Plant metabolism is more complex relative to individual microbes. In single‐celled microbes, transcriptional regulation by single transcription factors (TFs) is sufficient to shift primary metabolism. Corresponding genome‐level transcriptional regulatory maps of metabolism reveal the underlying design principles responsible for these shifts as a model in which master regulators largely coordinate specific metabolic pathways. Plant primary and specialized metabolism occur within innumerable cell types, and their reactions shift depending on internal and external cues. Given the importance of plants and their metabolites in providing humanity with food, fiber, and medicine, we set out to develop a genome‐scale transcriptional regulatory map of Arabidopsis metabolic genes. A comprehensive set of protein–DNA interactions between Arabidopsis thaliana TFs and gene promoters in primary and specialized metabolic pathways were mapped. To demonstrate the utility of this resource, we identified and functionally validated regulators of the tricarboxylic acid (TCA) cycle. The resulting network suggests that plant metabolic design principles are distinct from those of microbes. Instead, metabolism appears to be transcriptionally coordinated via developmental‐ and stress‐conditional processes that can coordinate across primary and specialized metabolism. These data represent the most comprehensive resource of interactions between TFs and metabolic genes in plants.
Background. The diatom Phaeodactylum tricornutum is a model photosynthetic organism. Functional genomic work in this organism has established a variety of genetic tools including RNA interference (RNAi). RNAi is a post-transcriptional regulatory process that can be utilized 25 to knockdown expression of genes of interest in eukaryotes. RNAi has been previously demonstrated in P. tricornutum, but in practice the efficiency of inducing RNAi is low. Methods.We developed an efficient method for construction of inverted repeat hairpins based on Golden Gate DNA assembly into a Gateway entry vector. The hairpin constructs were then 30 transferred to a variety of destination vectors through the Gateway recombination system. After recombining the hairpin into the destination vector, the resulting expression vector was mobilized into P. tricornutum using direct conjugation from E. coli. Because the hairpin expression vectors had sequences allowing for episomal maintenance in P. tricornutum, we tested whether a consistent, episomal location for hairpin expression improved RNAi induction Results. We successfully demonstrated that RNAi could be induced using hairpin constructs expressed from an episome. After testing two different reporter targets and a variety of hairpin sequences with 3 polymerase II and 2 polymerase III promoters, we achieved a maximal RNAi 40 induction efficiency of 25% of lines displaying knockdown of reporter activity by 50% or more. We created many useful genetic tools through this work including Gateway destination vectors for P. tricornutum expression from a variety of polymerase II and III promoters including the P. tricornutum FCPB, H4, and 49202 polymerase II promoters as well as the U6 and snRNA polymerase III promoters. We also created Gateway destination vectors that allow a cassette 45 cloned in an entry vector to be easily recombined into a transcriptional fusion with either ShBle or, for polymerase III promoters, the green fluorescent Spinach aptamer. Such transcriptional fusions allow for linkage of expression with a marker such as bleomycin resistance or fluorescence from the Spinach aptamer to easily select or screen for lines that maintain transgene expression. 50Discussion. While RNAi can be used as an effective tool for P. tricornutum genetics, especially where targeted knockouts may be lethal to the cell, induction of this process remains low efficiency. Techniques resulting in higher efficiency establishment of RNAi would be of great use to the diatom genetics community and would enable this technique to be used as a forward
In single-celled microbes, transcriptional regulation by single transcription factors is sufficient to shift primary metabolism. Corresponding genome-level transcriptional regulatory maps of metabolism reveal the underlying design principles responsible for these shifts as a model in which master regulators largely coordinate specific metabolic pathways. Relative to individual microbes, plant metabolism is more complex. Primary and specialized metabolism occur within innumerable cell types, and their reactions shift depending on internal and external cues. Given the importance of plants and their metabolites in providing humanity with food, fiber and medicine, we set out to develop a genome-scale transcriptional regulatory map of Arabidopsis metabolic genes. A comprehensive set of protein-DNA interactions between Arabidopsis thaliana transcription factors and promoters of primary metabolism and specialized metabolism were mapped. To demonstrate the utility of this resource, we identified and functionally validated regulators of the TCA cycle. The resulting network suggests that plant metabolic design principles are distinct from that of microbes. Instead, metabolism appears to be transcriptionally coordinated via developmental- and stress-conditional processes that can coordinate across primary and specialized metabolism. These data represent the most comprehensive resource of interactions between TFs and metabolic genes in plants.
Background. The diatom Phaeodactylum tricornutum is a model photosynthetic organism. Functional genomic work in this organism has established a variety of genetic tools including RNA interference (RNAi). RNAi is a post-transcriptional regulatory process that can be utilized 25 to knockdown expression of genes of interest in eukaryotes. RNAi has been previously demonstrated in P. tricornutum, but in practice the efficiency of inducing RNAi is low. Methods.We developed an efficient method for construction of inverted repeat hairpins based on Golden Gate DNA assembly into a Gateway entry vector. The hairpin constructs were then 30 transferred to a variety of destination vectors through the Gateway recombination system. After recombining the hairpin into the destination vector, the resulting expression vector was mobilized into P. tricornutum using direct conjugation from E. coli. Because the hairpin expression vectors had sequences allowing for episomal maintenance in P. tricornutum, we tested whether a consistent, episomal location for hairpin expression improved RNAi induction Results. We successfully demonstrated that RNAi could be induced using hairpin constructs expressed from an episome. After testing two different reporter targets and a variety of hairpin sequences with 3 polymerase II and 2 polymerase III promoters, we achieved a maximal RNAi 40 induction efficiency of 25% of lines displaying knockdown of reporter activity by 50% or more. We created many useful genetic tools through this work including Gateway destination vectors for P. tricornutum expression from a variety of polymerase II and III promoters including the P. tricornutum FCPB, H4, and 49202 polymerase II promoters as well as the U6 and snRNA polymerase III promoters. We also created Gateway destination vectors that allow a cassette 45 cloned in an entry vector to be easily recombined into a transcriptional fusion with either ShBle or, for polymerase III promoters, the green fluorescent Spinach aptamer. Such transcriptional fusions allow for linkage of expression with a marker such as bleomycin resistance or fluorescence from the Spinach aptamer to easily select or screen for lines that maintain transgene expression. 50Discussion. While RNAi can be used as an effective tool for P. tricornutum genetics, especially where targeted knockouts may be lethal to the cell, induction of this process remains low efficiency. Techniques resulting in higher efficiency establishment of RNAi would be of great use to the diatom genetics community and would enable this technique to be used as a forward
Bacterial conjugation utilizes a type IV secretion system and a DNA transfer mechanism to deliver DNA from one cell to another. Conjugative partners are conventionally confined to the prokaryotic domain. In a prominent exception, Agrobacterium tumefaciens type IV secretion-mediated transfer of DNA to plant cells can result in subsequent chromosomal integration. Recently, we demonstrated interdomain conjugation from Escherichia coli to the diatom Phaeodactylum tricornutum with the subsequent maintenance of an episome at chromosomal copy numbers if it contains diatom centromeres or centromere-like elements. The genes involved in the conjugation process can be separated into those encoding the type IV secretion system, also called the mating pair formation (MPF) genes, and genes involved in DNA processing called the mobilization (MOB) genes. Various protein families compose each class of conjugation genes, including common MOB types F, P, and Q and MPF types F, P, and T. The conjugative transfer from E. coli to P. tricornutum was demonstrated with a vector expressing MOBP and MTFP. Here we show that the MOBPsystem can be deleted and complemented with a MOBQ system in E.coli-diatom conjugations with subsequent episomal maintenaince. Utilization of both MOBP and MOBQ systems results in substantially higher efficiencies in E. coli-diatom conjugation. Finally, we demonstrate conjugative gene transfer between P. tricornutum and A. tumefaciens expressing a MPFT, the first demonstration of this system in diatoms,resulting in episomal maintainance or chromosomal integration, depending on the ex-conjugant. The promiscuity of MOB and MTF systems permitting prokaryote to diatom conjugative DNA transfer suggest major environmental and evolutionary importance of this process. The increased efficiency of dual MOB systems immediately improves genetic engineering in diatoms and has interesting basic cellular biology implications.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
