Insertion Sequence (IS) Element-Mediated Activating Mutations of the Cryptic Aromatic β-Glucoside Utilization (BglGFB) Operon Are Promoted by the Anti-Terminator Protein (BglG) in Escherichia coli.

Zhongge Zhang,Milton Saier,Dennis Tran,Kingswell Zhou

doi:10.3390/ijms23031505

Abstract

The cryptic β-glucoside GFB (bglGFB) operon in Escherichia coli (E. coli) can be activated by mutations arising under starvation conditions in the presence of an aromatic β-glucoside. This may involve the insertion of an insertion sequence (IS) element into a “stress-induced DNA duplex destabilization” (SIDD) region upstream of the operon promoter, although other types of mutations can also activate the bgl operon. Here, we show that increased expression of the bglG gene, encoding a well-characterized transcriptional antiterminator, dramatically increases the frequency of both IS-mediated and IS-independent Bgl+ mutations occurring on salicin- and arbutin-containing agar plates. Both mutation rates increased with increasing levels of bglG expression but IS-mediated mutations were more prevalent at lower BglG levels. Mutations depended on the presence of both BglG and an aromatic β-glucoside, and bglG expression did not influence IS insertion in other IS-activated operons tested. The N-terminal mRNA-binding domain of BglG was essential for mutational activation, and alteration of BglG’s binding site in the mRNA nearly abolished Bgl+ mutant appearances. Increased bglG expression promoted residual bgl operon expression in parallel with the increases in mutation rates. Possible mechanisms are proposed explaining how BglG enhances the frequencies of bgl operon activating mutations.

Highlights

The cryptic β-glucoside GFB operon in Escherichia coli (E. coli) can be activated by mutations arising under starvation conditions in the presence of an aromatic β-glucoside
The first and perhaps best documented example, in which numerous control experiments have been performed to verify the occurrence of directed mutation, involved transposon Insertion Sequence 5 (IS5)mediated activation of the Escherichia coli (E. coli) glycerol FK operon [7,8]
2.1R. eOsuvletrsexpression of the BglG Gene Increases the Frequencies of Both insertion sequence (IS)- and Non-IS-Mediated B2.g1l.+OMveuretxaptiroensssion of the BglG Gene Increases the Frequencies of Both IS- and Non-IS-Mediated Bgl+ MFuigtautrioen1s A shows the total numbers of Bgl+ mutations arising on salicin M9 minimal agarFpiglautrees1aAs ashfouwnscttihoentootfatlinmuemibnewrsioldf Btgylp+ emEu.tactoiloincselalrsisaisngwoenllsaaslicthineMsa9mmeinciemllaslin which baglaGr pwlaatesseaxsparfeusnscetdiown oitfhtimtheeinusweilodfttyhpee iEn.tceorlimceeldlsiatsewlealcltaossteheopsaemroencerlelspirnewsshoirchpromoter

Summary

Introduction

The cryptic β-glucoside GFB (bglGFB) operon in Escherichia coli (E. coli) can be activated by mutations arising under starvation conditions in the presence of an aromatic β-glucoside. We show that increased expression of the bglG gene, encoding a well-characterized transcriptional antiterminator, dramatically increases the frequency of both ISmediated and IS-independent Bgl+ mutations occurring on salicin- and arbutin-containing agar plates. Both mutation rates increased with increasing levels of bglG expression but IS-mediated mutations were more prevalent at lower BglG levels. The first and perhaps best documented example, in which numerous control experiments have been performed to verify the occurrence of directed mutation, involved transposon Insertion Sequence 5 (IS5)mediated activation of the Escherichia coli (E. coli) glycerol FK (glpFK) operon [7,8]. Wang and Wood subsequently described an example of IS-activation of the flagella master switch (flhDC) operon encoding the master regulator of motility in E. coli [9], confirmed a(InSd5)-emxetdeinadteeddaicntivaatliaotnerofsthuedEyscbhyeroicuhira rceolsie(aEr.ccholig)rgolyucpero[l10FK]. (AglnpFoKth) eorpeerxoanm[7p,8l]e. deals with tHraonwsepvoers,oWna-ancgtaivnadtWioonoodfsuzibnsecqrueesnistltyadnecsecriinbeCduapnreiaxvaimduplsemofetISa-lalicdtuivraatniosnionfathme felac-hanistically fgaelilralymawsteerlls-wdietcfihn(efldhDpCr)oocpeesrson[1e1n]c. oTdwingo tohtehmerasetexrarmegpulleastoirnovfomlvoetilittryaninspE.ocsoolin[9e],xcision that sceoenmfirsmteod banedreegxtuelnadteedd i[n5,a12la]t.erItstaupdpyebayrsouthr artesseuacrchh egxraoumpp[l1e0s].aArenonthoetruenxcaommplme on in both btdashinaeoeiacnslttfseiutchwrcaaioliatltsyhseaeftAnearamidOrnlsyse(ptufwouoksecbaolAelnr-Oydr-eaeo)gcfttiuoeinvlpseaadet[teri1dpoo3nrn[]o5.oci,f1enAs2zs]iEdn.[.dIc1tc1iroat]ei.lpsoiTipsn[wet1aaa4onlr]sco,eettfxhhuianearmrtaCzsepuuoxpllacierhmdisaoepvnixilndeeausmsbsieapnmncvlseetoitsetalviralvlieriaidettuyrinranoaAncntslsupauinonndscdeoaonmBmISeme(5xncochfains--cAtivanatdionnfsoBf) iinnabcottihvabtaicotneribayanISdeeluekmareynottse,sa[l1s3o]. iAndEd.itcioolnia[l1e5x,1am6]p, ltehseinrebgauctleartiiaoinncoluf dceapISs5ualectbiviao-synthesis in NtioenissoefrtihaemfeuncoinsegAitOidi(sfu[1cA7O], )doepveerloonpimn eEn. tcaollliy[1p4r],ofgurraazmolmidoende tsreannsistpivoitsyoAn aenxdcisBio(nnfsiAn the Bacillus saunbdtinlfissBs)pinoarcutilvaattiioon bcaysIcSaedleem[e1n2t]s,,dalrsuogin(pEi.pcoelria[1c5il,l1i6n],/tthaezroebgauclattaiomn)orfecsaipstsaunlecbeioin- E. coli [18], asynndthreestirsointrNaneissperoisaomne-nriengiutildaiste[1d7]g, edneveeeloxppmrensstaiollynpirnogeruakmamryedotterasn[s1p9o,s2o0n].exTchisuiosn, there is an einvethr-einBcarciellaussinsugbtniluismspboerruolafteioxnamcapsclaedseo[f1t2h],edrreuggu(lpaitpieornacoilfligne/tnaezoebxapctraemss)iorensiastnadncfeunction that minaEy. cboeli [s1u8b],jeacntdtroettrroatnrasnpsopsoosnon-m-reegduilaatteedd gdeinreecetxepdreosrsiaodn ainpetiuvkearmyoutteast[i1o9n,2.0I]t. sThhouus,ld be noted, hbtfshuheoenoewrcunetleidiomvsnbeaeerntc,hnhteaohavttneeamdrti-s,aimtnhyicocorbwaseeltaelsysvoiuenfdbrgt,jehetnfihceutanmItteSomdb-rteo.rersagtonoufsfpletaxohtaseeomdInSp--gmlreeesegndoueiflaaettthexedepdrrdgeeeigsrnuesecliaoteetxnidopsnroteruosfsadigdoieeannpssettdiuveedxespicemrrseiudsbtseaeisotdcinorainabb.neoIddtve have not aboveWheavheanvoetubseeedn mE.eccohlai naisstoicuarllmy doedfeinl eodr.ganism for studying the involvement of transposons in mWedeiahtaivneguesendviEr.ocnomli aesnotaulrlymopdroelmorogtaendi,smDNfoAr stbuidnydininggthperiontveoinlv-ecmonentrtoolfletdra,ngs-ene/operon apcotsiovnastioinn mweitdhiaetixnagmepnlveirsoansmnenottaeldly apbroovmeo. teInd,thDiNs Arepboinrtdiwnge tpurronteitno-caonwtreollllecdh,aracterized ogepneer/oonpe, rtohneaβc-tigvlautcionsidweitGhFeBxa(mbgplGesFaBs)noopteedroanboovfe.EI.ncothli,s trheaptorhtawsebteuernn ktonaowwnellfor decades tcohabreacatecrtiizveadteodpebroynI,Sthiensβe-grltuicoonsiadleeGvFeBn(tbsgl[G2F1B,2)2o]p. eAroltnhoofuEg. hcogli,rethaattehfafsorbteehnasknboewenn devoted to ufonrddeercsatdaensdtoinbgetahcetivtraatendscbryipIStiionnsearltrioengaulleavtieonntso[2f1b,g22l ]o. pAeltrhoonuegxhpgrreesastieofnfobrtyhaans baenetnitermination mdaneetvicotehtreamdnitinosamutino, ndveemrrseytcahnliadtntilniesgmrt,ehvseeertaryraclnihtstclheriaprestsioednaerasclchrrehigbauselddaetitsohcnreibomefdbegcthlheoapmneierscomhna(ensxi)spmbrey(sss)wibohyniwcbhyhiacISnh insertional mISuintsaetriotionnsaol fmtuhteatbiognl soopfetrhoenbgalroepreergounlaarteedregSuclhaetemdeSc1h.eme 1

Methods

Results

Conclusion