2013 Annual Report
1a.Objectives (from AD-416):
The long-term goal of this program is to define the cellular, molecular and biochemical mechanisms by which light-activated phytochrome (phy) molecules transduce environmentally-generated signaling information to the genes they regulate. The specific objectives of this project plan are:
Objective 1: Define the functional roles of phytochrome (phy) interacting transcription factors (PIFs) in regulating plant growth and developmental responses to light using mutant analysis. [NP 301, C3, PS 3A]
Objective 2: Identify phy-PIF-pathway-regulated genes through high-throughput RNAseq analysis. [NP 301, C3, PS 3A]
Objective 3: Define the primary phy-PIF-regulated transcriptional network using ChIPseq (chromatin immunoprecipitation sequence) analysis to identify direct targets of the PIFs among the rapidly light-regulated gene-set. [NP 301, C3, PS 3A]
Objective 4: Define the functional roles and downstream targets of the transcription-factor-encoding (TFE) genes in this primary network using CHIPseq analysis and RNAseq-based transcript profiling of mutants at these loci. [NP 301, C3, PS 3A]
1b.Approach (from AD-416):
Hypothesis: Phytochrome (phy) interacting transcription factors (PIFs) in addition to PIFs 1,3,4 and 5 have functional roles in regulating plant growth and
developmental responses to light.
Approach: We will obtain higher order combinations of mutants with the PIF mutants and with mutants in other components of the light signaling pathway in order to determine the phenotypes. We will screen for mutants starting with quadruple mutants in the PIF genes.
Contingencies: Although we plan to use high-throughput sequencing to identify
mutants of interest, if this proves to be problematic, we will consider including
more traditional map-based procedures that have previously provided numerous
mutants for our program over many years.
Hypothesis: Genes identified by RNAseq analysis of wild-type and various pif-
mutant combinations will identify genes that include potential direct targets of
PIF-regulated transcription genome-wide.
Approach: We will analyze the expression profiles of selected combinations of the
PIF mutants by RNAseq.
Hypothesis: ChlPseq analysis will identify the promoter sites to which the PIF
proteins bind physically in vivo, data which, when integrated with the RNAseq
transcriptome data, will identify direct targets of PIF transcriptional regulation.
Approach: We will carry out chromatin immunoprecipitation in dark grown wild type
or PIF:MYC fusion protein plants. A subset of these genes will be selected for
validation and reproducibility of the observed PIF binding by qPCR. For a further
subset, we will generate promoter-fusion constructs with the LUC reporter gene.
Initially we will use these constructs in a transient transfection assay that we
developed for examining transcriptional activity in etiolated Arabidopsis seedlings using particle bombardment.
Hypothesis: Integration of ChlPseq and RNAseq analyses of the downstream targets of PIF-targeted TFE genes will define the landscape and predicted functional trajectory of the various branches of the transcriptional cascade presumed to emanate from the primary transcriptional network.
Approach: We will use the ChIP-seq strategy to screen for promoters that bind selected members of the transcription factors identified encoded by direct PIF-target genes. T-DNA-insertional mutants in these selected TFE genes will be identified and used for RNA-seq analysis to define the downstream transcriptional network they regulate.
Contingencies - Objectives 2, 3 and 4
Most aspects of the proposed technology are already operative in this laboratory,
and our preliminary data indicate that the assays and analysis are working
successfully. However, should we encounter difficulties with the RNAseq or
ChlPseq experiments, we will consider refined or alternative strategies. For
example, should the RNAseq strategy not provide interpretable data, we will revert to the use of the now available Affymetrix tiling array platform for full genome transcriptome coverage, a technology with which we have extensive experience in the ATH1 format (Tepperman et al., 2001; 2004; 2006; Monte et al., 2004; Leivar et al.,2009; 2012a).
This report documents progress for Project Number 5335-21000-042-00D, which started in June 2013 and continues research from Project Number 5335-21000-032-00D, entitled “Molecular Mechanisms of Phytochrome Signaling and Gene Regulating”. Dark-grown seedlings exhibit skotomorphogenic development. Genetic and molecular evidence indicates that a quartet of Arabidopsis Phytochrome (phy)-Interacting bHLH Factors (PIF1, 3, 4 and.
5)are critically necessary to maintaining this developmental state, and that light activation of phy induces a switch to photomorphogenic development by inducing rapid degradation of the PIFs. Using integrated ChIP-seq and RNA-seq analyses, we identified genes that are direct targets of PIF3 transcriptional regulation, exerted by sequence-specific binding to G-box (CACGTG), or PBE-box (CACATG), motifs in the target promoters, genome-wide. In addition, expression analysis of selected genes in this set, in all triple pif-mutant combinations, provides evidence that the PIF-quartet members collaborate to generate an expression pattern that is the product of a mosaic of differential transcriptional responsiveness of individual genes to the different PIFs, and differential regulatory activity of individual PIFs toward the different genes. To examine this possibility directly, we have recently expanded this analysis to include identification of direct-targets of PIF1, PIF4 and PIF5 genome-wide.
The genetic network underlying seedling establishment. A key component of the successful colonization of land by terrestrial flowering plants was the evolution of a developmental strategy termed skotomorphogenesis (etiolated growth). This strategy enabled post-germinative seedlings emerging from buried seed to grow heterotrophically, on seed reserves, rapidly upwards through the subterranean darkness to the soil surface. Coupled with this was the evolution of a photosensory mechanism to trigger a switch to autotrophic, photomorphogenic (deetiolated) development upon emergence into sunlight. This transition is critical to the establishment of vigorously competitive seedlings, a crucial component of successful crop production. ARS scientists in Albany, California, have identified a battery of genes that underlie this process and that are the direct targets of regulation by the light-activated phytochrome photosensory system. These findings provide potential targets for genetic or reverse genetic manipulation of the developmental pathways involved in seedling vigor.