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Abstract Arabidopsis thaliana is currently the most-studied plant species on earth, with an unprecedented number of genetic, genomic, and molecular resources having been generated in this plant model. In the era of translating foundational discoveries to crops and beyond, we aimed to highlight the utility and challenges of using Arabidopsis as a reference for applied plant biology research, agricultural innovation, biotechnology, and medicine. We hope that this review will inspire the next generation of plant biologists to continue leveraging Arabidopsis as a robust and convenient experimental system to address fundamental and applied questions in biology. We aim to encourage laboratory and field scientists alike to take advantage of the vast Arabidopsis datasets, annotations, germplasm, constructs, methods, and molecular and computational tools in our pursuit to advance understanding of plant biology and help feed the world's growing population. We envision that the power of Arabidopsis-inspired biotechnologies and foundational discoveries will continue to fuel the development of resilient, high-yielding, nutritious plants for the betterment of plant and animal health and greater environmental sustainability. 

SUMMARY Genome editing technologies like CRISPR/Cas have greatly accelerated the pace of both fundamental research and translational applications in agriculture. However, many plant biologists are functionally limited to creating small, targeted DNA changes or large, random DNA insertions. The ability to efficiently generate large, yet precise, DNA changes will massively accelerate crop breeding cycles, enabling researchers to more efficiently engineer crops amidst a rapidly changing agricultural landscape. This review provides an overview of existing technologies that allow plant biologists to integrate large DNA sequences within a plant host and some associated technical bottlenecks. Additionally, this review explores a selection of emerging techniques in other host systems to inspire tool development in plants. 

Summary DNA assembly systems based on the Golden Gate method are popular in synthetic biology but have several limitations: small insert size, incompatibility with other cloning platforms, DNA domestication requirement, generation of fusion scars, and lack of post‐assembly modification. To address these obstacles, we present the DASH assembly toolset, which combines features of Golden Gate‐based cloning, recombineering, and site‐specific recombinase systems. We developed (1) a set of donor vectors based on the GoldenBraid platform, (2) an acceptor vector derived from the plant transformation‐competent artificial chromosome (TAC) vector, pYLTAC17, and (3) a re‐engineered recombineering‐readyE. colistrain, CZ105, based on SW105. The initial assembly steps are carried out using the donor vectors following standard GoldenBraid assembly procedures. Importantly, existing parts and transcriptional units created using compatible Golden Gate‐based systems can be transferred to the DASH donor vectors using standard single‐tube restriction/ligation reactions. The cargo DNA from a DASH donor vector is then efficiently transferredin vivoinE. coliinto the acceptor vector by the sequential action of a rhamnose‐inducible phage‐derived PhiC31 integrase and arabinose‐inducible yeast‐derived Flippase (FLP) recombinase using CZ105. Furthermore, recombineering‐based post‐assembly modification, including the removal of undesirable scars, is greatly simplified. To demonstrate the utility of the DASH system, a 116 kilobase (kb) DNA construct harbouring a 97 kb cargo consisting of 35 transcriptional units was generated. One of the coding DNA sequences (CDSs) in the final assembly was replaced through recombineering, and thein plantafunctionality of the entire construct was tested in both transient and stable transformants. 

Summary Advancement of DNA‐synthesis technologies has greatly facilitated the development of synthetic biology tools. However, high‐complexity DNA sequences containing tandems of short repeats are still notoriously difficult to produce synthetically, with commercial DNA synthesis companies usually rejecting orders that exceed specific sequence complexity thresholds. To overcome this limitation, we developed a simple, single‐tube reaction method that enables the generation of DNA sequences containing multiple repetitive elements. Our strategy involves commercial synthesis and PCR amplification of padded sequences that contain the repeats of interest, along with random intervening sequence stuffers that include type IIS restriction enzyme sites. GoldenBraid molecular cloning technology is then employed to remove the stuffers, rejoin the repeats together in a predefined order, and subclone the tandem(s) in a vector using a single‐tube digestion–ligation reaction. In our hands, this new approach is much simpler, more versatile and efficient than previously developed solutions to this problem. As a proof of concept, two different phytohormone‐responsive, synthetic, repetitive proximal promoters were generated and testedin plantain the context of transcriptional reporters. Analysis of transgenic lines carrying the synthetic ethylene‐responsive promoter10x2EBS‐S10fused to theGUSreporter gene uncovered several developmentally regulated ethylene response maxima, indicating the utility of this reporter for monitoring the involvement of ethylene in a variety of physiologically relevant processes. These encouraging results suggest that this reporter system can be leveraged to investigate the ethylene response to biotic and abiotic factors with high spatial and temporal resolution. 

Plants often live in adverse environmental conditions and are exposed to various stresses, such as heat, cold, heavy metals, salt, radiation, poor lighting, nutrient deficiency, drought, or flooding. To adapt to unfavorable environments, plants have evolved specialized molecular mechanisms that serve to balance the trade-off between abiotic stress responses and growth. These mechanisms enable plants to continue to develop and reproduce even under adverse conditions. Ethylene, as a key growth regulator, is leveraged by plants to mitigate the negative effects of some of these stresses on plant development and growth. By cooperating with other hormones, such as jasmonic acid (JA), abscisic acid (ABA), brassinosteroids (BR), auxin, gibberellic acid (GA), salicylic acid (SA), and cytokinin (CK), ethylene triggers defense and survival mechanisms thereby coordinating plant growth and development in response to abiotic stresses. This review describes the crosstalk between ethylene and other plant hormones in tipping the balance between plant growth and abiotic stress responses.