Azelaic Acid

Azelaic Acid

SCHEMBL2380307

O=C([O-])CCCCCCCC(=O)O.[K+]

nearest known ligand 0.67

Full drug profile on Sugi Atlas →

Known targets — ChEMBL curated mechanism

AGTR1DHFRGABBR1GABBR2GABRA1GABRA2GABRA3GABRA4GABRA5GABRA6GABRB1GABRB2GABRB3GABRDGABREGABRG1GABRG2GABRG3GABRPGABRQGARTNR3C2PBP2XPTGS1PTGS2VKORC1blablaT-3blaT-4blaT-5blaT-6dacAdacBdacCfolAftsImrcAmrcBmrdApbp1apbp1bpbp2apbp2bpbp3polthyA

The experimentally established mechanism targets of Azelaic Acid. The predicted profile below is derived independently by chemical similarity — agreement is a validation signal, a miss is honest.

Predicted protein targets (top 20)

geneUniProtsupporting neighboursconfidence
TSHR P16473 5/20 0.67
LMNA P02545 3/20 0.67
NFKB1 P19838 1/20 0.67
PMP22 Q01453 1/20 0.67
GPR84 Q9NQS5 6/20 0.55
FFAR1 O14842 2/20 0.55
FFAR4 Q5NUL3 2/20 0.55
SLC22A6 Q4U2R8 2/20 0.53
PPARG P37231 6/20 0.52
PPARD Q03181 6/20 0.52
PPARA Q07869 6/20 0.52
HDAC11 Q96DB2 5/20 0.52
ALDH1A1 P00352 3/20 0.52
TLR2 O60603 2/20 0.52
TDP1 Q9NUW8 2/20 0.52
MEN1 O00255 2/20 0.52
FABP4 P15090 2/20 0.52
ALOX15 P16050 2/20 0.52
PTPN1 P18031 2/20 0.52
KMT2A Q03164 2/20 0.52

Click a target to see other patent compounds predicted against it — the reverse direction, in place.

Similar compounds — the chemically nearest patent molecules

Nearest neighbours by Morgan-fingerprint cosine across the patent-compound collection, with each neighbour's top predicted target and the predicted targets it shares with this molecule.

Compoundsimilaritytop predictedshared targets
Sebacic Acid SCHEMBL29049531 1.00 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Azelaic Acid SCHEMBL29070842 1.00 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Potassium Ion SCHEMBL30384886 1.00 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Adipic Acid SCHEMBL105192 0.97 LMNA (0.65) TSHRLMNANFKB1PMP22GPR84
Sebacic Acid SCHEMBL6135890 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Azelaic Acid SCHEMBL31148332 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Pimelic Acid SCHEMBL30384892 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Azelaic Acid SCHEMBL11445736 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Octanedioate SCHEMBL11440382 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84
Octanedioate SCHEMBL9642090 0.94 TSHR (0.67) TSHRLMNANFKB1PMP22GPR84

Similarity is cosine over the 2,048-bit Morgan fingerprint (≈ Tanimoto). Identical fingerprints score 1.00.

Patent provenance — the patents this molecule appears in, and who filed them

Claimed or disclosed in 15 patents. claimed = in the patent's claims; disclosed = body only.

PatentTitleAssigneePublishedPriorityFilingCountryStatus
EP-3749081-B1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MAN INC (US) 2025-05-21 EP disclosed
WO-2024177875-A1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT INC. (US) 2024-08-29 WO disclosed
US-11638401-B2 Methods and compositions for increasing tolerance to abiotic stress in plants CROP MICROCLIMATE MANAGEMENT INC. (US) 2023-05-02 US disclosed
US-20210037717-A1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT INC. 2021-02-11 US disclosed
EP-3749081-A1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS Crop Microclimate Management, Inc. (US) 2020-12-16 EP disclosed
WO-2019152632-A1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT INC. (US) 2019-08-08 WO disclosed
EP-2549864-B1 METHODS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MAN INC (US) 2019-01-23 EP disclosed
US-10136641-B2 Methods for increasing tolerance to abiotic stress in plants CROP MICROCLIMATE MANAGEMENT INC. (US) 2018-11-27 US disclosed
US-20170208800-A1 Methods for Increasing Tolerance to Abiotic Stress in Plants CROP MICROCLIMATE MANAGEMENT INC. 2017-07-27 US disclosed
US-9648877-B2 Methods for increasing tolerance to abiotic stress in plants CROP MICROCLIMATE MANAGEMENT INC. (US) 2017-05-16 US disclosed
US-20140364314-A1 METHODS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT INC. 2014-12-11 US disclosed
US-8846573-B2 Methods for increasing tolerance to abiotic stress in plants CROP MICROCLIMATE MANAGEMENT INC. (US) 2014-09-30 US disclosed
EP-2549864-A1 METHODS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS Crop Microclimate Management, Inc. (US) 2013-01-30 EP disclosed
WO-2011119681-A1 METHODS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT INC. (US) 2011-09-29 WO disclosed
US-20110232181-A1 METHODS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS CROP MICROCLIMATE MANAGEMENT, INC. 2011-09-29 US disclosed

Patent text — is the patent's own abstract consistent with the prediction?

For each of this compound's patents that has machine-readable text (2 of them — usually the abstract, not the full specification), we ask MedCPT which protein the text reads most about, and where the chemistry-predicted target lands among 4885 human targets. A high rank means the patent's own wording is consistent with the prediction — a weak, independent signal, not proof of activity.

PatentTitleText reads most aboutPredicted target · text-rank
US-20210037717-A1 METHODS AND COMPOSITIONS FOR INCREASING TOLERANCE TO ABIOTIC STRESS IN PLANTS HPD, NOS3, HNMT TSHR 4859/4885LMNA 3002/4885NFKB1 1526/4885
US-11638401-B2 Methods and compositions for increasing tolerance to abiotic stress in plants HPD, NOS3, HNMT TSHR 4859/4885LMNA 3002/4885NFKB1 1526/4885

“Text reads most about” is the patent abstract's nearest protein in MedCPT space (background-debiased). Only ~1.4% of patents have machine-readable text, so most compounds won't have this panel.