Next-generation mapping of genetic mutations using bulk population sequencing.

Next-generation sequencing platforms have made it possible to very rapidly map genetic mutations in Arabidopsis using whole-genome resequencing against pooled members of an F2 mapping population. In the case of recessive mutations, all individuals expressing the phenotype will be homozygous for the mutant genome at the locus responsible for the phenotype, while all other loci segregate roughly equally for both parental lines due to recombination. Importantly, genomic regions flanking the recessive mutation will be in linkage disequilibrium and therefore also be homozygous due to genetic hitchhiking. This information can be exploited to quickly and effectively identify the causal mutation. To this end, sequence data generated from members of the pooled population exhibiting the mutant phenotype are first aligned to the reference genome. Polymorphisms between the mutant and mapping line are then identified and used to determine the homozygous, nonrecombinant region harboring the mutation. Polymorphisms in the identified region are filtered to provide a short list of markers potentially responsible for the phenotype of interest, which is followed by validation at the bench. Although the focus of recent studies has been on the mapping of point mutations exhibiting recessive phenotypes, the techniques employed can be extended to incorporate more complicated scenarios such as dominant mutations and those caused by insertions or deletions in genomic sequence. This chapter describes detailed procedures for performing next-generation mapping against an Arabidopsis mutant and discusses how different mutations might be approached.

The shoot regeneration capacity of excised Arabidopsis cotyledons is established during the initial hours after injury and is modulated by a complex genetic network of light signalling.

Excised plant tissues (explants) can regenerate new shoot apical meristems in vitro, but regeneration rates can be inexplicably variable. Light affects rates of shoot regeneration, but the underlying mechanisms are poorly understood. Here, excised Arabidopsis cotyledons were dark-light shifted to define the timing of explant light sensitivity. Mutants and pharmacological agents were employed to uncover underlying physiological and genetic mechanisms. Unexpectedly, explants were most light sensitive during the initial hours post-excision with respect to shoot regeneration. Only ∼100 µmol m(-2 ) s(-1) of fluorescent light was sufficient to induce reactive oxygen species (ROS) accumulation in new explants. By 48 h post-excision, induction of ROS, or quenching of ROS by xanthophylls, increased or decreased shoot regeneration, respectively. Phytochrome A-mediated signalling suppressed light inhibition of regeneration. Early exposure to blue/UV-A wavelengths inhibited regeneration, involving photoreceptor CRY1. Downstream transcription factor HY5 mediated explant photoprotection, perhaps by promoting anthocyanin accumulation, a pigment also induced by cytokinin. Surprisingly, early light inhibition of shoot regeneration was dependent on polar auxin transport. Early exposure to ethylene stimulated dark-treated explants to regenerate, but inhibited light-treated explants. We propose that variability in long-term shoot regeneration may arise within the initial hours post-excision, from inadvertent, variable exposure of explants to light, modulated by hormones.

Incipient stem cell niche conversion in tissue culture: using a systems approach to probe early events in WUSCHEL-dependent conversion of lateral root primordia into shoot meristems.

Adventitious shoot organogenesis contributes to the fitness of diverse plant species, and control of this process is a vital step in plant transformation and in vitro propagation. New shoot meristems (SMs) can be induced by the conversion of lateral root primorida/meristems (LRP/LRMs) or callus expressing markers for this identity. To study this important and fascinating process we developed a high-throughput methodology for the synchronous initiation of LRP by auxin, and subsequent cytokinin-induced conversion of these LRP to SMs. Cytokinin treatment induces the expression of the shoot meristematic gene WUSCHEL (WUS) in converting LRP (cLRP) within 24-30 h, and WUS is required for LRP â†’ SM conversion. Subsequently, a transcriptional reporter for CLAVATA3 (CLV3) appeared 32-48 h after transfer to cytokinin, marking presumptive shoot stem cells at the apex of cLRP. Thus the spatial expression of these two components (WUS and CLV3) of a regulatory network maintaining SM stem cells already resembles that seen in a vegetative shoot apical meristem (SAM), suggesting the very rapid initiation and establishment of the new SMs. Our high-throughput methodology enabled us to successfully apply a systems approach to the study of plant regeneration. Herein we characterize transcriptional reporter expression and global gene expression changes during LRP â†’ SM conversion, elaborate the role of WUS and WUS-responsive genes in the conversion process, identify and test putative functional targets, perform a comparative analysis of domain-specific expression in cLRP and SM tissue, and develop a bioinformatic tool for examining gene expression in diverse regeneration systems.

Tissue-specific GAL4 expression patterns as a resource enabling targeted gene expression, cell type-specific transcript profiling and gene function characterization in the Arabidopsis vascular system.

Cell type-specific fluorescent gene expression markers are a prerequisite for various strategies in functional genomics and developmental biology. To increase the resolution of vascular tissue analysis and to identify more genes expressed in the vasculature, we searched for expression in vascular tissues within a new collection of transactivated enhancer trap lines. Among 33 lines with vascular expression, we identified five lines with expression profiles marking procambial or procambium-associated cell states. In stem cross-sections we identified one line with phloem- and four with xylem-specific expression, as well as nine lines with expression in both phloem and xylem and two with cambial expression. For all lines, we also report the expression patterns in different organs and developmental stages. Special features of expression patterns include a line with auxin-dependent expression domains. We determined the flanking sequences of 21 enhancer trap insertions, 16 of which are found in, or in close proximity to, annotated genes and thus may reflect the expression patterns of natural promoters. Finally, we analyzed the loss-of-function phenotypes of 14 putatively affected genes. Remarkably, mutations in a gene encoding a putative F-box protein were associated with an auxin-hypersensitive hypocotyl elongation response. Our compendium provides a diverse selection of markers for different vascular cell states, which can be used for targeted gene expression, cell type-specific transcript profiling and gene function assignment in the plant vascular system.

Ethylene and shoot regeneration: hookless1 modulates de novo shoot organogenesis in Arabidopsis thaliana.

We have investigated the role of ethylene in shoot regeneration from cotyledon explants of Arabidopsis thaliana. We examined the ethylene sensitivity of five ecotypes representing both poor and prolific shoot regenerators and identified Dijon-G, a poor regenerator, as an ecotype with dramatically enhanced ethylene sensitivity. However, inhibiting ethylene action with silver nitrate generally reduced shoot organogenesis in ecotypes capable of regeneration. In ecotype Col-0, we found that ethylene-insensitive mutants (etr1-1, ein2-1, ein4, ein7) exhibited reduced shoot regeneration rates, whereas constitutive ethylene response mutants (ctr1-1, ctr1-12) increased the proportion of explants producing shoots. Our experiments with ethylene over-production mutants (eto1, eto2 and eto3) indicate that the ethylene biosynthesis inhibitor gene, ETO1, can act as an inhibitor of shoot regeneration. Pharmacological elevation of ethylene levels was also found to significantly increase the proportion of explants regenerating shoots. We determined that the hookless1 (hls1-1) mutant, a suppressor of the ethylene response phenotypes of ctr1 and eto1 mutants, is capable of dramatically enhancing shoot organogenesis. The effects of ACC and loss of HLS1 function on shoot organogenesis were found to be largely additive.