Contacts of ligand GLC 2E in PDB entry 1MPN
Ligand-Protein Contacts (LPC) are derived
with the LPC software (Sobolev V., Sorokine A.,
Prilusky J., Abola E.E. and Edelman M. (1999) Automated
analysis of interatomic contacts in proteins.
Bioinformatics, 15, 327-332). A
short description of the analytical approach
is given at the end of the page.
On this page you will find:
- 3D ligand structure presentation with
Jmol, an open-source
Java viewer for chemical structures in 3D (top left window)
- Solvent accessible surface of the ligand
complexed with protein and in uncomplexed form
(top right window). Clicking
on "select" buttons highlights atoms in 3D picture
- List of residues in contact
with the ligand
- List of putative hydrogen
bonds formed by the ligand
- Full list of atomic contacts
formed by the ligand
- Values of ligand complementarity
(a function of atomic contact
surface area and the chemical properties of contacting atoms)
- Prediction of complementarity changes as a
function of atomic substitution
in the
ligand
Table II
Residues in contact with ligand GLC 2E
in PDB entry 1MPN (back to top of page)
Legend:
Dist - nearest distance (Å) between atoms of the ligand and the residue
Surf - contact surface area (Å2) between the ligand and the residue
HB - hydrophilic-hydrophilic contact (hydrogen bond)
Arom - aromatic-aromatic contact
Phob - hydrophobic-hydrophobic contact
DC - hydrophobic-hydrophilic contact (destabilizing contact)
+/- - indicates presence/absence of a specific contacts
* - indicates residues contacting ligand by their side chain
(including CA atoms)
----------------------------------------------------------
Specific contacts
---------------------------
Residue Dist Surf HB Arom Phob DC
----------------------------------------------------------
6B TYR* 3.2 18.6 - - - -
8B ARG* 3.4 19.6 + - - -
33B ARG* 2.3 31.7 + - - -
41B TYR* 3.7 21.4 - - - -
43B GLU* 2.5 38.2 + - - +
106B PHE* 3.8 0.7 - - - -
109B ARG* 2.9 27.1 + - - -
116B ASP* 2.8 29.5 + - - -
118B TYR* 3.3 13.3 + - - -
1E GLC 1.4 65.6 + - - -
3E GLC 1.4 93.7 + - - -
----------------------------------------------------------
Table III
List of putative hydrogen bonds between ligand GLC 2E
and protein in PDB entry 1MPN
(back to top
of page)
Legend:
N - ligand atom number in PDB entry
Dist - distance (Å) between the ligand and protein atoms
Surf - contact surface area (Å2) between the ligand and protein atoms
------------------------------------------------------------------------
Ligand atom Protein atom
----------------- ---------------------------- Dist Surf
N Name Class Residue Name Class
------------------------------------------------------------------------
7 O2 I GLC 1E O4 I 2.8 2.4
7 O2 I ASP 116B OD2 II 2.8 17.8
7 O2 I ARG 8B NH2 III 3.4 15.4
7 O2 I GLC 1E O3 I 3.5 2.9
8 O3 I ARG 33B NH2 III 2.3 31.7
8 O3 I GLC 3E O2 I 3.0 0.5
8 O3 I ARG 8B NH1 III 3.4 0.2
9 O4 I GLC 3E O5 II 2.3 0.7
9 O4 I GLC 3E O2 I 2.6 0.3
9 O4 I TYR 118B OH I 3.5 1.4
11 O6 I GLU 43B OE2 II 2.5 25.8
11 O6 I ARG 109B NH2 III 2.9 11.6
11 O6 I GLU 43B OE1 II 3.1 2.3
------------------------------------------------------------------------
Table IV
Full list of atomic contacts with ligand GLC 2E
in PDB entry 1MPN (back
to top of page)
Total number of contacts is 56
Legend:
N - ligand atom number in PDB entry
Dist - distance (A) between the ligand and protein atoms
Surf - contact surface area (A**2) between the ligand and protein atoms
* - indicates destabilizing contacts
------------------------------------------------------------------------
Ligand atom Protein atom
----------------- ---------------------------- Dist Surf
N Name Class Residue Name Class
------------------------------------------------------------------------
1 C1 VIII GLC 1E O4 I 1.4 35.4
1 C1 VIII GLC 1E C4 VI 2.5 11.0
1 C1 VIII GLC 1E C6 VI 3.2 4.9
1 C1 VIII TYR 41B CE2 V 3.7 8.3
1 C1 VIII TYR 41B CZ V 4.3 0.2
2 C2 VI TYR 41B CE2 V 3.9 11.9
2 C2 VI ARG 8B NH1 III 3.9 4.0
2 C2 VI TYR 41B CD2 V 4.1 0.4
2 C2 VI TYR 6B CZ V 4.8 0.4
3 C3 VI GLC 1E O4 I 3.0 2.0
3 C3 VI GLC 3E C1 VIII 3.3 0.2
3 C3 VI ASP 116B OD1 II 3.4 11.7
4 C4 VI GLC 3E C1 VIII 2.4 7.9
4 C4 VI TYR 6B CD2 V 3.8 6.1
4 C4 VI TYR 6B CG V 4.2 0.4
5 C5 VIII GLC 1E O4 I 3.0 2.7
5 C5 VIII TYR 118B OH I 3.3 8.3
5 C5 VIII ARG 109B NH2 III 3.9 1.1
6 C6 VI ARG 109B NH2 III 3.2 13.5
6 C6 VI TYR 118B OH I 3.4 3.6
6 C6 VI GLU 43B OE2 II 3.8 0.2
6 C6 VI GLC 3E O5 II 3.8 7.0
6 C6 VI GLC 3E C5 VIII 3.8 4.9
6 C6 VI GLC 3E O6 I 4.0 5.8
6 C6 VI ARG 109B CZ VI 4.2 0.4
6 C6 VI GLU 43B CD VI 4.3 1.1
6 C6 VI ARG 109B NH1 III 4.4 0.4
6 C6 VI TYR 6B CD2 V 4.9 2.5
6 C6 VI TYR 6B CB IV 4.9 2.2
7 O2 I GLC 1E O4 I 2.8 2.4
7 O2 I ASP 116B OD2 II 2.8 17.8
7 O2 I ARG 8B NH2 III 3.4 15.4
7 O2 I GLC 1E O3 I 3.5 2.9
7 O2 I GLC 1E C4 VI 3.6 0.3
7 O2 I TYR 41B CD2 V 4.5 0.2
8 O3 I ARG 33B NH2 III 2.3 31.7
8 O3 I GLC 3E O2 I 3.0 0.5
8 O3 I GLC 3E C1 VIII 3.2 1.9
8 O3 I TYR 6B CE2 V 3.2 5.9
8 O3 I TYR 6B CZ V 3.3 1.0
8 O3 I ARG 8B NH1 III 3.4 0.2
9 O4 I GLC 3E C1 VIII 1.4 56.1
9 O4 I GLC 3E O5 II 2.3 0.7
9 O4 I GLC 3E C2 VI 2.3 4.3
9 O4 I GLC 3E O2 I 2.6 0.3
9 O4 I GLC 3E C5 VIII 2.7 2.6
9 O4 I GLC 3E C3 VI 2.9 1.4
9 O4 I TYR 118B OH I 3.5 1.4
10 O5 II GLC 1E C6 VI 3.2 3.8
10 O5 II GLU 43B OE2 II 3.4 3.3*
10 O5 II TYR 41B CE2 V 3.7 0.3
11 O6 I GLU 43B OE2 II 2.5 25.8
11 O6 I ARG 109B NH2 III 2.9 11.6
11 O6 I GLU 43B CD VI 3.0 5.5
11 O6 I GLU 43B OE1 II 3.1 2.3
11 O6 I PHE 106B CE2 V 3.8 0.7
------------------------------------------------------------------------
Table V
Complementarity values for the ligand GLC 2E
in PDB entry 1MPN (back to top of page)
---------------------------------------------
Theoretical maximum (Å2) 306
Actual value (Å2) 352
Normalised complementarity 1.15
---------------------------------------------
Table VI
Normalised complementarity as a function of atomic
substitution for ligand GLC 2E
in PDB entry 1MPN (back
to top of page)
Legend:
| N | - ligand atom number in PDB entry |
| Bold
| - indicates atomic
substitution which could stabilize the complex |
| Italics | - indicates atomic
substitution which could destabilize the complex |
|
Ligand atom | Atom class |
|---|
| N | Type | Class | I
| II | III | IV | V |
VI | VII | VIII |
|---|
| 1 | C1
| VIII |
1.15 |
1.15
|
1.15 |
0.92
|
1.15 |
1.15
|
1.15 |
1.15
|
| 2 | C2
| VI |
1.15 |
1.15
|
1.13 |
1.13
|
1.15 |
1.15
|
1.13 |
1.15
|
| 3 | C3
| VI |
1.15 |
1.07
|
1.15 |
1.06
|
1.15 |
1.15
|
1.15 |
1.07
|
| 4 | C4
| VI |
1.15 |
1.10
|
1.15 |
1.15
|
1.15 |
1.15
|
1.15 |
1.10
|
| 5 | C5
| VIII |
1.15 |
1.15
|
1.14 |
1.07
|
1.15 |
1.15
|
1.14 |
1.15
|
| 6 | C6
| VI |
1.14 |
1.06
|
1.05 |
0.95
|
1.15 |
1.15
|
1.06 |
1.07
|
| 7 | O2
| I |
1.15 |
1.04
|
1.05 |
0.90
|
1.15 |
1.15
|
1.05 |
1.04
|
| 8 | O3
| I |
1.15 |
1.14
|
0.94 |
0.94
|
1.15 |
1.15
|
0.94 |
1.14
|
| 9 | O4
| I |
1.15 |
0.76
|
1.15 |
1.14
|
1.15 |
1.15
|
1.15 |
0.76
|
| 10 | O5
| II |
1.17 |
1.15
|
1.17 |
1.15
|
1.17 |
1.17
|
1.17 |
1.15
|
| 11 | O6
| I |
1.15 |
0.97
|
1.08 |
0.89
|
1.15 |
1.15
|
1.08 |
0.97
|
A short description of the
analytical approach (back to top of page)
The analysis of ligand-protein contacts used in this page
is based upon the surface complementarity approach
developed in:
Sobolev V., Wade R.C., Vriend G.
and Edelman M. PROTEINS (1996)
25, 120-129.
The complementarity function
therein is defined as:
Where Sl is the sum of all
surface areas of legitimate atomic contacts between
ligand and receptor, Si is the sum of
all surface areas of illegitimate atomic
contacts, and E is a repulsion term.
Legitimacy depends on the hydrophobic-hydrophilic
properties of the contacting atoms. In order to
define it, for each inter-atomic contact,
eight atom classes have been introduced:
I Hydrophilic - N and O that can donate and accept hydrogen bonds
(e.g., oxygen of hydroxyl group of Ser. or Thr)
II Acceptor - N or O that can only accept a hydrogen bond
III Donor - N that can only donate a hydrogen bond
IV Hydrophobic - Cl, Br, I and all C atoms that are not in
aromatic rings and do not have a covalent bond to
a N or O atom
V Aromatic - C in aromatic rings irrespective of any other
bonds formed by the atom
VI Neutral - C atoms that have a covalent bond to at least one
atom of class I or two or more atoms from class II
or III; atoms; S, F, P, and metal atoms in all cases
VII Neutral-donor - C atoms that have a covalent bond with only one
atom of class III
VIII Neutral-acceptor - C atoms that have a covalent bond with only
one atom of class II
For each pair of contacts the state of legitimacy
is shown below:
Legend:
+, legitimate
-, illegitimate
------------------------------------------------------------
Atomic class I II III IV V VI VII VIII
------------------------------------------------------------
I (Hydrophilic) + + + - + + + +
II (Acceptor) + - + - + + + -
III (Donor) + + - - + + - +
IV (Hydrophobic) - - - + + + + +
V (Aromatic) + + + + + + + +
VI (Neutral) + + + + + + + +
VII (Neutral-donor) + + - + + + - +
VIII (Neutral-acceptor) + - + + + + + -
------------------------------------------------------------
WARNING !!
Atom classes for ligands are automatically
assigned based on the atomic coordinates. However, in
three cases the automatic assignment is
currently ambiguous (due to low resolution). In these
three cases, the user is advised to manually analyze
the full list of contacts (Table IV).
1. Carbon atoms belonging to a 4-, 5- or 6-member ring are
considered "aromatic" (Class V) if the ring is approximately
planar, and "hydrophobic" (Class IV) or "neutral" (Classes
VI, VII, VIII) if the ring is non-planar.
2. The oxygen atom of a carbonyl or hydroxy group is considered
"hydroxy" (Class I) if the CO bond is longer than 1.29 Å, and
"carbonyl" (Class II) if shorter.
3. All nitrogen atoms are considered "hydrophilic" (Class I).
IN YOUR STRUCTURE, the following atoms
fall in these ambiguous cases:
Ligand GLC 1
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O1 8 O2 9 O3 10 O4 12 O6
Ligand GLC 2
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Ligand GLC 3
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Ligand GLC 1
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O1 8 O2 9 O3 10 O4 12 O6
Ligand GLC 2
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Ligand GLC 3
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Ligand GLC 1
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O1 8 O2 9 O3 10 O4 12 O6
Ligand GLC 2
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Ligand GLC 3
1. Carbon (in rings)
1 C1 2 C2 3 C3 4 C4 5 C5
2. Oxygen ("hydroxy" or "carbonyl")
7 O2 8 O3 9 O4 11 O6
Please E-mail any questions and/or suggestions
concerning this page to
Vladimir.Sobolev@weizmann.ac.il