Tumorski faktor nekroze

TNF
Dostupne strukture
PDB	Pretraga ortologa: PDBe RCSB
Spisak PDB ID kodova
	1A8M, 1TNF, 2AZ5, 2E7A, 2TUN, 2ZJC, 2ZPX, 3ALQ, 3IT8, 3L9J, 3WD5, 4G3Y, 4TSV, 4TWT, 5TSW
Identifikatori
Aliasi	TNF
Vanjski ID-jevi	OMIM: 191160 MGI: 104798 HomoloGene: 496 GeneCards: TNF
Lokacija gena (čovjek)
Hrom.	Hromosom 6 (čovjek)
Kraj	31,578,336 bp
Lokacija gena (miš)
Hrom.	Hromosom 17 (miš)
Kraj	35,420,983 bp
Obrazac RNK ekspresije
	Više referentnih podataka o ekspresiji
Ontologija gena
Molekularna funkcija	• GO:0001948, GO:0016582 vezivanje za proteine; • protease binding; • tumor necrosis factor receptor binding; • cytokine activity; • vezivanje identičnih proteina;
Ćelijska komponenta	• membrana; • cell surface; • integral component of membrane; • reciklirajući endosom; • intracellular anatomical structure; • integral component of plasma membrane; • phagocytic cup; • external side of plasma membrane; • extracellular region; • ćelijska membrana; • Lipidni splav; • Vanćelijsko;
Biološki proces	• regulation of protein phosphorylation; • positive regulation of protein phosphorylation; • positive regulation of MAP kinase activity; • response to salt stress; • positive regulation of calcidiol 1-monooxygenase activity; • positive regulation of programmed cell death; • positive regulation of JNK cascade; • response to organic substance; • negative regulation of osteoblast differentiation; • positive regulation of cysteine-type endopeptidase activity involved in apoptotic process; • negative regulation of viral genome replication; • humoral immune response; • positive regulation of interleukin-8 production; • intrinsic apoptotic signaling pathway in response to DNA damage; • positive regulation of protein localization to cell surface; • positive regulation of ERK1 and ERK2 cascade; • glucose metabolic process; • animal organ morphogenesis; • apoptotic signaling pathway; • negative regulation of alkaline phosphatase activity; • regulation of I-kappaB kinase/NF-kappaB signaling; • GO:0051637 defense response to Gram-positive bacterium; • regulation of branching involved in salivary gland morphogenesis; • positive regulation of phagocytosis; • negative regulation of fat cell differentiation; • negative regulation of myoblast differentiation; • positive regulation of protein kinase B signaling; • regulation of insulin secretion; • osteoclast differentiation; • regulation of tumor necrosis factor-mediated signaling pathway; • response to virus; • positive regulation of osteoclast differentiation; • GO:0002719 negative regulation of cytokine production involved in immune response; • positive regulation of peptidyl-serine phosphorylation; • negative regulation of branching involved in lung morphogenesis; • JNK cascade; • death-inducing signaling complex assembly; • regulation of osteoclast differentiation; • defense response to bacterium; • positive regulation of interleukin-6 production; • I-kappaB kinase/NF-kappaB signaling; • positive regulation of translational initiation by iron; • sequestering of triglyceride; • positive regulation of chronic inflammatory response to antigenic stimulus; • positive regulation of chemokine (C-X-C motif) ligand 2 production; • positive regulation of JUN kinase activity; • positive regulation of hair follicle development; • chronic inflammatory response to antigenic stimulus; • GO:1904579 cellular response to organic cyclic compound; • positive regulation of fever generation; • extracellular matrix organization; • positive regulation of DNA-binding transcription factor activity; • cellular response to nicotine; • positive regulation of podosome assembly; • GO:1904489 regulation of reactive oxygen species metabolic process; • positive regulation of protein transport; • negative regulation of glucose import; • GO:0046730, GO:0046737, GO:0046738, GO:0046736 Imuni odgovor; • leukocyte tethering or rolling; • positive regulation of chemokine production; • cellular extravasation; • negative regulation of lipid storage; • negative regulation of myosin-light-chain-phosphatase activity; • GO:0045996 negative regulation of transcription, DNA-templated; • GO:0033109 cortical actin cytoskeleton organization; • embryonic digestive tract development; • leukocyte migration; • lipopolysaccharide-mediated signaling pathway; • positive regulation of smooth muscle cell proliferation; • positive regulation of protein kinase activity; • positive regulation of superoxide dismutase activity; • defense response; • positive regulation of ceramide biosynthetic process; • positive regulation of protein-containing complex assembly; • protein kinase B signaling; • GO:0032737 positive regulation of cytokine production; • epithelial cell proliferation involved in salivary gland morphogenesis; • positive regulation of nitric oxide biosynthetic process; • negative regulation of interleukin-6 production; • positive regulation of membrane protein ectodomain proteolysis; • positive regulation of humoral immune response mediated by circulating immunoglobulin; • positive regulation of interferon-gamma production; • response to glucocorticoid; • positive regulation of vitamin D biosynthetic process; • positive regulation of mononuclear cell migration; • MAPK cascade; • negative regulation of protein-containing complex disassembly; • multicellular organism development; • negative regulation of bicellular tight junction assembly; • positive regulation of protein-containing complex disassembly; • regulation of cell population proliferation; • cellular response to amino acid stimulus; • negative regulation of extrinsic apoptotic signaling pathway in absence of ligand; • cellular response to lipopolysaccharide; • negative regulation of lipid catabolic process; • regulation of establishment of endothelial barrier; • positive regulation of cell adhesion; • regulation of protein secretion; • positive regulation of apoptotic process; • inflammatory response; • activation of cysteine-type endopeptidase activity involved in apoptotic process; • tumor necrosis factor-mediated signaling pathway; • positive regulation of I-kappaB kinase/NF-kappaB signaling; • necroptotic signaling pathway; • GO:1901313 positive regulation of gene expression; • extrinsic apoptotic signaling pathway; • extrinsic apoptotic signaling pathway via death domain receptors; • GO:1901227 negative regulation of transcription by RNA polymerase II; • positive regulation of NF-kappaB transcription factor activity; • GO:0060469, GO:0009371 positive regulation of transcription, DNA-templated; • GO:0003257, GO:0010735, GO:1901228, GO:1900622, GO:1904488 positive regulation of transcription by RNA polymerase II; • positive regulation of leukocyte adhesion to arterial endothelial cell; • positive regulation of leukocyte adhesion to vascular endothelial cell; • positive regulation of blood microparticle formation; • negative regulation of endothelial cell proliferation; • positive regulation of heterotypic cell-cell adhesion; • negative regulation of mitotic cell cycle; • endothelial cell apoptotic process; • positive regulation of vascular associated smooth muscle cell proliferation; • negative regulation of gene expression; • protein localization to plasma membrane; • GO:1903364 positive regulation of protein catabolic process; • regulation of signaling receptor activity; • regulation of inflammatory response; • cytokine-mediated signaling pathway; • positive regulation of calcineurin-NFAT signaling cascade; • positive regulation of NIK/NF-kappaB signaling;
	Izvori:Amigo / QuickGO
Ortolozi
	7124
	21926
ENSG00000228978; ENSG00000230108; ENSG00000223952; ENSG00000204490; ENSG00000228321;
	ENSG00000232810; ENSG00000228849; ENSG00000206439
	ENSMUSG00000024401
	P01375
	P06804
	NM_000594
	NM_001278601; NM_013693
	NP_000585
	NP_001265530; NP_038721
	Wikipodaci
Pogledaj/uredi – čovjek	Pogledaj/uredi – miš

Tumorski faktor nekroze (TNF, kaheksin ili kahektin, zvani i tumorski faktor nekroze alfa ili TNF-α) citokinski mali protein koji koristi imunski sistem za ćelijsku signalizaciju. Ako makrofazi (određena bijela krvna zrnca) otkriju infekciju, oslobađaju TNF, kako bi upozorili druge ćelije imunskog sistema kao dio upalnog odgovora. TNF je član superporodica TNF, koja se sastoji od različitih transmembranskih proteina s homolognim domenom TNF.

TNF signalizacija javlja se putem dva receptora: TNFR1 i TNFR2.^[5]^[6] TNFR1 je konstitutivno eksprimiran na većini tipova ćelija, dok je TNFR2 ograničen prvenstveno na endotelne, epitelne i podskupine imunskih ćelija.^[5]^[6] Signalizacija TNF1 ima tendenciju da bude proupalna i apoptotska, dok je signalizacija TNFR2 protivupalna i podstiče ćelijsku proliferaciju.^[5]^[6] Suzbijanje signalizacije TNFR1 bilo je važno za liječenje autoimunske bolesti,^[7] dok signalizacija TNFR2 podstiče zacjeljivanje rana.^[6]

TNF-α postoji kao transmembranski oblik (mTNF-α) i kao topljivi oblik (sTNF-α). sTNF-α je rezultat enzimskog cijepanja mTNF-α.^[8] mTNF-α se uglavnom nalazi na monocitima/makrofazima, gdje stupa u interakciju s tkivnim receptorima, dodirom ćelija na ćeliju.^[8] sTNF-α se selektivno veže za TNFR1, dok se mTNF-α veže i za TNFR1 i za TNFR2.^[9] Vezivanje TNF-α za TNFR1 je ireverzibilno, dok je vezivanje za TNFR2 reverzibilno.^[10]

Primarna uloga TNF-a je u regulaciji imunskih ćelija. TNF, kao endogeni pirogen, može izazvati groznicu, apoptotsku ćelijsku smrt, kaheksiju, upalu i inhibirati tumorigenezu, replikaciju virusa, a i reagiraju na sepsu putem ćelijskih IL-1 i IL-6. Disregulacija proizvodnje TNF-a uključena je u različite ljudske bolesti, uključujući Alzheimerovu,^[11] kancer,^[12] glavnu depresiju,^[13] psorijazu^[14] i upalnu bolest crijeva (IBD).^[15] Iako kontroverzne, neke studije povezuju depresiju i IBD s povećanim nivoom TNF -a.^[16]^[17]

Pod imenom tasonermin, TNF se koristi kao imunostimulacijski lijek u liječenju određenih karcinoma. Lijekovi koji se suprotstavljaju djelovanju TNF-a koriste se u liječenju različitih upalnih bolesti, naprimjer reumatoidnog artritisa.

Određeni karcinomi mogu uzrokovati hiperprodukciju TNF-a. TNFsu paralele paratireoidnih hormona i u izazivanju sekundarne hiperkalcemije i u raku s kojim je povezana prekomerna proizvodnja.

Otkriće

Teoriju antitumorskog odgovora imunskog sistema in vivo otkrio je ljekar William B. Coley. u 1968, Gale A Granger sa Univerziteta Kalifornija, Irvine, prijavio citotoksični faktor kojeg proizvode limfociti i nazvao ga limfotoksin (LT).^[18] Zaslugu za ovo otkriće dijeli Nancy H. Ruddle sa Univerziteta Yale, koja je prijavila istu aktivnost u sekvenci leđa-leđa objavljenih u istom mjesecu.^[19] Nakon toga, 1975. Lloyd J. Old iz Memorial Sloan-Kettering Cancer Center, New York, izvijestio je o drugom citotoksičnom faktoru kojegh proizvode makrofazi i nazvao ga faktor tumorske nekroze (TNF).^[20] Oba faktora su opisana na osnovu njihove sposobnosti da ubiju mišje fibrosarkomske ćelije L-929. Ovi koncepti su prošireni na sistemske bolesti 1981. godine, kada je Ian A. Clark, sa Australian National University, u saradnji sa Elizabeth Carswell iz Oldove grupe, radio na podacima iz doba sekvenciranja, obrazložio da prekomjerna proizvodnja TNF-a uzrokuje bolest malarija i trovanje endotoksinom.^[21]^[22]

cDNK kodirajući LT i TNF su klonirani u 1984^[23] i otkriveno je da su slični. Vezivanje TNF -a za njegov receptor i njegovo pomicanje pomoću LT potvrdilo je funkcionalnu homologiju između dva faktora. Sekvencna i funkcionalna homologija TNF-a i LT-a dovela je do preimenovanja TNF-a u TNFα i LT u TNFβ. U 1985. Bruce A. Beutler i Anthony Cerami otkrili su da je kahektin (hormon koji inducira kaheksiju) zapravo TNF.^[24] Zatim su identificirali TNF kao posrednika u trovanju smrtonosnim endotoksinom.^[25] Kevin J. Tracey i Cerami otkrili su ključnu posredničku ulogu TNF-a u smrtonosnom sepsnom šoku i identificirali terapeutske učinke monoklonskih anti-TNF antitijela.^[26]^[27]

Istraživanja u Laboratoriji Marka Mattsona pokazala su da TNF može spriječiti smrt/apoptozu neurona mehanizmom koji uključuje aktivaciju transkripcijskog faktora NF-κB, koji inducira ekspresiju antioksidativnih enzima i Bcl-2.^[28]^[29]

Aminokiselinska sekvenca

Dužina polipeptidnog lanca je 233 aminokiseline, a molekulska težina 25.644 Da.^[30].

10	20	30	40	50
MSTESMIRDV	ELAEEALPKK	TGGPQGSRRC	LFLSLFSFLI	VAGATTLFCL
LHFGVIGPQR	EEFPRDLSLI	SPLAQAVRSS	SRTPSDKPVA	HVVANPQAEG
QLQWLNRRAN	ALLANGVELR	DNQLVVPSEG	LYLIYSQVLF	KGQGCPSTHV
LLTHTISRIA	VSYQTKVNLL	SAIKSPCQRE	TPEGAEAKPW	YEPIYLGGVF
QLEKGDRLSA	EINRPDYLDF	AESGQVYFGI	IAL

C: Cistein

D: Asparaginska kiselina

E: Glutaminska kiselina

F: Fenilalanin

G: Glicin

H: Histidin

I: Izoleucin

K: Lizin

L: Leucin

M: Metionin

N: Asparagin

P: Prolin

Q: Glutamin

R: Arginin

S: Serin

T: Treonin

V: Valin

W: Triptofan

Y: Tirozin

Gen

Ljudski TNF gen je kloniran 1985. godine.^[31] Mapiran je na hromosomu 6, p21.3, obuhvatajući približno 3 kB i sadrži 4 egzona. Posljednji egzon ima sličnost sa limfotoksinom alfa (LTA, ranije imenovan kao TNF-β).^[32] Tri glavna netranslatirana područja (3'-UTR) TNF-a sadrži AU-bogati element (ARE).

Struktura

TNF se prvenstveno proizvodi kao 233 aminokiseline dugi transmembranski protein tipa II raspoređen u stabilne homotrimere.^[33]^[34] Iz ovog membranski integriranog oblika, oslobađa se rastvorljivi homotrimerni citokin (sTNF), proteolitskim cijepanjem pomoću enzima koji pretvara TNF alfa-metaloproteazu (TACE, također zvana ADAM17).^[35] Rastvorljivi trimerni sTNF od 51 kDa ima tendenciju disocijacije pri koncentracijama ispod nanomolarnog raspona, čime se gubi njegova bioaktivnost. Izlučeni oblik ljudskog TNF-a poprima oblik trokutaste piramide i teži oko 17 kDa. I izlučeni i membranski vezani oblici su biološki aktivni, iako su specifične funkcije svakog od njih kontroverzne. No, oba oblika imaju preklapajuće i različite biološke aktivnosti.^[36]

TNF običnog kućnog miša i ljudski TNF strukturno se razlikuju.^[37] TNF protomori, dugi 17 kDa (185 aminokiselina) sastavljeni su od dva antiparalelna β-nabrana lista sa antiparalelnim β-lacima, tvoreći β-strukturu 'žele valjaka', tipsku za porodicu TNF, ali se također nalazi u proteinima virusne kapside.

Ćelijska signalizacija

TNF može vezati dva receptora, TNFR1 (TNF receptor tip 1; CD120a; p55/60) i TNFR2 (TNF receptor tip 2; CD120b; p75/80). TNFR1 je 55 kDa, a TNFR2 75 kDa.^[38] TNFR1 je eksprimiran u većini tkiva i može se u potpunosti aktivirati i membranski vezanim i rastvorljivim trimernim oblicima TNF-a, dok se TNFR2 obično nalazi u ćelijama imunskog sistema i reagira na membranski vezan oblik TNF homotrimer. Kako je većina informacija o TNF-signalizaciji izvedena iz TNFR1, uloga TNFR2 je vjerojatno potcijenjena. Barem djelomično jer TNFR2 nema unutarćelijski domen smrti, pokazuje neuroprotektivna svojstva.^[29]

Signalini put TNFR1. Isprekidane sive linije predstavljaju više koraka.

Nakon kontakta sa svojim ligandom, TNF receptori također formiraju trimere, čiji se vrhovi uklapaju u utore formirane između TNF monomera. Ovo vezivanje uzrokuje konformacijsku promjenu u receptoru, što dovodi do disocijacije inhibitornog proteina SODD iz domena unutaćelijske smrti. Ova disocijacija omogućava adapterskom proteinu TRADD da se veže za domen smrti, služeći kao platforma za kasnije vezivanje proteina. Nakon vezanja TRADD-a, mogu se pokrenuti tri puta.^[39]^[40]

Aktiviranje NF-κB: TRADD regrutira TRAF2 i RIP. TRAF2 zauzvrat regrutira višekomponentni protein kinaza IKK, omogućavajući serin-treonin kinazama RIP da ga aktivira. Inhibitorni protein, IκBα, koji se normalno veže za NF-κB i inhibira njegovu translokaciju, fosforiliranjem pomoću IKK-a, a zatim se razgrađuje, oslobađajući NF-κB. NF-κB je heterodimerni transkripcijski faktor koji se translocira u jedro i posreduje u transkripciji velikog broja proteina uključenih u preživljavanje i proliferaciju ćelija, upalni odgovor i apoptotski faktori.
Aktivacija MAPK puteva: Od tri velike kaskade MAPK, TNF izaziva snažnu aktivaciju stres-vezanih JNK grupa, izazivajući umjeren odgovor p38-MAPK i odgovorna je za minimalnu aktivaciju klasičnih ERK. TRAF2/Rac aktivira JNK-inducirajuće kinaze inducirane putemMLK2/MLK3,^[41] TAK1, MEKK1 i ASK1 (bilo direktno ili putem GCK-a i Trx-a). Osa SRC-Vav-Rac aktivira MLK2/MLK3 i ove kinaze fosforila MKK7, koja zatim aktivira JNK. JNK prelazi u jedro i aktivira transkripcijske faktore kao što su c-jun i ATF2. Put JNK je uključen u ćelijsku diferencijaciju, proliferaciju i općenito je pro-apoptozan.
Indukcija signalizacije ćelijske smrti: Kao i svi članovi superporodice TNFR koji sadrže domen smrti, TNFR1 je uključen u signalizaciju smrti.^[42] Međutim, ćelijska smrt inducirana TNF-om ima samo manju ulogu u usporedbi s njenom snažnom funkcijom u upalnom procesu. Njegova sposobnost izazivanja smrti je slaba u poređenju s drugim članovima porodice (kao što je Fas) i često je prikrivena anti-apoptotskim efektima NF-κB. Ipak, TRADD veže FADD, koji zatim regrutuje cistein-proteazu kaspazu-8. Visoka koncentracija kaspaze-8 inducira njenu autoproteolitsku aktivaciju i naknadno cijepanje efektora kaspaza, što dovodi do ćelijske apoptoze.

Nebrojeni i često sukobljeni efekti posredovani gore navedenim putevima ukazuju na postojanje opsežnog unakrsnog uticaja. Naprimjer, NF-κB pojačava transkripciju C-FLIP, Bcl-2 i cIAP1 / cIAP2, inhibitornih proteina koji ometaju signalizaciju smrti . S druge strane, aktivirane kaspaze cijepaju nekoliko komponenti puta NF-κB, uključujući RIP, IKK i podjedinice samog NF-κB. Drugi faktori, poput tipa ćelije, istovremene stimulacije drugih citokina ili količine reaktivnih vrsta kisika (ROS) mogu promijeniti ravnotežu u korist jednog ili drugog puta. Takva komplicirana signalizacija osigurava da, kad god se TNF oslobodi, različite ćelije s izrazito različitim funkcijama i stanjima mogu na odgovarajući način reagirati na upalu. Faktori tumorske nekroze alfa i keratin 17mogu biti povezani u slučaju oralne submukozne fibroze,^[43]

Postoje i dokazi da signalizacija TNF-α izaziva nizvodne epigenetičke modifikacije koje rezultiraju trajnim poboljšanjem proupalnih odgovora u ćelijama.^[44]^[45]^[46]^[47]

Enzimska regulacija

Ovaj protein može koristiti morfeinski model alosterne regulacije.^[48]

Fiziologija

Smatralo se da TNF prvenstveno proizvode makrofazi,^[49] ali ga proizvodi i veliki broj tipova ćelija, uključujući limfoidne, mastocite, endotelne, srčani miociti, masno tkivo , fibroblasti i neuroni.^[50] Velike količine TNF-a oslobađaju se kao odgovor na lipopolisaharidne, druge bakterijske 1 proizvode i interleukin-1 (IL-1). U koži su mastociti dominantni izvor prethodno formiranog TNF-a, koji se može osloboditi nakon upalnog podražaja (npr. LPS).^[51]

Ima niz djelovanja na različite organske sisteme, općenito zajedno s IL-1 i interleukin-6 (IL-6):

Na hipotalamusu:
- Stimulacija hipotalamusno-hipofizno-nadbubrežne osi, stimulacijom otpuštanja kortikotropin oslobađajućeg hormona (CRH)
- Suzbijanje apetita
- Vrućica
Na jetri: stimulacija akutne faze odgovora, što dovodi do povećanja C-reaktivnog proteina i niza drugih medijatora. Također inducira inzulinsku rezistenciju podsticanjem fosforilacije serinskog supstrata insulinskog receptora-1 (IRS-1), što narušava signalizaciju insulina
To je moćan hemoatraktant za neutrofileds i potiče ekspresiju adhezijskih molekula na endotelnim ćelijama, pomažući u migraciji neutrofila.
Na makrofagima: stimulira fagocitozu i proizvodnju oksidanata IL-1 i upalnih lipida prostaglandin E2 (PGE₂)
Na drugim tkivima: povećanje insulinska rezistencije. TNF fosforilira ostatke serinskih receptora insulina, blokirajući transdukciju signala.
U metabolizmu i unosu hrane: regulira percepciju gorkog okusa.^[52]

Lokalno povećanje koncentracije TNF -a uzrokovat će kardinalne znakove upale: vrućinu, oteklinu, crvenilo, bol i gubitak funkcije.

Dok visoke koncentracije TNF-a izazivaju simptome slične šoku, produžena izloženost niskim koncentracijama TNF-a može rezultirati kaheksijom, sindromom trošenja. Ovo se može naći, naprimjer, kod pacijenata sa kancerom.

Said et al. pokazali su da TNF uzrokuje IL-10-ovisnu inhibiciju ekspanzije i funkcije CD4 T-ćelija, reguliranjem povećane razine PD-1 na monocitima, što dovodi do proizvodnje IL-10 u monocitima, nakon vezivanja PD-1 za PD-L.^[53]

Istraživanje Pedersena et al. ukazuje da je povećanje TNF-a kao odgovora na sepsu inhibiranog proizvodnjom miokina induciranih vježbom. Da bi se ispitalo izaziva li akutna vježba pravi protivupalni odgovor, uspostavljen je model „upale niskog stupnja“ u kojem je niska doza endotoksina E. coli primijenjena na zdrave dobrovoljce, koji su randomizirani na odmor ili vježbanje prije primjene endotoksina. Kod ispitanika u mirovanju, endotoksin je inducirao dva do tri puta povećanje cirkulirajućeg nivoa TNF-a. Nasuprot tome, kada su ispitanici izveli tri sata vožnje na ergometru i primili endotoksinski bolus nakon 2,5 sata, odgovor na TNF bio je potpuno prigušen.^[54] Ova studija pruža neke dokaze da akutna vježba može spriječiti proizvodnju TNF -a.^[55]

Farmakologija

TNF podstiče upalni odgovor, koji zauzvrat uzrokuje mnoge kliničke probleme povezane s autoimunskim poremećajima, kao što su reumatoidni artritis, ankilozantni spondilitis, upalna bolest crijeva, psorijaza , hidradenitis suppurativa i vatrostalna astma. Ovi se poremećaji ponekad liječe upotrebom TNF inhibitora. Ova inhibicija se može postići monoklonskim antitijelima, kao što je infliksimab (Remicade), koji se direktno vežu za TNF, adalimumab (Humira), certolizumab pegol (Cimzia) ili s mamcem cirkulacijski receptor fuzijski protein kao što je etanercept (Enbrel) koji se veže za TNF s većim afinitetom od TNFR -a.^[56]

S druge strane, neki pacijenti liječeni inhibitorima TNF-a imaju pogoršanje svoje bolesti ili novi početak autoimunosti. Čini se da TNF ima i imunosupresivni aspekt. Jedno objašnjenje mogućeg mehanizma je ovo zapažanje da TNF ima pozitivan učinak na regulatorne T-ćelije (Tregs), zbog svog vezivanja za receptor 2 faktora nekroze tumora (TNFR2).^[57]

Anti-TNF terapija pokazala je samo skromne efekte u terapiji raka. Liječenje karcinoma bubrežnih ćerlija infliksimabom rezultiralo je produženom stabilizacijom bolesti kod određenih pacijenata. Etanercept je testiran za liječenje pacijenata s rakom dojke i rakom jajnika, koji pokazuju produženu stabilizaciju bolesti kod određenih pacijenata, putem snižavanja IL-6 i CCL2 . S druge strane, dodavanje infliximaba ili etanercepta u gemcitabin za liječenje pacijenata s uznapredovalim rakom gušterače nije povezano s razlikama u učinkovitosti u usporedbi s placebom.^[58]

Interakcije

Pokazano je da TNF komunicira sa TNFRSF1A.^[59]^[60]

Nomenklatura

Zato što se LTα više ne naziva TNFβ,^[61] TNFα, kao prethodni simbol gena, sada se jednostavno naziva TNF, kako je prikazano u bazi podataka HGNC (HUGO odbor za nomenklaturu gena).

Reference

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Vanjski linkovi

"Tasonermin". Drug Information Portal. U.S. National Library of Medicine.
"Tumor Necrosis Factor-alpha". Drug Information Portal. U.S. National Library of Medicine.
Tumor Necrosis Factor-alpha na US National Library of Medicine Medical Subject Headings (MeSH)
P01375

</noinclude>

	Portal Biologija
	Portal Medicina

[refGRCh38Ensembl-1] ENSG00000230108, ENSG00000223952, ENSG00000204490, ENSG00000228321, ENSG00000232810, ENSG00000228849, ENSG00000206439 GRCh38: Ensembl release 89: ENSG00000228978, ENSG00000230108, ENSG00000223952, ENSG00000204490, ENSG00000228321, ENSG00000232810, ENSG00000228849, ENSG00000206439 - Ensembl, maj 2017

[refGRCm38Ensembl-2] GRCm38: Ensembl release 89: ENSMUSG00000024401 - Ensembl, maj 2017

[3] "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.

[4] "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.

[pmid33192311-5] Heir R, Stellwagen D (2020). "TNF-Mediated Homeostatic Synaptic Plasticity: From in vitro to in vivo Models". Frontiers in Cellular Neuroscience. 14: 565841. doi:10.3389/fncel.2020.565841. PMC 7556297. PMID 33192311.

[pmid33324405-6] Gough P, Myles IA (2020). "Tumor Necrosis Factor Receptors: Pleiotropic Signaling Complexes and Their Differential Effects". Frontiers in Immunology. 11: 585880. doi:10.3389/fimmu.2020.585880. PMC 7723893. PMID 33324405.

[pmid33053859-7] Rolski F, Błyszczuk P (2020). "Complexity of TNF-α Signaling in Heart Disease". Journal of Clinical Medicine. 9 (10): 3267. doi:10.3390/jcm9103267. PMC 7601316. PMID 33053859.

[pmid29234328-8] Probert L (2017). "Forward and Reverse Signaling Mediated by Transmembrane Tumor Necrosis Factor-Alpha and TNF Receptor 2: Potential Roles in an Immunosuppressive Tumor Microenvironment". Frontiers in Immunology. 8: 1675. doi:10.3389/fimmu.2017.01675. PMC 5712345. PMID 29234328.

[pmid26117714-9] Rolski F, Błyszczuk P (2015). "TNF and its receptors in the CNS: The essential, the desirable and the deleterious effects". Neuroscience. 302: 2–22. doi:10.1016/j.neuroscience.2015.06.038. PMID 26117714.

[pmid27888159-10] Szondy Z, Pallai A (2017). "Transmembrane TNF-alpha reverse signaling leading to TGF-beta production is selectively activated by TNF targeting molecules: Therapeutic implications". Pharmacological Research. 115: 124–132. doi:10.1016/j.phrs.2016.11.025. PMID 27888159.

[pmid20692646-11] Swardfager W, Lanctôt K, Rothenburg L, Wong A, Cappell J, Herrmann N (2010). "A meta-analysis of cytokines in Alzheimer's disease". Biol Psychiatry. 68 (10): 930–941. doi:10.1016/j.biopsych.2010.06.012. PMID 20692646. S2CID 6544784.

[pmid11239407-12] Locksley RM, Killeen N, Lenardo MJ (2001). "The TNF and TNF receptor superfamilies: integrating mammalian biology". Cell. 104 (4): 487–501. doi:10.1016/S0092-8674(01)00237-9. PMID 11239407. S2CID 7657797.

[pmid20015486-13] Dowlati Y, Herrmann N, Swardfager W, Liu H, Sham L, Reim EK, Lanctôt KL (2010). "A meta-analysis of cytokines in major depression". Biol Psychiatry. 67 (5): 446–457. doi:10.1016/j.biopsych.2009.09.033. PMID 20015486. S2CID 230209.

[pmid12851985-14] Victor FC, Gottlieb AB (2002). "TNF-alpha and apoptosis: implications for the pathogenesis and treatment of psoriasis". J Drugs Dermatol. 1 (3): 264–75. PMID 12851985.

[pmid12077089-15] Brynskov J, Foegh P, Pedersen G, Ellervik C, Kirkegaard T, Bingham A, Saermark T (2002). "Tumour necrosis factor alpha converting enzyme (TACE) activity in the colonic mucosa of patients with inflammatory bowel disease". Gut. 51 (1): 37–43. doi:10.1136/gut.51.1.37. PMC 1773288. PMID 12077089.

[pmid17206706-16] Mikocka-Walus AA, Turnbull DA, Moulding NT, Wilson IG, Andrews JM, Holtmann GJ (2007). "Controversies surrounding the comorbidity of depression and anxiety in inflammatory bowel disease patients: a literature review". Inflammatory Bowel Diseases. 13 (2): 225–234. doi:10.1002/ibd.20062. PMID 17206706.

[pmid27991935-17] Bobińska K, Gałecka E, Szemraj J, Gałecki P, Talarowska M (2017). "Is there a link between TNF gene expression and cognitive deficits in depression?". Acta Biochim. Pol. 64 (1): 65–73. doi:10.18388/abp.2016_1276. PMID 27991935.

[pmid5249808-18] Kolb WP, Granger GA (1968). "Lymphocyte in vitro cytotoxicity: characterization of human lymphotoxin". Proc. Natl. Acad. Sci. U.S.A. 61 (4): 1250–5. Bibcode:1968PNAS...61.1250K. doi:10.1073/pnas.61.4.1250. PMC 225248. PMID 5249808.

[pmid5693925-19] Ruddle NH, Waksman BH (decembar 1968). "Cytotoxicity mediated by soluble antigen and lymphocytes in delayed hypersensitivity. 3. Analysis of mechanism". J. Exp. Med. 128 (6): 1267–79. doi:10.1084/jem.128.6.1267. PMC 2138574. PMID 5693925.

[pmid1103152-20] Carswell EA, Old LJ, Kassel RL, Green S, Fiore N, Williamson B (1975). "An endotoxin-induced serum factor that causes necrosis of tumors". Proc. Natl. Acad. Sci. U.S.A. 72 (9): 3666–70. Bibcode:1975PNAS...72.3666C. doi:10.1073/pnas.72.9.3666. PMC 433057. PMID 1103152.

[pmid6166564-21] Clark IA, Virelizier JL, Carswell EA, Wood PR (juni 1981). "Possible importance of macrophage-derived mediators in acute malaria". Infect. Immun. 32 (3): 1058–66. doi:10.1128/IAI.32.3.1058-1066.1981. PMC 351558. PMID 6166564.

[pmid6181289-22] Clark IA (juli 1982). "Suggested importance of monokines in pathophysiology of endotoxin shock and malaria". Klin. Wochenschr. 60 (14): 756–8. doi:10.1007/BF01716573. PMID 6181289. S2CID 26446784.

[pmid6392892-23] Pennica D, Nedwin GE, Hayflick JS, Seeburg PH, Derynck R, Palladino MA, Kohr WJ, Aggarwal BB, Goeddel DV (1984). "Human tumour necrosis factor: precursor structure, expression and homology to lymphotoxin". Nature. 312 (5996): 724–9. Bibcode:1984Natur.312..724P. doi:10.1038/312724a0. PMID 6392892. S2CID 4245957.

[pmid2993897-24] Beutler B, Greenwald D, Hulmes JD, Chang M, Pan YC, Mathison J, Ulevitch R, Cerami A (1985). "Identity of tumour necrosis factor and the macrophage-secreted factor cachectin". Nature. 316 (6028): 552–4. Bibcode:1985Natur.316..552B. doi:10.1038/316552a0. PMID 2993897. S2CID 4339006.

[pmid3895437-25] Beutler B, Milsark IW, Cerami AC (august 1985). "Passive immunization against cachectin/tumor necrosis factor protects mice from lethal effect of endotoxin". Science. 229 (4716): 869–71. Bibcode:1985Sci...229..869B. doi:10.1126/science.3895437. PMID 3895437.

[pmid3764421-26] Tracey KJ, Beutler B, Lowry SF, Merryweather J, Wolpe S, Milsark IW, Hariri RJ, Fahey TJ, Zentella A, Albert JD (oktobar 1986). "Shock and tissue injury induced by recombinant human cachectin". Science. 234 (4775): 470–74. Bibcode:1986Sci...234..470T. doi:10.1126/science.3764421. PMID 3764421.

[pmid3317066-27] Tracey KJ, Fong Y, Hesse DG, Manogue KR, Lee AT, Kuo GC, Lowry SF, Cerami A (decembar 1987). "Anti-cachectin/TNF monoclonal antibodies prevent septic shock during lethal bacteraemia". Nature. 330 (6149): 662–64. Bibcode:1987Natur.330..662T. doi:10.1038/330662a0. PMID 3317066. S2CID 4308324.

[pmid16397579-28] Mattson MP, Meffert MK (2006). "Roles for NF-kappaB in nerve cell survival, plasticity, and disease". Cell Death & Differentiation. 13 (5): 852–860. doi:10.1038/sj.cdd.4401837. PMID 16397579.

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[UniProt-30] "UniProt, P01375". Pristupljeno 19. 8. 2021.

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