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Pearce, Simon and Ferguson, Alison and King, John and Wilson, Zoe A. (2015) FlowerNet: a gene expression correlation metwork for anther and pollen development. Plant Physiology, 167 (4). pp. 1717-1730. ISSN 0032-0889 Access from the University of Nottingham repository: http://eprints.nottingham.ac.uk/29658/3/Plant%20Physiol.-2015-Pearce-1717-30.pdf Copyright and reuse: The Nottingham ePrints service makes this work by researchers of the University of Nottingham available open access under the following conditions. This article is made available under the University of Nottingham End User licence and may be reused according to the conditions of the licence. For more details see: http://eprints.nottingham.ac.uk/end_user_agreement.pdf A note on versions: The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher’s version. Please see the repository url above for details on accessing the published version and note that access may require a subscription. For more information, please contact [email protected] FlowerNet: A Gene Expression Correlation Network for 1[OPEN] Anther and Pollen Development Simon Pearce2, Alison Ferguson2, John King, and Zoe A. Wilson* Division of Plant Crop Sciences (S.P., A.F., Z.A.W.) and Centre for Plant Integrative Biology (S.P., J.K., Z.A.W.), School of Biosciences, University of Nottingham, Sutton Bonington Campus, Loughborough, Leicstershire LE12 5RD, United Kingdom; and School of Mathematical Sciences, University of Nottingham, Nottingham NG7 2RD, United Kingdom (S.P., J.K.) Floralformation,inparticularantherandpollendevelopment,isacomplexbiologicalprocesswithcriticalimportanceforseed setandfortargetedplantbreeding.Manykeytranscriptionfactorsregulatingthisprocesshavebeenidentified;however,their direct role remains largely unknown. Using publicly available gene expression data from Arabidopsis (Arabidopsis thaliana), focusing on those studies that analyze stamen-, pollen-, or flower-specific expression, we generated a network model of the globaltranscriptionalinteractions(FlowerNet).FlowerNethighlightsclustersofgenesthataretranscriptionallycoregulatedand therefore likely to have interacting roles. Focusing on four clusters, and using a number of data sets not included in the generation of FlowerNet, we show that there is a close correlation in how the genes are expressed across a variety of conditions, including male-sterile mutants. This highlights the important role that FlowerNet can play in identifying new players in anther and pollen development. However, due to the use of general floral expression data in FlowerNet, it also hasbroadapplicationinthecharacterizationofgenesassociatedwithallaspectsoffloraldevelopmentandreproduction.Toaid the dissection of genes of interest, we have made FlowerNet available as a community resource (http://www.cpib.ac.uk/ anther). For this resource, we also have generated plots showing anther/flower expression from a variety of experiments: Theseare normalizedtogetherwherepossibletoallowfurther dissectionoftheresource. Anther and pollen development is a complex biolog- aspects of anther development have been discovered. ical process that is indispensable for the generation of APETALA3 (AP3; Jack et al., 1994), SPOROCYTELESS/ male gametophytes and the production of the next gen- NOZZLE (SPL/NZZ; Liu et al., 2009), and EXCESS eration in flowering plants. This development includes a MICROSPOROCYTES1 (Zhao et al., 2002) have impor- series of crucial events that require interactions between tant roles in early anther development and differentia- gametophytic and sporophytic genes in a cooperative tion, while ABORTED MICROSPORE (AMS; Sorensen fashion (Goldberg et al., 1993; Ma, 2005). The mature et al., 2003; Xu et al., 2010), DEFECTIVE IN TAPETAL anthercontainsfourlobes,eachofwhichcontainsmeiotic DEVELOPMENT AND FUNCTION1 (Zhu et al., 2008), cells surrounded by four somatic cell layers, with the DYSFUNCTIONAL TAPETUM1 (DYT1; Zhang et al., sporophytictapetumplayinganimportantroleinpollen 2006), MALE STERILITY1 (MS1; Wilson et al., 2001; grain development (Goldberg et al., 1993). The tapetum Alves-Ferreira et al., 2007; Ito et al., 2007; Yang et al., serves as a nutritive tissue, providing metabolites, nu- 2007a), MYB33/MYB65 (Millar and Gubler, 2005), and trients, and cell wall precursors for the development of MYB80/MYB103 (Higginson et al., 2003; Zhang et al., pollen grains. 2007; Zhu et al., 2010) are involved in tapetum and The use of classical genetic screens has uncovered a pollen wall development (Wilson and Zhang, 2009). largenumberofgenesinvolvedinantherdevelopment MYB26(Steiner-Langeetal.,2003;Yangetal.,2007b) andintheproductionofviablepollen.Forexample,in and RECEPTOR-LIKE PROTEIN KINASE2 (RPK2; Arabidopsis (Arabidopsis thaliana), a number of genes Mizuno et al., 2007a) are involved in the later stages of encoding putative transcription factors involved in all anther dehiscence and pollen release. Although a num- ber of the main regulators are known and a large number of genesdirectly involved inanther and pollen 1Thisworkwassupportedbythe BiotechnologyandBiological development have been identified, themeans by which SciencesResearchCouncil(grantno.BB/J001295/1),theRoyalSoci- theyinteractandfunctioninthisprocessremainlargely ety,andtheWolfsonFoundation. uncharacterized. 2Theseauthorscontributedequallytothearticle. Inthiswork,wetrytoaddressthisknowledgegapby *[email protected]. uncovering groups of genes involved in floral develop- Theauthorresponsiblefordistributionofmaterialsintegraltothe ment, specifically focusing on anther and pollen devel- findingspresented in this article in accordancewith the policy de- opment,throughthecreationofacoexpressionnetwork. scribed in the Instructions for Authors (www.plantphysiol.org) is: This coexpression network connects genes expressed ZoeA.Wilson([email protected]). [OPEN]Articlescanbeviewedwithoutasubscription. during floral development by their transcriptional reg- www.plantphysiol.org/cgi/doi/10.1104/pp.114.253807 ulation.Coexpressedgeneshaveanincreasedlikelihood Plant Physiology!, April 2015, Vol. 167, pp. 1717–1730, www.plantphysiol.org "2014AmericanSociety ofPlant Biologists. All RightsReserved. 1717 DDDooowwwnnnllloooaaadddeeeddd fffrrrooommm wwwwwwwww...ppplllaaannntttppphhhyyysssiiiooolll...ooorrrggg ooonnn AAAuuuggguuusssttt 222555,,, 222000111555 --- PPPuuubbbllliiissshhheeeddd bbbyyy wwwwwwwww...ppplllaaannnttt...ooorrrggg CCCooopppyyyrrriiiggghhhttt ©©© 222000111555 AAAmmmeeerrriiicccaaannn SSSoooccciiieeetttyyy ooofff PPPlllaaannnttt BBBiiiooolllooogggiiissstttsss... AAAllllll rrriiiggghhhtttsss rrreeessseeerrrvvveeeddd... Pearce et al. of being involved in the same developmental or bio- sterile phenotypes linked to a failure of pollen forma- chemical pathways; therefore, the correlation of gene tion or dehiscence. The Affymetrix microarrays were expressionisapowerfulapproachtoanalyzelargedata renormalized together (see “Materials and Methods”) sets to identify genes involved in the same functional to make the data comparable between samples. pathway (Peng and Weselake, 2011; Wang et al., 2012). A number of additional highly relevant data sets This approach has been successfully applied to two were also available, but since they utilize different state-dependentsetsofinteractionsassociatedwithseed transcriptomic platforms, they cannot be integrated dormancy or germination, with good correlation of easily with the Affymetrix array data sets. Alves- transcriptionalregulatorsofknownseeddormancyand Ferreira et al. (2007) used Agilent two-color micro- germination regulatory genes (Bassel et al., 2011). arrays to analyze the effect of MS1 (At5g22260) on With the recent advances in postgenomic technolo- gene expression, comparing buds between the wild gies, a large number of genome-wide transcriptomic type and ms1 mutants. In this experiment, the first datasetshavebeengenerated,oftentolookatspecific sample consists of stage 13 flowers, with subsequent changes such as a transcription factor mutant com- samples containing successively younger buds, until pared with a wild type. Deposition of these data sets the seventh sample contains the very earliest buds into publicly accessible online databases enables other and the inflorescence meristem. Xu et al. (2010) used researcherstoanalyzethesecollateddataanduncover anin-house-printedtwo-colormicroarraytocompare novelinformation,whichmaybetangentialtothegoal wild-typeandamsbudsatpollenmothercellmeiosis, of the original experiment. In this study, we used pollen mitosis I, bicellular pollen, and pollen mitosis publicly available gene expression data deposited in IIstages.Thissecond,developmentaltimecoursehas the National Center for Biotechnology Information’s finertemporalandspatialdetailaroundthesekeystages Gene Expression Omnibus (Edgar et al., 2002; Barrett and therefore may be used in conjunction with the one et al., 2013), choosing microarray data sets that in- generated from the data of Alves-Ferreira et al. (2007). cluded flowers, buds, anthers, or pollen materials to Data from these two-color microarray experiments generate a coexpression network. Through generating (Alves-Ferreira et al., 2007; Xu et al., 2010) were the network, compact clusters of coexpressed genes renormalized using a method similar to that of single- werefound(i.e.setsofgeneshavingsimilarexpression color arrays (see “Materials and Methods”), producing patternsacrossallthesamples).Thisclusteringenables two comparative developmental time courses of gene the identification of novel genes that may be involved expression in wild-type, ms1, and ams buds. This en- in specific biological processes based on known com- ables us to use the wild-type and mutant values as a ponents within the cluster. biologically meaningful developmental time course. It Additionally, we reanalyzed two previously con- is noted that this method seems more prone to noise ducted two-color microarray experiments associated than the use of single-color microarrays, but it is par- with anther and pollen development (Alves-Ferreira ticularly useful where genes are not present on the et al., 2007; Xu et al., 2010) in order to compare gene Affymetrix microarrays, such as MS1. expression across these time series as well as between The resulting plots (e.g. for AMS; Fig. 1) from both the mutants. Along with the Affymetrix microarrays the Affymetrix and two-color array data give imme- used to generate the correlation network, these three diate visual indicationof howthe genesare expressed data sets give a clear indication of the spatial and tem- across various samples. These plots show the indi- poralexpressionofanther-relatedgenes.Plotshavebeen vidual replicates rather than means, allowing those createdforeachgeneinthecorrelationnetworkandare geneswhosebehaviorappearstobevariable,possibly available online at http://www.cpib.ac.uk/anther. duetosensitivitytoconditionsortotheprecisestaging In this work, we have generated a valuable tool for of the samples, to be easily visually detected. These the analysis of genes involved in anther and pollen plots are freely available online at http://www.cpib. developmentandshowhowthiscanbeusedtoidentify ac.uk/anther, allowing quick analysis of anther ex- new players in anther and pollen development. How- pression data for genes of interest. Closed circles rep- ever,thedatausedforthegenerationofthecorrelation resentwild-typesamples,andopensymbolsrepresent network are from all floral organs and developmental the different mutants. stages; therefore, FlowerNet also has broader applica- tion in the characterization of all genes associated with aspects of plant reproduction and flowering. FlowerNet CorrelationNetwork In order to investigate gene behavior across a wide RESULTS range of samples, we generated a correlation network using 66 Arabidopsis Affymetrix wild-type micro- GeneExpressionPlots arrays from plant reproduction-related experiments, Arabidopsis anther, stamen, and bud microarray which included flowers, buds, anther/stamen sam- data sets were selected that comprised wild-type or ples, and isolated pollen samples (see “Materials and mutant samples associated with anther and pollen Methods”; Supplemental Files S1 and S2). These micro- development; all mutants selected displayed male- array data sets were mostly publicly available in the 1718 Plant Physiol. Vol. 167, 2015 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. FlowerNet: A Gene Discovery Correlation Network Figure1. PlotfromtheWebsitetoolshowingtheexpressionofAMSinvariousantherandfloralmicroarrays(http://www.cpib. ac.uk/anther). National Center for Biotechnology Information’s Gene genes considered correlate well with each other. For Expression Omnibus (Honys and Twell, 2004; Schmid example, the largest cluster (cluster 1) contains 14,433 et al., 2005; Mandaokar et al., 2006; Yang et al., 2007a) edges between 171 genes, 99.3% of the possible edges; with some previously unpublished data (Z.A. Wilson thus, these genes have very similar expression profiles. andJ.Song,unpublisheddata).Anumberofotheranther- Figure 3 shows a representative cluster (cluster 110), related published studies were used for gene list overlay whichdemonstrateshowtheexpressionprofileofeach comparison;however,thesecouldnotbeincludedinthis gene within the cluster has a highly correlated expres- network,orintheexpressionplots,sincetherawdatafor sion pattern in the microarrays used to generate the these analyses were not publicly available at the time of network. construction. Overlaying expression data from different experi- The resulting network has 605,686 edges between ments that have not been used in the creation of the 10,797 genes (Fig. 2); a visualization of the network is network (e.g. mutant data from the two-color micro- available as a Cytoscape file (Supplemental File S3), arrays detailed above) indicate that certain clusters withanavigablelistofgenesthatareconnectedtoeach aresignificantlyoverrepresentedforthesetranscripts. genepresentedundereachgeneexpressionplotimage. Similarly, the majority of the clusters contain a signifi- Within this network, compact highly intracorrelated cant overrepresentation of Gene Ontology (GO) terms, clusterswereidentifiedusingtheTransClustalgorithm suggesting that genes within clusters are involved in (Wittkop et al., 2010) and the correlation values as an the same developmental processes. A number of the edge weight to generate small, well-connected clusters clusters are enriched for general plant pathways; for basedonexpressioninthenetwork(see“Materialsand example, cluster 2 is enriched in the GO term photo- Methods”). The resultant clusters describe groups of synthesis,cluster11inGAbiosynthesis,andcluster16in genes that are highly positively correlated across all water transport, although these do not show significant the samples included, with almost all the edges be- expression changes linked to anther/stamen-specific tween the genes included (for cluster allocations, see gene expression. Other clusters show reproduction- Supplemental File S4). These compact clusters have related enrichment; for example, cluster 67 is a set of extremely similar expression patterns within the sam- 14 genes that all have higher expression in the carpel ples used, avoiding the problem of chain-like clusters, (and to a lesser extent the petal) samples from the wheregenesareseveralneighborsremovedfromthose AtGenExpress Developmental Map, which have not at the other end of the cluster, leading to genes in the been used in the generation of the network. To focus same cluster having very diverse expression patterns. onanther/stamen-relatedclusters,weusedanumber The resulting clusters contain almost all of the possible ofdatasetstoselectclustersofinterest,suchasstamen- edgesbetweenthenodesinvolved,ensuringthatallthe specific transcripts (Wellmer et al., 2004), the presence Plant Physiol. Vol. 167, 2015 1719 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. Pearce et al. to have an important regulatory role during anther and pollen development. We chose eight mutants: ap3 (early stages only); spl/nzz and ems, which are involved in anther cell specification (Zhang et al., 2006; Alves-Ferreira et al., 2007; Wijeratne et al., 2007); dyt1 and ams (combination of all four stages); ms1 and myb80 (previously known as myb103), which are in- volved in tapetum development and mature pollen (Zhangetal.,2006;Alves-Ferreiraetal.,2007;Xuetal., 2010; Phanet al.,2011); and rpk2 (flower stages 12–14), which is involved in anther dehiscence (Mizuno et al., 2007b). Wild-type data were used to initially generate the FlowerNet network, but when the corresponding mutant data were overlaid onto the network, a large proportion of genes within each cluster showed corre- lated expression in the specific mutants (Fig. 7). This clustering of expression was also shown as a heat map (Fig. 8), utilizing developmental staged microarray datafromthems1mutant(Alves-Ferreiraetal.,2007). Thissuggestsnotonlythatthesegenesarecoexpressed but also that they may be coregulated. To characterize the clusters further, we compared the gene expression of these clusters in the develop- Figure 2. Cytoscape visualization of the full correlation network. mental time courses generated from the data of Xu Genes shown byWellmer et al. (2004)to have higherexpressionin etal.(2010)andAlves-Ferreiraetal.(2007).InFigure5, stamenarecoloredinpurple. each gene within the four clusters is represented by a different color line, the thick black line being the me- dian trend line, while Figure 8 shows a heat map of of known anther-related genes within a cluster, and expression levels of each gene within each of the four clusters that are highly regulated by previously de- chosen clusters. From both of these sets of data, the scribedmale-sterilemutantssuchasamsandms1;these genesintheclustersareexpressedinasimilarmanner are shown in Figure 4. and in most cases at a similar level of expression. Therefore,despiteonlyusingthewild-typeAffymetrix ClustersAssociated withPollenWallFormation In order to validate the association between genes identified within the same cluster, four clusters were selected for detailed investigation. These were chosen based on their expression patterns, GO annotations, and behavior in other data sets. Each of these clusters has overrepresented GO terms associated with pollen or anther development. The selected clusters show enrichment of gene expression at specific time points during pollen development based upon staged bud expression data (Xu et al., 2010); cluster 37 includes genes that show up-regulation at pollen mother cell meiosis, cluster 81 at pollen mitosis I, cluster 21 at the bicellularpollenstage,andcluster116atpollenmitosis II(forpollendevelopmentreview,seeBorgetal.,2009; Table I). This allowed us to infer a good overview of the developmental expression changes during anther andpollendevelopmentthroughtheseclusters(Fig.5). Figure 6 shows the expression patterns of individ- ual genes within these particular clusters, looking at pollen-specific expression stages and the whole bud; both of these microarray data sets were used to create the network and illustrate the expected similar be- havior of gene expression within each cluster. To in- Figure3. Plotofthegenesincluster110,showingexpressioninthe terrogate these clusters further, we collected publicly 66microarraysthatareusedtogenerateFlowerNet.Theorderofthe availablemicroarraydatafromvariousmutantsknown microarraysislistedinSupplementalFileS1. 1720 Plant Physiol. Vol. 167, 2015 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. FlowerNet: A Gene Discovery Correlation Network Figure4. SelectionofFlowerNetclusters, chosenforbeingbudrelatedbasedona numberofcriteriasuchasknownanther- relatedgenesandmale-sterilemutantex- pression. Highlighted in pink are those genesfoundtobestamenspecific(Wellmer etal.,2004). arrays to generate the network, the clusters show role, with the GO term pollen exine formation over- similar expression in the developmental time courses represented; however, their specific function is cur- available in two-color Agilent arrays (Alves-Ferreira rently undetermined. These genes are up-regulated in et al., 2007) as well as the various sets of correspond- the stamen of stage 12 flowers (using the data from ingmutantdata.Thisimpliesthatthegeneswithinthe Schmid et al. [2005]) and in pollen; the majority are clusters have expression patterns that are closely cor- down-regulated in old ms1 buds, particularly in the related, suggesting that they may be involved in the second and third samples of the time course from same process and potentially may be regulated by the Alves-Ferreira et al. (2007; sample 1 equates to mature same mechanism. Use of this network clustering to flowers and sample 7 to immature buds/inflorescence find clusters that change in different mutant back- meristem). This corresponds with a peak in the wild- grounds may allow new targets and processes to be typebicellularpollendevelopmentstageofbudsinthe inferred from the results. To focus on these coex- datafromXuetal.(2010),withthemajorityofthegenes pression similarities, we also looked at the individual within this cluster being down-regulated in the ams genes in each cluster in more detail to compare ex- mutant from the same data set. The majority of these pression and show that, within a cluster, the genes geneshavehigherexpressioninthetapetumcompared show very similar expression in both wild-type and with other anther tissues at pollen mitosis II (Z.A. mutant data (Fig. 9). Wilson and G. Vizcay-Barrena, unpublished data). Twenty-one of these genes were found to be down- regulated in stage 5 to 8 myb80 anthers (Phan et al., 2011), suggesting that this cluster acts downstream Cluster21:PollenExineFormation of AMS and MYB80. Cluster21contains31geneswith464edgesbetween Of the three pollen-specific genes, AtSAC1b shows them(99.78%ofthepossibleedges),whichareinvolved specific expression in pollen, with higher levels at the in pollen exine formation, and contains three charac- uninucleate stage (Despres et al., 2003), VHA-E2 is terized genes that are known to be pollen specific, specific to the vegetative cell in the pollen (Strompen Arabidopsis SUPPRESSOR OF ACTIN (AtSAC1b), et al., 2005), while APK3 has expression throughout ADENOSINE-59-PHOSPHOSULFATE KINASE (APK3), development, with strongest expression in pollen and VACUOLAR H+-ATPASE SUBUNIT E (VHA-E2; grains (Mugford et al., 2009). The single mutants in all Despresetal.,2003;Dettmeretal.,2010;Mugfordetal., of these three genes have no phenotype, most likely 2010); 23 of these genes were found to be specifically because of functional redundancy of other isoforms expressed in stamens (Wellmer et al., 2004). The ma- expressed within the pollen: only in the triple mutant jorityofthegeneswithinthisclusterhaveanunknown of APK1 isoforms (apk1 apk3 apk4) is there a pollen Plant Physiol. Vol. 167, 2015 1721 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. Pearce et al. TableI. Genespresentinthefourselectedclustersincludingtheirpredictedrolesandpublishedexpressionpatterns ClusterNo. Name;TheArabidopsisInformationResource10Annotation Role PublishedExpression Cluster21 AT1G04290 Thioesterasesuperfamily AT1G07850 DOMAINOFUNKNOWNFUNCTION(DUF)064 AT1G20080 SYNAPTOTAGMIN2 Proteinsecretion AT1G22150 SULTR1;1;sulfatetransporter Sulfatemembranetransport AT1G32250 Calcium-bindingEF-handfamily AT1G52570 PLDALPHA2;phospholipaseDa-2 AT1G54560 MYOSINXIE Golgimovement AT1G72960 RHD3;roothairdefective3GTP-binding AT2G25890 Oleosinfamilyprotein Lipidstorage AT2G30290 VSR2;vacuolarsortingreceptor Vacuolarsorting AT2G30630 P-loop-containingnucleosidetriphosphate Cellkilling hydrolasesuperfamily AT2G47770 TSPO;outermembraneTrp-richsensoryprotein Abscisicacidandsalt Seed stressinduced AT3G03900 APK3 Sulfationofsecondary Pollen metabolites AT3G08560 VHA-E2 Pollen AT3G17630 CHX19;cation/H+exchanger Membranetrafficking AT3G19090 RNA-bindingprotein RNAbinding AT3G25160 Endoplasmicreticulumlumanprotein-retaining Endoplasmicreticulum receptorfamily retention AT3G51490 TMT3;tonoplastmonosaccharidetransporter Sugartransport Filament AT3G60540 PreproteintranslocaseSec Translocase AT4G02140 AT4G10440 S-Adenosyl-L-Met-dependentmethyltransferases AT4G11030 AMP-dependentsynthetaseandligasefamily AT4G18920 DUF1264 AT4G26770 Phosphatidatecytidyltransferasefamily AT4G36600 Lateembryogenesis-abundantprotein AT4G37840 HEXOKINASE-LIKE3 Hexokinase AT5G10730 NAD(P)-bindingRossmannfoldsuperfamily AT5G13350 Auxin-responsiveGH3family AT5G15490 UDP-Glc-6-dehydrogenasefamily Cellwallcomposition Throughoutplant AT5G66020 AtSAC1B;suppressorofactin Pollen AT5G66150 Glycosylhydrolasefamily Cluster37 AT1G01280 CYP703A2;cytochromeP450family703 Sporopolleninbiosynthesis Anther AT1G02050 LAP6;lessadhesivepollen6 Sporopolleninbiosynthesis Anther,tapetumspecific AT1G02813 DUF538 AT1G62940 ACOS5;acyl-CoAsynthetase Sporopolleninbiosynthesis Anther,tapetumspecific AT1G69500 CYP704B1;cytochromeP450family704 Sporopolleninbiosynthesis Anther,tapetumspecific AT1G76470 NAD(P)-bindingRossmannfoldsuperfamily Ligninbiosynthesis AT2G42870 PAR1;Phytochromerapidlyregulated Cellelongation AT3G11980 MS2;malesterility2 Exineformation Anther,tapetumspecific AT3G13220 WHITE/BROWNCOMPLEXSUBFAMILY27(WBC27); Exineformation Anther,tapetumspecific ABCtransporter-like AT3G23770 O-Glycosylhydrolasesfamily17 Exineformation AT3G42960 ATA1;tapetum1 Anther,tapetumspecific AT4G14080 MEE48;maternaleffectembryoarrest Exineformation AT4G20420 TAP35/44;tapetum-specificprotein Tapetumspecific AT4G34850 LAP5;lessadhesiveprotein Sporopolleninbiosynthesis Anther,tapetumspecific AT4G35420 DRL1/TKPR1;dihydroflavonol4-reductase-like Sporopolleninbiosynthesis Anther,tapetumspecific AT5G07230 Bifunctionalinhibitor/lipidtransferprotein Lipidtransfer AT5G47600 HSP20-likechaperonesuperfamily AT5G59000 REALLYINTERESTINGNEWGENE/FYVE/PLANT HOMEODOMAINGENEzincfingersuperfamily AT5G62080 Bifunctionalinhibitor/lipidtransferprotein Lipidtransfer AT5G65410 HB25;homeoboxprotein Cluster81 AT1G13140 CYP86C3;cytochromeP450,family86 Exineformation (Tablecontinuesonfollowingpage.) 1722 Plant Physiol. Vol. 167, 2015 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. FlowerNet: A Gene Discovery Correlation Network TableI.(Continuedfrompreviouspage.) ClusterNo. Name;TheArabidopsisInformationResource10Annotation Role PublishedExpression AT1G67990 TSM1;tapetum-specificmethyltransferase1 Spermidineformation Anther,tapetumspecific AT1G71160 KCS7;3-ketoacyl-CoAsynthase Lipidbiosynthesis AT2G19070 SHT;spermidinehydroxycinnamoyltransferase Spermidineformation Anther,tapetumspecific AT3G52160 KCS15;3-ketoacyl-CoAsynthase Lipidbiosynthesis AT4G28395 A7;anther7 Lipidtransfer Anther AT5G13380 Auxin-responsiveGH3family AT5G16920 Fasciclin-likearabinogalactanfamily Exineformation AT5G16960 Zinc-bindingdehydrogenasefamily AT5G48210 Exineformation AT5G49070 KCS21;3-ketoacyl-CoAsynthase Lipidbiosynthesis AT5G65205 NAD(P)-bindingRossmannfoldsuperfamily Cluster116 AT1G14420 ArabidopsisLAT59ORTHOLOG(At59) Cellwallmodification Pollenspecific AT1G23350 Plantinvertase/pectinmethylesterase Actinfilamentmovement AT1G49290 Actinfilamentmovement AT1G64740 TUA1;a-1tubulin Microtubulemovement Pollenspecific AT2G17500 Pectinlyase-likesuperfamily Actinfilamentmovement AT2G31500 CPK24;calcium-dependentproteinkinase24 Regulatesgrowth Pollen;pollentubes AT3G17060 Pectinlyase-likesuperfamily Actinfilamentmovement AT3G25170 RAPIDALKALINIZATIONFACTOR-LIKE26 AT5G23270 STP11;sugartransporter11 Sugartransport Pollenspecific AT5G39400 PTEN1 Phosphatase Pollenspecific lethality phenotype (Mugford et al., 2010). APK3 is an toregulatethePHOSPHOINOSITOL-4-phosphatepool ADENOSINE-59-PHOSPHOSULFATE kinase involved and could control ATP transport (Despres et al., 2003). insulfurmetabolism,whileAtSAC1bhasbeensuggested ThislinkswithVHA-E2,whichisavacuolarH+-ATPase Figure 5. Gene expression levels in the four selected clusters in different pollen development stages in whole buds,basedonwild-typedatafromXu et al. (2010) for each gene within the cluster. The thick black line shows theaveragetrendofallthegenesinthe cluster. Plant Physiol. Vol. 167, 2015 1723 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. Pearce et al. Figure6. Geneexpressionlevelsinthefourselectedclusters,showingthedata(HonysandTwell,2004;Yangetal.,2007a) usedtogenerateFlowerNet.UNM,Unicellularmicrospores;BCP,bicellularpollen;TCP,tricellularpollen;MPG,maturepollen grain.YoungbudsrepresentpollenmothercellmitosisI,whileoldbudsrepresentmitosisII. that plays an important role in maintaining the pH of up-regulatedinthems1mutant,particularlyinthethird endomembranecompartmentsineukaryoticcells(Dettmer to fifth samples of the time course generated from the et al., 2010). The double and triple knockouts of dataofAlves-Ferreiraetal.(2007),whilethemajorityof AtSAC1bandVHA-E2wouldbeinterestingtostudyto these genes are down-regulated in ams mutants, par- see if they have a similar phenotype to APK3 and dis- ticularly at the meiosis and pollen mitosis I stages (Xu cover what role these families of genes have in pollen etal.,2010).Thiscorrespondstoapeakinexpressionin development. Another two published genes from this wild-typedatafromthesamedatasetatthemeiosisstage, cluster,AT5G15490(UDP-GLUCOSEDEHYDROGENASE; with the majority of the genes more highly expressed in Reboul et al., 2011) and AT3G51490 (TONOPLAST thetapetum than in the other anther tissues at the tetrad MONOSACCHARIDETRANSPORTER1;Wormitetal., stage (Z.A. Wilson and G. Vizcay-Barrena, unpublished 2006), are involved in cell wall composition and sugar data). Collectively, this suggests that these genes are transport,whichalsomaybeimportantforpollenwall downstreamofAMSandareup-regulatedbyAMS,while formation. they are negatively regulated by MS1 to give a specific By focusing research on the other cluster members expression pattern. withinthegroup,wemaybeabletoinferfurtherroles A large proportion of these genes are involved in of this cluster, as many of the genes have predicted the biosynthesis of sporopollenin, which is a major roles in protein movement and in secretion. It will be constituent of exine in the outer pollen wall. Recently interestingtodiscovertherolestheyplayinantherand in Arabidopsis, a number of genes have been demon- pollen development. strated to be involved in sporopollenin biosyn- thesis: ACYL-COENZYME A SYNTHETASE (ACOS5), CYTOCHROME P450 (CYP703A2), CYP704B1, LESS ADHESIVE POLLEN3 (LAP3), LAP5 (POLYKETIDE Cluster 37:SporopolleninBiosynthesis SYNTHASE B), LAP6 (POLYKETIDE SYNTHASE A), Cluster37isa20-nodeclique,withalledgesbetween MS2, FACELESS POLLEN1 (FLP1), and TETRAKETIDE thempresent,andcontainsanumberofgenesknownto a-PYRONEREDUCTASE1(TKPR1[DIHYDROFLAVONOL be tapetum specific and linked to sporopollenin bio- 4-REDUCTASE-LIKE1]; Ariizumi and Toriyama, 2011); synthesis. Of these 20 genes, 11 were found to be sta- all of these except LAP3 and FLP1 are found within men specific (Wellmer et al., 2004); however, two of this cluster. Lallemand et al. (2013) demonstrated these 20 genes are not included in the array analysis. that ACOS5, LAP5, LAP6, TKPR1, CYP703A2, and The genes in this cluster are up-regulated in flowers CYP704B1 all interact together on the endoplasmic at stage 9 to 11 (Schmid et al., 2005) and are mostly reticulum of plant cells, and all of these interacting 1724 Plant Physiol. Vol. 167, 2015 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved. FlowerNet: A Gene Discovery Correlation Network Figure 7. Gene expressionchanges in the four selected clusters in different known antherand pollen development mutant microarraydatasets;dataareshownforap3(flowerearlystagesonly),spl/nzz(flowerstages1–13),ms1(flowerstages1–13; Alves-Ferreiraetal.,2007),ems(flowerstages8and9;Wijeratneetal.,2007),dyt1(flowerstages8–10;Fengetal.,2012),ams (flowerstages9–12;Xuetal.,2010),myb80(flowerstages9and10;Phanetal.,2011),andrpk2(flowerstages12–14;Mizuno etal.,2007a).Eachcirclerepresentsagene,withredsignifyingup-regulationandbluefordown-regulationineachmutant comparedwiththewildtype. genes are found in this cluster. Of the studied genes proteins, At5g07230 and At5g62080, which also may be within this cluster, the phenotypes range from an ab- involved in sporopollenin biosynthesis. This strongly sence of production of pollen due to compromised suggests that the remaining six unknown genes within pollen walls (ACOS5 and TKPR1; de Azevedo Souza thisclustercouldplayaroleinsporopolleninsynthesis et al., 2009; Tang et al., 2009; Grienenberger et al., in some manner, and studying the knockouts of these 2010) to having irregular exine layers (CYP703A2, genes could further our understanding of the sporo- CYP704B1, ATP-BINDING CASSETTE G26 [ABCG26], pollenin biosynthesis pathway and transport to the pol- LAP5, LAP6, and MS2; Morant et al., 2007; Dobritsa len coat wall. et al., 2009, 2010; Kim et al., 2010; Choi et al., 2011), with varying phenotypes from loss of fertility to re- duced pollen viability to no effect on pollen viability. Cluster81:PollenSpermidine Formation The sporopollenin precursor biosynthesis gene WBC27 (ABCG26)is also within this clusterandis involved in Cluster 81 is a 12-gene clique, with all 12 of these the transport of these sporopollenin precursors from genesfoundtobestamenspecific(Wellmeretal.,2004) the tapetum, facilitating exine formation on the pollen and up-regulated in flower stages 9 to 11 (Schmid surface(Choietal.,2011).Twoothergenesofunknown et al., 2005). These genes are differentially expressed function are believed to play a role in pollen exine (mostlydown-regulated)inbothms1andamsmutants formation, At3g23770 and At4g14080 (MATERNAL throughout pollen developmental stages (Alves- EFFECTEMBRYOARREST48),andtwofurtherunknown Ferreira et al., 2007; Xu et al., 2010) as well as tapetum genes are tapetum specific, At3g4290 (TAPETUM1) and specific (Z.A. Wilson and G. Vizcay-Barrena, unpub- At4g20420, based on their description in AtEnsembl lished data) and particularly expressed in the pollen (Flicek et al., 2013; http://atensembl.arabidopsis.info/ mitosis I stage (Xu et al., 2010). Two genes (At5g49070 index.html).Therefore,12outof20genesinthiscluster and At3g52160) were also down-regulated in myb80 have a direct role in the tapetum, with one-half of the anthers. genes in this cluster involved in exine/sporopollenin Similar to cluster 37, the majority of these genes formation. The rest of the genes in this cluster have an have suggestive roles in pollen exine formation (five), unknownfunction,includingtwoputativelipidtransfer lipidbiosynthesis(three),andlipidtransfer(one),with Plant Physiol. Vol. 167, 2015 1725 Downloaded from www.plantphysiol.org on August 25, 2015 - Published by www.plant.org Copyright © 2015 American Society of Plant Biologists. All rights reserved.

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The version presented here may differ from the published version or from the FlowerNet: A Gene Expression Correlation Network for grain development (Goldberg et al., 1993). endomembrane compartments in eukaryotic cells (Dettmer to fifth samples of the time course generated from the.
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