Solanaceae specialized metabolism in a non-model plant: trichome acylinositol biosynthesis

Leong, Bryan J.; Hurney, Steven M.; Fiesel, Paul D.; Moghe, Gaurav D.; Jones, A. Daniel

doi:10.1101/2020.03.04.977181

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“…Targeting ASAT1H, ASAT3H, and ASAT4H individually caused reductions in the four major acylinositols (Figure 2a,b, Tables S1 and S2). This phenotype is reminiscent of results from CRISPR knockout lines of ASATs in S. lycopersicum and S. pennellii , as well as VIGS of P. axillaris , S. sinuata , S. nigrum (Lou et al, 2021), and S. quitoense ASATs (Fan et al, 2016; Leong, 2019; Moghe et al, 2017; Nadakuduti et al, 2017; Schilmiller et al, 2015). Real‐time quantitative reverse transcription polymerase chain reaction (qRT‐PCR) analysis confirmed reductions in candidate transcript abundance in target plants relative to the controls, with three of six constructs significant at p < .05 (Figures S3 and S4).…”

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confidence: 86%

Identification of BAHD acyltransferases associated with acylinositol biosynthesis in Solanum quitoense (naranjilla)

et al. 2022

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Plants make a variety of specialized metabolites that can mediate interactions with animals, microbes, and competitor plants. Understanding how plants synthesize these compounds enables studies of their biological roles by manipulating their synthesis in vivo as well as producing them in vitro. Acylsugars are a group of protective metabolites that accumulate in the trichomes of many Solanaceae family plants.Acylinositol biosynthesis is of interest because it appears to be restricted to a subgroup of species within the Solanum genus. Previous work characterized a triacylinositol acetyltransferase involved in acylinositol biosynthesis in the Andean fruit plant Solanum quitoense (lulo or naranjilla). We characterized three additional S. quitoense trichome expressed enzymes and found that virus-induced gene silencing of each caused changes in acylinositol accumulation. pH was shown to influence the stability and rearrangement of the product of ASAT1H and could potentially play a role in acylinositol biosynthesis. Surprisingly, the in vitro triacylinositol products of these enzymes are distinct from those that accumulate in planta. This suggests that additional enzymes are required in acylinositol biosynthesis. These characterized S. quitoense enzymes, nonetheless, provide opportunities to test the biological impact and properties of these triacylinositols in vitro.

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