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PDBsum entry 1x1v
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Sugar binding protein
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PDB id
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1x1v
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Contents |
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* Residue conservation analysis
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Glycobiology
15:1025-1032
(2005)
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PubMed id:
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Unusual sugar specificity of banana lectin from Musa paradisiaca and its probable evolutionary origin. Crystallographic and modelling studies.
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D.D.Singh,
K.Saikrishnan,
P.Kumar,
A.Surolia,
K.Sekar,
M.Vijayan.
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ABSTRACT
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The crystal structure of a complex of methyl-alpha-D-mannoside with banana
lectin from Musa paradisiaca reveals two primary binding sites in the lectin,
unlike in other lectins with beta-prism I fold which essentially consists of
three Greek key motifs. It has been suggested that the fold evolved through
successive gene duplication and fusion of an ancestral Greek key motif. In other
lectins, all from dicots, the primary binding site exists on one of the three
motifs in the three-fold symmetric molecule. Banana is a monocot, and the three
motifs have not diverged enough to obliterate sequence similarity among them.
Two Greek key motifs in it carry one primary binding site each. A common
secondary binding site exists on the third Greek key. Modelling shows that both
the primary sites can support 1-2, 1-3, and 1-6 linked mannosides with the
second residue interacting in each case primarily with the secondary binding
site. Modelling also readily leads to a bound branched mannopentose with the
nonreducing ends of the two branches anchored at the two primary binding sites,
providing a structural explanation for the lectin's specificity for branched
alpha-mannans. A comparison of the dimeric banana lectin with other beta-prism I
fold lectins, provides interesting insights into the variability in their
quaternary structure.
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Literature references that cite this PDB file's key reference
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PubMed id
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Reference
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A.Sharma,
and
M.Vijayan
(2011).
Influence of glycosidic linkage on the nature of carbohydrate binding in beta-prism I fold lectins: an X-ray and molecular dynamics investigation on banana lectin-carbohydrate complexes.
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Glycobiology,
21,
23-33.
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PDB codes:
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M.Bajaj,
A.Hinge,
L.S.Limaye,
R.K.Gupta,
A.Surolia,
and
V.P.Kale
(2011).
Mannose-binding dietary lectins induce adipogenic differentiation of the marrow-derived mesenchymal cells via an active insulin-like signaling mechanism.
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Glycobiology,
21,
521-529.
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A.Hinge,
M.Bajaj,
L.Limaye,
A.Surolia,
and
V.Kale
(2010).
Oral administration of insulin receptor-interacting lectins leads to an enhancement in the hematopoietic stem and progenitor cell pool of mice.
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Stem Cells Dev,
19,
163-174.
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T.Moulaei,
S.R.Shenoy,
B.Giomarelli,
C.Thomas,
J.B.McMahon,
Z.Dauter,
B.R.O'Keefe,
and
A.Wlodawer
(2010).
Monomerization of viral entry inhibitor griffithsin elucidates the relationship between multivalent binding to carbohydrates and anti-HIV activity.
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Structure,
18,
1104-1115.
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PDB codes:
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G.Gupta,
S.Vishveshwara,
and
A.Surolia
(2009).
Stability of dimeric interface in banana lectin: Insight from molecular dynamics simulations.
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IUBMB Life,
61,
252-260.
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G.Gupta,
S.Sinha,
and
A.Surolia
(2008).
Unfolding energetics and stability of banana lectin.
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Proteins,
72,
754-760.
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M.Gavrovic-Jankulovic,
K.Poulsen,
T.Brckalo,
S.Bobic,
B.Lindner,
and
A.Petersen
(2008).
A novel recombinantly produced banana lectin isoform is a valuable tool for glycoproteomics and a potent modulator of the proliferation response in CD3+, CD4+, and CD8+ populations of human PBMCs.
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Int J Biochem Cell Biol,
40,
929-941.
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S.Nakamura-Tsuruta,
N.Uchiyama,
W.J.Peumans,
E.J.Van Damme,
K.Totani,
Y.Ito,
and
J.Hirabayashi
(2008).
Analysis of the sugar-binding specificity of mannose-binding-type Jacalin-related lectins by frontal affinity chromatography--an approach to functional classification.
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FEBS J,
275,
1227-1239.
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A.Sharma,
D.Chandran,
D.D.Singh,
and
M.Vijayan
(2007).
Multiplicity of carbohydrate-binding sites in beta-prism fold lectins: occurrence and possible evolutionary implications.
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J Biosci,
32,
1089-1110.
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C.Clavel,
A.Canales,
G.Gupta,
J.I.Santos,
F.J.Cañada,
S.Penadés,
A.Surolia,
and
J.Jiménez-Barbero
(2007).
NMR studies on the conformation of oligomannosides and their interaction with banana lectin.
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Glycoconj J,
24,
449-464.
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M.Vijayan
(2007).
Peanut lectin crystallography and macromolecular structural studies in India.
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J Biosci,
32,
1059-1066.
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N.Chandra
(2006).
Common scaffolds, diverse recognition profiles.
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Structure,
14,
1093-1094.
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T.Haraguchi,
K.Nomura,
and
F.Yagi
(2006).
Cloning and expression of a mannose-binding jacalin-related lectin from leaves of Japanese cycad (Cycas revoluta Thunb.).
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Biosci Biotechnol Biochem,
70,
2222-2229.
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The most recent references are shown first.
Citation data come partly from CiteXplore and partly
from an automated harvesting procedure. Note that this is likely to be
only a partial list as not all journals are covered by
either method. However, we are continually building up the citation data
so more and more references will be included with time.
Where a reference describes a PDB structure, the PDB
codes are
shown on the right.
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Links
