Auxins help development at all levels in plants, from the
cellular level, through organs, and ultimately to the whole plant.
Molecular mechanisms When a plant cell comes into contact with auxin, it causes dramatic changes in
gene expression, with many genes up- or down-regulated. The precise mechanisms by which this occurs are still an area of active research, but there is now a general consensus on at least two auxin signalling pathways.
Perception The best-characterized auxin receptors are the TIR1/ AFB family of
F-box proteins. F-box proteins target other proteins for degradation via the
ubiquitin degradation pathway. When TIR1/ AFB proteins bind to auxin, the auxin molecule acts as a '
molecular glue', a term coined by
Ning Zheng, that allows these proteins to then bind to their targets (see below). The atomic structure of the perception mechanism of auxin by TIR1 was determined by
X-ray crystallography. Another auxin-binding protein, ABP1 is now often regarded as an auxin receptor (at the
apoplast), but it is generally considered to have a much more minor role than the TIR1/AFB signaling pathway, and much less is known about ABP1 signaling. The large number of Aux/IAA and ARF binding pairs possible, and their different distributions between cell types and across developmental age are thought to account for the astonishingly diverse responses that auxin produces. In June 2018, it was demonstrated that plant tissues can respond to auxin in a TIR1-dependent manner extremely quickly (probably too quickly to be explained by changes in gene expression). This has led some scientists to suggest that there is an as yet unidentified TIR1-dependent auxin-signalling pathway that differs from the well-known transcriptional response.
On a cellular level On the cellular level, auxin is essential for
cell growth, affecting both
cell division and cellular expansion. Auxin concentration level, together with other local factors, contributes to
cell differentiation and specification of the cell fate. Depending on the specific tissue, auxin may promote axial elongation (as in shoots), lateral expansion (as in root swelling), or iso-diametric expansion (as in fruit growth). In some cases (coleoptile growth), auxin-promoted cellular expansion occurs in the absence of cell division. In other cases, auxin-promoted cell division and cell expansion may be closely sequenced within the same tissue (root initiation, fruit growth). In a living plant, auxins and other plant hormones nearly always appear to interact to determine patterns of plant development.
Organ patterns Growth and division of plant cells together result in the growth of
tissue, and specific tissue growth contributes to the development of plant
organs. Growth of cells contributes to the plant's size, unevenly localized growth produces bending, turning and directionalization of organs- for example, stems turning toward light sources (
phototropism), roots growing in response to gravity (
gravitropism), and other
tropisms originated because cells on one side grow faster than the cells on the other side of the organ. So, precise control of auxin distribution between different cells has paramount importance to the resulting form of plant growth and organization.
Auxin transport and the uneven distribution of auxin To cause growth in the required domains, auxins must of necessity be active preferentially in them. Local auxin maxima can be formed by active biosynthesis in certain cells of tissues, for example via tryptophan-dependent pathways, but auxins are not synthesized in all cells (even if cells retain the potential ability to do so, only under specific conditions will auxin synthesis be activated in them). For that purpose, auxins have to be not only translocated toward those sites where they are needed but also they must have an established mechanism to detect those sites. Translocation is driven throughout the plant body, primarily from
peaks of shoots to peaks of roots (from up to down). For long distances, relocation occurs via the stream of fluid in
phloem vessels, but, for short-distance transport, a unique system of coordinated polar transport directly from cell to cell is exploited. This short-distance, active transport exhibits some
morphogenetic properties. This process,
polar auxin transport, is directional, very strictly regulated, and based in uneven distribution of auxin efflux carriers on the plasma membrane, which send auxins in the proper direction. While PIN-FORMED (PIN) proteins are vital in transporting auxin in a polar manner, the family of AUXIN1/LIKE-AUX1 (AUX/LAX) genes encodes for non-polar auxin influx carriers. The regulation of PIN protein localisation in a cell determines the direction of auxin transport from cell, and concentrated effort of many cells creates peaks of auxin, or auxin maxima (regions having cells with higher auxin – a maximum). Proper and timely auxin maxima within developing roots and shoots are necessary to organise the development of the organ. PINs are regulated by multiple pathways, at both the transcriptional and the post-translational levels. PIN proteins can be phosphorylated by PINOID, which determines their apicobasal polarity and thereby the directionality of auxin fluxes. In addition, other AGC kinases, such as D6PK, phosphorylate and activate PIN transporters. AGC kinases, including PINOID and D6PK, target to the plasma membrane via binding to phospholipids. Upstream of D6PK, 3'-phosphoinositide dependent protein kinase 1 (PDK1) acts as a master regulator. PDK1 phosphorylates and activates D6PK at the basal side of plasma membrane, executing the activity of PIN-mediated polar auxin transport and subsequent plant development. Surrounding auxin maxima are cells with low auxin troughs, or auxin minima. For example, in the
Arabidopsis fruit, auxin minima have been shown to be important for its tissue development. Auxin has a significant effect on spatial and temporal gene expressions during the growth of apical meristems. These interactions depend both on the concentration of Auxin as well as the spatial orientation during primordial positioning. Auxin relies on PIN1 which works as an auxin efflux carrier. PIN1 positioning upon membranes determines the directional flow of the hormone from higher to lower concentrations. Initiation of primordia in apical meristems is correlated to heightened auxin levels. They are upregulated via auxin influx. they are also fundamentally required for proper development of the plant itself. Without hormonal regulation and organization, plants would be merely proliferating heaps of similar cells. Auxin employment begins in the embryo of the plant, where the directional distribution of auxin ushers in subsequent growth and development of primary growth poles, then forms buds of future organs. Next, it helps to coordinate proper development of the arising organs, such as roots, cotyledons, and leaves and mediates long-distance signals between them, contributing so to the overall architecture of the plant. Throughout the plant's life, auxin helps the plant maintain the polarity of growth, and actually "recognize" where it has its branches (or any organ) connected. An important principle of plant organization based upon auxin distribution is
apical dominance, which means the auxin produced by the apical bud (or growing tip) diffuses (and is transported) downwards and inhibits the development of ulterior lateral bud growth, which would otherwise compete with the apical tip for light and nutrients. Removing the apical tip and its suppressively acting auxin allows the lower dormant lateral buds to develop, and the buds between the leaf stalk and stem produce new shoots which compete to become the lead growth. The process is actually quite complex because auxin transported downwards from the lead shoot tip has to interact with several other plant hormones (such as
strigolactones or
cytokinins) in the process on various positions along the growth axis in plant body to achieve this phenomenon. This plant behavior is used in
pruning by horticulturists. Finally, the sum of auxin arriving from stems to roots influences the degree of root growth. If shoot tips are removed, the plant does not react just by the outgrowth of lateral buds — which are supposed to replace to original lead. It also follows that smaller amount of auxin arriving at the roots results in slower growth of roots and the nutrients are subsequently in higher degree invested in the upper part of the plant, which hence starts to grow faster. ==Effects==