Plant hormones and their gene regulatory networks orchestrate a diverse array of metabolic and physiological changes crucial for growth, development, and environmental responses. Targeting the engineering of hormone signaling networks holds promise for enhancing plant health, crop productivity, and vigor. However, these networks are intricate, featuring negative feedback loops, extensive interconnections between pathways, pleiotropy, and overlapping gene expression. These complexities pose challenges in identifying candidate genes and parsing apart their isolated functions that could be strategically engineered to achieve desired plant phenotypes. Integration of comparative evolution, synthetic biology, and expression analysis facilitates the deconstruction of these networks. Through systems biology approaches data dimensionality can be reduced, enabling the attribution of specific phenotypes to associated genes. Here, I reviewed how the employment of these above-mentioned approaches can aid in the identification of candidate genes involved the regulation of growth and development within specific tissues, and how through synthetic biology we can explore the sequence-function space of candidate genes and their pathway modules. Candidate genes identified through this process can be evaluated through comparative evolutionary approaches, and efficiently tested in synthetic systems for engineering of their molecular functionalities in a high-throughput manner. Here, as a case study, I employ a systems biology approach to identify tissue-specific candidate genes within the auxin regulatory network in soybean shoot development. This method aims to minimize pleiotropy and off-target effects by utilizing expression analysis tissue-specificity score and principal component analysis.
I primarily, focused on three pivotal components of the nuclear auxin signaling pathway: Aux/IAA transcriptional repressors, ARF transcription factors, and TIR1/AFB auxin receptors. These components collectively modulate auxin signaling, influencing various growth and environmental responses. I identified genes within the three pivotal components of auxin signaling involved in early shoot architecture development, which has advantages from weed suppression to yield in soybean cultivation. I used a yeast chassis to investigate the function of pleiotropic auxin receptors, which primarily regulate Aux/IAA levels and orchestrate transcriptional changes in response to auxin. I explored whether these receptors modulate auxin response in a concerted fashion, as they are generally not tissue specific. Here, I reported that auxin receptors interact in an epistatic manner to modulate auxin response. This case of study serves as a foundation in engineering plant genotype-phenotype via auxin signaling. / Doctor of Philosophy / Plant hormones are essential for controlling various processes that drive plant growth, development, and responses to the environment. Scientists are exploring ways to engineer the networks that regulate these hormones to improve plant health, boost crop yields, and enhance plant strength. However, these networks are complex, with many interacting parts, making it difficult to identify which genes to modify to achieve specific outcomes in plants. To tackle this challenge, researchers use a combination of approaches, including studying how these networks have evolved, analyzing large amounts of biological data, and using synthetic biology to test and refine their findings. By breaking down the complexity of these networks, they can link specific genes to particular plant traits. Once these genes–trait links are identified, they can be further tested and engineered to optimize plant characteristics. In this study, I focused on the auxin hormone, which plays a key role in numerous aspects of plant growth including soybean shoot development and Arabidopsis root development. I looked at three main components of the auxin regulatory network: Aux/IAA proteins (which act as repressors), ARF transcription factors (which control gene expression), and TIR1/AFB receptors (which detect auxin levels). These components work together to regulate how plants grow and respond to their environment. I identified key genes within these main auxin components that are important for early development of soybean shoots and minimizes off-target effects. This can help improve soybean farming by enhancing weed control and enhancing crop yields Using a synthetic biology yeast system, I studied the function of TIR1/AFB auxin receptors and how this family of receptors interact to perceive auxin and control the levels of Aux/IAA proteins, consequently controlling the plant's growth in response to auxin. I found that auxin receptors work in concert in a way that reduces their overall effect on the plants response to auxin. This research lays the groundwork for future efforts to engineer plant traits by modifying the auxin signaling pathway, which could lead to improved crop performance and resilience.
Identifer | oai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/121131 |
Date | 13 September 2024 |
Creators | Ferreira Neres, Deisiany |
Contributors | Biological Systems Engineering, Wright, Robert Clay, Sobrado, Pablo, Senger, Ryan S., Sherif, Sherif Mohamed |
Publisher | Virginia Tech |
Source Sets | Virginia Tech Theses and Dissertation |
Language | English |
Detected Language | English |
Type | Dissertation |
Format | ETD, application/pdf |
Rights | Creative Commons Attribution-NonCommercial 4.0 International, http://creativecommons.org/licenses/by-nc/4.0/ |
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