Background: Lonicera macranthoides is an important woody plant with high medicinal values widely cultivated in southern China. WRKY, one of the largest transcription factor families, participates in plant development, senescence, and stress responses. However, a comprehensive study of the WRKY family in L. macranthoides hasn't been reported previously.
Objective: To establish an extensive overview of the WRKY family in L. macranthoides and identify senescence-responsive members of LmWRKYs.
Methods: RNA-Seq and phylogenetic analysis were employed to identify the LmWRKYs and their evolutionary relationships. Quantitative real-time (qRT-PCR) and transgenic technology was utilized to investigate the roles of LmWRKYs in response to developmental-, cold-, and ethylene-induced senescence.
Results: A total of 61 LmWRKY genes with a highly conserved motif WRKYGQK were identified. Phylogenetic analysis of LmWRKYs together with their orthologs from Arabidopsis classified them into three groups, with the number of 15, 39, and 7, respectively. 17 LmWRKYs were identified to be differentially expressed between young and aging leaves by RNA-Seq. Further qRT-PCR analysis showed 15 and 5 LmWRKY genes were significantly induced responding to tissue senescence in leaves and stems, respectively. What's more, five LmWRKYs, including LmWRKY4, LmWRKY5, LmWRKY6, LmWRKY11, and LmWRKY16 were dramatically upregulated under cold and ethylene treatment in both leaves and stems, indicating their involvements commonly in developmental- and stress-induced senescence. In addition, function analysis revealed LmWRKY16, a homolog of AtWRKY75, can accelerate plant senescence, as evidenced by leaf yellowing during reproductive growth in LmWRKY16-overexpressing tobaccos.
Conclusion: The results lay the foundation for molecular characterization of LmWRKYs in plant senescence.

1 Niu CF, "Wheat WRKY genes TaWRKY2 and TaWRKY19 regulate abiotic stress tolerance in transgenic Arabidopsis plants" 35 (35): 1156-1170, 2012

2 Chen L, "WRKY8 transcription factor functions in the TMV-cg defense response by mediating both abscisic acid and ethylene signaling in Arabidopsis" 110 (110): E1963-E1971, 2013

3 Bhattarai KK, "WRKY72-type transcription factors contribute to basal immunity in tomato and Arabidopsis as well as gene-for-gene resistance mediated by the tomato R gene Mi-1" 63 (63): 229-240, 2010

4 Besseau S, "WRKY54 and WRKY70 co-operate as negative regulators of leaf senescence in Arabidopsis thaliana" 63 (63): 2667-2679, 2012

5 Xiang Zhou ; Diqiu Yu ; Yanjuan Jiang, "WRKY22 Transcription Factor Mediates Dark-Induced Leaf Senescence in Arabidopsis" 한국분자세포생물학회 31 (31): 303-313, 2011

6 Jiang J, "WRKY transcription factors in plant responses to stresses" 59 (59): 86-101, 2017

7 Rushton DL, "WRKY transcription factors : key components in abscisic acid signalling" 10 (10): 2-11, 2012

8 Rushton PJ, "WRKY transcription factors" 15 (15): 247-258, 2010

9 Park CY, "WRKY group IId transcription factors interact with calmodulin" 579 (579): 1545-1550, 2005

10 Aguayo P, "Transcriptome-wide identification of WRKY family genes and their expression under cold acclimation in Eucalyptus globulus" 33 (33): 1313-1327, 2019

11 Guo Y, "Transcriptome of Arabidopsis leaf senescence" 27 (27): 521-549, 2004

12 Chen ZX, "Transcriptome analysis reveals the mechanism underlying the production of a high quantity of chlorogenic acid in young leaves of Lonicera macranthoides Hand.-Mazz" 2015

13 Chen Z, "Transcriptome analysis reveals molecular signatures of luteoloside accumulation in senescing leaves of Lonicera macranthoides" 19 (19): 1012-, 2018

14 Cannon SB, "The roles of segmental and tandem gene duplication in the evolution of large gene families in Arabidopsis thaliana" 4 (4): 10-, 2004

15 Pu X, "The honeysuckle genome provides insight into the molecular mechanism of carotenoid metabolism underlying dynamic flower coloration" 227 (227): 930-943, 2020

16 Sun XM, "The ethylene response factor VaERF092 from Amur grape regulates the transcription factor VaWRKY33, improving cold tolerance" 99 (99): 988-1002, 2019

17 Eulgem T, "The WRKY superfamily of plant transcription factors" 5 (5): 199-206, 2000

18 Wang L, "ThERF1 from Tamarix hispida confers decreased tolerance to oxidative and drought stresses and is regulated by a WRKY protein" 27 (27): 767-772, 2016

19 Miao Y, "Targets of the WRKY53 transcription factor and its role during leaf senescence in Arabidopsis" 55 (55): 853-867, 2004

20 Robatzek S, "Targets of AtWRKY6 regulation during plant senescence and pathogen defense" 16 (16): 1139-1149, 2002

21 Zhou QY, "Soybean WRKY-type transcription factor genes, GmWRKY13, GmWRKY21, and GmWRKY54, confer differential tolerance to abiotic stresses in transgenic Arabidopsis plants" 6 (6): 486-503, 2008

22 Wang L, "Regulation of ethylene-responsive SlWRKYs involved in color change during tomato fruit ripening" 2017

23 Chen XT, "Overexpression of AtWRKY28 and AtWRKY75 in Arabidopsis enhances resistance to oxalic acid and Sclerotinia sclerotiorum" 32 (32): 1589-1599, 2013

24 Mohanta TK, "Novel genomic and evolutionary insight of WRKY transcription factors in plant lineage" 2016

25 Zou CS, "Male gametophyte-specific WRKY34 transcription factor mediates cold sensitivity of mature pollen in Arabidopsis" 61 (61): 3901-3914, 2010

26 Shi C-Y, "Luteoloside exerts analgesic effect in a complete freund’s adjuvant-induced inflammatory model via inhibiting interleukin-1β expression and macrophage/microglia activation" 11 : 1158-, 2020

27 Chen L, "Leaf senescence exhibits stronger climatic responses during warm than during cold autumns" 10 (10): 777-780, 2020

28 Woo HR, "Leaf senescence : systems and dynamics aspects" 70 : 347-376, 2019

29 Zhang H, "Identification and function analyses of senescence-associated WRKYs in wheat" 474 (474): 761-767, 2016

30 Wu J, "Genome-wide investigation of WRKY transcription factors involved in terminal drought stress response in common bean" 2016

31 Ding W, "Genome-wide investigation of WRKY transcription factors in sweet osmanthus and their potential regulation of aroma synthesis" 40 (40): 557-572, 2020

32 Ding M, "Genome-wide investigation and transcriptome analysis of the WRKY gene family in Gossypium" 290 (290): 151-171, 2015

33 Guo H, "Genome-wide identification of WRKY transcription factors in the Asteranae" 8 (8): 393-, 2019

34 Wang LN, "Genome-wide identification of WRKY family genes and their response to cold stress in Vitis vinifera" 2014

35 Baranwal VK, "Genome-wide identification and structural, functional and evolutionary analysis of WRKY components of mulberry" 2016

36 de Silva MAD, "Genome-wide identification and characterization of cacao WRKY transcription factors and analysis of their expression in response to witches’ broom disease" 12 (12): e0187346-, 2017

37 Dou L, "Genome-wide analysis of the WRKY gene family in cotton" 289 (289): 1103-1121, 2014

38 Huang S, "Genome-wide analysis of WRKY transcription factors in Solanum lycopersicum" 287 (287): 495-513, 2012

39 Nan H, "Genome-wide analysis of WRKY genes and their response to hormone and mechanic stresses in carrot" 10 : 363-, 2019

40 Ling J, "Genome-wide analysis of WRKY gene family in Cucumis sativus" 12 (12): 471-, 2011

41 Li Z, "Gene network analysis and functional studies of senescence-associated genes reveal novel regulators of Arabidopsis leaf senescence F" 54 (54): 526-539, 2012

42 Shujia Li ; Xiang Zhou ; Ligang Chen ; Weidong Huang ; Diqiu Yu, "Functional Characterization of Arabidopsis thaliana WRKY39 in Heat Stress" 한국분자세포생물학회 29 (29): 475-483, 2010

43 Naveed M, "Chlorogenic acid(CGA) : a pharmacological review and call for further research" 97 : 67-74, 2018

44 Ye YJ, "Banana fruit VQ motif-containing protein5 represses cold-responsive transcription factor MaWRKY26 involved in the regulation of JA biosynthetic genes" 2016

45 Dey S, "Bacteria-triggered systemic immunity in barley is associated with WRKY and ethylene responsive factors but not with salicylic acid" 166 (166): 2133-2151, 2014

46 Li H, "BZR1 positively regulates freezing tolerance via CBF-dependent and CBF-independent pathways in Arabidopsis" 10 (10): 545-559, 2017

47 Li SJ, "Arabidopsis thaliana WRKY25, WRKY26, and WRKY33 coordinate induction of plant thermotolerance" 233 (233): 1237-1252, 2011

48 Jiang Y, "Arabidopsis WRKY57 functions as a node of convergence for jasmonic acid–and auxinmediated signaling in jasmonic acid–induced leaf senescence" 26 (26): 230-245, 2014

49 Hu Y, "Arabidopsis WRKY46 coordinates with WRKY70 and WRKY53 in basal resistance against pathogen Pseudomonas syringae" 185 : 288-297, 2012

50 Chen L, "Arabidopsis WRKY45 interacts with the DELLA protein RGL1 to positively regulate age-triggered leaf senescence" 10 (10): 1174-1189, 2017

51 Guo PR, "A tripartite amplification loop involving the transcription factor WRKY75, salicylic acid, and reactive oxygen species accelerates leaf senescence" 29 (29): 2854-2870, 2017