Target Pathogen

Overview

Basic information about this protein and its source genome.

Accession: PA4274
Assembly: Pseudomonas aeruginosa PAO1, complete genome
Gene: rplK PA4274
Status: annotated
Amino acids: 143
Structure source: AlphaFold

GO

GO:0022625 The large subunit of a ribosome located in the cytosol. GO:0070180 Binding to large ribosomal subunit RNA (LSU rRNA), a constituent of the large ribosomal subunit. In S. cerevisiae, this is the 25S rRNA. GO:0003735 The action of a molecule that contributes to the structural integrity of the ribosome. GO:0006412 The cellular metabolic process in which a protein is formed, using the sequence of a mature mRNA or circRNA molecule to specify the sequence of amino acids in a polypeptide chain. Translation is mediated by the ribosome, and begins with the formation of a ternary complex between aminoacylated initiator methionine tRNA, GTP, and initiation factor 2, which subsequently associates with the small subunit of the ribosome and an mRNA or circRNA. Translation ends with the release of a polypeptide chain from the ribosome. GO:0005840 An intracellular organelle, about 200 A in diameter, consisting of RNA and protein. It is the site of protein biosynthesis resulting from translation of messenger RNA (mRNA). It consists of two subunits, one large and one small, each containing only protein and RNA. Both the ribosome and its subunits are characterized by their sedimentation coefficients, expressed in Svedberg units (symbol: S). Hence, the prokaryotic ribosome (70S) comprises a large (50S) subunit and a small (30S) subunit, while the eukaryotic ribosome (80S) comprises a large (60S) subunit and a small (40S) subunit. Two sites on the ribosomal large subunit are involved in translation, namely the aminoacyl site (A site) and peptidyl site (P site). Ribosomes from prokaryotes, eukaryotes, mitochondria, and chloroplasts have characteristically distinct ribosomal proteins.

Target profile

Computed evidence for target prioritization.

Human off-target: hit
Human identity (%): 46.552
Human E-value: 2.45e-12
Gut microbiome off-target: hit
Essential (DEG): Y
Localization: Cytoplasmic

Selected Druggability evidence

Selected Druggability is the FPocket score chosen for ranking using the curated structure priority. The 3D viewer may show a different loaded structure, so its visible pockets can differ.

FPocket 0.261

Structure –

Pocket –

Sequence

Primary amino-acid sequence viewer.

Functional Annotations

Enzyme classification and Gene Ontology terms linked to this protein.

5 GO

Gene Ontology (GO)

5

GO:0022625 The large subunit of a ribosome located in the cytosol.
GO:0070180 Binding to large ribosomal subunit RNA (LSU rRNA), a constituent of the large ribosomal subunit. In S. cerevisiae, this is the 25S rRNA.
GO:0003735 The action of a molecule that contributes to the structural integrity of the ribosome.
GO:0006412 The cellular metabolic process in which a protein is formed, using the sequence of a mature mRNA or circRNA molecule to specify the sequence of amino acids in a polypeptide chain. Translation is mediated by the ribosome, and begins with the formation of a ternary complex between aminoacylated initiator methionine tRNA, GTP, and initiation factor 2, which subsequently associates with the small subunit of the ribosome and an mRNA or circRNA. Translation ends with the release of a polypeptide chain from the ribosome.
GO:0005840 An intracellular organelle, about 200 A in diameter, consisting of RNA and protein. It is the site of protein biosynthesis resulting from translation of messenger RNA (mRNA). It consists of two subunits, one large and one small, each containing only protein and RNA. Both the ribosome and its subunits are characterized by their sedimentation coefficients, expressed in Svedberg units (symbol: S). Hence, the prokaryotic ribosome (70S) comprises a large (50S) subunit and a small (30S) subunit, while the eukaryotic ribosome (80S) comprises a large (60S) subunit and a small (40S) subunit. Two sites on the ribosomal large subunit are involved in translation, namely the aminoacyl site (A site) and peptidyl site (P site). Ribosomes from prokaryotes, eukaryotes, mitochondria, and chloroplasts have characteristically distinct ribosomal proteins.

Sequence Features

Domain/signature hits from InterPro and related databases.

26 records

Show feature table

Start	End	DB	Term	Name
3	141	NCBIfam	TIGR01632	50S ribosomal protein L11
3	141	InterPro	IPR006519	Ribosomal protein L11, bacterial-type
71	142	FunFam	G3DSA:1.10.10.250:FF:000001	50S ribosomal protein L11
1	81	Gene3D	G3DSA:3.30.1550.10	-
1	81	InterPro	IPR036796	Ribosomal protein L11/L12, N-terminal domain superfamily
127	142	ProSitePatterns	PS00359	Ribosomal protein L11 signature.
127	142	InterPro	IPR020785	Ribosomal protein L11, conserved site
82	143	Gene3D	G3DSA:1.10.10.250	-
82	143	InterPro	IPR036769	Ribosomal protein L11, C-terminal domain superfamily
2	70	FunFam	G3DSA:3.30.1550.10:FF:000001	50S ribosomal protein L11
9	141	SMART	SM00649	rl11c
9	141	InterPro	IPR000911	Ribosomal protein L11/L12
3	72	SUPERFAMILY	SSF54747	Ribosomal L11/L12e N-terminal domain
3	72	InterPro	IPR036796	Ribosomal protein L11/L12, N-terminal domain superfamily
72	140	Pfam	PF00298	Ribosomal protein L11, RNA binding domain
72	140	InterPro	IPR020783	Ribosomal protein L11, C-terminal
5	142	Hamap	MF_00736	50S ribosomal protein L11 [rplK].
5	142	InterPro	IPR000911	Ribosomal protein L11/L12
68	141	SUPERFAMILY	SSF46906	Ribosomal protein L11, C-terminal domain
68	141	InterPro	IPR036769	Ribosomal protein L11, C-terminal domain superfamily
9	140	CDD	cd00349	Ribosomal_L11
9	140	InterPro	IPR000911	Ribosomal protein L11/L12
3	140	PANTHER	PTHR11661	60S RIBOSOMAL PROTEIN L12
3	140	InterPro	IPR000911	Ribosomal protein L11/L12
9	67	Pfam	PF03946	Ribosomal protein L11, N-terminal domain
9	67	InterPro	IPR020784	Ribosomal protein L11, N-terminal

3D Structure

Selected loaded structure. Experimental PDB entries may cover only a portion of the sequence; predicted models typically cover the full protein.

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Structural evidence

0 + 1

Experimental PDB entries and predicted models. Click Switch to display a different structure in the viewer.

Entry	Method	Resolution	Chain	Coverage	Links	Status
AlphaFold PA4274	AlphaFold	—	—	full sequence	—	Viewing

Pocket details FPocket · P2Rank — toggle visibility and zoom from here, or open full viewer

Pockets (FPOCKET)

Showing top-ranked FPocket candidates by druggability. Druggability is color-coded: high (0.7 or higher), medium (0.4 to 0.69), low (below 0.4).

FPOCKET	Sticks	Spheres	Surfaces	Druggability	Labels	Zoom	Positions
1				0.261

Ligand evidence

Ligands grouped by evidence source. PDB ligands keep the source crystal visible, and loaded crystals can be opened directly in the structure viewer.

17 records

Highest-confidence structural evidence: ligands co-crystallized with this exact protein. If the source PDB is loaded in TPW, use Open crystal to inspect it in the structure viewer.

No PDB structure with a co-crystallized ligand found for this exact protein.

Structural evidence inferred from similar proteins. The source crystal indicates where the ligand was observed; the UniProt column identifies the homologous protein carrying that ligand.

No PDB ligands found through similar proteins.

Experimental bioactivity from ChEMBL measured directly on this protein. Score = pchembl (−log Ki/IC₅₀; higher = more potent).

No ChEMBL bioactivity data found for this exact protein.

Bioactivity inferred from similar proteins in ChEMBL. Score = pchembl (−log Ki/IC₅₀; higher = more potent).

No ChEMBL hits found through similar proteins.

Proposed virtual-screening candidates from ZINC. Score = Tanimoto similarity to a known binder (0–1; higher = more similar).

Ligand	Tanimoto	MW · LogP · TPSA	Lipinski	PAINS	SMILES
ZINC1532902	0.700	206.2 Da LogP -0.86 TPSA 132.1	✓ Ro5	✓ Clean	`O=C(O)CC[C@@](O)(CC(=O)O)C(=O)O`
ZINC2018106	0.700	206.2 Da LogP -0.86 TPSA 132.1	✓ Ro5	✓ Clean	`O=C(O)CC[C@](O)(CC(=O)O)C(=O)O`
ZINC3593496	0.652	206.2 Da LogP -1.16 TPSA 121.1	✓ Ro5	✓ Clean	`COC(=O)C[C@@](O)(CC(=O)O)C(=O)O`
ZINC3593497	0.652	206.2 Da LogP -1.16 TPSA 121.1	✓ Ro5	✓ Clean	`COC(=O)C[C@](O)(CC(=O)O)C(=O)O`
ZINC14686440	0.625	436.4 Da LogP -2.64 TPSA 247.9	1 viol.	✓ Clean	`O=C(O)C[C@](O)(CC(=O)NCCCCNC(=O)C[C@@](O)(CC(=O…`
ZINC14686442	0.625	436.4 Da LogP -2.64 TPSA 247.9	1 viol.	✓ Clean	`O=C(O)C[C@@](O)(CC(=O)NCCCCNC(=O)C[C@](O)(CC(=O…`
ZINC14686444	0.625	436.4 Da LogP -2.64 TPSA 247.9	1 viol.	✓ Clean	`O=C(O)C[C@@](O)(CC(=O)NCCCCNC(=O)C[C@@](O)(CC(=…`
ZINC13398039	0.577	234.2 Da LogP -0.38 TPSA 121.1	✓ Ro5	✓ Clean	`CC(C)OC(=O)C[C@](O)(CC(=O)O)C(=O)O`
ZINC2528012	0.577	234.2 Da LogP -0.38 TPSA 121.1	✓ Ro5	✓ Clean	`CC(C)OC(=O)C[C@@](O)(CC(=O)O)C(=O)O`
ZINC146315135	0.560	204.2 Da LogP 0.86 TPSA 94.8	✓ Ro5	✓ Clean	`CCCCC[C@@](O)(CC(=O)O)C(=O)O`
ZINC146315336	0.560	204.2 Da LogP 0.86 TPSA 94.8	✓ Ro5	✓ Clean	`CCCCC[C@](O)(CC(=O)O)C(=O)O`
ZINC1850353	0.556	206.1 Da LogP -0.86 TPSA 132.1	✓ Ro5	✓ Clean	`O=C(O)CC(O)(CC(=O)O)CC(=O)O`
ZINC13398014	0.522	220.2 Da LogP -1.07 TPSA 110.1	✓ Ro5	✓ Clean	`COC(=O)CC(O)(CC(=O)OC)C(=O)O`
ZINC3861629	0.522	206.1 Da LogP -1.16 TPSA 121.1	✓ Ro5	✓ Clean	`COC(=O)C(O)(CC(=O)O)CC(=O)O`
ZINC100969993	0.500	359.5 Da LogP 2.70 TPSA 123.9	✓ Ro5	✓ Clean	`CCCCCCCCCCCCNC(=O)C[C@](O)(CC(=O)O)C(=O)O`
ZINC100969996	0.500	359.5 Da LogP 2.70 TPSA 123.9	✓ Ro5	✓ Clean	`CCCCCCCCCCCCNC(=O)C[C@@](O)(CC(=O)O)C(=O)O`
ZINC1711854	0.500	248.2 Da LogP -0.13 TPSA 149.2	✓ Ro5	✓ Clean	`O=C(O)CC(CC(=O)O)(CC(=O)O)CC(=O)O`

PDB and ChEMBL records on this protein are shown in full. ChEMBL records from similar proteins are capped at the top 100 per protein (by pchembl) and ZINC at the top 50 (Tanimoto ≥ 0.5). ADME columns are descriptor-based screening flags, not experimental toxicity results.

PA4274