Isolation and characterization of a novel thermostable non-specific lipid transfer protein-like antimicrobial protein from motherwort (Leonurus japonicus Houtt) seeds

Peptides

Volumn 27, Issue 12, 2006, Pages 3122-3128

  Yang, Xingyong ^a   Li, Jun ^a   Li, Xianbi ^a   She, Rong ^a   Pei, Yan ^a  

^a AGRO ENVIRONMENTAL PROTECTION INSTITUTE   (China)

Author keywords

Antibacterial; Antifungal; IC50; Motherwort; nsLTPs; Seeds

Indexed keywords

LIPID TRANSFER PROTEIN; POLYPEPTIDE ANTIBIOTIC AGENT;

ALTERNARIA; AMINO TERMINAL SEQUENCE; ANTIMICROBIAL ACTIVITY; ARTICLE; ASPERGILLUS NIDULANS; BACILLUS SUBTILIS; BACTERIAL GROWTH; BOTRYTIS; CONTROLLED STUDY; DRUG DETERMINATION; DRUG INHIBITION; DRUG ISOLATION; DRUG POTENCY; DRUG PURIFICATION; FUNGICIDAL ACTIVITY; FUNGUS GROWTH; FUSARIUM OXYSPORUM; HYPHOMYCETES; IC 50; ION EXCHANGE CHROMATOGRAPHY; LEONURUS; MEDICINAL PLANT; NONHUMAN; PENICILLIUM DIGITATUM; PLANT SEED; PRIORITY JOURNAL; REVERSED PHASE HIGH PERFORMANCE LIQUID CHROMATOGRAPHY; SACCHAROMYCES CEREVISIAE; STRUCTURAL HOMOLOGY; THERMOSTABILITY;

AMINO ACID SEQUENCE; ANTIMICROBIAL CATIONIC PEPTIDES; CARRIER PROTEINS; CELL LINE, TUMOR; CELL PROLIFERATION; HUMANS; LEONURUS; MOLECULAR SEQUENCE DATA; SEEDS;

ALTERNARIA BRASSICAE; ASPERGILLUS NIGER; BACILLUS SUBTILIS; BOTRYTIS; CERATOBASIDIUM CEREALE; FUNGI; FUSARIUM OXYSPORUM; LEONURUS; LEONURUS JAPONICUS; PENICILLIUM DIGITATUM; SACCHAROMYCES CEREVISIAE;

EID: 33750945091     PISSN: 01969781     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.peptides.2006.07.019     Document Type: Article

References (32)

1. Blein J., Coutos-Thévenot P., Marion D., and Ponchet M. From elicitins to lipid-transfer proteins: a new insight in cell signalling involved in plant defence mechanisms. Trends Plant Sci 7 (2002) 293-296
2. Bohlmann H. The role of thionins in plant-protection. Crit Rev Plant Sci 13 (1994) 1-16
3. Bradford M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72 (1976) 248-254
4. Buhot N., Gomes E., Milat M.L., Ponchet M., Marion D., Lequeu J., et al. Modulation of the biological activity of a tobacco LTP1 by lipid complexation. Mol Biol Cell 15 (2004) 5047-5052
5. Cammue B.P.A., Thevissen K., Hendriks M., Eggermont K., Goderis I.J., Proost P., et al. A potent antimicrobial protein from onion seeds showing sequence homology to plant lipid transfer proteins. Plant Physiol 109 (1995) 445-455
6. Castro M.S., and Fontes W. Plant defense and antimicrobial peptides. Protein Pept Lett 12 (2005) 13-18
7. Cheng C.S., Samuel D., Liu Y.J., Shyu J.C., Lai S.M., Lin K.F., et al. Binding mechanism of nonspecific lipid transfer proteins and their role in plant defense. Biochemistry 43 (2004) 13628-13636
8. Douady D., Grosbois M., Guerbette F., and Kader J.-C. Purification of a basic phospholipid transfer protein from maize seedlings. BBA: Lipids Lipid Metabol 710 (1982) 143
9. Feng J., Yuan F., Gao Y., Liang C., Xu J., Zhang C., et al. A novel antimicrobial protein isolated from potato (Solanum tuberosum) shares homology with an acid phosphatase. Biochem J 376 (2003) 481-487
10. Fritig B., Heitz T., and Legrand M. Antimicrobial proteins in induced plant defense. Curr Opin Immunol 10 (1998) 16-22
11. Garcia-Olmedo F., Molina A., Alamillo J.M., and Rodriguez-Palenzuela P. Plant defense peptides. Biopolymers 47 (1998) 479-491
12. Jung H.W., Kim K.D., and Hwang B.K. Identification of pathogen-responsive regions in the promoter of a pepper lipid transfer protein gene (CALTPI) and the enhanced resistance of the CALTPI transgenic Arabidopsis against pathogen and environmental stresses. Planta 221 (2005) 361-373
13. Jung H.W., Kim W., and Hwang B.K. Three pathogen-inducible genes encoding lipid transfer protein from pepper are differentially activated by pathogens, abiotic, and environmental stresses. Plant Cell Environ 26 (2003) 915-928
14. Kader J.-C. Lipid-transfer proteins in plants. Annu Rev Plant Physiol Plant Mol Biol 47 (1996) 627-654
15. Kristensen A.K., Brunstedt J., Nielsen K.K., Roepstorff P., and Mikkelsen J.D. Characterization of a new antifungal non-specific lipid transfer protein (nsLTP) from sugar beet leaves. Plant Sci 155 (2000) 31-40
16. Liang X.Q., Holbrook C.C., Lynch R.E., and Guo B.Z. beta-1,3-Glucanase activity in peanut seed (Arachis hypogaea) is induced by inoculation with Aspergillus flavas and copurifies with a conglutin-like protein. Phytopathology 95 (2005) 506-511
17. Lin K.F., Liu Y.N., Hsu S.T.D., Samuel D., Cheng C.S., Bonvin A.M.J.J., et al. Characterization and structural analyses of nonspecific lipid transfer protein 1 from mung bean. Biochemistry 44 (2005) 5703-5712
18. Lindorff-Larsen K., and Winther J.R. Surprisingly high stability of barley lipid transfer protein, LTP1, towards denaturant, heat and proteases. FEBS Lett 488 (2001) 145-148
19. Molina A., and Garcia-Olmedo F. Enhanced tolerance to bacterial pathogens caused by the transgenic expression of barley lipid transfer protein LTP2. Plant J 12 (1997) 669-675
20. Molina A., Segura A., and Garcia-Olmedo F. Lipid transfer proteins (nsLTPs) from barley and maize leaves are potent inhibitors of bacterial and fungal plant pathogens. FEBS Lett 316 (1993) 119-122
21. Moore K.G., Price M.S., Boston R.S., Weissinger A.K., and Payne G.A. A chitinase from Tex6 maize kernels inhibits growth of Aspergillus flavus. Phytopathology 94 (2004) 82-87
22. Nagasawa H., Inatomi H., Suzuki M., and Mori T. Further study on the effects of motherwort (Leonurus sibiricus L.) on preneoplastic and neoplastic mammary gland growth in multiparous GR/A mice. Anticancer Res 12 (1992) 141-143
23. Park S.W., Vepachedu R., Sharma N., and Vivanco J.M. Ribosome-inactivating proteins in plant biology. Planta 219 (2004) 1093-1096
24. Samuel D., Liu Y.J., Cheng C.S., and Lyu P.C. Solution structure of plant nonspecific lipid transfer protein-2 from rice (Oryza sativa). J Biol Chem 277 (2002) 35267-35273
25. Segura A., Moreno M., and Garcia-Olmedo F. Purification and antipathogenic activity of lipid transfer proteins (LTPs) from the leaves of Arabidopsis and spinach. FEBS Lett 332 (1993) 243-246
26. Serna A., Maitz M., O'Connell T., Santandrea G., Thevissen K., Tienens K., et al. Maize endosperm secretes a novel antifungal protein into adjacent maternal tissue. Plant J 25 (2001) 687-698
27. Sharma N., Park S.-W., Vepachedu R., Barbieri L., Ciani M., Stirpe F., et al. Isolation and characterization of an RIP (ribosome-inactivating protein)-like protein from tobacco with dual enzymatic activity. Plant Physiol 134 (2004) 171-181
28. Terras F.R.G., Eggermont K., Kovaleva V., Raikhel N.V., Osborn R.W., Kester A., et al. Small cysteine-rich antifungal proteins from radish: their role in host defense. Plant Cell 7 (1995) 573-588
29. Thomma B., Cammue B.P.A., and Thevissen K. Plant defensins. Planta 216 (2002) 193-202
30. Wang S.Y., Wu J.H., Ng T.B., Ye X.Y., and Rao P.F. A non-specific lipid transfer protein with antifungal and antibacterial activities from the mung bean. Peptides 25 (2004) 1235-1242
31. Yang X., Li J., Wang X., Fang W., Bidochka M.J., She R., et al. Psc-AFP, an antifungal protein with trypsin inhibitor activity from Psoralea corylifolia seeds. Peptides 27 (2006) 1726-1731
32. Zhang C.F., Jia Y.S., Wei H.C., Zhu X.M., Hui Y.M., Zhang C.Y., et al. Studies on actions of extract of motherwort. J Tradit Chin Med 2 (1982) 267-270