ConclusionsSolar tracking by sunflo

Conclusions
Solar tracking by sunflower stems is a fascinating, developmen-tally and environmentally dynamic trait about which much is leftto discover. Many open questions remain about its phenomeno-logy, underlying mechanisms, and environmental significance, andwe have endeavored here to specifically highlight key avenues forfuture research in each of these areas. The complex regulation of themovement over both daily and ontogenetic time scales by putativeendogenous cues as well as light and perhaps other environmen-tal signals suggests that understanding their respective roles willyield novel insights into how plant growth is continuously andadaptively tuned to changing environments. In addition, under-standing the mechanisms that regulate shoot apical heliotropismand the ecological advantages provided by the behavior may helpidentify new pathways or genetic variants that can be utilized forimprovement of sunflower and other crop plants.One central question that particularly needs to be addressedin the future is whether or not the mechanisms governingphototropism in sunflower seedlings and heliotropism by inflore-scences are fundamentally different. Detailed characterization ofthe anatomical, ionic, and hormonal changes associated with stembending under a series of light conditions (fixed vs. moving, bluevs. red, varied diurnal cycle lengths, etc.) and at multiple devel-opmental stages will be necessary to address this problem. If thedichotomy is trivial, then a number of candidate pathways suggestthemselves, and the phenomenon may be more tractably studiedunder controlled conditions. To the extent that the processes dif-fer, either in the daytime interpretation of directional light cues orin the nighttime incorporation of endogenous rhythms, mechanis-tic insight into sunflower heliotropism may shed new and uniqueinsights into the ways that intrinsic and extrinsic signals are inte-grated to regulate plant growth.The new genetic and genomic resources being developed forsunflower promise to greatly accelerate such work. A draft genomehas recently become available (www.sunflowergenome.org), andthe assembly is currently being anchored to dense geneticand physical maps and annotated with extensive transcriptomesequencing datasets [18]. These resources will foster candidategene identification through transcriptomic comparisons of lateralstem sections in tracking and top lit non-tracking plants. Recentadvances facilitating reverse genetics through targeted inducedlesions and germline transformation will allow targeted alterationof candidate genes [19]. In addition, recently generated germplasmresources – including advanced generation recombinant inbredlines and association mapping panels [18,20] – will provide pow-erful tools for connecting natural allelic variation to phenotypicvariation in solar tracking.AcknowledgementsThis work was funded by support from National Science Founda-tion Plant Genome Research Program (NSF-IOS 1238040) to S.L.H.and B.K.B. and a University of Virginia Harrison UndergraduateResearch Fellowship to E.A.B. The authors thank Jonathan Gresselfor his advice and patience as well as several anonymous reviewersfor their comments.