About the Lectin

The seeds of Griffonia simplicifolia contain four distinct lectins. Two of these lectins, referred to as GS-I and GS-II, have been well characterized with regard to binding specificity and structure. GS-I exists as a mixture of five isolectins. Each isolectin is a tetramer consisting of different amounts of two subunits, termed A and B ¹ . The five isolectins have the following general forms: A ₄ , A ₁ B ₃ , A ₂ B ₂ , A ₃ B, B ₄ . The subscripted numbers indicate the quantity of each subunit associated with the tetrameric form. Comparative binding studies have been performed using the A ₄ and B ₄ isolectins. The B ₄ isolectin has a specificity for type B erythrocytes, while the A ₄ isolectin has a specificity for type A cells. Each of the two isolectins has an equal affinity for a-galactosyl end groups, however the A ₄ isolectin has a greater affinity for α-GalNAc than the B ₄ isolectin. A specific anti-B lectin can be produced by the addition of GalNAc to the GS-I preparation ² . The abundance of the individual isolectins will vary from seed to seed, and potentially from batch to batch, depending on the purification method used. Purified GS-I-B ₄ has been shown to be cytotoxic to Swiss 3T3 mouse cells and to Ehrlich ascites tumor cells ³ . Stimulated mouse macrophages express a carbohydrate determinant that will react specifically with GS-I-B ₄ . This determinant is not present on unstimulated cell populations ⁴ . GS-I-B ₄ also reacts with laminin ⁵ isolated from the mouse EHS sarcoma, and with thyroglobulin ⁶ .

Immobilized GS-I-B ₄ was employed to resolve oligosaccharides containing α-D-galactosyl ⁷ , and to isolate Gal α1-3Gal-containing end groups from calf thyroid cells. ⁸ The tissues from a normal ⁹ and an &#945-1,3-galactosyltransferase knockout mouse ¹⁰ were scanned using biotinylated ¹⁰ and fluorescein-labeled B ₄ ⁹ . Nucleotide sugars and oligosaccharides bearing &#945-D-GalNAc end groups were resolved by affinity chromatography on immobilized GS I-A₄.¹¹ The A₄ isolectin was also shown to bind to the Tn antigen (&#945-GalNAc-O-Ser/Thr) in humans with colon cancer, and to colon tissue from familial adenomatous polyopsis; it bound and was cytotoxic to two colon cancer cell lines, much more so often than other GalNAc-specific lectins. ¹²

GS-II is specific for terminal, non-reducing α- or β-linked N-acetylDglucosamine. This lectin is not blood group specific, unlike GS-I. GS-II is also a tetramer but it is composed of identical subunits. Each subunit has a single carbohydrate binding site for GlcNAc. GS-II is the only lectin isolated that is specific for only a terminal GlcNAc residue. The subterminal saccharide does play an important role in lectin binding. GlcNAc linked &#946(1,3) or &#945(1,6) to galactose is a poor inhibitor of the lectin while GlcNAc linked α(1,3) to galactose or glucose is a potent inhibitor ¹³ . The GS-II lectin has been used as a probe for the isolectin GlcNAcβ1-3Galβ1-4GlcNAc sequence in tissue sections following treatment with endo-β-galactosidase. ¹⁴ Glycogen in tissue sections was demonstrated in man and rodents using a GS-II-horseradish peroxidase system. ¹⁵

GS-II has insecticidal activity against cowpea weevil. ¹⁶ A cDNA clone encoding GS-II was isolated, sequenced and expressed in a bacterial expression system; the recombinant protein bound GlcNAc and had insecticidal activity against the weevil. The crude form of the lectin contains both the GS-I isolectins and the GS-II lectin.

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