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Identification of Differentially-Expressed Genes Associated with Pistil Abortion in Japanese Apricot PDF

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Preview Identification of Differentially-Expressed Genes Associated with Pistil Abortion in Japanese Apricot

Identification of Differentially-Expressed Genes Associated with Pistil Abortion in Japanese Apricot by Genome-Wide Transcriptional Analysis Ting Shi., Zhihong Gao*., Liangju Wang, Zhen Zhang, Weibing Zhuang, Hailong Sun, Wenjun Zhong CollegeofHorticulture,NanjingAgriculturalUniversity,Nanjing,People’sRepublicChina Abstract ThephenomenonofpistilabortionwidelyoccursinJapaneseapricot,andimperfectflowerswithpistilabortionseriously decreasetheyieldinproduction.Althoughtranscriptomeanalyseshavebeenextensivelystudiedinthepast,asystematic studyofdifferentialgeneexpressionhasnotbeenperformedinJapaneseapricot.Toinvestigategenesrelatedtothepistil development of Japanese apricot, high-throughput sequencing technology (Illumina) was employed to survey gene expressionprofilesfromperfectandimperfectJapaneseapricotflowerbuds.3,476,249and3,580,677tagsweresequenced from two libraries constructed from perfect and imperfect flower buds of Japanese apricot, respectively. There were 689 significantdifferentially-expressedgenesbetweenthetwolibraries.GOannotationrevealedthathighlyrankedgeneswere thoseimplicatedinsmallmoleculemetabolism,cellularcomponentorganisationorbiogenesisatthecellularlevelandfatty acidmetabolism.Accordingtotheresults,weassumedthatlateembryogenesisabundantprotein(LEA),Dicer-like3(DCL3) Xyloglucanendotransglucosylase/hydrolase2(XTH2),Pectinlyase-likesuperfamilyprotein(PPME1),Lipidtransferprotein3 (LTP3),Fattyacidbiosynthesis1(FAB1)andFattyaciddesaturase5(FAD5)mighthaverelationshipswiththepistilabortion inJapaneseapricot.Theexpressionpatternsof36differentiallyexpressedgeneswereconfirmedbyreal-time(RT)-PCR.This is the first report of the Illumina RNA-seq technique being used for the analysis of differentially-expressed gene profiles related to pistil abortion that both computationally and experimentally provides valuable information for the further functional characterisation ofgenes associatedwith pistil developmentinwoody plants. Citation:ShiT,GaoZ,WangL,ZhangZ,ZhuangW,etal.(2012)IdentificationofDifferentially-ExpressedGenesAssociatedwithPistilAbortioninJapanese ApricotbyGenome-WideTranscriptionalAnalysis.PLoSONE7(10):e47810.doi:10.1371/journal.pone.0047810 Editor:ChristianScho¨nbach,KyushuInstituteofTechnology,Japan ReceivedJune19,2012;AcceptedSeptember17,2012;PublishedOctober16,2012 Copyright:(cid:2)2012Shietal.Thisisanopen-accessarticledistributedunderthetermsoftheCreativeCommonsAttributionLicense,whichpermitsunrestricted use,distribution,andreproductioninanymedium,providedtheoriginalauthorandsourcearecredited. Funding:SpecializedFundfortheBasicResearchOperatingexpensesProgramofCentralCollege2012,theNationalScienceFoundationofChina(31101526) andthePriorityAcademicProgramDevelopmentofJiangsuHigherEducationInstitutions(PAPD)forfundingpartofthisstudy.Thefundershadnoroleinstudy design,datacollectionandanalysis,decisiontopublish,orpreparationofthemanuscript. CompetingInterests:Theauthorshavedeclaredthatnocompetinginterestsexist. *E-mail:[email protected] .Theseauthorscontributedequallytothiswork. Introduction between perfect and imperfect flowers [4]. In addition, morpho- logicalresearchindicatedthatduringthefirstandsecondtendays Japanese apricot (Prunus mume Sieb. et Zucc) belongs to the of December, flower buds of the ‘Daqiandi’ cultivar did not Rosaceaefamilyoffruitsandisanimportanteconomicfruitcropin continue to elongate, instead the pistil differentiation stagnated ChinaandJapan[1].Owingtoitshighnutritionalvalue,thefruit and gradually disintegrated, which was the key stage of pistil has not only been used in the preparation of preserved fruit and abortion of the ‘Daqiandi’ cultivar. The factors leading to the wine,butcanalsobeusedasadietingredient[1,2].However,the selectiveabortionofpistilsmayrelatetocatabolismofmacromol- phenomenonofimperfectflowerswidelyoccursandhasseriously ecule nutrients in the flower bud [6]. However, the molecular affected the production yield [3]. The imperfect flowers are mechanism involved in pistil abortion remains unknown for characterisedbyeitherpistilsbelowthestamens,witheredpistilsor Japanese apricot. an absence of pistils, and such flowers fail to bear fruit [4]. Inmostfloralplants,floralorgansplayasignificantroleinplant Comparative proteomic analysis has been performed for perfect sexualreproduction,butonlyafewoftheflowersandovulesthat and imperfect flowers and the different proteins have been are initiated actually give rise to mature seeds and fruits [7]. analysed in both perfect and imperfect flowers for the different Several different mechanisms have been proposed to explain the stages of young bud, mature bud and blossom flower; moreover, phenomenon of female sterility, including pistil abortion. Female glucosemetabolism,starchmetabolismandphotosynthesisrelated sterility is thought to be triggered by environmental and to pistil abortion were found [5]. More recently, real-time nutritional conditions [8,9], low sink strength [10,11], the quantitative reverse transcription polymerase chain reactions and influence of pathogens [12], the occurrence of sporophytic or in situ hybridisation have shown that PmAG mRNA was highly gametophytic mutations [13], ABCDE model and other related expressedinthesepals,carpelandstamens,andaweaksignalwas genes[14–16]andphytohermone[17–20].Morphologicalstudies detectedintheseedandnutlet.Noexpressionwasdetectedinthe have shown that pistil development of staminate flowers in the leavesorpetals,butnosignificantdifferentialexpressionwasfound PLOSONE | www.plosone.org 1 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot olive is interrupted after differentiation of the megaspore mother Results cell. At that stage, no starch was observed in the pistils of the staminate flowers;theplastids hadfewthylakoid membranesand Statistics of tag sequencing grana and the staminate flowers appeared very similar to To identify differentially-expressed genes involved in the pistil proplastids [10]. In Arabidopsis, heat-stress reduced the total development of flowers in Japanese apricot, we used Illumina number of ovules and increased ovule abortion [21]. Early ovule sequencing on DGE from the perfect (PF) and imperfect (IF) degeneration was also caused by high temperatures in sweet flower buds. A total of 3,476,249 and 3,580,677 tags were cherry,andovuledevelopmentwasregulatedbygibberellin(GA) obtained from the PF and IF flower bud libraries, respectively insweetcherryflowers[9].GAsuppressedthedevelopmentofthe (Table1).Toincreasetherobustnessoftheapproach,single-copy embryo sacandshortened itslongevityin grapes [20]. tagsinthetwolibraries(141,270inthePFand142,287intheIF Next-generation high-throughput sequencing technologies pro- library) were excluded from further analysis (Figure 1). After vide a powerful strategy to identify genome-wide expression. discarding the low quality tags (tags containing ‘N’, adaptor Genome-wide expression analyses are essential tools for elucidat- sequences and copy number ,2), 3,331,468 and 3,434,800 tags (clean tags) remained in the PF and IF libraries, from which ing molecular function. Recent studies have highlighted the 129,933 (PF) and 126,485 (IF) distinct tags were obtained significance of high-throughput expression data, particularly with (Figure 1). There were 3,448 more distinct tags in the PF than the integration of large, diverse data sets, in constructing in the IF library, possibly representing genes related to pistil biochemical and regulatory networks in silico [22–25]. Digital development. The percentage of distinct tags rapidly declined as gene expression tag profiling (DGE) is a revolutionary approach copynumberincreased,indicatingthatonlyasmallportionofthe for expression analysis [26,27]. Driven by Solexa/Illumina transcripts were expressed at a high level under the conditions technology, DGE creates genome-wide expression profiles by tested. sequencing. This method combines the sequencing serial analysis The saturation of the library was determined by the identifi- of gene expression (SAGE) principle with the sequencing cationofuniquetags.Sequencingwasconsideredtohavereached technology for generating a digital output proportional to the saturation when no new unique tags were detected. The results number of transcripts per mRNA [28]. The benefit of not shown in Figure 2 indicate that the PF and IF libraries were requiring pre-synthesised oligonucleotide probes (as in micro- sequenced to saturation, producing a full representation of the arrays)allowsthedirectenumerationoftranscripts,whichishighly transcriptsintheconditionstested.Inbothlibraries,fewerunique replicable, accurate and comparable across experiments [29,30]. tags were identified as the number of sequencing tags increased, In addition, the quantification of weakly expressed genes can be reachingaplateaushortlyafter1Mtagsweresequenced.Nonew performed,whichcannotbeassessedusingmicroarrays[31].DGE unique tags were identified as the total tag number approached also offers researchers a global orthogonal hybridisation array 3 MinthePFlibrary and2.5M intheIFlibrary. validationmethod,withalmostunlimiteddynamicrange,provid- The distribution of the clean tag copy number is shown in ingatuneabledepthofcoverageforraretranscriptdiscoveryand figure 3. The copy number of clean tags between 2 and 5 was quantification.Forexample,toexplorethemolecularmechanism 208,111,between6and10was153,194,between11and20was of plant developmental-stage transition and cell-fate determina- 213,051, between 21 and 50 was 396,739, between 51 and 100 tion, DGE analysis was undertaken of sequential developmental was 382,603, and .100 was 1,977,770 in the PF library. In time-points and individual tissue types in the model moss contrast, the copy number of distinct clean tags was mostly Physcomitrella patens [24], which was chosen because of the short distributedbetween2and5,with55.45%ofthetotalcleantagsin life-cycleandrelativestructuralsimplicityofthisplant.Tovalidate the PF library (Figure 3). In the IF library, the copy number of gene expression in the models for trichome development in clean tags between 2 and 5 was 199,910, between 6 and 10 was soybean, DGE analysis and RNA-Seq were used to compare the 147,600,between11and20was205,594,between21and50was transcriptional profiles in wild-type and glabrous soybean lines 395,033, between 51 and 100 was 392,318, and .100 was [32]. Early developing cotton fibre was analysed by deep 2,094,345. Similar to the PF library, the copy number of distinct sequencing, and differential expressions of genes in a fuzzless/ cleantagswasmostlydistributedbetween2and5,with54.88%of lintlessmutantwererevealed[33].DGEsignatureswerealsoused thetotal clean tagsin theIFlibrary(Figure 3). to study the maize RA3 gene [22] and the development of brace root [34]. In addition, Solexa/Illumina technology was used to Annotation analysis of the unique tags analyse gene expression during female flower development in Thedistincttagswerecomparedagainstthegenomeandgene cucumber [35]. Overall, the DGE approach has provided more sequences of peach using BLASTn. Tags with a complete match valuable tools for qualitative and quantitative gene expression oronebase-pairmismatchwereconsideredfurther.Theresultsin analysis than theprevious microarray-based assays [26]. Table1showthataproportionoftags(26.70%inthePFlibrary Here, we used the DGE method to perform a deep and27.52%intheIFlibrary)matchedtothepeachgenome,but transcriptome analysis of pistil abortion in Japanese apricot. 64,599 (49.72% of unique tags) and 58,309 (46.10% of unique Althoughtranscriptomeanalyseshavebeenextensivelystudiedin tags) in the PF and IF libraries matched to 17,056 (59.45%) and the past years, for example, 454-pyrosequencing of the transcrip- 16,386 (57.12%) peach genes. Further analysis revealed that tome was used in the research of dormant stages in Japanese 57,871 unique tags (44.54%) in the PF library and 52,144 apricot[36],asystematicstudyofdifferentialgeneexpressionhas (41.23%) inthe IFlibrary matched toonlyonegene sequence in not been carried out on Japanese apricot. To investigate the the peach genome (Table 1 and Figure 4), including perfect differentially-expressed genes related to the pistil development of matchingtogenesandwitha1bpmismatch.Thesedataindicate Japaneseapricot,high-throughputsequencingtechnology(Solexa) that approximately 50% of the transcripts predicted in Japanese was employedtosurveythegeneexpression profilesfromperfect apricot are expressed in the perfect or imperfect flowers, with and imperfectJapanese apricot flowerbuds. moretranscriptspresentintheperfectsample.Figure4showsthat sense regulation, with clean sequencing tags perfectly mapped to thesensegenebeing22.84%(antisensewas11.14%)and21.39% PLOSONE | www.plosone.org 2 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Figure1.Distributionoftagexpression.LeftisPFandrightisIF.Totalcleantagsrepresentthesumofallcleantagnumbers;distinctcleantags representalltypesofcleantags. doi:10.1371/journal.pone.0047810.g001 (antisense was 9.86%) in PF and IF, respectively, was the main Pathway enrichment analysis for DEGs regulated model. AQ-valueof#0.05definedthosegenesthatweresignificantly differentially expressed (enriched). 227 differentially expressed Gene ontology functional enrichment analysis of genes associated with 12 metabolic and signal transduction differentially-expressed genes (DEGs) pathways were found (Figure 6). The pathways with the most Using the P-value #0.05 as the threshold value, 333 differen- unique genes were metabolic pathways (250 genes), cellular tiallyexpressedgenesthatcouldbecategorisedinto14functional process (66 genes) and genetic information processing (20 genes). groups were found (Figure 5), which included four cellular Webelievethatthesepathwaysaresignificantinthepistilabortion components,fourmolecularfunctionsandsixbiologicalprocesses. ofJapaneseapricot,inparticularmetabolicpathwaysandcellular The four component categories were as follows: anchored to processes. In our study, metabolic pathways (ko01100) are large membrane(9),ribosome(16),ATPasecomplex(10)andorganelle complexes comprising several metabolic patterns, including: the part (96). Based on molecular function, the genes were finally biosynthesis of secondary metabolites (ko01110, 66 genes); classified into four categories: ammonia ligase activity (3), acid- flavonoid biosynthesis (ko00941, 15); oxidative phosphorylation ammonia (or amide) ligase activity (3), Rho GTPase activator (ko00190, 10 genes); arginine and proline metabolism (ko00330, activity(2)andtransferaseactivity(37).Additionally,sixbiological eight genes); galactose metabolism (ko00052, seven genes); the processes were identified: nitrogen cycle metabolism (3), proton biosynthesis of unsaturated fatty acids (ko01040, seven genes); transport (6), fatty acid metabolism (20), cellular component pyruvatemetabolism(ko00620,sevengenes);nitrogenmetabolism organisation or biogenesis at the cellular level (44), glutamine (ko00910, six genes) and alanine, aspartate and glutamate metabolism (3) and small molecule metabolism (81). The genes metabolism (ko00330, six genes). Cellular processes included involved in small molecule metabolism [GO: 0044281] were the phagosome (ko04145, 14 genes) and endocytosis (ko04144, nine most significantly enriched in comparison to the other five genes). Genetic information processing only included protein biologicalprocesses.Forty-fourdifferentiallyexpressedgeneswere processing intheendoplasmic reticulum (ko04141,20genes). involved in the cellular component organisation or biogenesis at the cellular level [GO: 0071841], which is carried out at the Comparison of gene expression between the two cellular level and results in the biosynthesis of constituent libraries macromolecules, assembly, arrangement of constituent parts, or Differences in thetag frequencies that appeared in thePFand disassembly of a cellular component. Among the significantly IF libraries were used to estimate gene expression levels in enrichedtranscriptswere20DEGsassociatedwiththeregulation responsetopistilabortion.Thetranscriptsdetectedwithatleasta of fatty acid metabolism [GO: 0006631], which includes the two-folddifferencebetweenthetwolibrariesareshowninFigure7 chemical reactions and pathways involving fatty acids and (FDR,0.001).Thereddots(468)andgreendots(221)represent aliphaticmonocarboxylicacidsliberatedfromnaturallyoccurring transcripts with a higher or lower abundance of more than two- fats andoils byhydrolysis. fold than in the PF library, respectively. The blue dots represent PLOSONE | www.plosone.org 3 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Table1. StatisticsofDGE sequencing. Summary PF IF RawData Total 3,476,249 3,580,677 RawData DistinctTag 274,206 271,884 CleanTag Totalnumber 3,331,468 3,434,800 CleanTag DistinctTagnumber 129,933 126,485 AllTagMappingtoGene Totalnumber 1783091 1703889 AllTagMappingtoGene Total%ofcleantag 53.52% 49.61% AllTagMappingtoGene DistinctTagnumber 64599 58309 AllTagMappingtoGene DistinctTag%ofcleantag 49.72% 46.10% UnambiguousTagMappingtoGene Totalnumber 1564689 1496735 UnambiguousTagMappingtoGene Total%ofcleantag 46.97% 43.58% UnambiguousTagMappingtoGene DistinctTagnumber 57871 52144 UnambiguousTagMappingtoGene DistinctTag%ofcleantag 44.54% 41.23% AllTag-mappedGenes number 17056 16386 AllTag-mappedGenes %ofrefgenes 59.45% 57.12% UnambiguousTag-mappedGenes number 14106 13486 UnambiguousTag-mappedGenes %ofrefgenes 49.17% 47.01% MappingtoGenome Totalnumber 776068 849241 MappingtoGenome Total%ofcleantag 23.30% 24.72% MappingtoGenome DistinctTagnumber 34698 34806 MappingtoGenome DistinctTag%ofcleantag 26.70% 27.52% UnknownTag Totalnumber 772309 881670 UnknownTag Total%ofcleantag 23.18% 25.67% UnknownTag DistinctTagnumber 30636 33370 UnknownTag DistinctTag%ofcleantag 23.58% 26.38% doi:10.1371/journal.pone.0047810.t001 transcripts that differed less than two-fold between the two five-fold in the IF library, while the expression level of 99.3% libraries, which were arbitrarily designated as ‘‘no difference in unique tags was within the five-fold difference between the two expression’’. The differentially-expressed genes with five-fold or samples. greater differences in accumulation are shown in Figure 8 and Of DEGs with differences greater than five-fold (Table 2), 11 Table2.About0.23%totaluniquetagsincreasedbyatleastfive- genes were present at higher levels in the IF library, which were fold,andabout0.47%totaluniquetagsweredecreasedbyatleast associatedwithdefence(2),metabolism(6),signaltransduction(2) Figure2.Saturationevaluationofdifferentialexpression.TheleftfigureisPFandtherightfigureisIF. doi:10.1371/journal.pone.0047810.g002 PLOSONE | www.plosone.org 4 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Figure3.Distributionofcleantagcopynumber.LeftisPFandrightisIF.Totalcleantagsrepresentthesumofallcleantagnumbers;distinct cleantagsrepresentalltypesofcleantags. doi:10.1371/journal.pone.0047810.g003 Figure4.Alignmentresultsofthecleantags.Thefigureexhibitsthealignmentstatisticsofthetagcopynumberandthetagtype.Note:1PM (senseorantisense):perfectmatchtogene(senseorantisense);1tag-.1gene:matchtoonegene;1tag-.ngene:matchtomorethanonegene; 1MM (sense or antisense): match to gene (sense or antisense) with 1bp mismatch; PM Genome 1 tag-.1 position: perfect match to genome sequencewithonebesthit;PMGenome1tag-.nposition:perfectmatchtogenomesequencewithmultiplebesthits;1MMGenome:matchto genomesequencewith1bpmismatch;UnknownTag:nomatchtogene(senseandanti-sense)andgenomesequence. doi:10.1371/journal.pone.0047810.g004 PLOSONE | www.plosone.org 5 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Figure5.HistogramshowingtheGeneOntologyfunctionalenrichmentofDEGs. doi:10.1371/journal.pone.0047810.g005 and transport (1). The greatest differences between IF and PF Theactualmeltingcurvesof36genesareshowedintheTableS2. DEGsweretheDCL3(dicer-like3)geneandthevacuolarATPase The expression level of each gene in the perfect and imperfect subunit F family protein gene, both of which were present 8.95- flower buds was compared with its abundance from the fold higherin theIFlibrarythan inthePFlibrary. sequencing data of DGE sequencing (Figure 9). The apparent Forty-nine DEGs were less abundant in the IF library. Those discrepancies with respect to ratio can be attributed to the presentfive-foldormoreinthePFlibraryarealsolistedinTable2, essentiallydifferentalgorithmsdeterminedbythetwotechniques. inwhich43geneswere classified asdefence (5),development (2), In the analysis of gene profiles, the DGE method generates metabolism (27), signal transduction (3), transcription (2) and absolute ratherthan relative expression measurements. However, transport (4). The highest DEG was the FAD5 (fatty acid theresultsshowedthatexpressionofthese36geneswasconsistent desaturase 5) gene, which was present at levels 14.82-fold higher between the qRT-PCR and the DGE analyses. Transcripts from than PFlevels. highly abundant Illumina tags appeared at the expected high expression level in the quantitative PCR analyses. Additionally, Real-time RT-PCR analysis high-foldchangeswereobservedforgenesthatshowedlowcopy- ToconfirmthereliabilityofIlluminasequencingtechnology,36 numbersinthePFlibrarybuthighabundancesintheIFlibrary. genes were randomly selected for quantitative RT-PCR assays. For example, CPK13 (calcium-dependent protein kinase 13; Figure6.Histogramillustratingpathwayenrichmentanalyses. doi:10.1371/journal.pone.0047810.g006 PLOSONE | www.plosone.org 6 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Figure8.Differentially-expressedtagsintheIFtissuelibrary. The x-axis represents fold-change of differentially expressed unique tags in the imperfect library. The y-axis represents the number of Figure 7. Comparison of gene expression levels between the uniquetags(log10).Differentiallyaccumulatinguniquetagswithafive- twolibraries.Forcomparinggeneexpressionlevelsbetweenthetwo folddifferencebetweenlibrariesareshownintheredregion(99.30%). libraries, each library was normalised to 1 million tags. Red dots Theblue(0.23%)andgreen(0.47%)regionsrepresentuniquetagsthat representtranscriptsmoreprevalentintheinfectedleaflibrary,green are up- and down-regulated more than five-fold in the IF library, dotsshowthosepresentatalowerfrequencyintheinfectedtissueand respectively. blue dots indicate transcripts that did not change significantly. The doi:10.1371/journal.pone.0047810.g008 parametersFDR,0.001andlog2ratio$1wereusedasthethreshold tojudgethesignificanceofgeneexpressiondifference. thosedetectedbytheSolexa-basedsequencingmethod,thetrends doi:10.1371/journal.pone.0047810.g007 of up- and down-regulation were similar. The lower expression level detected by RT-PCR could be due to the difference in ppa004141m) showedno expression in the PFlibrary, whereas it sensitivity between the two technologies [37]. Solexa sequencing was detected at levels of 8.86-fold in the IF library. It was has been documented to be more sensitive for the estimation of significantly up-regulated by more than 15-fold in the RT-PCR gene expression, especially for low-abundance transcripts, com- analysis. Similarly, DCL3 (ppa021659m) was induced by more pared tomicroarrays and real-timeRT-PCR [38]. than 5-fold. In addition, FAD5 (ppa027208m) showed no 60 DEGs were found to have differences greater than five-fold expression in the IF library, while it was detected 14.26-fold in (Table 2), 54 of which were associated with metabolism (33), the IF library, and was significantly down-regulated in the RT- defence (7), signal transduction (5), transport (5), development (2) PCR analysis. These results confirmed the reliability of the and transcription (2). These transcripts possibly encode genes transcriptome analysis. responding for pistil abortion or programmed cell death (PCD), whichwerebroadlygroupedintothefollowingcategoriesbasedon Discussion theirknown rolesinother plant systems: Illuminasequencingtechnology,ahigh-throughputsequencing Defence response genes approach, was utilised to estimate gene expression in libraries There were two up-regulated genes and five down-regulated prepared from perfect and imperfect flower bud tissues. The genesinthedefenceresponsegroup.Amongthedefenceresponse results (Figure 2) provide estimates of gene expression as genes, CPK13 [39], CPR30 F-box and associated interaction determined by the frequency that any given tag (representing a domains-containing protein [40], ENODL5 (early nodulin-like transcript) is sequenced. The data indicate that there is sufficient protein 5) [41], FRO2 (ferric reduction oxidase 2) [42,43], and coverage depth to reach saturation, i.e. there is a complete MAPKKK15 (mitogen-activated protein kinase kinase kinase 15) assessment of all transcripts present in the libraries. This study [44] have been widely studied in plant pathogen resistance. The demonstrated differential transcript abundance and regulation in lateembryogenesisabundantprotein(LEA)familyproteinshowed the development of pistils in Japanese apricot between perfect lessexpressionintheimperfectflowerbuds,whichwasconsistent flower buds and imperfect flower buds. The phenomenon of with previous research on the comparative proteomic analysis of imperfect flowers widely occurs and seriously affects the produc- pistil abortion in Japanese apricot and belonged to the group of tionyield;thereforeitisnecessarytoidentifythegenesrelatedto down-regulated genes [45]. This was similar to many other cold the molecular mechanism of pistil abortion in the Japanese resistant proteins [46], a number of which enhance freezing apricot.Theseresultsrepresentthefirstlarge-scaleinvestigationof tolerancebyputativelystabilisingmembranes,orincreasinglevels geneexpressioninthepistilabortionanalysisofJapaneseapricot. ofprotectiveosmolytes[8].Astudyonchickpeasshowedreduced 17,056 putative genes were identified among the Illumina ovule size, reduced ovule viability, missing embryo sacs, and sequencing tags for the PF library and 16,386 were identified for impairedpistil functionintemperature-sensitive cultivars forcold theIFlibrary.Thesteady-statetranscriptlevelforasetofselected stress [47]. In addition, LEA proteins contain hydrophilic side- genes was confirmed by real-time (RT)-PCR. Although the chains thought to interact with and protect hydrophilic proteins differences in gene expression did not match the magnitude of duringdesiccationbycausingproteinaggregation[48,49].Water PLOSONE | www.plosone.org 7 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Table2. Listofdifferentially expressed genes changed byfive-foldormore in theIFlibrary. Gene log2Ratio(IF/PF) Description Up-regulatedgenes Defence ppa004141m 8.86 Calcium-dependentproteinkinase13(CPK13) ppa018301m 8.86 CPR30F-boxandassociatedinteractiondomains-containingprotein Metabolism ppa000615m 8.86 EMB3011RNAhelicasefamilyprotein ppa010131m 8.67 Peptidyl-tRNAhydrolasefamilyprotein ppa006743m 8.67 AGD2Pyridoxalphosphate(PLP)-dependenttransferasessuperfamilyprotein ppa006182m 8.86 Proteinkinasesuperfamilyprotein ppa021659m 8.95 Dicer-like3(DCL3) ppa005799m 8.77 Pre-mRNA-splicingfactorCWC26 Signaltransduction ppa012743m 8.77 SLY2F-boxfamilyprotein ppa003105m 8.67 Leucine-richrepeatproteinkinasefamilyprotein Transport ppa013294m 8.95 VacuolarATPasesubunitFfamilyprotein Down-regulatedgenes Defence ppa002249m 28.61 Early-responsivetodehydrationstressprotein(ERD4) ppa016718m 28.99 ENODL5earlynodulin-likeprotein5 ppa002203m 29.37 FRO2ferricreductionoxidase2 ppa006485m 29.61 Mitogen-activatedproteinkinasekinasekinase15(MAPKKK15) ppa021261m 210.04 Lateembryogenesisabundantprotein(LEA)familyprotein Development ppa001970m 28.71 Glutamine-richprotein23(GRP23) ppa016920m 28.99 BTB/POZdomain-containingprotein Metabolism ppa023612m 25.96 Lipidtransferprotein3(LTP3) ppa011478m 27.11 Plantinvertase/pectinmethylesteraseinhibitorsuperfamilyprotein ppa023515m 27.18 Cysteineproteinasessuperfamilyprotein ppa009726m 28.61 ABI-1-like1(ABIL1) ppa025960m 28.61 BEN1NAD(P)-bindingRossmann-foldsuperfamilyprotein ppa015204m 28.61 SYDP-loopcontainingnucleosidetriphosphatehydrolasessuperfamilyprotein ppa002676m 28.61 Pentatricopeptiderepeat(PPR)superfamilyprotein ppa005209m 28.81 XF1FAD/NAD(P)-bindingoxidoreductasefamilyprotein ppa026851m 28.81 Subtilisin-likeserineendopeptidasefamilyprotein ppa007640m 28.91 IRX9Nucleotide-diphospho-sugartransferasessuperfamilyprotein ppa003553m 28.91 P-loopcontainingnucleosidetriphosphatehydrolasessuperfamilyprotein ppa022113m 28.91 3-ketoacyl-CoAsynthase7(KCS7) ppb019226m 29.08 Plantinvertase/pectinmethylesteraseinhibitorsuperfamilyprotein ppa007503m 29.15 PLC-likephosphodiesterasessuperfamilyprotein ppa017270m 29.3 Alpha/beta-Hydrolasessuperfamilyprotein ppa005976m 29.55 Pectinlyase-likesuperfamilyprotein(PPME1) ppa018639m 29.61 CytochromeP450,family735,subfamilyA,polypeptide1(CYP735A1) ppa013439m 29.76 RING/U-boxsuperfamilyprotein ppa004479m 29.95 Fattyacidbiosynthesis1(FAB1) ppa020149m 210.16 Alphadioxygenase ppa005749m 210.55 Purpleacidphosphatase22(PAP22) ppa004364m 210.55 Non-specificphospholipaseC3(NPC3) PLOSONE | www.plosone.org 8 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot Table2. Cont. Gene log2Ratio(IF/PF) Description ppa019741m 210.97 Xyloglucanendotransglucosylase/hydrolase2(XTH2) ppa025833m 211.32 Alpha/beta-Hydrolasessuperfamilyprotein ppa020405m 211.33 GDSL-likeLipase/Acylhydrolasesuperfamilyprotein ppa027208m 214.26 Fattyaciddesaturase5(FAD5) ppa016543m 214.82 Fattyaciddesaturase5(FAD5) Signaltransduction ppa015093m 28.91 CyclinD6 ppa016219m 28.91 Stigma-specificStig1familyprotein ppa012463m 29.61 PollenOlee1allergenandextensinfamilyprotein Transcription ppa011751m 28.61 Mybdomainprotein24(MYB24) ppa008450m 29.23 Mybdomainprotein73(MYB73) Transport ppa004487m 28.61 MATEeffluxfamilyprotein ppa010364m 28.61 TIP1;3tonoplastintrinsicprotein1;3 ppa000945m 28.81 HA9H(+)2ATPase9 ppa006913m 29.61 AAC2ADP/ATPcarrier2 Variousfunctions ppa014641m 28.71 Plantproteinofunknownfunction(DUF868) ppa020792m 28.71 ARMrepeatsuperfamilyprotein ppa022037m 28.81 Uncharacterizedproteinfamily(UPF0016) ppa014616m 28.81 Proteinofunknownfunction(DUF1278) ppa021534m 210.16 Proteinofunknownfunction(DUF679) ppa008861m 210.33 Familyofunknownfunction(DUF716) doi:10.1371/journal.pone.0047810.t002 Figure 9. Digital gene expression tag profiling and quantitative real-time PCR analysis of the expression of randomly selected genes.Allreal-timePCRreactionswererepeatedthreetimesandthedataarepresentedasthemean6SD.Thex-axisindicatesthedifferentgenes. They-axisshowstheexpressionlevels:theleftshowstherelativeexpressionlevelbyqRT-PCRandtherightshowstagnumberpermilliontagsby DGE. doi:10.1371/journal.pone.0047810.g009 PLOSONE | www.plosone.org 9 October2012 | Volume 7 | Issue 10 | e47810 TranscriptionalAnalysisofJapaneseApricot stressimposedduringthedevelopmentofflowersisamajorfactor istypicallydepositedintotheapoplasminahighlymethylesterified increasing the rate of abortion, and long-term or frequent water condition. Pectin methylesterase in the apoplasm catalyses the deficits during this period might decrease yield [50,51]. In our demethylesterificationoftheseHGAs,exposingcarboxylresidues, study, LEA protein expression in perfect flower buds was higher which can be cross-linked by calcium [70]. These changes than that in imperfect flower buds. Therefore, we speculate the significantly affect the rheological properties of the cell wall as reduction of this temperature-resistant protein might increase the wellasitsporosityandionicstatus.Itfollowsthatthetightcontrol ratio of pistil abortion. There were both up-regulated and down- ofPMEactivity,bothspatiallyandtemporally,occupiesapivotal regulated genes in this category. Temperature and water stress position in the control of cell-wall growth and development [71]. response-related proteins were associated with hot or cold An important post-transcriptional mechanism of regulation of temperature stresses and may also play important roles in pistil theseenzymesisrepresentedbyproteinaceousinhibitors[72].Our abortion inJapanese apricot. previousresearchfoundthatthepistilofimperfectflowersstopped differentiation in early December and finally disintegrated, while Genes involved in RNA metabolism the pistil of perfect flowers continued to differentiate and In our study, there were six up-regulated genes and down- developed perfectly (Shi et al., 2011). This phenomenon might regulatedgenesinvolvedindifferentkindsofmetabolism,suchas result fromthestrain formation ofcellwalls. RNA, protein,pectinandfatty acidmetabolism. FAB1[73]andFAD5[74]areinvolvedinunsaturatedfattyacid The EMB3011 RNA helicase family protein [52], peptidyl- biosynthesis.Unsaturatedfattyacidplaysaveryimportantrolein tRNA hydrolase family protein [53], DCL3 [54,55] and pre- lipidbiosynthesisandcellwallorganisation.Thesetwogeneswere mRNA-splicing factor CWC26 [56,57] are involved in RNA down-regulatedinpistilabortion,andtheirexpressionwashigher processing,includingsmallRNAmetabolism.DCL3produces24- in the perfect flower buds than in the imperfect flower buds. nt small interfering RNAs (siRNAs) at heterochromatic loci [58]. Therefore,wehypothesisethattheformingofanimperfectflower PlantscanutilisesiRNAstoguidedenovoDNAmethyltransferases has a crucialrelationship withthecell-wall organisation. fortheestablishmentofsequence-specificDNAmethylation[59], which has several functions in angiosperms, such as transposon Materials and Methods silencing and transcriptional gene silencing (TGS) [60]. In Arabidopsis thaliana, double mutants between dicer-like 1 and dicer- Plant materials like 3 exhibit a delay in flowering that is caused by increased The ratio of imperfect flowers of Japanese apricot cultivars expression of the floral repressor FLOWERING LOCUS C [61]. Daqiandi is about 76%. While the pistil of a perfect flower This delayed-flowering phenotype is similar to that of autono- continues to differentiate and develop perfectly, the pistil of an mous-pathwaymutants,andthefloweringdelaycanbeovercome imperfect flower stops differentiation in early December and byvernalisation[61,62].Infact,smallRNAsplayimportantroles finally disintegrates. We chose two types of flower buds of this in the termination of floral stem cells, especially miR172 and periodfromDaqianditreesgrownintheNationalFieldGenBank miR165/166[63]. We have found that miR319, miR319a, forJapaneseApricot,Nanjing,JiangsuProvince,China.Allofthe miR319e, miR160, miR393, miR394 are significantly differen- sampleswerecollectedandimmediatelyfrozeninliquidnitrogen tially-expressed between perfect and imperfect flower buds, and andstored at 280uC. that most of their targets were transcription factors or F-box proteins[64].Inourstudy,thegenesinvolvedinRNAmetabolism DGE library construction and Illumina sequencing were up-regulated in pistil abortion, and their expression was To construct DGE libraries, total RNA was extracted from higherintheimperfectflowerbudsthanthatintheperfectflower perfect andimperfect flowerbuds using themethod accordingto buds. These data provide clues to the molecular mechanism of Meisel et al. [75]. Library construction was carried out at the pistil abortion regulated by small RNA metabolism in Japanese Beijing Genomics Institute (BGI, Shenzhen, Guangdong, China), apricot. usingIllumina’sDGEtagprofilingtechnology.Themainreagents andsuppliesweretheIlluminaGeneExpressionSamplePrepKit Cell-wall organisation: pectin and fatty acid metabolism and the Solexa Sequencing Chip (flowcell), and the main In this study, we have found many genes related to cell-wall instruments were the Illumina Cluster Station and the Illumina organisation.Peptidyl-tRNAhydrolasehasconnectionstocell-wall HiSeqTM2000System.6mgoftotalRNAwasextracted,oligo(dT) carbohydrates and morphogenesis and belongs to a highly magnetic bead adsorption was used to purify mRNA, and then interconnected core network of G-protein signalling [65]. LTP3 oligo(dT)swereusedasprimerstosynthesisethefirstandsecond- is involved in cutin synthesis during the fibre primary cell wall strandcDNA.The59endsoftagscouldbegeneratedbytwotypes synthesisstage [66]. of endonuclease: NlaIII or DpnII. The bead-bound cDNA was XTHs are cell-wall enzymes that catalyse the cleavage and subsequently digested by the restriction enzyme NlaIII, which molecular grafting of xyloglucan chain functions in the loosening recognisedandcuttheCATGsites.Thefragments(exceptforthe andrearrangementofthecellwall[67,68].Inourpreviousstudy, 39 cDNA fragments) connected to oligo(dT) beads were washed wefoundthat XTH2 expression was higherintheperfectflower awayandtheIlluminaadaptor1wasligatedtothesticky59endof buds than that in the imperfect flower buds [45]. As they are the digested bead-bound cDNA fragments. The junction of involved in the modification of the load-bearing cell-wall Illumina adaptor 1 and the CATG site was the recognition site components, they are believed to be very important in the of MmeI, which is a type of endonuclease with separated regulation of growth and development [69]. Hyodo et al. (2003) recognitionanddigestionsites.Thisenzymecut17bpdownstream showed that XTH9 tends to be expressed strongly in rapidly of the CATG site, producing tags with adaptor 1 ends. After dividing andexpanding tissues in Arabidopsis [68]. removing 39 fragments with magnetic bead precipitation, the Plant invertase/pectin methylesterase inhibitor superfamily Illuminaadaptor2wasligatedtothe39endsoftags,acquiringtags protein and PPME1 pectin lyase-like superfamily protein, two withdifferentadaptorsatbothendstoformataglibrary.After15 down-regulated genes, are involved in pectin metabolism. The cyclesoflinearPCRamplification,105bpfragmentswerepurified homogalacturonan(HGA)fraction,amajorcomponentofpectins, by 6% TBE PAGE gel electrophoresis. After denaturation, the PLOSONE | www.plosone.org 10 October2012 | Volume 7 | Issue 10 | e47810

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The phenomenon of pistil abortion widely occurs in Japanese apricot, and imperfect flowers with pistil abortion Introduction http://www2.sci.u-szeged.hu/ABS/2008/tart08a.html. Lim PO, Lee IC, Kim J, Kim HJ, Ryu JS, et al.
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