ORIGINALRESEARCHARTICLE published:07January2013 doi:10.3389/fmicb.2012.00436 Combination of culture-independent and culture-dependent molecular methods for the determination of bacterial community of iru, a fermented Parkia biglobosa seeds GbengaA.Adewumi1,2,3,FolarinA.Oguntoyinbo1*,SantoshKeisam2,WahengbamRomi2 and KumaraswamyJeyaram2 1DepartmentofMicrobiology,FacultyofScience,UniversityofLagos,Akoka,Lagos,Nigeria 2MicrobialResourcesDivision,InstituteofBioresourcesandSustainableDevelopment,TakyelpatInstitutionalArea,Imphal,Manipur,India 3DepartmentofFoodScienceandTechnology,CollegeofFoodSciences,BellsUniversityofTechnology,Ota,Nigeria Editedby: In this study, bacterial composition of iru produced by natural, uncontrolled fermentation DaniloErcolini,UniversitàdegliStudi of Parkia biglobosa seeds was assessed using culture-independent method in diNapoliFedericoII,Italy combination with culture-based genotypic typing techniques. PCR-denaturing gradient Reviewedby: gel electrophoresis (DGGE) revealed similarity in DNA fragments with the two DNA Jean-PierreGuyot,Institutde extraction methods used and confirmed bacterial diversity in the 16 iru samples RecherchePourleDévelopement, France from different production regions. DNA sequencing of the highly variable V3 region LucaCocolin,UniveristyofTurin, of the 16S rRNA genes obtained from PCR-DGGE identified species related to Italy Bacillus subtilis as consistent bacterial species in the fermented samples, while other *Correspondence: major bands were identified as close relatives of Staphylococcus vitulinus, Morganella FolarinA.Oguntoyinbo,Department morganii, B. thuringiensis, S. saprophyticus, Tetragenococcus halophilus, Ureibacillus ofMicrobiology,FacultyofScience, UniversityofLagos,Akoka,Lagos, thermosphaericus, Brevibacillus parabrevis, Salinicoccus jeotgali, Brevibacterium sp. and Nigeria. uncultured bacteria clones. Bacillus species were cultured as potential starter cultures e-mail:[email protected] and clonal relationship of different isolates determined using amplified ribosomal DNA restriction analysis (ARDRA) combined with 16S–23S rRNA gene internal transcribed spacer(ITS)PCRamplification,restrictionanalysis(ITS-PCR-RFLP),andrandomlyamplified polymorphic DNA (RAPD-PCR). This further discriminated B. subtilis and its variants from food-borne pathogens such as B. cereus and suggested the need for development of controlled fermentation processes and good manufacturing practices (GMP) for iru productiontoachieveproductconsistency,safetyquality,andimprovedshelflife. Keywords:iru,fermentation,safety,Bacillus,DGGE INTRODUCTION (Achi, 2005). Nonetheless, the production process is generally Fermentedvegetableproteinseedsusedforcondimentsproduc- characterized by spontaneous solid substrate alkalinefermenta- tioninWestAfricaincludeAfricanlocustbean[Parkiabiglobosa tion with increase in pH as a result of extensive hydrolysis of (Jacq. Benth)], melon seeds [Citrullus vulgaris (Schrad)], castor the proteins into peptides, amino acids and ammonia, which oilseeds(Ricinuscommunis),flutedpumpkinseeds(Telfariaocci- favorsthedominanceofBacillusspp.asthefermentingorganisms dentale),Africanyambean(Stenophylisstenocarpa),cottonseeds (Kiers et al.,2000; Sarkar et al., 2002; Ouoba et al.,2003; Achi, [Gossypiumhirsitium(L.)],roselleseeds(Hibiscussabdariffa),and 2005).Theartisalsocarriedoutinexclusiveuncontrollableenvi- baobab seeds [Adansonia digitata (L.)] (Odunfa and Oyewole, ronmental conditions thereby yielding products with variation 1998;Ouobaetal.,2008;Parkoudaetal.,2010).Condimentscon- in qualityandorganoleptic properties (Sanni,1993; Steinkraus, stituteasignificantproportionofAfricandietswheretheyserve 1997;Ouobaetal.,2007).Thisnecessitatestheneedforthedevel- asflavorsomeandculinarycomponentsinvariousdishes(Achi, opmentofappropriatestarterculturestoinitiatefermentationfor 2005). They include iru or dawadawa in Nigeria and Ghana; theproductionofconsistentproductswithacceptablequalities. soumbala, bikalga, and maari in Burkina Faso; afitin and sonru Theprocessing operations of Africanlocustbean to produce in Benin Republic; nététou in Senegal; kinda in Sierra Leone; iruinvolvecleaningandsorting,boiling,dehulling,andfermen- dawadawa botso in Niger Republic; datou in Mali; mbuja in tationatambienttemperature(Oyeyiola,1988).Investigationson CameroonandfurunduinSudan(N’Diretal.,1994;Ouobaetal., the microbiology of iru using selective isolation andcultivation 2008,2010;Parkoudaetal.,2010). based on traditional culture-dependent methods including the Though,thevegetableseedsusedfortheproductionofthese biochemical changes that occur during fermentation have been condiments differ considerably from one region to another documented(Odunfa,1981,1985;Omafuvbeetal.,2004).These www.frontiersin.org January2013|Volume3|Article436|1 Adewumietal. Moleculardeterminationofirubacterial techniquesoftenfailtoaccountforminormicrobialpopulations; CULTURE-DEPENDENTANALYSIS stressed andinjuredcells thatarepresentinlownumber (Fleet, A total of 280 bacterial isolates were isolated from 20 iru sam- 1999), and have been observed not to give a complete repre- ples and Reference bacterial strains obtained from Microbial sentation of foodmicrobialcommunities (Kesmen et al.,2012). TypeCultureCollection(MTCC),Indiaweresubjectedtogeno- Also,theyarebias,unreliableandlackaccuratedetectionofpop- typic characterization. Amplified ribosomal DNA restriction ulation dynamics and microbial diversity (Amann et al., 1995; analysis (ARDRA) combined with PCR amplification of the Hugenholtz et al., 1998; Giraffa and Neviani, 2001; Jany and 16S–23SrRNAgeneinternaltranscribedspacer(ITS),ITS-PCR- Barbier,2008). restrictionfragmentlengthpolymorphism(ITS-PCR-RFLP),and Culture-independent microbial techniques, such as PCR- randomly amplified polymorphic DNA (RAPD-PCR) as previ- denaturing gradient gel electrophoresis (DGGE) has proven ouslydescribed (Oguntoyinboet al.,2010) were used for geno- much more reliable, fast, and economical in profiling complex typic grouping, clonal relationship, and isolates diversity. The bacterialcommunitystructure,dynamicsandevolutionofmicro- almostcomplete16SrRNAgenesofrepresentativeisolatesfrom bialpopulationsoffermentedfoods (GiraffaandNeviani,2001; theclustersgeneratedfromdendrogramofgelfingerprintswere Randazzo et al., 2002; Cocolin et al., 2007; Jany and Barbier, amplifiedandsequencedasdescribedpreviously(Jeyarametal., 2008). PCR-DGGE has been successfully employed to study- 2010).Closestknownidentitiesofthe16SrRNAgenesequences ing the microbial community structures and dynamics of fer- wereobtainedfromNCBIGenBankdatabase. mented vegetal protein seeds such as doenjang and meju (Cho and Seo, 2007; Kim et al., 2009; Lee et al., 2010) as found in CULTURE-INDEPENDENTANALYSIS Asia. More recently, barcoded pyrosequencing of V1/V2 region DNAextractionandPCRamplification of 16S rRNA gene was used in assessing the microbial com- Two methods of bacterial genomic DNA described previously munity of doenjang (Nam et al., 2012). Meanwhile, there is by Ercolini et al. (2003) and Rantsiou et al. (2005) were used dearth of informationon theapplicationof thesetechniques to to extract genomic DNA from 16 iru samples (no apprecia- profile microbial community of fermented vegetable foods in ble DNA was obtained from remaining four samples). The V3 Africa. region of the 16S rRNA gene was amplified using the set of (cid:3) (cid:3) Studies involving the use of both culture-dependent and primers 338f (5-ACTCCTACGGGAGGCAGCAG-3) and 518r culture-independentmolecularmethodsfortheidentificationof (5(cid:3)-ATTACCGCGGCTGCTGG-3(cid:3)) (Sigma-Aldrich). A GC-rich dominantbacterialspecies; accuratedeterminationanddetailed clampwasattachedtotheforwardprimerasdescribedbyMuyzer investigationofmicrobialcompositionoffermentedfoodprod- et al. (1993). Five-microliters PCR amplified product was anal- ucts have been reported (Pulido et al., 2005; Vilela et al., ysed on 2% agarose (Promega, USA) containing ethidium bro- 2010; Alegría et al., 2012; Kesmen et al., 2012). In this study, mide(0.5µg/ml)(E1510,Sigma-Aldrich),using0.5×TBEbuffer wecombinedbothculture-dependentand-independentmolec- (45mM Tris-borate, 1mM EDTA, pH 8.0) with running con- ular techniques as a polyphasic strategy to first understand ditions of 80V for about 1h. DNA fragments of about 240bp and characterize the microbial community profile of iru pro- obtained by comparing with PCR 100bp low ladder (P1473, duced by natural, uncontrolled fermentation process; secondly, Sigma-Aldrich)wasusedforDGGEanalysis. to have a deeper insight into the bacterial diversity, which can be used to locate and identify the dominant bacteria with DGGEanalysisoffermentedirusamples technological and functional potentials that can be further DGGE was performed using a DCODE™ Universal Mutation developed as autochthonous starter cultures to improve indus- Detection System (BIO-RAD, USA) following manufacturer’s trial production of condiments in W. Africa and guarantee instructions.PCRampliconsincludingaDGGEmarkerdesigned productsafety. andusedasareferenceDNAladder,wereseparatedin8%poly- acrylamidegelscontaining1×TAEwithdenaturinggradientsof MATERIALSANDMETHODS 25–55% [100% denaturant corresponds to 7M urea and 40% SAMPLECOLLECTION (v/v) formamide]. Electrophoresis was run initially at 20V for ◦ Fermenting P. biglobosa during iru production were obtained 10min and at a constant temperature of 60 C, and finally at ◦ fromlocalproducers aswell asretailmarkets samplesinsouth- 140Vfor5hat60 C.Thegelswerestainedwithethidiumbro- west (Lagos, Ibadan, Abeokuta, Oyo, andAdo-Ekiti) and north mide, visualized under UV light and documented using Gene central Nigeria (Kaduna and Ilorin). They were transported Snap(PerkinElmerGELIANCE200,USA). immediatelyintothelaboratorywiththeaidoficepack,storedin therefrigeratorat4◦Candanalyzedwithinfewdaysofcollection. PCR-DGGEgelimagesanalysis TheDGGEgelimagesobtainedwereconvertedtodensitometric ISOLATIONOFMICROORGANISMS profilesusingthesoftwareTL120v2006(Phoretix1DAdvanced Samples of fermented iru were homogenized in 90ml Ringer’s Software, NonLinear Dynamics, Newcastle, UK). The similarity solution. Serial dilutions were made and 0.1ml of appropriate between theDGGElaneswas investigated byconstructing non- dilutionswasspreadplatedonnutrientagar(Oxoid,Hampshire, metricmultidimensionalscaling(non-metricMDS)scatterplots ◦ UK). Plates were subsequently incubated at 37 C for 18–24h. as described elsewhere (Boon et al., 2002; McOrist et al., 2008) Bacterialcoloniesobtainedwerepurifiedbyrepeatedstreakingto using the software package P A S T (PAleontological STatistics, obtainpurecultures. http://folk.uio.no/ohammer/past/). The Shannon–Weaver index FrontiersinMicrobiology|FoodMicrobiology January2013|Volume3|Article436|2 Adewumietal. Moleculardeterminationofirubacterial of H diversity and R richness index were determined based on Similarity and variation among DGGE gel patterns of the vari- thenumberpresence/absenceinthefragments.Theimportance ous fermentedcondimentswereestablishedbasedoncombined probabilityPiandH werecalculatedusingPAST(Shannonand analysis of Dice similarity coefficient and nMDS. The results Weaver,1963). obtainedshowedthatthe16irusamplesanalysedclusteredinto five groups—a, b, c, d, and e (Figure1). Noticeable similarity ExcisionofDGGEbandsandsequencingofamplicons can be saidto exist in thebacterial community structure of the DGGE major bands of interest were excised from the poly- different samples of iru obtained in the two geographical zones acrylamide gels, eluted in 50µl sterile deionized water (Milli under study (southwest and north central Nigeria). Apart from ◦ Q, Millipore, Bangalore) and incubated overnight at 4 C as twoirusamplesfromLagossouthwesternNigeria,thatclustered describedbyCocolinetal.(2001).Onemicroliterofeacheluate into the same group “a” variation was observed among sam- wasused asDNAtemplate forPCRreamplification.PCRprod- ples within the same geographical location especially southwest uctsoriginatingfromtheexcisedbandswereprofiledandchecked Nigeriansamples. forqualityinagarose;presenceandpositionofthebandsofinter- estinDGGEandcomparisonwithparentDGGEprofiles.Elution IDENTIFICATIONOFMAJORBACTERIALPCR-DGGEBANDS andreamplificationwerecarriedoutatleasttwiceoruntilasingle DNA sequencing was carried out on the major bacterial bands. bandthatco-migrateatthesamepositionwiththeparentDGGE Theclosestknownidentities,percentagesimilarityandfrequency band is obtained. Sequences of major bands obtained from the of occurrence of each bandin thefermented condiments areas DGGE gel fragments were compared with the NCBI GenBank showninTable3.Amongthemall,B.subtilisoccurredmostfre- databasetodetermineclosestrelatives. quently(band10),Figure2).Itwasfoundtobepresentin94% of the iru samples, which confirms its consistency, dominance, RESULTS and viability in the fermented condiments. B. licheniformis and CULTURE-BASEDMOLECULARAPPROACH Brevibacillusspeciespreviouslyisolatedintheculture-dependent Intheculturedanalysis,similarcolonialmorphologyandpopu- study were also found present in at least a sample of the fer- lationprofilerangingfrom106–107CFU/mlwereobtainedfrom mented condiment (Table3). Other bands identified include fermented samples as well as final product. A total of 280 iso- closerelativesofS.vitulinus,Morganellamorganii,B.thuringien- lates selected for analysis by ARDRA restriction endonucleases sis, S. saprophyticus,T. halophilus, Ureibacillus thermosphaericus, especiallyCfoIshoweddifferentiationoftheisolatesintovarying Salinicoccus jeotgali,Brevibacterium sp.,andunculturedbacteria species,inparticular,B.subtilisandB.cereusphylotypes.Further clones. characterizationwithITS-PCR-RFLPrevealedintraspeciesdiver- genceamongtheBacillusisolates.ThegeldataofARDRA,ITS- DISCUSSION PCR,ITS-PCR-RFLP,andRAPD-PCRwerecombinedtogenerate In W. Africa traditional fermented condiments form an impor- polyphasic gel fingerprint. Representative of the major clusters tantcomponentofthedietaryproteinrequirementofthepeople, obtainedwereidentifiedbysequencedataof16SrRNAgenethat where they are added generously to various dishes to supple- identified two major bacilli groups; B. subtilis and B. amyloliq- mentproteinintake,improvenutritivevalue,andimpartsensory uefaciensasthedominant,aswellasB.cereus groupasmember attributes. This study combined molecular techniques to reveal ofthecultivatablebacteriaassociatedwithfermentedP.biglobosa microbiotaoftraditionalfermentedcondimentssampletestedat cotyledon(Table1). differentfermentationtimeregimes withconsiderationforgeo- graphical spread in Nigeria. This is aimed at future objectives ANALYSISOFBACTERIALCOMMUNITIESANDDIVERSITYOFiru of developing predictable process through the use of identified USINGPCR-DGGE bacteria that can be applied as starter cultures to dominate the The two genomic DNA extraction protocols- enzymatic and fermentation,impactdesirablebiochemicalchangesandimprove chemicalprovedtobeefficientinterms ofquantity,purity,and safetyquality. amplifiabiltiy,andthusproducedDNAsuitableforPCRamplifi- Theresultsofculture-dependentanalysisand16SrRNAgene cation.Theresultsof thePCR-DGGEgelfingerprintsoftheV3 sequencing showed that iru is composed of clonally related regionofamplified16SrRNAgeneshowedidenticalDGGEpat- Bacillus species identified as B. subtilis, B. amyloliquefaciens, B. ternsandhighdegreeofsimilarityinDNAfragmentswiththetwo cereus,B.licheniformis,andBrevibacillusformosusinorderoffre- DNAextractionmethods.ThePCR-DGGEgelprofileswerealso quencyofincidence.Also,thecombinationofARDRA,ITS-PCR, usedtoassessthebacterialcommunityprofile;richness,biodiver- ITS-PCR-RFLP,andRAPD-PCRrevealedhighdegreeofdiversity sity, anddominanceindexes of naturallyfermented iru samples amongtheBacillusisolatesandidentifiedthedominantspeciesto obtained from different geographical locations in Nigeria. The beB.subtilisandB.amyloliquefaciens.Theresultsclearlyshowed species richness index (R) determined was highest for DGGE sub-typingofautochthonousclonallyrelatedspeciesofbacilliand profiles of iru samples from Ilorin (R 19), thus exhibiting the geneticallyidentifieddominantgroups,thisisinagreementwith highest number of bands/bacterial species than those of Lagos previous reports in W. Africa and India duringfermentation of (16<R<18); Ado-Ekiti (R♦16); Ibadan (11<R<14); Oyo similarvegetableproteinsstudies(Sarkaretal.,2002;Ouobaetal., (R(cid:4)10) and Abeokuta (9<R<17) (Table2). Bacterial diver- 2004; Jeyarametal.,2008; Kimet al.,2010; Oguntoyinboetal., sity index (H) calculated on thebasis of number of bands on a 2010;Parkoudaetal.,2010). gel trackwasalsohighestforirusamples fromIlorin(H 2.92) Culture-independenttechniqueshavebeenpreviouslyusedto with the lowest being Abeokuta (2.19<H <2.80) (Table2). describemicrobiotaoffermentedfoodsinAfrica(Humblotand www.frontiersin.org January2013|Volume3|Article436|3 Adewumietal. Moleculardeterminationofirubacterial o. d) n 1 e ncing NCBIacc. JN255703 JN165753. JN255715 JN255725 JN255727 JN255710 JN255726 JN255717 JN255722 JN255707 (Continu e u q y genese Similarit 99% 98% 100% 97% 100% 99% 99% 100% 99% 98% A N SrR own e- e- 16 Closestknrelative B.subtilis B.subtilis B.subtilis B.subtilis B.subtilis B.subtilis B.pumilus B.pumilus B.amyloliqufaciens B.amyloliqufaciens e v ati nt preseains EBA 04 54B 91A 33 22A 13A 58 84B 9BA Restr U4 U1 U1 U1 U2 U1 U2 U1 U1 U7 s ofate No.isol 93 26 1 3 1 1 2 62 37 a. s o mentedParkiabiglob R-RFLPsub-groupsnbp) 7,339,278,260,214, 6 9,280,141 1,322,263,247,218,9 9,271,231,137 6,330,269,255,7,120 9,268,223,134 9259,149 0,343,274,5,137 4,384,369,343,0,147,138 onalfer ITS-PC(sizesi IA1. 502,41 143,13 IA2. 506,33 IIA1. 485,40138,12 IIA2. 489,32 IIA3.494,40225,12 IIA4.494,32 IIA5. 490,33 IIIAl.504,42259,14 IIIA2.506,42274,26 diti b-es 63 a uz 8 fromiru,tr ITS-PCRsgroups(si inbp) IA. 1065,945, 869, IIA. 1036,845 IIIA.1057,939, d e isolat RsaI 525 477 429 149 515 470417 146 515424147 es p) speci sinb TaqI 573 458 349 214 590 412361 221 722375232 s e u z Bacill file(si HinfI 581 355 317 177 592 362324 183 609374335 190 aracterizationof SrRNA-RFLPpro CfoIDdeI 908508 451465 248237 150 122 904504 445,381243280 147 117 510912392451286247 236122 h 6 Genomicc 1 HaeIII a627,473 318 156 622,467 314,151 627,472,318,156 1| As Table ARDRgroup I II III FrontiersinMicrobiology|FoodMicrobiology January2013|Volume3|Article436|4 Adewumietal. Moleculardeterminationofirubacterial o. n ncing NCBIacc. JN255724 JN255711 JN255721 JN255728 JN255723 e u q y genese Similarit 98% 100% 96% 92% 99% A N rR wn mis mis 16S Closestknorelative B.lichenifor B.lichenifor B.cereus B.cereus Brevibacillusformosus e v ati nt e presains 86 26 75 43 85B Restr U1 U1 U1 U2 U1 s ofate No.isol 3 1 49 1 9 5, s 2 03 p 1 23 grou 142 271, 225,42,1 RFLPsub-bp) 272,229, 414,335, 168,136 294,262,167,157,1 R-n 6, 5, 1, 5,3, ITS-PC(sizesi IVAl. 496,33 IVB1. 489,43 VA1. 506,31 VIA1.461,35198,19 b-es ITS-PCRsugroups(sizinbp) IVA. 1024,845 IVB. 1044,926, 842,339 VA. 1078,827 VIA.1359,1161,1103,1020,910 RsaI 498 459 409 142 494 411 355 142 452411353131107 p) inb TaqI 570 395 345 211 600 481 134 575389365196 s e z (si nfI 1 4 7 6 3 2 0 3447 file Hi 58 34 30 16 94 31 17 97302316 o FLPpr DdeI 518 288 277 237 132 115 516 287 275 172 150 115 546441238167120 R A- N oI 4 6 8 2 7 7 2 5 2482 rR Cf 41 32 22 17 56 41 33 17 41322117 S 6 Continued 1 HaeIII 622,475 324,156 595,477 322,161 627,477,228,157 mentsizes. g Table1| ARDRAgroups IV V VI aDNAfra www.frontiersin.org January2013|Volume3|Article436|5 Adewumietal. Moleculardeterminationofirubacterial Table2|Speciesrichnessestimates(R)andShannon’sindexof Guyot, 2009; Oguntoyinbo et al., 2011). Although none of this diversity(H)ofDGGEprofilesoffermentedirusamplesobtained studiesreportedmicrobiotaoffermentedvegetableproteinused fromvariousgeographicallocationsinNigeria. ascondiments.Inthisstudy,duringprofilingofbacterialcommu- nityoffermentediru,twomethods ofgenomicDNAextraction Samples R H were employed. No significant differences in the DNA yields, fragmentsandDGGEbandpatternswereobserved.Mafraetal. iruAbeokuta1 12 2.44 (2008)reportedsimilarfindingsinastudyinvolvingcomparison iruAbeokuta2 13 2.57 of four DNA extraction methods for downstream processing, iruAbeokuta3 17 2.80 comparison such as this guarantees better microbiome profil- iruAbeokuta4 12 2.49 ing. Results of PCR-DGGE gel analysis of iru sampled from iruAbeokuta5 11 2.34 Ilorin, north central Nigeria had the highest number of bacte- iruAbeokuta6 11 2.35 rialspecies thanothers,includingthehighestbacterial diversity iruAbeokuta7 15 2.70 index;thevariableproductionprocesscouldpossiblyberespon- iruAbeokuta8 9 2.19 sibleforthisobservation.Theintraspecificvariationobservedin iruLagos1 18 2.88 thefermentedirusamplesaspredicatedbyDicesimilaritycoef- iruLagos2 16 2.74 ficientandnMDSisanindicationthatthebacterialcommunity iruIlorin1 19 2.92 profileofthiscondimentisdiverse;havinggroupedintodistinct iruIlorin2 19 2.92 clusters with varying diversity indexes. Iru from different geo- iruIbadan1 11 2.40 graphicalzoneswereproducedfromthesamesubstrateP.biglo- iruIbadan2 14 2.60 bosaseedsbutvariablefermentationperiods.Therefore,diversity iruOyo 10 2.25 observed in the microbial communities could be due to differ- iruAdo-Ekiti 16 2.77 enceinfermentationconditions,whichisalsospontaneous and MeaniruAbeokuta(±STDEV) 12.50±2.35 2.49±0.19 uncontrolled, without the use of any known specific isolate as MeaniruLagos(±STDEV) 17.00±1.00 2.81±0.05 starterculture.Otherworkershavealsoreportedsimilarvariation inthemicrobialcompositionofnaturallyfermentedfoodmate- MeaniruIlorin(±STDEV) 19.00±0.00 2.92±0.00 rials produced using same substrate (Ampe and Miambi, 2000; MeaniruIbadan(±STDEV) 12.50±1.50 2.50±0.10 Oguntoyinboetal.,2011). FIGURE1|Non-metricMultidimensionalScalinganalysisofDGGEdata (b):iruAbeokuta4southwestNigeria((cid:3)).Group(c):iruAbeokuta1southwest Group(a):iruAbeokuta2southwestNigeria(+);iruAbeokuta3 Nigeria((cid:4));iruAbeokuta5southwestNigeria( );iruAbeokuta8 southwestNigeria((cid:2));iruLagos1southwestNigeria((cid:2));iruLagos2 southwestNigeria( );iruOyosouthwestNigeria((cid:4));iruAdo-Ekitisouthwest southwestNigeria(•);iru Ilorin1northcentralNigeria((cid:3));iruIlorin2 Nigeria(♦).Group(d):iruAbeokuta6southwestNigeria((cid:6));irulbadan2 northcentralNigeria( );iru Ibadan1southwestNigeria( ).Group southwestNigeria((cid:7)).Group(e):iruAbeokuta7southwestNigeria( ). FrontiersinMicrobiology|FoodMicrobiology January2013|Volume3|Article436|6 Adewumietal. Moleculardeterminationofirubacterial Table3|IdentitiesofmajorbacterialbandsexcisedfromPCR-DGGEgelsoffermentedParkiabiglobosaseeds. Bands Source/locationsa 16SrRNAgeneclosestknownrelative %Similarity 1 Oyo(1),Abeokuta(4),Ado-Ekiti(1),Lagos(1),Ibadan(1),Ilorin(2) Staphylococcusvitulinus 98 2 Ado-Ekiti(1),Ibadan(2),Abeokuta(4),Lagos(2),Ilorin(2) Morganellamorganii 98 3 Abeokuta(2),Ibadan(1),Lagos(1) Bacillusthuringiensis 99 4 Abeokuta(2),Ibadan(1),Ilorin(1) B.licheniformis 98 5 Oyo(1),Abeokuta(1),Lagos(1),Ilorin(1) S.saprophyticus 99 6 Oyo(1),Abeokuta(7),Ado-Ekiti(1),Lagos(2),Ilorin(2) Unculturedbacteriumclone 97 7 Abeokuta(3),Ibadan(1),Lagos(1) Tetragenococcushalophilus 95 8 Oyo(2),Ibadan(2),Abeokuta(1),Lagos(1) Ureibacillusthermosphaericus 100 9 Ado-Ekiti(1),Ibadan(1),Abeokuta(1),Lagos(1) Bacillussp. 98 10 Oyo(1),Abeokuta(7),Ado-Ekiti(1),Ibadan(2),Lagos(2),Ilorin(2) B.subtilis 99 11 Abeokuta(1) Brevibacillusparabrevis 97 12 Ibadan(1),Abeokuta(1) Salinicoccusjeotgali 99 13 Ado-Ekiti(1),Lagos(1) Brevibacteriumsp. 97 BandsareasshowninFigure2. aValuesinparenthesisrepresentnumberoffermentedirusamples,withtotalnumberofirusampledbeing16. S.saprophyticus,B.thuringiensis,Tetragenococcus halophilus,etc. Of interest is T. halophilus, a halophilic lactic acid bacterium, predominantlyfoundinfermentedfoodswithhighsaltconcen- trationsuchassoysauce,misoanddoenjang (Tanasupawatetal., 2002; Onda et al., 2003; Kim et al., 2009). The source of this bacterium in iru can somewhat be attributed to the salt added as a preservative at the end of the fermentation process. The detectionofB.cereus,B.thuringiensis,andStaphylococcusspecies clearly raises doubt regarding the microbiological safety of this fermentedcondiment.Informationonthetoxigenicpotentialof food-bornepathogenintraditionalAfricanfermentedfoodsexist (OguntoyinboandOni,2004;Abrioueletal.,2007;Oguntoyinbo etal.,2010). In conclusion, the results indicated that combination of culture-dependent and culture-independent techniques can be usedtoprofilebacterialmicrobiota,examinedynamicsanddiver- sityofnaturallyfermentedfood.Ontheoverall,thisstudyshowed that bacterial composition of iru is significantly more diverse than earlier reported and justified the need to develop process across production sites to facilitate safety quality and consis- FIGURE2|DGGEprofilesofPCR-amplified16SrRNAgenefragments ofsixteen(16)fermentedirusamplesshowingmajorbacterial tency. This study confirmed dominance of Bacillus species and amplicons.SamplesA:iruOyo;B:iruLagos1;C:iru Ilorin2;D:iru Ilorin occurrenceofotherbacteriawithpathogenictraitandunknown 1;E:iru Ibadan1;F:iruAdo-Ekiti;G:iruAbeokuta2;H:iruAbeokuta1;I: functions. Condiments can support dietary need of the people iru Ibadan2;J:iruAbeokuta3;K:iruAbeokuta4;L:iruAbeokuta5;M:iru ifbetter understandingofthefunctionalrolesofallmembersof Abeokuta6;N:iruLagos2;Î:iruAbeokuta7;P:iruAbeokuta8;“m”is thecommunityduringfermentationcanbedetermined,thiswill DGGEreferenceDNAladder.Bands1:Staphylococcusvitulinus;2: Morganellamorganii;3:Bacillusthuringiensis;4:B.licheniformis;5:S. supportdevelopmentofpredictableprocess, eliminatevariation saprophyticus;6:Unculturedbacteriumclone;7:Tetragenococcus andinconsistency. halophilus;8:Ureibacillusthermosphaericus;9:Bacillussp.;10:B.subtilis; 11:Brevibacillusparabrevis;12:Salinicoccusjeotgali;13:Brevibacteriumsp. ACKNOWLEDGMENTS This project was funded by the Department of Biotechnology PCR-DGGE bands sequencing identified B. subtilis as the (DBT), Government of India and the academy of Sciences for major bacterial species associated with iru, which is in agree- the Developing World (TWAS), Italy through the award of a mentwiththeresultofculture-basedPCRanalysis.Earlierstudies DBT-TWAS Postgraduate Sandwich fellowship to Gbenga A. using traditional culture-dependent methods and biochemical Adewumi and SfAM New Lecturer Grant, UK to Folarin A. characterization havealsoreported thedominanceof B. subtilis Oguntoyinbo. The leave of absence also granted to Gbenga A. duringirufermentation(AntaiandIbrahim,1986; Odunfaand Adewumi by Bells University of Technology, Ota, Nigeria that Oyewole, 1986). 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Food semi-dry processed coffee (Coffee distributed under the terms of the 292–301. Microbiol.18,85–95. arabica L.). Food Microbiol. 27, CreativeCommonsAttributionLicense, Pulido,R.P.,BenOmar,N.,Abriouel, Sarkar,P.K.,Hasenack,B.,andNout, 1128–1135. which permits use, distribution and H., López, R. L., Cañamero, M. J. R. (2002). Diversity and reproduction in other forums,provided M. M., and Gálvez, A. (2005). functionalityofBacillusandrelated Conflict of Interest Statement: The theoriginalauthorsandsourcearecred- Microbiological study of lactic generaisolatedfromspontaneously authors declare that the research itedandsubjecttoanycopyrightnotices fermentation of caper berries by fermented soybeans (Indian was conducted in the absence of any concerninganythird-partygraphicsetc. www.frontiersin.org January2013|Volume3|Article436|9