PUBLICATION LIST

PUBLICATION LIST<= /p>

(upd= ated 4/15/06)

Xuemin (Sam) Wang=

1.&n= bsp; Mi= shra, G, W. Zhang, F. Deng, J. Zhao, and X. Wang. 2006. A bifurcating pathway directs abscisic acid effects on stom= atal closure and opening in Arabidopsis. Science 312: 264-266

2.&n= bsp; Li, M., C. Qin, R.Welti., and = X. Wang. 2006. Double knocko= uts of phospholipase Dζ1 and ζ2 in Arabidopsis affect root elongation du= ring phosphate-limited growth, but do not affect root hair patterning. Plant Physiol. 140: 761-770

3.&n= bsp; Wang, X., W. Li., M. Li., a= nd R. Welti. 2006. Profiling lipid changes in plant response to low temperatures. Physiol. Plant. = 126:90-96

4.&n= bsp; Wang, X. 2006. Phospholipid-derived signaling in plant response to tempera= ture and water stresses. Genetic Engineering, 27: 57-66.

5.&n= bsp; Wang, X., S.D. Devaiah, W. Zhang, and R. Welti. 2006. = Signaling functions of phosphatidic acid. Prog. Lipid Research (in press= )

6.&n= bsp;     Zh= ang W., Yu L., Zhang Y. and X. Wang. 2= 005. Phospholipase D in the signaling network of plant responses to abscisic acid and reactive oxygen species Biochim. Biophys. Acta 1736= :1-9

7.&n= bsp;     Wang, X. 2005. Regulatory func= tions of phospholipase D and phosphatidic acid in plant growth development, and stress responses. Plant Physiol. 139:566-573

8.&n= bsp;     We= lti R., M. Roth, Y. Deng, J. Shah, and X. Wang. 2005. Lipidomics: ESI-MS/MS-based profiling to determine the func= tion of genes involved in metabolism of complex lipids. In Plant Metabolomics,= Kluwer Academic Publishers, New York, NY. Ed. Nikolau, Basil

9.&n= bsp;     We= lti, R., J. Shah, S. LeVine, W. Esch, T. Williams, and X. Wang. 2005. High throughput lipid profiling to identify and characterize genes involved in lipid metabolism, signaling, and stress response. In Functional Lipidomics. Edited by L. Feng and G. Prestwich, = CRC Press , Boca Raton<= /st1:place>, FL. pp. 308-320.

10.&= nbsp; Pappan K, L, Zheng, R. Krishnamoorthi, = and X. Wang. 2004. Evidence for and characterization of Ca²⁺ binding to the catalytic region of Arabidopsis thaliana phospholipase Dβ. J. Biol. Chem. 279: 47833-47839.

11.&= nbsp; Zhang, W. C. Qin, J. Zhao, and X. Wang. 2004. Phospholipase Da1-derived phosphatidic acid interacts w= ith ABI1 phosphatase 2C and regulates abscisic acid signaling. Proc. Natl. Acad. Sci. USA 101: 9508-9513.

12.&= nbsp; Li, W., M. Li, W. Zhang, R. Welti, and = X. Wang. 2004. The plasma membrane-bound phospholipase D= d enhances freezing tolerance in Arabidopsis. Nature Biotech. 22= : 427-433.

13.&= nbsp; Zhao, J. and X. Wang. 2004. Arabidopsis phospholipase Dα1 interacts with the heterotrimeric G-protein α-subunit through a motif analogous to the DRY motif in G-protein-coupled receptors.&= nbsp; J. Biol. Chem. 27= 9:1794-1800.

14. Wang, X. 2004. Lipid signaling. Curr. Opin. Plant Biol. 7: 329-336

15. Welti, R and X. Wang. 2004. Lipid species profiling: A high through= put approach to identify lipid compositional changes and determine the function= of genes involved in lipid metabolism and signaling. Curr. Opin. Plant Biol. 7: 337-344

16.&= nbsp; Zhang W., C. Wang, C. Qin, T. Wood, G. Olafsdottir, and X. Wang. 2003. Phospholipase Dd and phosphatidic acid decrease H₂₌O₂-induced cell death in Arabidopsis. Plant Cell 15: 2285-2295. <= /o:p>

17.&= nbsp; McGee J.D., J. Roe, T.A. Sweat, X. Wang, J= .A. Guikema, and J.E. Leach. 2003. Rice phospholipase D isoforms show different= ial cellular location and gene induction. Plant Cell Physiol. 44: 1013-1026.

18.&= nbsp; Welti, R., X. Wang, and T. D. Williams. 2003. Electrospray ionization tand= em mass spectrometry scan modes for plant chloroplast lipids. Anal. Biochem. 314: 149-152.
19.&= nbsp; Kusner, D.J., J.A. Barton, C. Qin, X. Wang, S.S. Iyer. 2003. Evoluti= onary conservation of physical and functional interactions between phospholipase D and actin. Arch. Biochem. Biophys.= 412: 231-241.

20. Qin, C, W. Li, Y. Hong, W. Zhang, T. Wo= od, M. Li, R. Welti, and X. Wang 2003= . Two novel types of Arabidopsis phospholipase D: oleate-stimulated PLD= d and Ca²⁺-independent PLD= z1.&nbs= p; in Advanced Research on Plant Lipids, ed. N. Murata, M Yamada,= I. Nishida, H. Okuyama. J. Sekiya, and W. Hajime. K= luwer Academic Publishers, Dordrecht/Boston/London. pp. 259-262.

21.&= nbsp; Welti R and X. Wang 2003. Lipidomics. Inform 14: 607-608

22. Wang, X. 2002. Phospholipase D in hormonal and st= ress signaling. Current Opinion in Plant Biol. 5: 408-414.

23.&= nbsp; Qin, B, C. Wang, and X. Wang. 2002. Kinetic analysis of Arabidopsis phospholipase D<= /span>= d: substrate preference and mechanism of activation by calcium and phosphatidylinositol 4,5-bisphosphate.&nbs= p; J. Biol. Chem. 277: 49685-49690.

24.&= nbsp; Kusner D.J., J.A. Barton, K-K. Wen, X. Wang, P.A. Rubenstein, and S.S. Iyer. 2002. Regulation of phospholipase D activity by actin: I actin exerts bidirectional modulation = of mammalian PLD activity in a polymerization-dependent, isoform-specific manner. J. Biol. Chem. 277: 50683-50692.

25.&= nbsp; Welti, R= ., W. Li, M. Li, Y. Sang, H. Biesiada, H-E. Zhou, C.B. Rajashekar, T.D. Williams, and X. Wang. 2002. Pro= filing membrane lipids in plant stress responses: role of phospholipase D= a in freezing-induced lipid changes in Arabidopsis. J. Biol. Chem. 277: 31994-32002.

26. Zheng, L., J. Shan, R. Krishnamoorthi, = and X. Wang. 2002. Activation of plant phospholipase Db by phosphatidylinositol 4,5-bisphosphate: characterization of bind= ing site and mode of action. Biochemistry 41: 4546-4553.

27. Wang, X. C. Wang, Y. Sang, C. Qin, and R. Welti.= 2002. Networking of phospholipases= in plant signal transduction. Physiol. Plant. 128: 1057-1068.=

28.&= nbsp; Qin, C. and X. Wang. 2002. The Arabidopsis phospholipase D family: characterization of a Ca²⁺-i= ndependent and phosphatidylcholine-selective PLDz1 with distinct regulatory domains. Plant Physiol. 128: 1057-106= 8.

29. Wang, X. Plant Phospholipases. 2001. Annu. Rev. Plant Physiol. Plant Mol. Biol. 52:211-231.

30. Sang, Y., S. Zheng, W. Li, B. Huang, an= d X. Wang. 2001. Regulation of plant water loss by manipulating the expression of phospholipase D= a. Plant Journal. 28: 135-144.<= /p>
31. Wang, C. and X. Wang. 2001. A = novel phospholipase D of Arabidopsis that is activated by oleic acid and associat= ed with the plasma membrane. Plant Physiol. 127: = 1102-1112.

32. Sang, Y., D. Cui, and X. Wang. 2001. Phospholipase D- and phosphatidic acid-mediated generation of superoxide in Arabidopsis. Plant Physiol. 126= : 1449-1458.

33. Zien, C.A.= , C. Wang, X. Wang, and R. We= lti. 2001. In-vivo substrates and the contribution of the common phospholipase D, PLDa, to wound-induced metabolism of lipids in Arabidopsis. Biochim. Biophys. Acta.= 1530: 236-248. =

34. Wang, C., C. Zien, M. Afitlhile, R. Wel= ti, D.F. Hildebrand, and X. Wang. = 2000. Involvement of phospholipase D in wound-induced accumulation of jasmonic ac= id in Arabidopsis. Plant Cell 12: 2237-2246.

35. Ransom-Hodgkins, W.D., I. Brglez, X. Wang, W.F. Boss. 20= 00. Calcium-induced proteolysis of eEF1A. Plant Physiol. 122: 957-965.

36. Zhang, W. and X. Wang. 2000. Phospholipid metabolism and signal transduction = in plants. Chinese Bulletin of Life Sc= iences 12:100-104.<= /p>
37. Wang, X. 2000. Multiple forms of phospholipase D = in plants: the gene family, catalytic and regulatory properties, and cellular functions. Progress in Lipid Research<= /i> 39:109-149.

38. Wang, X., C. Wang, Y. Sang, = L. Zheng, and C. Qin. 2000. Determining functions of multiple phospholipase Ds= in stress response in Arabidopsis.= Bioch. Soc. Trans. 28: 813-816.

39. Leach, J.E., L. Lloyd, D. McGee, X. Wang, and J.A. Guikema. 2000. Trafficking of plant defense response compounds. In N.T. Keen, S. Mayama, J= .E. Leach, and S. Tsuyumu eds: Delivery and Perception of Pathogen Si= gnals in Plants. APS Press, = Minneapolis, MN. pp. 241-250.=

40. Zheng, L., R. Krishnamoorthi, M. Zolkie= wski, and X. Wang. 2000. Distinct calcium binding propertie= s of novel C2 domains of plant phospholipase Da and b. J. Biol. Chem. = 275:19700-19706.

41.&= nbsp; Lu, F., S. Zheng, and X. Wang. 1999. Subcellular distribution and tissue expression of phospholipase D= a, b, and g in Arabidopsis. Plant Physiol. 119:1371-1378.

42.&= nbsp; Wang, X. 1999. The role of phospholipase D = in signaling cascades. Plant Physiol. 120: 645-651.=

43.&= nbsp; Pappan, K and X. Wang. 1999. Plant phospholipase Da is an acidic phospholipase active at near-physiological Ca²⁺ concentrations. Arch. Biochem. Biophys. 368: 347-353.

44.&= nbsp; Pappan, K. and X. Wang. 1999. Molecular and biochemical properties and physiological roles of plant phospholipase D. Biochim. Biophys. Acta 1439: 151-166.<= /p>
45.&= nbsp; Qin, W., J.H. Dyer, L. Zheng, and X. Wang. 1999. Isolation and nucl= eotide sequence of the fourth phospholipase D (accession No. AF138281), PLD= = g2, from Arabidopsis thaliana. Plant Physiol. 120= :635.

46.&= nbsp; Pappan, K., S. Austin-Brown, K. Chapman= and X. Wang. 1998. Substrate selectiv= ities and lipid modulation of phospholipase Da, b, and g from plants. Arch. Biochem. Biophys.353:131-140.

47.&= nbsp; Ryu, S.B. and X. Wang. 1998. Increase in free linolenic and linoleic acids associated with phospholipase D-mediated hydrolysis of phospholipids in wou= nded castor bean leaves. Biochim. Biophys. Acta 1393:193-202.
48.&= nbsp; Wang, X., K. Pappan, L. Fan,= and W. Qin. 1998. Multiple forms of phospholipase D in plant hormonal and stress signaling. In J. Sanchez et al. Eds: Advances in Plant Lipid Research. Servicio de Publicaciones, Spain. pp 398-401.

49.&= nbsp; Pappan, K. and X. Wang. 1998. Regulation of plant phospholipase D by polyphosphoinositides and non-lamellar lipids. In J. Sanchez et al. Eds: Advances in Plant Lipid Research. Servicio de Publicaciones, Spain. pp 402-405.=

50.&= nbsp; Lu, F., S. Zheng, and X. Wang. 1997. Antisense suppression of phospholipase D<= span style=3D'mso-bidi-font-size:12.0pt;font-family:Symbol;mso-ascii-font-family= :"Times New Roman"; mso-hansi-font-family:"Times New Roman";mso-char-type:symbol;mso-symbol-fon= t-family: Symbol'>= a retards abscisic acid- and ethylene- promoted senescence in postharvest = Arabidopsis leaves. Plant Cell. 9:= 2183-2196.

51.&= nbsp; Pappan, K. S. Zheng, and X. Wang. 1997. Identification and characterization of a novel phospholipase D that requires polyphosphoinositides and submicromolar calci= um for activity in Arabidopsis. J. Biol. Chem. 272:7048-7054.

52.&= nbsp; Pappan, K. W. Qin, J.H. Dyer, L. Zheng,= and X. Wang. 1997. Molecular cloning = and functional analysis of polyphosphoinositide-dependent phospholipase D, PLD<= /span>= b, from Arabidopsis. J. Biol. Chem. 272:7055-7061.

53.&= nbsp; Qin, W., K. Pappan, and X. Wang.1997. Molecular heterogeneity of PLD: cloning of plant = PLD= g and regulation of PLD= g, b, and a by polyphosphoinositides and Ca²⁺. J. Biol. Chem. 272:28267-28273.

54.&= nbsp; Wang, X., S. Zheng, K. Pappa= n, and L. Zheng. 1997. Characterization of phospholipase D-overexpressed and suppressed transgenic tobacco and A= rabidopsis. in J.P. Williams, M.U. Khan, N.W. = Lem eds: Physiology, Biochemistry and Molecular Biology of Plant Lipids. Kluwer Academic Publishers, Boston, pp. 345-34= 7.

55.&= nbsp; Xu, L., S. Zheng, L. Zheng, and X. Wang. 1997. Promoter analysis = and expression of a phospholipase D gene from Ricinus communis L. Plant Physiol. 115= :387-395.

56.&= nbsp; Wang, X. 1997. Molecular ana= lysis of phospholipase D. Trend. Plant Sci. 2:261-266.<= o:p>

57.&= nbsp; Young, S.A.= , X. Wang, and J.E. Leach. 1996. Changes in the plasma membrane distribution of rice phospholipase D during resistant interaction with X= anthomonas oryzae pv oryzae. Plant Cell 8:1079-1090.

58.&= nbsp; Xu, L., A.Q. Paulsen, S.B. Ryu, and X. Wang. 1996. Intracellular localization of phospholipase D in leaves and seedling tissues of castor be= an. Plant Physiol. 111:1001-107.=

59.&= nbsp; Xu, L., L. Zheng, S.J. Coughlan, and X. Wang. 1996. Structure and anal= ysis of phospholipase D gene from Ricinus communis L. Plant Mol. Biol. 3= 2:767-771.

60.&= nbsp; Ryu, S.B. and X. Wang. 1996. Activation of phospholipase D and the possible mechanism of activation in wound-induced lipid hydrolysis in castor bean leaves. Biochim. Biophys. Acta&nbs= p; 1303:243-250.

61.&= nbsp; Ryu, S.B., L. Zheng, and X. Wang. 1996. Ch= anges in phospholipase D expression in soybeans during seed development and follo= wing germination. J. Am. Oil Chem. Soc. 73:1171-1176.
62.&= nbsp; Dyer, J.H., S. Zheng, and X. Wang. 1996. Structural heterog= eneity of phospholipase D in ten dicots. = Biochem. Biophys. Res. Commu. 221:31-36.

63.&= nbsp; Ryu, S.B. and X. Wang. 1995. Expression of phospholipase D during castor bean leaf senescence. Plant Physiol. 108:713-719.

64.&= nbsp; Dyer, J.H., L. Zheng, and X. Wang. 1995. Cloning and nucleo= tide sequence of a cDNA encoding phospholipase D from Arabidopsis (Accession No. U36381) (PGR 95-096). Plant Physiol. 109:1497.

65.&= nbsp; Wang, X., L. Xu, and L. Zhen= g. 1994. Cloning and expression of phosphatidylcholine-hydrolyzing phospholipa= se D from Ricinus communis L. J. Biol. Chem. 269:20312-20317.

66.&= nbsp; Dyer, J.H., S.B. Ryu, and X. Wang. 1994. Multiple forms of phospholipase D following seed germination and during leave development of castor bean. Plant Physiol. = 105:715-724.

67.&= nbsp; Wang, X. 1993. Phospholipases. in T.S. Moore ed: Lipid Metabolism In Plants<= /i>.= CRC Press, Boca Raton, FL, pp. 499-520.=

68.&= nbsp; Wang, X., J.H. Dyer, and L. = Zheng. 1993. Purification and immunological analysis of phospholipase D from germinating castor bean endosperm. Arch. Biochem. Biophys. 306: 486-494.

69.&= nbsp; Zheng, L., X. Wang, and H. D. Braymer. 1992. Purification and N-terminal sequen= ces of two polypeptides encoded by mcr= B from Escherichia coli K-12. Gene. 112:97-100.

70.&= nbsp; Wang, X. and T.S. Moore, Jr. 1991. Phosphatidylethanolamine biosynthesis in castor bean endosperm: Intracellular distribution and characteristics of CTP:ethanolamine-phosphate cytidylyltransferase. J. Biol. Chem. 266:19981-19987.

71.&= nbsp; Wang, X. and T.S. Moore, Jr. 1990. Phosphatidylcholine biosynthesis in castor bean endosperm: purification and properties of CTP:choline-phosphate cytidylyltransferase. Plant Physiol. 93:250-255.=

72.&= nbsp; Moore, Jr., T.S. and X. Wang. 1990. A comparison of CTP:cholinephosphate cytidylyltransferase and CTP:ethanolaminephosphate cytidylyltransferase of castor bean endosperm. In P.J. Quinn and J.L. Harwood Eds= : Plant Lipid Biochemistry, Structure, and Utilization. Portland Press, pp.251-253.

73.&= nbsp; Wang, X. and T.S. Moore, Jr. 1989. Partial purification and characterization of CTP:choline-phosphate cytidylyltransferase from castor bean. Arch. Biochem. Biophys.= 274:388-347.

74.&= nbsp; Wang, X., H.A. Norman, J.B. = St. John, T. Yin, and D.F. Hildebrand. 1989.&n= bsp; Comparison of fatty acid composition in soybean tissues with low linolenate mutants. Phytochem. 28:= 411-414.

75.&= nbsp; Wang, X., G.Bookjans, M. Altschuler, G.B. Collins, and D.F. Hildebrand. 1988. Alteration of the synthesis of lip= oxygenase in the early stages of soybean cotyledon culture. Physiol. Plant. 72:127-132.

76.&= nbsp; Wang, X. and D.F. Hildebrand. 1987. Effect of a substituted pyridazinone on the decrease of lipoxygenase activity in soybean cotyledons= . Plant Science. 51:29-36.

77.&= nbsp; Wang, X. D.F. Hildebrand, H.= A. Norman, M.L. Dahmer, J.B. St. John, and G.B. Collins. 1987. Reduction of linolenate content in soybean cotyledons by a substituted pyridazinone. Phytochem. 26:955-960.<= /p>
78.&= nbsp; Wang, X., D.F. Hildebrand, a= nd G.B. Collins. 1987. Identific= ation of proteins associated with the change in linolenate content of soybean cotyledons. In P. K. Stumpf, J. B. Mudd, and W. D. Nes Eds: The metabolism, Structure, and Function of Plant Lipids. Plenum Press, pp.533-535.

79.&= nbsp; Hildebrand, D.F., M. Altschuler, G. Boo= kjans, G. Benzion, T.R. Hamilton-Kemp, R. A. Anderson, J.G. Rodriguez, J.C. Polacc= o, M.L. Dahmer, A.G. Hunt, X. Wang, and G.B. Collins. 1987. Physiolog= ical and transformational analysis of lipoxygenase. In P.K. Stumpf, J.B. Mudd, a= nd W.D. Nes Eds: The metabolism, Structure, and Function of Plant Lipids. Pl= enum Press, pp. 715-717.

80.&= nbsp; Wang, X., K.A. Feldmann, and= R.L. Scholl. 1988. A chlorate-hypersensitive, high nitrate/chlorate uptake mutant of Arabidopsis thaliana. Physiol. Plant. 73= :305-310.

81.&= nbsp; Wang, X., R.L. Scholl, and K= .A. Feldmann. 1986. Characterizat= ion of a chlorate-hypersensitive, high nitrate reductase Arabidopsis thaliana mutant.&n= bsp; Theor. Appl. Genet. 72:328-336.