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Hepatocyte growth factor

From Wikipedia, the free encyclopedia

Mammalian protein found in Homo sapiens

Hepatocyte growth factor (HGF) orscatter factor (SF) is aparacrine cellular growth,motility andmorphogenic factor. It is secreted bymesenchymal cells and targets and acts primarily uponepithelial cells andendothelial cells, but also acts onhaemopoietic progenitor cells andT cells. It has been shown to have a major role in embryonic organ development, specifically inmyogenesis, in adult organ regeneration, and in wound healing.^[1]

Function

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Hepatocyte growth factor regulates cell growth, cell motility, andmorphogenesis by activating atyrosine kinase signaling cascade after binding to the proto-oncogenicc-Met receptor.^[2]^[3] Hepatocyte growth factor is secreted byplatelets,^[4] andmesenchymal cells and acts as a multi-functionalcytokine on cells of mainly epithelial origin. Its ability to stimulatemitogenesis, cell motility, and matrix invasion gives it a central role inangiogenesis,tumorogenesis, and tissue regeneration.^[5]

Structure

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It is secreted as a single inactive polypeptide and is cleaved by serine proteases into a 69-kDa alpha-chain and 34-kDa beta-chain. A disulfide bond between the alpha and beta chains produces the active, heterodimeric molecule. The protein belongs to theplasminogen subfamily of S1 peptidases but has no detectableprotease activity.^[5]

Clinical significance

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Human HGF plasmid DNA therapy ofcardiomyocytes is being examined as a potential treatment forcoronary artery disease as well as treatment for the damage that occurs to the heart aftermyocardial infarction.^[6]^[7]As well as the well-characterised effects of HGF onepithelial cells,endothelial cells andhaemopoietic progenitor cells, HGF also regulates thechemotaxis of T cells into heart tissue. Binding of HGF by c-Met, expressed on T cells, causes the upregulation of c-Met,CXCR3, andCCR4 which in turn imbues them with the ability to migrate into heart tissue.^[8] HGF also promotes angiogenesis in ischemia injury.^[9] HGF may further play a role as an indicator for prognosis of chronicity forChikungunya virus inducedarthralgia. High HGF levels correlate with high rates of recovery.^[10]

Excessive local expression of HGF in thebreasts has been implicated inmacromastia.^[11] HGF is also importantly involved in normalmammary gland development.^[12]^[13]

HGF has been implicated in a variety ofcancers, including of thelungs,pancreas,thyroid,colon, andbreast.^[14]^[15]^[16]

Increased expression of HGF has been associated with the enhanced and scarlesswound healing capabilities offibroblast cells isolated from theoral mucosa tissue.^[17]

Circulating plasma levels

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Plasma from patients with advanced heart failure presents increased levels of HGF, which correlates with a negative prognosis and a high risk of mortality.^[18]^[19] Circulating HGF has been also identified as a prognostic marker of severity in patients with hypertension.^[20] Circulating HGF has been also suggested as a precocious biomarker for the acute phase of bowel inflammation.^[21]

Pharmacokinetics

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Exogenous HGF administered byintravenous injection is cleared rapidly from circulation by theliver, with ahalf-life of approximately 4 minutes.^[22]^[23]^[24]^[25]

Modulators

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Dihexa is an orally active, centrally penetrantsmall-molecule compound that directly binds to HGF and potentiates its ability to activate its receptor, c-Met.^[26]^[27] It is a strong inducer ofneurogenesis and is being studied for the potential treatment ofAlzheimer's disease andParkinson's disease.^[28]^[29]

Interactions

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Hepatocyte growth factor has been shown tointeract with the protein product of the c-Met oncogene, identified as the HGF receptor (HGFR).^[2]^[30]^[31] Both overexpression of the Met/HGFR receptor protein andautocrine activation of Met/HGFR by simultaneous expression of the hepatocyte growth factor ligand have been implicated in oncogenesis.^[32]^[33]Hepatocyte growth factor interacts with the sulfatedglycosaminoglycans heparan sulfate and dermatan sulfate.^[34]^[35] The interaction with heparan sulfate allows hepatocyte growth factor to form a complex with c-Met that is able to transduce intracellular signals leading to cell division and cell migration.^[34]^[36]

References

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^Gallagher JT, Lyon M (2000). "Molecular structure of Heparan Sulfate and interactions with growth factors and morphogens". In Iozzo MV (ed.).Proteoglycans: structure, biology and molecular interactions. Marcel Dekker Inc. New York, New York. pp. 27–59.
^^a ^bBottaro DP, Rubin JS, Faletto DL, Chan AM, Kmiecik TE, Vande Woude GF, et al. (February 1991). "Identification of the hepatocyte growth factor receptor as the c-met proto-oncogene product".Science.251 (4995):802–804.Bibcode:1991Sci...251..802B.doi:10.1126/science.1846706.PMID 1846706.
^Johnson M, Koukoulis G, Matsumoto K, Nakamura T, Iyer A (June 1993)."Hepatocyte growth factor induces proliferation and morphogenesis in nonparenchymal epithelial liver cells".Hepatology.17 (6):1052–1061.doi:10.1016/0270-9139(93)90122-4.PMID 8514254.
^Custo S, Baron B, Felice A, Seria E (5 July 2022)."A comparative profile of total protein and six angiogenically-active growth factors in three platelet products".GMS Interdisciplinary Plastic and Reconstructive Surgery DGPW.11 (Doc06): Doc06.doi:10.3205/iprs000167.PMC 9284722.PMID 35909816.
^^a ^b"Entrez Gene: HGF hepatocyte growth factor (hepapoietin A; scatter factor)".
^Yang ZJ, Zhang YR, Chen B, Zhang SL, Jia EZ, Wang LS, et al. (July 2009). "Phase I clinical trial on intracoronary administration of Ad-hHGF treating severe coronary artery disease".Molecular Biology Reports.36 (6):1323–1329.doi:10.1007/s11033-008-9315-3.PMID 18649012.S2CID 23419866.
^Hahn W, Pyun WB, Kim DS, Yoo WS, Lee SD, Won JH, et al. (October 2011). "Enhanced cardioprotective effects by coexpression of two isoforms of hepatocyte growth factor from naked plasmid DNA in a rat ischemic heart disease model".The Journal of Gene Medicine.13 (10):549–555.doi:10.1002/jgm.1603.PMID 21898720.S2CID 26812780.
^Komarowska I, Coe D, Wang G, Haas R, Mauro C, Kishore M, et al. (June 2015)."Hepatocyte Growth Factor Receptor c-Met Instructs T Cell Cardiotropism and Promotes T Cell Migration to the Heart via Autocrine Chemokine Release".Immunity.42 (6):1087–1099.doi:10.1016/j.immuni.2015.05.014.PMC 4510150.PMID 26070483.
^Chang HK, Kim PH, Cho HM, Yum SY, Choi YJ, Son Y, et al. (September 2016)."Inducible HGF-secreting Human Umbilical Cord Blood-derived MSCs Produced via TALEN-mediated Genome Editing Promoted Angiogenesis".Molecular Therapy.24 (9):1644–1654.doi:10.1038/mt.2016.120.PMC 5113099.PMID 27434585.
^Chow A, Her Z, Ong EK, Chen JM, Dimatatac F, Kwek DJ, et al. (January 2011)."Persistent arthralgia induced by Chikungunya virus infection is associated with interleukin-6 and granulocyte macrophage colony-stimulating factor".The Journal of Infectious Diseases.203 (2):149–157.doi:10.1093/infdis/jiq042.PMC 3071069.PMID 21288813.
^Zhong A, Wang G, Yang J, Xu Q, Yuan Q, Yang Y, et al. (July 2014)."Stromal-epithelial cell interactions and alteration of branching morphogenesis in macromastic mammary glands".Journal of Cellular and Molecular Medicine.18 (7):1257–1266.doi:10.1111/jcmm.12275.PMC 4124011.PMID 24720804.
^Niranjan B, Buluwela L, Yant J, Perusinghe N, Atherton A, Phippard D, et al. (September 1995). "HGF/SF: a potent cytokine for mammary growth, morphogenesis and development".Development.121 (9):2897–2908.doi:10.1242/dev.121.9.2897.PMID 7555716.
^Kamalati T, Niranjan B, Yant J, Buluwela L (January 1999). "HGF/SF in mammary epithelial growth and morphogenesis: in vitro and in vivo models".Journal of Mammary Gland Biology and Neoplasia.4 (1):69–77.doi:10.1023/A:1018756620265.PMID 10219907.S2CID 9310133.
^Thomas R. Ziegler, Glenn F. Pierce, David N. Herndon (6 December 2012).Growth Factors and Wound Healing: Basic Science and Potential Clinical Applications. Springer Science & Business Media. pp. 311–.ISBN 978-1-4612-1876-0.
^Sheen-Chen SM, Liu YW, Eng HL, Chou FF (March 2005)."Serum levels of hepatocyte growth factor in patients with breast cancer".Cancer Epidemiology, Biomarkers & Prevention.14 (3):715–717.doi:10.1158/1055-9965.EPI-04-0340.PMID 15767355.S2CID 3089594.
^El-Attar HA, Sheta MI (2011)."Hepatocyte growth factor profile with breast cancer".Indian Journal of Pathology & Microbiology.54 (3):509–513.doi:10.4103/0377-4929.85083.PMID 21934211.
^Dally J, Khan JS, Voisey A, Charalambous C, John HL, Woods EL, et al. (August 2017)."Hepatocyte Growth Factor Mediates Enhanced Wound Healing Responses and Resistance to Transforming Growth Factor-β₁-Driven Myofibroblast Differentiation in Oral Mucosal Fibroblasts".International Journal of Molecular Sciences.18 (9): 1843.doi:10.3390/ijms18091843.PMC 5618492.PMID 28837064.
^Richter B, Koller L, Hohensinner PJ, Zorn G, Brekalo M, Berger R, et al. (September 2013). "A multi-biomarker risk score improves prediction of long-term mortality in patients with advanced heart failure".International Journal of Cardiology.168 (2):1251–1257.doi:10.1016/j.ijcard.2012.11.052.PMID 23218577.
^Rychli K, Richter B, Hohensinner PJ, Kariem Mahdy A, Neuhold S, Zorn G, et al. (July 2011). "Hepatocyte growth factor is a strong predictor of mortality in patients with advanced heart failure".Heart.97 (14):1158–1163.doi:10.1136/hrt.2010.220228.PMID 21572126.S2CID 22426278.
^Nakamura S, Morishita R, Moriguchi A, Yo Y, Nakamura Y, Hayashi S, et al. (December 1998). "Hepatocyte growth factor as a potential index of complication in diabetes mellitus".Journal of Hypertension.16 (12 Pt 2):2019–2026.doi:10.1097/00004872-199816121-00025.PMID 9886892.S2CID 6615179.
^Sorour AE, Lönn J, Nakka SS, Nayeri T, Nayeri F (January 2015)."Evaluation of hepatocyte growth factor as a local acute phase response marker in the bowel: the clinical impact of a rapid diagnostic test for immediate identification of acute bowel inflammation".Cytokine.71 (1):8–15.doi:10.1016/j.cyto.2014.07.255.PMID 25174881.
^Yang J, Chen S, Huang L, Michalopoulos GK, Liu Y (April 2001)."Sustained expression of naked plasmid DNA encoding hepatocyte growth factor in mice promotes liver and overall body growth".Hepatology.33 (4):848–859.doi:10.1053/jhep.2001.23438.PMC 1821076.PMID 11283849.
^Appasamy R, Tanabe M, Murase N, Zarnegar R, Venkataramanan R, Van Thiel DH, et al. (March 1993). "Hepatocyte growth factor, blood clearance, organ uptake, and biliary excretion in normal and partially hepatectomized rats".Laboratory Investigation; A Journal of Technical Methods and Pathology.68 (3):270–276.PMID 8450646.
^Kato Y, Liu KX, Nakamura T, Sugiyama Y (August 1994). "Heparin-hepatocyte growth factor complex with low plasma clearance and retained hepatocyte proliferating activity".Hepatology.20 (2):417–424.doi:10.1002/hep.1840200223.PMID 8045504.S2CID 20021569.
^Yu Y, Yao AH, Chen N, Pu LY, Fan Y, Lv L, et al. (July 2007)."Mesenchymal stem cells over-expressing hepatocyte growth factor improve small-for-size liver grafts regeneration".Molecular Therapy.15 (7):1382–1389.doi:10.1038/sj.mt.6300202.PMID 17519892.
^Wright JW, Harding JW (January 2015). "The Brain Hepatocyte Growth Factor/c-Met Receptor System: A New Target for the Treatment of Alzheimer's Disease".Journal of Alzheimer's Disease.45 (4):985–1000.doi:10.3233/JAD-142814.PMID 25649658.
^Hu B, Yin N, Yang R, Liang S, Liang S, Faiola F (July 2020). "Silver nanoparticles (AgNPs) and AgNO₃ perturb the specification of human hepatocyte-like cells and cardiomyocytes".The Science of the Total Environment.725 138433.Bibcode:2020ScTEn.72538433H.doi:10.1016/j.scitotenv.2020.138433.PMID 32302844.
^Wright JW, Harding JW (2015). "The Brain Hepatocyte Growth Factor/c-Met Receptor System: A New Target for the Treatment of Alzheimer's Disease".Journal of Alzheimer's Disease.45 (4):985–1000.doi:10.3233/JAD-142814.PMID 25649658.
^Wright JW, Kawas LH, Harding JW (February 2015). "The development of small molecule angiotensin IV analogs to treat Alzheimer's and Parkinson's diseases".Progress in Neurobiology.125:26–46.doi:10.1016/j.pneurobio.2014.11.004.PMID 25455861.S2CID 41360989.
^Comoglio PM (1993). "Structure, biosynthesis and biochemical properties of the HGF receptor in normal and malignant cells".Exs.65:131–165.PMID 8380735.
^Naldini L, Weidner KM, Vigna E, Gaudino G,Bardelli A, Ponzetto C, et al. (October 1991)."Scatter factor and hepatocyte growth factor are indistinguishable ligands for the MET receptor".The EMBO Journal.10 (10):2867–2878.doi:10.1002/j.1460-2075.1991.tb07836.x.PMC 452997.PMID 1655405.
^Johnson M, Koukoulis G, Kochhar K, Kubo C, Nakamura T, Iyer A (September 1995). "Selective tumorigenesis in non-parenchymal liver epithelial cell lines by hepatocyte growth factor transfection".Cancer Letters.96 (1):37–48.doi:10.1016/0304-3835(95)03915-j.PMID 7553606.
^Kochhar KS, Johnson ME, Volpert O, Iyer AP (1995). "Evidence for autocrine basis of transformation in NIH-3T3 cells transfected with met/HGF receptor gene".Growth Factors.12 (4):303–313.doi:10.3109/08977199509028968.PMID 8930021.
^^a ^bLyon M, Deakin JA, Gallagher JT (January 2002)."The mode of action of heparan and dermatan sulfates in the regulation of hepatocyte growth factor/scatter factor".The Journal of Biological Chemistry.277 (2):1040–1046.doi:10.1074/jbc.M107506200.PMID 11689562.S2CID 29982976.
^Lyon M, Deakin JA, Rahmoune H, Fernig DG, Nakamura T, Gallagher JT (January 1998)."Hepatocyte growth factor/scatter factor binds with high affinity to dermatan sulfate".The Journal of Biological Chemistry.273 (1):271–278.doi:10.1074/jbc.273.1.271.PMID 9417075.S2CID 39689713.
^Sergeant N, Lyon M, Rudland PS, Fernig DG, Delehedde M (June 2000)."Stimulation of DNA synthesis and cell proliferation of human mammary myoepithelial-like cells by hepatocyte growth factor/scatter factor depends on heparan sulfate proteoglycans and sustained phosphorylation of mitogen-activated protein kinases p42/44".The Journal of Biological Chemistry.275 (22):17094–17099.doi:10.1074/jbc.M000237200.PMID 10747885.S2CID 25507615.

External links

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Hepatocyte+growth+factor at the U.S. National Library of MedicineMedical Subject Headings (MeSH)
Hepatocyte growth factor on theAtlas of Genetics and Oncology
UCSD Signaling Gateway Molecule Page onHGF
Overview of all the structural information available in thePDB forUniProt:P14210 (Hepatocyte growth factor) at thePDBe-KB.

v t e PDB gallery
1bht: NK1 FRAGMENT OF HUMAN HEPATOCYTE GROWTH FACTOR 1gmn: CRYSTAL STRUCTURES OF NK1-HEPARIN COMPLEXES REVEAL THE BASIS FOR NK1 ACTIVITY AND ENABLE ENGINEERING OF POTENT AGONISTS OF THE MET RECEPTOR 1gmo: CRYSTAL STRUCTURES OF NK1-HEPARIN COMPLEXES REVEAL THE BASIS FOR NK1 ACTIVITY AND ENABLE ENGINEERING OF POTENT AGONISTS OF THE MET RECEPTOR 1gp9: A NEW CRYSTAL FORM OF THE NK1 SPLICE VARIANT OF HGF/SF DEMONSTRATES EXTENSIVE HINGE MOVEMENT AND SUGGESTS THAT THE NK1 DIMER ORIGINATES BY DOMAIN SWAPPING 1nk1: NK1 FRAGMENT OF HUMAN HEPATOCYTE GROWTH FACTOR/SCATTER FACTOR (HGF/SF) AT 2.5 ANGSTROM RESOLUTION 1shy: The Crystal Structure of HGF beta-chain in Complex with the Sema Domain of the Met Receptor. 1si5: Protease-like domain from 2-chain hepatocyte growth factor 2hgf: HAIRPIN LOOP CONTAINING DOMAIN OF HEPATOCYTE GROWTH FACTOR, NMR, MINIMIZED AVERAGE STRUCTURE

PDB gallery

1bht: NK1 FRAGMENT OF HUMAN HEPATOCYTE GROWTH FACTOR
1gmn: CRYSTAL STRUCTURES OF NK1-HEPARIN COMPLEXES REVEAL THE BASIS FOR NK1 ACTIVITY AND ENABLE ENGINEERING OF POTENT AGONISTS OF THE MET RECEPTOR
1gmo: CRYSTAL STRUCTURES OF NK1-HEPARIN COMPLEXES REVEAL THE BASIS FOR NK1 ACTIVITY AND ENABLE ENGINEERING OF POTENT AGONISTS OF THE MET RECEPTOR
1gp9: A NEW CRYSTAL FORM OF THE NK1 SPLICE VARIANT OF HGF/SF DEMONSTRATES EXTENSIVE HINGE MOVEMENT AND SUGGESTS THAT THE NK1 DIMER ORIGINATES BY DOMAIN SWAPPING
1nk1: NK1 FRAGMENT OF HUMAN HEPATOCYTE GROWTH FACTOR/SCATTER FACTOR (HGF/SF) AT 2.5 ANGSTROM RESOLUTION
1shy: The Crystal Structure of HGF beta-chain in Complex with the Sema Domain of the Met Receptor.
1si5: Protease-like domain from 2-chain hepatocyte growth factor
2hgf: HAIRPIN LOOP CONTAINING DOMAIN OF HEPATOCYTE GROWTH FACTOR, NMR, MINIMIZED AVERAGE STRUCTURE

v t e Intercellular signaling peptides and proteins /ligands
Growth factors	Epidermal growth factor Fibroblast growth factor Nerve growth factor Platelet-derived growth factor Transforming growth factor beta superfamily Vascular endothelial growth factor
Ephrin	EFNA1 EFNA2 EFNA3 EFNA4 EFNA5 EFNB1 EFNB2 EFNB3
Other	Adipokine Agouti signaling protein Agouti-related protein Angiogenic protein CCN intercellular signaling protein Cysteine-rich protein 61 Connective tissue growth factor Nephroblastoma overexpressed protein Cytokine Endothelin EDN1 EDN2 EDN3 Hedgehog protein Interferon Kinin Parathyroid hormone-related protein Semaphorin Somatomedin Tolloid-like metalloproteinase Tumor necrosis factor Wnt protein
see alsoextracellular ligand disorders

Growth factors

Fibroblast

FGF receptor ligands:	FGF1/FGF2/FGF5 FGF3/FGF4/FGF6
KGF	FGF7/FGF10/FGF22 FGF8/FGF17/FGF18 FGF9/FGF16/FGF20
FGF homologous factors:	FGF11(FHF3) FGF12(FHF1) FGF13(FHF2) FGF14(FHF4)
hormone-like:FGF15/19	FGF15 FGF19 FGF21 FGF23

EGF-like domain

TGFβ pathway

TGFβ

Insulin/IGF/
Relaxin family

Insulin andInsulin-like growth factor	IGF1 IGF2
Relaxin family peptide hormones	INSL3 INSL4 INSL5 INSL6 Relaxin 1 2 3

Platelet-derived

Vascular endothelial

Other

Nerve
Hepatocyte

Growth factor receptor modulators

Angiopoietin

Agonists:Angiopoietin 1
Angiopoietin 4

Antagonists:Angiopoietin 2
Angiopoietin 3

Kinase inhibitors:Altiratinib
CE-245677
Rebastinib

Antibodies:Evinacumab (against angiopoietin 3)
Nesvacumab (against angiopoietin 2)

CNTF

EGF (ErbB)

EGF (ErbB1/HER1)	Agonists:Amphiregulin Betacellulin EGF (urogastrone) Epigen Epiregulin Heparin-binding EGF-like growth factor (HB-EGF) Murodermin Nepidermin Transforming growth factor alpha (TGFα) Kinase inhibitors:Afatinib Agerafenib Brigatinib Canertinib Dacomitinib Erlotinib Gefitinib Grandinin Icotinib Lapatinib Neratinib Osimertinib Vandetanib WHI-P 154 Antibodies:Cetuximab Depatuxizumab Depatuxizumab mafodotin Futuximab Imgatuzumab Matuzumab Necitumumab Nimotuzumab Panitumumab Zalutumumab
ErbB2/HER2	Agonists:Unknown/none Antibodies:Ertumaxomab Pertuzumab Trastuzumab Trastuzumab deruxtecan Trastuzumab duocarmazine Trastuzumab emtansine Kinase inhibitors:Afatinib Lapatinib Mubritinib Neratinib Tucatinib
ErbB3/HER3	Agonists:Neuregulins (heregulins) (1,2,6 (neuroglycan C)) Antibodies:Duligotumab Patritumab Seribantumab
ErbB4/HER4	Agonists:Betacellulin Epigen Heparin-binding EGF-like growth factor (HB-EGF) Neuregulins (heregulins) (1,2,3,4,5 (tomoregulin, TMEFF))

FGF

FGFR1	Agonists:Ersofermin FGF (1,2 (bFGF),3,4,5,6,8,10 (KGF2),20) Repifermin Selpercatinib Trafermin Velafermin
FGFR2	Agonists:Ersofermin FGF (1,2 (bFGF),3,4,5,6,7 (KGF),8,9,10 (KGF2),17,18,22) Palifermin Repifermin Selpercatinib Sprifermin Trafermin Antibodies:Aprutumab Aprutumab ixadotin Kinase inhibitors:Infigratinib
FGFR3	Agonists:Ersofermin FGF (1,2 (bFGF),4,8,9,18,23) Selpercatinib Sprifermin Trafermin Antibodies:Burosumab (against FGF23)
FGFR4	Agonists:Ersofermin FGF (1,2 (bFGF),4,6,8,9,19) Trafermin
Unsorted	Agonists:FGF15/19

HGF (c-Met)

Agonists:Fosgonimeton
Hepatocyte growth factor

Potentiators:Dihexa (PNB-0408)

IGF

IGF-1	Agonists:des(1-3)IGF-1 Insulin-like growth factor-1 (somatomedin C) IGF-1 LR3 Insulin-like growth factor-2 (somatomedin A) Insulin Mecasermin Mecasermin rinfabate Kinase inhibitors:BMS-754807 Linsitinib NVP-ADW742 NVP-AEW541 OSl-906 Antibodies:AVE-1642 Cixutumumab Dalotuzumab Figitumumab Ganitumab Robatumumab R1507 Teprotumumab Xentuzumab (against IGF-1 and IGF-2)
IGF-2	Agonists:Insulin-like growth factor-2 (somatomedin A) Antibodies:Dusigitumab Xentuzumab (against IGF-1 and IGF-2)
Others	Binding proteins:IGFBP (1,2,3,4,5,6,7) Cleavage products/derivatives with unknown target:Glypromate (GPE, (1-3)IGF-1) Trofinetide

LNGF (p75^NTR)

Antibodies:Against NGF:ABT-110 (PG110)
ASP-6294
Fasinumab
Frunevetmab
Fulranumab
MEDI-578
Ranevetmab
Tanezumab

Aptamers:Against NGF:RBM-004

Decoy receptors:LEVI-04 (p75^NTR-Fc)

PDGF

Agonists:Becaplermin
Platelet-derived growth factor (A,B,C,D)

RET (GFL)

GFRα1	Agonists:Glial cell line-derived neurotrophic factor (GDNF) Liatermin Kinase inhibitors:Vandetanib
GFRα2	Agonists:Neurturin (NRTN) Kinase inhibitors:Vandetanib
GFRα3	Agonists:Artemin (ARTN) Kinase inhibitors:Vandetanib
GFRα4	Agonists:Persephin (PSPN) Kinase inhibitors:Vandetanib
Unsorted	Kinase inhibitors:Agerafenib

SCF (c-Kit)

Agonists:Ancestim
Stem cell factor

TGFβ

Seehere instead.

Trk

TrkA	Agonists:Amitriptyline BNN-20 BNN-27 Cenegermin DHEA DHEA-S Gambogic amide NGF Tavilermide Antagonists:ALE-0540 Dexamethasone FX007 Testosterone Positive allosteric modulators:ACD856 ACD857 Ponazuril (ACD855) Toltrazuril Negative allosteric modulators:VM-902A Kinase inhibitors:Altiratinib AZD-6918 CE-245677 CH-7057288 DS-6051 Entrectinib GZ-389988 K252a Larotrectinib Lestaurtinib Milciclib ONO-4474 ONO-5390556 PLX-7486 Rebastinib SNA-120 (pegylated K252a)) Antibodies:Against TrkA:GBR-900;Against NGF:ABT-110 (PG110) ASP-6294 Fasinumab Frunevetmab Fulranumab MEDI-578 Ranevetmab Tanezumab Aptamers:Against NGF:RBM-004 Decoy receptors:ReN-1820 (TrkAd5)
TrkB	Agonists:3,7-DHF 3,7,8,2'-THF 4'-DMA-7,8-DHF 7,3'-DHF 7,8-DHF 7,8,2'-THF 7,8,3'-THF Amitriptyline Braegen-02 BDNF BNN-20 Deoxygedunin Diosmetin DMAQ-B1 HIOC LM22A-4 N-Acetylserotonin NT-3 NT-4 Norwogonin (5,7,8-THF) R7 R13 (BrAD-R13, Braegen-01) TDP6 Antagonists:ANA-12 Cyclotraxin B Gossypetin (3,5,7,8,3',4'-HHF) Ligands:DHEA Positive allosteric modulators:ACD856 ACD857 Ponazuril (ACD855) Toltrazuril Kinase inhibitors:Altiratinib AZD-6918 CE-245677 CH-7057288 DS-6051 Entrectinib GZ-389988 K252a Larotrectinib Lestaurtinib ONO-4474 ONO-5390556 PLX-7486
TrkC	Agonists:BNN-20 DHEA NT-3 Positive allosteric modulators:ACD856 Kinase inhibitors:Altiratinib AZD-6918 CE-245677 CH-7057288 DS-6051 Entrectinib GZ-389988 K252a Larotrectinib Lestaurtinib ONO-4474 ONO-5390556 PLX-7486