HSPE1
Protein 1 toplotnog šoka od 10 kDa (Hsp10), poznat i kao šaperonin 10 (cpn10) ili faktor rane trudnoće (EPF), je protein koji u ljudi je kodiran genom HSPE1. Homolog u E. coli je GroES, šaperonin koji obično djeluje zajedno sa GroEL-om.[5]
| Cpn10 | |
|---|---|
 Košaperonin gp31 bakteriofaga t4 | |
| Identifikatori | |
| Simbol | Cpn10 |
Struktura i funkcija uredi
GroES postoji u obliku oligomernog prstena između šest i osam identičnih podjedinica, dok šaperonin od 60 kDa (cpn60 ili groEL) u bakterijama tvori sekundarnu strukturu koja se sastoji od dva naslagana prstena, od kojih svaki sadrži po sedam identičnih podjedinica.[6] Ove prstenaste strukture sastavljaju se samostimulacijom u prisustvu Mg2+-ATP. Centralna šupljina cilindričnog cpn60 tetradekamera pruža izolirano okruženje za presavijanje proteina, dok je cpn-10 vezan na cpn-60 i sinhronizira oslobađanje presavijenih proteina, ovisano o Mg2+-ATP.[7] Molekulskoo vezivanje cpn10 na cpn60 hibira slaba aktivnost ATPaze cpn60.
Također se pokazalo da GroES u Escherichia coli kooperativno veže ATP, sa afinitetom uporedivim sa GroEL-ovim.[8] Svaka podjedinica GroEL-a sadrži tri strukturno različita domena: apikalni, srednji i ekvatorski. Apikalni domena sadrži vezujuće mjesto i za GroES i za nerazvijeni proteinski supstrat. Ekvatorijalna domen sadrži ATP-vezujuće mjesto i većinu oligomernih kontakata. Srednji domen povezuje apikalni i ekvatorski domen i prenosi alosternne informacije između njih. GroEL-ni oligomer je tetradekamer, cilindričnog oblika, organiziran u dva heptamerna prstena složena jedan na drugi. Svaki prsten GroEL-a sadrži centralnu šupljinu, poznatu kao "Anfinsenov kafez", koji pruža izolirano okruženje za savijanje proteina. Identične podjedinice GroES od 10 kDa, u rast voru formiraju kupolasti heptamerni oligomer. Vezanje ATP za GroES može biti važno za punjenje sedam podjedinica interaktivnog GroEL prstena sa ATP, kako bi se olakšalo kooperativno vezanje ATP i hidroliza za oslobađanje proteinskog supstrata.
Detekcija uredi
Faktor rane trudnoće ispitivan je testom inhibicije rozete. EPF je prisutan u majčinom serumu (krvna plazma) nedugo nakon oplodnje; EPF je prisutan i u sluz grlića maternice[9] i u amnionskoj tekućini.[10]
Kod ovaca, EPF se može otkriti u roku od 72 sata nakon parenja,[11] kod miša – nakon 24 sata,[12] a u uzorcima iz medija koji okružuju ljudske embrione oplođene in vitro, u roku od 48 sati od oplodnje[13] (iako druga studija nije uspjela ponoviti ovaj nalaz za embrione in vitro).[14]> EPF je otkriven u roku od šest sati nakon parenja.[15]
Budući da je inhibicijski esej rozete za EPF posredan, supstance koje imaju slične efekte mogu biti zbunjujće. Pokazalo se da svinjska sperma, poput EPF, inhibira stvaranje rozeta – ovaj esej bio je pozitivan jedan dan kod krmača parenih s vazektomiziranim nerastom, ali ne i kod krmača slično stimuliranih bez izlaganja sjemenu.[16] Brojne studije, u godinama nakon otkrića EPF-a, nisu mogle kod žena reproducirati dosljedno otkrivanje EPF-a nakon začeća, a valjanost eksperimenta prilikom otkrića dovedena je u pitanje.[17] Međutim, postignut je napredak u karakterizaciji EPF-a i njegovo je postojanje dobro je prihvaćeno u naučnoj zajednici.[18][19]
Porijeklo uredi
Ne vjeruje se da rani embrioni direktno proizvode EPF. Umjesto toga, smatra se da proizvode neku drugu hemikaliju koja inducira majčin sistem da stvori EPF.[20][21][22][23][24] Nakon implantacije, conceptus može direktno proizvesti EPF.[14]
EPF je imunosupresiv. Uz ostale supstance povezane s ranim embrionima, vjeruje se da EPF ima ulogu u sprečavanju da imunski sistem trudne žene napadne embrion.[15][25] Injektiranje antitijela na EPF miševa nakon parenja, značajno smanjuje broj uspješnih trudnoća i broj mladunaca sa anti-EPF;[26][27] nije opažen efekat na rast kada su miševi kultivirani u medijima koji sadrže anti-EPF antitijela.[28] Iako su neke aktivnosti EPF-a jednake kod svih sisara (inhibicija rozeta), drugi imunosupresivni mehanizmi variraju među vrstama.[29]
U miševa, razine EPF su visoke u ranoj trudnoći, ali 15. dana opadaju na nivoe koji su pronađeni u netrudnih mišica.[30] U žena, nivoi EPF su visoki tokom prvih dvadeset nedelja, a zatim opadaju i postaju neotkriveni tokom osam sedmica od porođaja.[31][32]
Kod ljudi, savremeni test trudnoće otkriva horionski gonadotropin (hCG), tek nakon implantacije, koja se javlja šest do dvanaest dana nakon oplodnje.[33] Nasuprot tome, EPF je prisutan u roku od nekoliko sati nakon oplodnje. Iako je identificirano nekoliko drugih signala prije implantacije, vjeruje se da je EPF najraniji mogući marker trudnoće.[12][34] Nekoliko studija je utvrdilo da je tačnost EPF kao testa trudnoće kod ljudi visoka.[35][36][37][38]
Kao tumorski marker uredi
Iako je gotovo isključivo povezana sa trudnoćom, aktivnost slična EPF-u otkrivena je i kod tumora klicnog porijekla[39][40] i kod drugih tipova tumora.[41] Predloženo je da može biti koristan kao tumorski marker za procjenu uspjeha hirurškog liječenja.[42]
Interakcije uredi
Pokazano je da GroES ima interakcije sa GroEL-om.[43][44]
Reference uredi
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Dopunska literatura uredi
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Vanjski linkovi uredi
- GroES Protein na US National Library of Medicine Medical Subject Headings (MeSH)
- 3D macromolecular structures of GroES in EMDB