Introduction

Auxins are plant hormones (phytohormones) which are involved in the regulation of plant growth and development¹. Indole acetic acid (IAA) is the most widely characterised auxin, and the primary auxin in most plant species². It is associated with many physiological processes in plants including cell elongation, cell division, tropisms to light and gravity, and root initiation and development¹.

Plants can naturally synthesise auxins, and the biosynthesis of IAA in A. thaliana occurs predominantly through a tryptophan dependent pathway utilising proteins from the tryptophan amino transferase of Arabidopsis (TAA) and Yucca (YUC) flavin monooxygenase-like protein families³. Bacteria can also synthesise IAA through a variety of pathways, and often utilise IAA to interact with and colonise plants⁴. To test our scaffold system we chose the two-step indole-3-acetamide pathway for IAA biosynthesis, the best characterised IAA biosynthetic pathway in bacteria⁴, as a proof of concept.

Although plants can synthesise IAA de novo, application of exogenous phytohormones is common in industry to stimulate specific responses⁵. Thus auxins, and phytohormones more broadly, have commercial significance. One example of this is the use of phytohormones in tissue culture. Tissue culture, which grows plant cells, tissues and organs, on nutrient medium in controlled aseptic conditions has many commercial applications including propagation of valuable samples which can not be propagated by traditional methods⁶.