PDBsum entry 1kzc

Immune system, sugar binding protein

PDB id

1kzc

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Contents

			Protein chains

					111 a.a. *

			Ligands

					MAN ×2

			Metals

					_CL


					_CA ×4

			Waters ×241

* Residue conservation analysis

PDB id:

1kzc

Links

Name:

Immune system, sugar binding protein

Title:

Complex of mbp-c and high-affinity linear trimannose

Structure:

Mannose-binding protein c. Chain: 1, 2. Fragment: subtilisin fragment (residues 129-243 of p08661). Synonym: mbp-c. Mannan-binding protein. Ra-reactive factor p28a subunit. Rarf/p28a. Engineered: yes

Source:

Rattus norvegicus. Norway rat. Organism_taxid: 10116. Gene: mbl1. Expressed in: escherichia coli. Expression_system_taxid: 562.

Resolution:

1.85Å

R-factor:

0.210

R-free:

0.242

Authors:

K.K.Ng,A.R.Kolatkar,S.Park-Snyder,H.Feinberg,D.A.Clark,K.Drickamer, W.I.Weis

Key ref:

K.K.Ng et al. (2002). Orientation of bound ligands in mannose-binding proteins. Implications for multivalent ligand recognition. J Biol Chem, 277, 16088-16095. PubMed id: 11850428 DOI: 10.1074/jbc.M200493200

Date:

06-Feb-02

Release date:

05-Jul-02

PROCHECK

	Headers

	References

Protein chains

P08661 (MBL2_RAT) - Mannose-binding protein C from Rattus norvegicus

Seq: Struc:					244 a.a. 111 a.a.

Key:

PfamA domain

Secondary structure

CATH domain

DOI no: 10.1074/jbc.M200493200	J Biol Chem 277:16088-16095 (2002)
PubMed id: 11850428

Orientation of bound ligands in mannose-binding proteins. Implications for multivalent ligand recognition.
K.K.Ng, A.R.Kolatkar, S.Park-Snyder, H.Feinberg, D.A.Clark, K.Drickamer, W.I.Weis.

ABSTRACT

Mannose-binding proteins (MBPs) are C-type animal lectins that recognize high mannose oligosaccharides on pathogenic cell surfaces. MBPs bind to their carbohydrate ligands by forming a series of Ca(2+) coordination and hydrogen bonds with two hydroxyl groups equivalent to the 3- and 4-OH of mannose. In this work, the determinants of the orientation of sugars bound to rat serum and liver MBPs (MBP-A and MBP-C) have been systematically investigated. The crystal structures of MBP-A soaked with monosaccharides and disaccharides and also the structure of the MBP-A trimer cross-linked by a high mannose asparaginyl oligosaccharide reveal that monosaccharides or alpha1-6-linked mannose bind to MBP-A in one orientation, whereas alpha1-2- or alpha1-3-linked mannose binds in an orientation rotated 180 degrees around a local symmetry axis relating the 3- and 4-OH groups. In contrast, a similar set of ligands all bind to MBP-C in a single orientation. The mutation of MBP-A His(189) to its MBP-C equivalent, valine, causes Man alpha 1-3Man to bind in a mixture of orientations. These data combined with modeling indicate that the residue at this position influences the orientation of bound ligands in MBP. We propose that the control of binding orientation can influence the recognition of multivalent ligands. A lateral association of trimers in the cross-linked crystals may reflect interactions within higher oligomers of MBP-A that are stabilized by multivalent ligands.

Selected figure(s)



	Figure 1. Fig. 1. Orientation of sugars bound in the MBP site. In A and B, the structure of the terminal mannose of the Man (1,2) branch of Man[6]GlcNAc[2]Asn (13) defining orientation I is shown on the left, and the structure of MeMan bound to MBP-C (14) defining orientation II is shown on the right. Ca^2+ coordination bonds are shown as long dashed lines, hydrogen bonds are shown as short dashed lines, and van der Waals contacts are shown as dotted lines. A, a view of the MBP binding site roughly perpendicular to the face of the pyranose ring. B, a view of the site rotated ~90° around the vertical axis with respect to A. For clarity, MBP-A residues His189 and Ile^207 and MBP-C residues Val194 and Val212 are shown only in B. The conformation of MBP-A His189 is determined by a hydrogen bond between His189 N[ 1] and the backbone NH of Gly191 (not shown).		Figure 2. Fig. 2. Structures of native and monosaccharide-bound MBP-A. The view is the same as that shown in Fig. 1A. For clarity, His189 and Ile^207 are shown only if they form contacts with the bound ligand. A, native crystal cryopreserved in MPD, showing the two water molecules that form the seventh and eighth coordination bonds with the Ca 2+. B, MeMan. C, MeGlcNAc protomer A (orientation I). van der Waals contacts between C6 of the pyranose ring and Ile^207 are shown. D, MeGlcNAc protomer C (orientation II). van der Waals contacts between the acetamido-moiety and Ile^207 are shown. E, MeFuc. van der Waals contacts between the side chain of His189 and the anomeric oxygen are shown. F, MeFuc.

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

21280017

Z.Ma, L.Zhang, Y.Nishiyama, M.F.Marais, K.Mazeau, and M.Vignon (2011).
The molecular structure and solution conformation of an acidic heteropolysaccharide from Auricularia auricula-judae.

Biopolymers, 95, 217-227.

20503257

J.Fortpied, D.Vertommen, and E.Van Schaftingen (2010).
Binding of mannose-binding lectin to fructosamines: a potential link between hyperglycaemia and complement activation in diabetes.

Diabetes Metab Res Rev, 26, 254-260.

20717628

K.C.Garber, K.Wangkanont, E.E.Carlson, and L.L.Kiessling (2010).
A general glycomimetic strategy yields non-carbohydrate inhibitors of DC-SIGN.

Chem Commun (Camb), 46, 6747-6749.

19505089

A.Datta, and K.N.Raymond (2009).
Gd-hydroxypyridinone (HOPO)-based high-relaxivity magnetic resonance imaging (MRI) contrast agents.

Acc Chem Res, 42, 938-947.

19799916

A.K.Shrive, C.Martin, I.Burns, J.M.Paterson, J.D.Martin, J.P.Townsend, P.Waters, H.W.Clark, U.Kishore, K.B.Reid, and T.J.Greenhough (2009).
Structural characterisation of ligand-binding determinants in human lung surfactant protein D: influence of Asp325.

J Mol Biol, 394, 776-788.

PDB codes:

3ikn 3ikp 3ikq 3ikr

19528664

M.E.Taylor, and K.Drickamer (2009).
Structural insights into what glycan arrays tell us about how glycan-binding proteins interact with their ligands.

Glycobiology, 19, 1155-1162.

17150970

H.Feinberg, R.Castelli, K.Drickamer, P.H.Seeberger, and W.I.Weis (2007).
Multiple modes of binding enhance the affinity of DC-SIGN for high mannose N-linked glycans found on viral glycoproteins.

J Biol Chem, 282, 4202-4209.

PDB codes:

2it5 2it6

17632570

J.Balzarini (2007).
Targeting the glycans of glycoproteins: a novel paradigm for antiviral therapy.

Nat Rev Microbiol, 5, 583-597.

17627761

L.R.Phaneuf, B.N.Lillie, M.A.Hayes, and P.V.Turner (2007).
Single nucleotide polymorphisms in mannan-binding lectins and ficolins in various strains of mice.

Int J Immunogenet, 34, 259-267.

17544814

R.Wallis (2007).
Interactions between mannose-binding lectin and MASPs during complement activation by the lectin pathway.

Immunobiology, 212, 289-299.

16001416

A.Laederach, and P.J.Reilly (2005).
Modeling protein recognition of carbohydrates.

Proteins, 60, 591-597.

16336259

A.N.Zelensky, and J.E.Gready (2005).
The C-type lectin-like domain superfamily.

FEBS J, 272, 6179-6217.

15296743

A.Lundell, A.I.Olin, M.Mörgelin, S.al-Karadaghi, A.Aspberg, and D.T.Logan (2004).
Structural basis for interactions between tenascins and lectican C-type lectin domains: evidence for a crosslinking role for tenascins.

Structure, 12, 1495-1506.

PDB code:

1tdq

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.