathione transferases in plants. Front Pharmacol 5:1–22 (2014).
Nyamai DW and Tastan Bishop Ö, Aminoacyl tRNA synthetases as malarial drug targets: a comparative bioinformatics study. Malar J 18:34 (2019).
Simader H, Hothorn M, Köhler C, Basquin J, Simos G and Suck D, Structural basis of yeast aminoacyl‐tRNA synthetase complex formation revealed by crystal structures of two binary sub‐complexes. Nucleic Acids Res 34:3968–3979 (2006).
Frechin M, Kern D, Martin RP, Becker HD and Senger B, Arc1p: anchoring, routing, coordinating. FEBS Lett 584:427–433 (2010).
Kumar S and Trivedi PK, Glutathione S‐transferases: role in combating abiotic stresses including arsenic detoxification in plants. Front Plant Sci 9:751 (2018).
Warner JR and Copley SD, Mechanism of the severe inhibition of tetrachlorohydroquinone dehalogenase by its aromatic substrates. Biochemistry 46:4438–4447 (2007).
Ioannou E, Papageorgiou AC and Labrou NE, Directed evolution of phi class glutathione transferases involved in multiple‐herbicide resistance of grass weeds and crops. Int J Mol Sci 23:1–26 (2022).
McGonigle B, Keeler SJ, Lau SM, Koeppe MK and O'Keefe DP, A genomics approach to the comprehensive analysis of the glutathione S‐transferase gene family in soybean and maize. Plant Physiol 124:1105–1120 (2000).
Parcharidou E, Dücker R, Zöllner P, Ries S, Orru R and Beffa R, Recombinant glutathione transferases from flufenacet‐resistant black‐grass (Alopecurus myosuroides Huds.) form different flufenacet metabolites and differ in their interaction with pre‐ and post‐emergence herbicides. Pest Manage Sci 79:7523 (2023).
Tal A, Romano ML, Stephenson GR, Schwan AL and Hall JC, Glutathione conjugation: a detoxification pathway for fenoxaprop‐ethyl in barley, crabgrass, oat and wheat. Pestic Biochem Physiol 46:190–199 (1993).
Goggin DE, Cawthray GR, Flematti GR, Bringans SD, Lim H, Beckie HJ et al., Pyroxasulfone‐resistant annual ryegrass (Lolium rigidum) has enhanced capacity for glutathione transferase‐mediated pyroxasulfone conjugation. J Agric Food Chem 69:6414–6422 (2021).
Anderson MP and Gronwald JW, Atrazine resistance in a velvetleaf (Abutilon theophrasti) biotype due to enhanced glutathione‐S‐transferase activity. Plant Physiol 96:104–109 (1991).
Shimabukuro RH, Swanson HR and Walsh WC, Glutathione conjugation: atrazine detoxication mechanism in corn. Plant Physiol 46:103–107 (1970).
Carringer RD, Rieck CE and Bush LP, Metabolism of EPTC in corn (Zea mays). Weed sci 26:157–160 (1978).
Cummins I, Cole DJ and Edwards R, A role for glutathione transferases functioning as glutathione peroxidases in resistance to multiple herbicides in black‐grass: glutathione transferases and herbicide resistance. Plant J 18:285–292 (1999).
Cummins I, Wortley DJ, Sabbadin F, He Z, Coxon CR, Straker HE et al., Key role for a glutathione transferase in multiple‐herbicide resistance in grass weeds. Proc Natl Acad Sci U S A 110:5812–5817 (2013).
Dücker R, Molecular Mechanisms of Flufenacet Resistance in Grass Weeds. Georg‐August University of Göttingen, Göttingen, Germany, (2020).
Yu Q and Powles S, Metabolism‐based herbicide resistance and cross‐resistance in crop weeds: a threat to herbicide sustainability and global crop production. Plant Physiol 166:1106–1118 (2014).
Bailly GC, Dale RP, Archer SA, Wright DJ and Kaundun SS, Role of residual herbicides for the management of multiple herbicide resistance to ACCase and ALS inhibitors in a black‐grass population. Crop Prot 34:96–103 (2012).
Lechelt‐Kunze C, Meissner RC, Drewes M and Tietjen K, Flufenacet herbicide treatment phenocopies the fiddlehead mutant in Arabidopsis thaliana. Pest Manage Sci 59:847–856 (2003).
Trenkamp S, Martin W and Tietjen K, Specific and differential inhibition of very‐long‐chain fatty acid elongases from Arabidopsis thaliana by different herbicides. Proc Natl Acad Sci U S A 101:11903–11908 (2004).
Haslam TM and Kunst L, Extending the story of very‐long‐chain fatty acid elongation. Plant Sci 210:93–107 (2013).
Dücker R, Zöllner P, Parcharidou E, Ries S, Lorentz L and Beffa R, Enhanced metabolism causes reduced flufenacet sensitivity in black‐grass (Alopecurus myosuroides Huds.) field populations. Pest Manage Sci 75:2996–3004 (2019).
Dücker R, Zöllner P, Lümmen P, Ries S, Collavo A and Beffa R, Glutathione transferase plays a major role in flufenacet resistance of ryegrass (Lolium spp.) field populations. Pest Manage Sci 75:3084–3092 (2019).
Dücker R, Parcharidou E and Beffa R, Flufenacet activity is affected by GST inhibitors in blackgrass (Alopecurus myosuroides) populations with reduced flufenacet sensitivity and higher expression levels of GSTs. Weed Sci 68:451–459 (2020).
Lallemand T, Leduc M, Landès C, Rizzon C and Lerat E, An overview of duplicated gene detection methods: why the duplication mechanism has to be accounted for in their choice. Genes 11:1046 (2020).
Leister D, Tandem and segmental gene duplication and recombination in the evolution of plant disease resistance genes. Trends Genet 20:116–122 (2004).
Liu H‐J, Tang Z‐X, Han X‐M, Yang Z‐L, Zhang F‐M, Yang H‐L et al., Divergence in enzymatic activities in the soybean GST supergene family provides new insight into the evolutionary dynamics of whole‐genome duplicates. Mol Biol Evol 32:2844–2859 (2015).
Khan N, Hu C, Amjad Khan W and Hou X, Genome‐wide identification, classification, and expression divergence of glutathione‐transferase family in Brassica rapa under multiple hormone treatments. Biomed Res Int 2018:1–19 (2018).
Wei L, Zhu Y, Liu R, Zhang A, Zhu M, Xu W et al., Genome wide identification and comparative analysis of glutathione transferases (GST) family genes in Brassica napus. Sci Rep 9:9196 (2019).
Nebert DW and Vasiliou V, Analysis of the glutathione S‐transferase (GST) gene family. Hum Genomics 1:460–464 (2004).
Fedoroff N, Transposons and genome evolution in plants. Proc Natl Acad Sci 97:7002–7007 (2000).
Bourque G, Burns KH, Gehring M, Gorbunova V, Seluanov A, Hammell M et al., Ten things you should know about transposable elements. Genome Biol 19:199 (2018).
Mascher M, Gundlach H, Himmelbach A, Beier S, Twardziok SO, Wicker T et al., A chromosome conformation capture ordered sequence of the barley genome. Nature 544:427–433 (2017).
Cai L, Comont D, MacGregor D, Lowe C, Beffa R, Neve P et al., The blackgrass genome reveals patterns of non‐parallel evolution of polygenic herbicide resistance. New Phytol 237:1891–1907 (2023).
Wicker T, Gundlach H, Spannagl M, Uauy C, Borrill P, Ramírez‐González RH et al., Impact of transposable elements on genome structure and evolution in bread wheat. Genome Biol 19:103 (2018).
Marrs KA, The functions and regulation of glutathione S‐transferases in plants. Annu Rev Plant Physiol Plant Mol Biol 47:127–158 (1996).
Frova C, The plant glutathione transferase gene family: genomic structure, functions, expression and evolution. Physiol Plant 119:469–479 (2003).
Zhang B and Singh KB, Ocs element promoter sequences are activated by auxin and salicylic acid in Arabidopsis. Proc Natl Acad Sci U S A 91:2507–2511 (1994).
Ulmasov T, Hagen G and Guilfoyle T, The ocs element in the soybean GH2/4 promoter is activated by both active and inactive auxin and salicylic acid analogues. Plant Mol Biol 26:1055–1064 (1994).
Chen W, Chao G and Singh KB, The promoter of a H2O2‐inducible, Arabidopsis glutathione S‐transferase gene contains closely linked OBF‐ and OBP1‐binding sites. Plant J 10:955–966 (1996).
Lam E and Lam YK, Binding site requirements and differential representation of TGF factors in nuclear ASF‐1 activity. Nucleic Acids Res 23:3778–3785 (1995).
Meraj TA, Fu J, Raza MA, Zhu C, Shen Q, Xu D et al., Transcriptional factors regulate plant stress responses through mediating secondary metabolism. Genes 11:346 (2020).
Uchida Y, Chiyomaru T, Enokida H, Kawakami K, Tatarano S, Kawahara K et al., MiR‐133a induces apoptosis through direct regulation of GSTP1 in bladder cancer cell lines. Urol Oncol 31:115–123 (2013).
Moriya Y, Nohata N, Kinoshita T, Mutallip M, Okamoto T, Yoshida S et al., Tumor suppressive microRNA‐133a regulates novel molecular networks in lung squamous cell carcinoma. J Hum Genet 57:38–45 (2012).
Zhang X, Zhu J, Xing R, Tie Y, Fu H, Zheng X et al., miR‐513a‐3p sensitizes human lung adenocarcinoma cells to chemotherapy by targeting GSTP1. Lung Cancer 77:488–494 (2012).
Robinson MD, McCarthy DJ and Smyth GK, edgeR: a Bioconductor package for differential expression analysis of digital gene expression data. Bioinformatics 26:139–140 (2010).
Oliveros JC, Venny. An interactive tool for comparing lists with Venn's diagrams (2007‐2015). https://bioinfogp.cnb.csic.es/tools/venny/index.html.
Edgar RC, MUSCLE: a multiple sequence alignment method with reduced time and space complexity. BMC Bioinf 5:113 (2004).
Tamura K, Stecher G and Kumar S, MEGA11: molecular evolutionary genetics analysis version 11, ed. by Battistuzzi FU. Mol Biol Evol 38:3022–3027 (2021).
Chen C, Chen H, Zhang Y, Thomas HR, Frank MH, He Y et al., TBtools: an integrative toolkit developed for interactive analyses of big biological data. Mol Plant 13:1194–1202 (2020).
WeedPedia, International Weed Genomics Consortium, International Weed Genomics Consortium https://www.weedgenomics.org/weedpedia/.
TAIR: Bulk Protein Search, https://www.arabidopsis.org/tools/bulk/protein/index.jsp. Accessed 18 June 2023.
Robinson JT, Thorvaldsdóttir H, Winckler W, Guttman M, Lander ES, Getz G et al., Integrative genomics viewer. Nat Biotechnol 29:24–26 (2011).
Tian F, Yang D‐C, Meng Y‐Q, Jin J and Gao G, PlantRegMap: charting functional regulatory maps in plants. Nucleic Acids Res 48:D1104–D1113 (2020).
Jin J, Tian F, Yang D‐C, Meng Y‐Q, Kong L, Luo J et al., PlantTFDB 4.0: toward a central hub for transcription factors and regulatory interactions in plants. Nucleic Acids Res 45:D1040–D1045 (2017).
Chronopoulou E, Ataya FS, Pouliou F, Perperopoulou F, Georgakis N, Nianiou‐Obeidat I et al., Structure, evolution and functional roles of plant glutathione transferases, in Glutathione in Plant Growth, Development, and Stress Tolerance, ed. by Hossain MA, Mostofa MG, Diaz‐Vivancos P, Burritt DJ, Fujita M and Tran L‐SP. Springer International Publishing, Cham, pp. 195–213 (2017).
Heap I, The International Herbicide‐Resistant Weed Database Accessed on Tuesday, August 08, 2023. Available on www.weedscience.org (2023).
Coleman J, Blake‐Kalff M and Davies E, Detoxification of xenobiotics by plants: chemical modification and vacuolar compartmentation. Trends Plant Sci 2:144–151 (1997).
Kersten S, Chang J, Huber CD, Voichek Y, Lanz C, Hagmaier T et al., Standing genetic variation fuels rapid evolution of herbicide resistance in blackgrass. Proc Natl Acad Sci U S A 120:e2206808120 (2023).
Gaines TA, Lorentz L, Figge A, Herrmann J, Maiwald F, Ott M et al., RNA‐Seq transcriptome analysis to identify genes involved in metabolism‐based diclofop resistance in Lolium rigidum. Plant J 78:865–876 (2014).
Kreiner JM, Tranel PJ, Weigel D, Stinchcombe JR and Wright SI, The genetic architecture and population genomic signatures of glyphosate resistance in Amaranthus tuberculatus. Mol Ecol 30:5373–5389 (2021).
Van Etten M, Lee KM, Chang S‐M and Baucom RS, Parallel and nonparallel genomic responses contribute to herbicide resistance in Ipomoea purpurea, a common agricultural weed. PLoS Genet 16:e1008593 (2020).
Werck‐Reichhart D, Hehn A and Didierjean L, Cytochromes P450 for engineering herbicide tolerance. Trends Plant Sci 5:116–123 (2000).
Buchmann A, Kuhlmann W, Schwarz M, Kunz W, Wolf CR, Moll E et al., Regulation and expression of four cytochrome P‐450 isoenzymes, NADPH‐cytochrome P‐450 reductase, the glutathione transferases B and C and microsomal epoxide hydrolase in preneoplastic and neoplastic lesions in rat liver. Carcinogenesis 6:513–521 (1985).
Goldberg‐Cavalleri A, Onkokesung N, Franco‐Ortega S and Edwards R, ABC transporters linked to multiple herbicide resistance in blackgrass (Alopecurus myosuroides). Front Plant Sci 14:1082761 (2023).
Sappl PG, Carroll AJ, Clifton R, Lister R, Whelan J, Harvey Millar A et al., The Arabidopsis glutathione transferase gene family displays complex stress regulation and co‐silencing multiple genes results in altered metabolic sensitivity to oxidative stress. Plant J 58:53–68 (2009).
Jain M, Ghanashyam C and Bhattacharjee A, Comprehensive expression analysis suggests overlapping and specific roles of rice glutathione S‐transferase genes during development and stress responses. BMC Genomics 11:73 (2010).
He G, Guan C‐N, Chen Q‐X, Gou X‐J, Liu W, Zeng Q‐Y et al., Genome‐wide analysis of the glutathione S‐transferase gene family in Capsella rubella: identification, expression, and biochemical functions. Front Plant Sci 7:1–14 (2016).
Rezaei MK, Shobbar Z‐S, Shahbazi M, Abedini R and Zare S, Glutathione S‐transferase (GST) family in barley: identification of members, enzyme activity, and gene expression pattern. J Plant Physiol 170:1277–1284 (2013).
Dong Y, Li C, Zhang Y, He Q, Daud MK, Chen J et al., Glutathione S‐transferase gene family in Gossypium raimondii and G. Arboreum: comparative genomic study and their expression under salt stress. Front Plant Sci 7:1–16 (2016).
Soranzo N, Sari Gorla M, Mizzi L, De Toma G and Frova C, Organisation and structural evolution of the rice glutathione S‐transferase gene family. Mol Genet Genomics 271:511–521 (2004).
Dixon DP, Lapthorn A and Edwards R, Plant glutathione transferases. Genome Biol 3:1–10 (2002).
Li Z, McKibben MTW, Finch GS, Blischak PD, Sutherland BL and Barker MS, Patterns and processes of diploidization in land plants. Annu Rev Plant Biol 72:387–410 (2021).
Wolfe KH, Yesterday's polyploids and the mystery of diploidization. Nat Rev Genet 2:333–341 (2001).
Loyall L, Uchida K, Braun S, Furuya M and Frohnmeyer H, Glutathione and a UV light‐induced glutathione S‐transferase are involved in signaling to chalcone synthase in cell cultures. Plant Cell 12:1939–1950 (2000).
Karavangeli M, Labrou NE, Clonis YD and Tsaftaris A, Development of transgenic tobacco plants overexpressing maize glutathione S‐transferase I for chloroacetanilide herbicides phytoremediation. Biomol Eng 22:121–128 (2005).
Benekos K, Kissoudis C, Nianiou‐Obeidat I, Labrou N, Madesis P, Kalamaki M et al., Overexpression of a specific soybean GmGSTU4 isoenzyme improves diphenyl ether and chloroacetanilide herbicide tolerance of transgenic tobacco plants. J Biotechnol 150:195–201 (2010).
Jha B, Sharma A and Mishra A, Expression of SbGSTU (tau class glutathione S‐transferase) gene isolated from Salicornia brachiata in tobacco for salt tolerance. Mol Biol Rep 38:4823–4832 (2011).
Gullner G, Komives T, Király L and Schröder P, Glutathione S‐transferase enzymes in plant‐pathogen interactions. Front Plant Sci 9:1836 (2018).
Hasan MS, Singh V, Islam S, MdS I, Ahsan R, Kaundal A et al., Genome‐wide identification and expression profiling of glutathione S‐transferase family under multiple abiotic and biotic stresses in Medicago truncatula L. PLoS One 16:e0247170 (2021).
Choudhuri S, Fundamentals of molecular evolution, in Bioinformatics for Beginners. Elsevier, UK, pp. 27–53 (2014).
Lan T, Yang Z‐L, Yang X, Liu Y‐J, Wang X‐R and Zeng Q‐Y, Extensive functional diversification of the Populus glutathione S—transferase supergene family. Plant Cell 21:3749–3766 (2010).
Maeso I and Tena JJ, Favorable genomic environments for cis‐regulatory evolution: a novel theoretical framework. Semin Cell Dev Biol 57:2–10 (2016).
Force A, Lynch M, Pickett FB, Amores A, Yan Y and Postlethwait J, Preservation of duplicate genes by complementary, degenerative mutations. Genetics 151:1531–1545 (1999).
van den Heuvel S and Dyson NJ, Conserved functions of the pRB and E2F families. Nat Rev Mol Cell Biol 9:713–724 (2008).
Ramirez‐Parra E and Gutierrez C, Characterization of wheat DP, a heterodimerization partner of the plant E2F transcription factor which stimulates E2F‐DNA binding. FEBS Lett 486:73–78 (2000).
Heckmann S, Lermontova I, Berckmans B, De Veylder L, Bäumlein H and Schubert I, The E2F transcription factor family regulates CENH3 expression in Arabidopsis thaliana: regulation of AtCENH3 expression. Plant J 68:646–656 (2011).
Shen W‐H, The plant E2F–Rb pathway and epigenetic control. Trends Plant Sci 7:505–511 (2002).
Ramirez‐Parra E, López‐Matas MA, Fründt C and Gutierrez C, Role of an atypical E2F transcription factor in the control of Arabidopsis cell growth and differentiation. Plant Cell 16:2350–2363 (2004).
Atchley W, Terhalle W and Dress A, Positional dependence, cliques, and predictive motifs in the bHLH protein domain. J Mol Evol 48:501–516 (1999).
Fisher F and Goding CR, Single amino acid substitutions alter helix‐loop‐helix protein specificity for bases flanking the core CANNTG motif. EMBO J 11:4103–4109 (1992).
Guo A‐Y, Chen X, Gao G, Zhang H, Zhu Q‐H, Liu X‐C et al., PlantTFDB: a comprehensive plant transcription factor database. Nucleic Acids Res 36:D966–D969 (2007).
PlantTFDB Plant Transcription Factor Database@CBI, PKU. http://planttfdb.gao-lab.org/help_famschema.php. Accessed 10 May 2023.
Nakano T, Suzuki K, Fujimura T and Shinshi H, Genome‐wide analysis of the ERF gene family in Arabidopsis and Rice. Plant Physiol 140:411–432 (2006).
Bartels D and Sunkar R, Drought and salt tolerance in plants. Crit Rev Plant Sci 24:23–58 (2005).
Wang J, Resistance to mesosulfuron‐methyl in Beckmannia syzigachne may involve ROS burst and non‐target‐site resistance mechanisms. Ecotoxicol Environ Saf 229:1–9 (2022).
معلومات مُعتمدة: Bayer AG, CropScience Division
فهرسة مساهمة: Keywords: E2F/DP; black‐grass GSTome; duplication; electrophoretic mobility shift assay (EMSA); herbicide resistance; transcription factor binding sites (TFBSs)
المشرفين على المادة: EC 2.5.1.18 (Glutathione Transferase)
0 (Herbicides)
0 (Acetamides)
0 (Plant Proteins)
142459-58-3 (FOE 5043)
0 (Thiadiazoles)
تواريخ الأحداث: Date Created: 20240207 Date Completed: 20240513 Latest Revision: 20240513
رمز التحديث: 20240513
DOI: 10.1002/ps.8012
PMID: 38323683
قاعدة البيانات: MEDLINE
الوصف
تدمد:1526-4998
DOI:10.1002/ps.8012