Literature DB >> 9844026

Carbohydrate binding and resistance to proteolysis control insecticidal activity of Griffonia simplicifolia lectin II.

K Zhu-Salzman1, R E Shade, H Koiwa, R A Salzman, M Narasimhan, R A Bressan, P M Hasegawa, L L Murdock.   

Abstract

Griffonia simplicifolia leaf lectin II (GSII), a plant defense protein against certain insects, consists of an N-acetylglucosamine (GlcNAc)-binding large subunit with a small subunit having sequence homology to class III chitinases. Much of the insecticidal activity of GSII is attributable to the large lectin subunit, because bacterially expressed recombinant large subunit (rGSII) inhibited growth and development of the cowpea bruchid, Callosobruchus maculatus (F). Site-specific mutations were introduced into rGSII to generate proteins with altered GlcNAc binding, and the different rGSII proteins were evaluated for insecticidal activity when added to the diet of the cowpea bruchid. At pH 5.5, close to the physiological pH of the cowpea bruchid midgut lumen, rGSII recombinant proteins were categorized as having high (rGSII, rGSII-Y134F, and rGSII-N196D mutant proteins), low (rGSII-N136D), or no (rGSII-D88N, rGSII-Y134G, rGSII-Y134D, and rGSII-N136Q) GlcNAc-binding activity. Insecticidal activity of the recombinant proteins correlated with their GlcNAc-binding activity. Furthermore, insecticidal activity correlated with the resistance to proteolytic degradation by cowpea bruchid midgut extracts and with GlcNAc-specific binding to the insect digestive tract. Together, these results establish that insecticidal activity of GSII is functionally linked to carbohydrate binding, presumably to the midgut epithelium or the peritrophic matrix, and to biochemical stability of the protein to digestive proteolysis.

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Year:  1998        PMID: 9844026      PMCID: PMC24586          DOI: 10.1073/pnas.95.25.15123

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  20 in total

1.  Peritrophic matrix structure and function.

Authors:  M J Lehane
Journal:  Annu Rev Entomol       Date:  1997       Impact factor: 19.686

Review 2.  Lectins, lectin genes, and their role in plant defense.

Authors:  M J Chrispeels; N V Raikhel
Journal:  Plant Cell       Date:  1991-01       Impact factor: 11.277

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Authors:  C L Díaz; P C van Spronsen; R Bakhuizen; G J Logman; E J Lugtenberg; J W Kijne
Journal:  Planta       Date:  1986-09       Impact factor: 4.116

Review 4.  Legume lectins--a large family of homologous proteins.

Authors:  N Sharon; H Lis
Journal:  FASEB J       Date:  1990-11       Impact factor: 5.191

5.  Lectin-induced apoptosis of tumour cells.

Authors:  M Kim; M V Rao; D J Tweardy; M Prakash; U Galili; E Gorelik
Journal:  Glycobiology       Date:  1993-10       Impact factor: 4.313

6.  Concanavalin A induced apoptosis in fibroblasts: the role of cell surface carbohydrates in lectin mediated cytotoxicity.

Authors:  G V Kulkarni; C A McCulloch
Journal:  J Cell Physiol       Date:  1995-10       Impact factor: 6.384

7.  Effects of snowdrop lectin (GNA) delivered via artificial diet and transgenic plants on the development of tomato moth (Lacanobia oleracea) larvae in laboratory and glasshouse trials.

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8.  An insecticidal N-acetylglucosamine-specific lectin gene from Griffonia simplicifolia (Leguminosae).

Authors:  K Zhu; J E Huesing; R E Shade; R A Bressan; P M Hasegawa; L L Murdock
Journal:  Plant Physiol       Date:  1996-01       Impact factor: 8.340

9.  Structures of the lectin IV of Griffonia simplicifolia and its complex with the Lewis b human blood group determinant at 2.0 A resolution.

Authors:  L T Delbaere; M Vandonselaar; L Prasad; J W Quail; K S Wilson; Z Dauter
Journal:  J Mol Biol       Date:  1993-04-05       Impact factor: 5.469

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Authors:  R van Eijsden; C L Díaz; B S de Pater; J W Kijne
Journal:  Plant Mol Biol       Date:  1995-11       Impact factor: 4.076
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Journal:  Transgenic Res       Date:  2007-01-31       Impact factor: 2.788

6.  Potential of the Lectin/Inhibitor Isolated from Crataeva tapia Bark (CrataBL) for Controlling Callosobruchus maculatus Larva Development.

Authors:  Natalia N S Nunes; Rodrigo S Ferreira; Rosemeire A Silva-Lucca; Leonardo F R de Sá; Antônia Elenir A de Oliveira; Maria Tereza dos S Correia; Patrícia Maria G Paiva; Alexander Wlodawer; Maria Luiza V Oliva
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9.  Foam nest components of the túngara frog: a cocktail of proteins conferring physical and biological resilience.

Authors:  Rachel I Fleming; Cameron D Mackenzie; Alan Cooper; Malcolm W Kennedy
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10.  The Digestive System of the Two-Spotted Spider Mite, Tetranychus urticae Koch, in the Context of the Mite-Plant Interaction.

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