Control of tissue dimensions in multicellular organisms requires the precise quantitative regulation of mitotic activity. In plants, where cells are immobile, tissue size is achieved through control of both cell division orientation and mitotic rate. The bHLH transcription factor heterodimer formed by target of monopteros5 (TMO5) and lonesome highway (LHW) is a central regulator of vascular width-increasing divisions. An important unanswered question is how its activity is limited to specify vascular tissue dimensions. Here we identify a regulatory network that restricts TMO5/LHW activity. We show that thermospermine synthase ACAULIS5 antagonizes TMO5/LHW activity by promoting the accumulation of SAC51-LIKE (SACL) bHLH transcription factors. SACL proteins heterodimerize with LHW-therefore likely competing with TMO5/LHW interactions-prevent activation of TMO5/LHW target genes, and suppress the over-proliferation caused by excess TMO5/LHW activity. These findings connect two thus-far disparate pathways and provide a mechanistic understanding of the quantitative control of vascular tissue growth.
Vitamin B 6 comprises a family of compounds that is essential for all organisms, most notable among which is the cofactor pyridoxal 59-phosphate (PLP). Other forms of vitamin B 6 include pyridoxamine 59-phosphate (PMP), pyridoxine 59-phosphate (PNP), and the corresponding nonphosphorylated derivatives. While plants can biosynthesize PLP de novo, they also have salvage pathways that serve to interconvert the different vitamers. The selective contribution of these various pathways to cellular vitamin B 6 homeostasis in plants is not fully understood. Although biosynthesis de novo has been extensively characterized, the salvage pathways have received comparatively little attention in plants. Here, we show that the PMP/PNP oxidase PDX3 is essential for balancing B 6 vitamer levels in Arabidopsis thaliana. In the absence of PDX3, growth and development are impaired and the metabolite profile is altered. Surprisingly, RNA sequencing reveals strong induction of stress-related genes in pdx3, particularly those associated with biotic stress that coincides with an increase in salicylic acid levels. Intriguingly, exogenous ammonium rescues the growth and developmental phenotype in line with a severe reduction in nitrate reductase activity that may be due to the overaccumulation of PMP in pdx3. Our analyses demonstrate an important link between vitamin B 6 homeostasis and nitrogen metabolism.
Triphosphate tunnel metalloenzymes (TTMs) are found in all biological kingdoms and have been characterized in microorganisms and animals. Members of the TTM family already characterized have divergent biological functions and act on a range of triphosphorylated substrates (RNA, thiamine tri-phosphate, inorganic polyphosphate). TTM proteins in plants have received considerably less atten-tion and are unique in that some homologs harbor additional domains including a P-loop kinase and transmembrane domain. Here we report on structural and functional aspects of the multimodular TTM1 and TTM2 of Arabidopsis thaliana. Tissue and cellular microscopy studies show that both AtTTM1 and AtTTM2 are expressed in actively dividing (meristem) tissue and are tail-anchored pro-teins at the outer mitochondrial membrane - mediated by the single transmembrane domain at the C-terminus, supporting earlier studies. Crystal structures of AtTTM1 in the presence and absence of a non-hydrolyzable ATP analog reveal a catalytically incompetent TTM tunnel domain tightly interact-ing with the P-loop kinase domain that is locked in an inactive conformation. Structural comparison reveals that a helical hairpin may facilitate movement of the TTM domain thereby activating the kinase. Genetic studies show that AtTTM2 is important for the developmental transition from the vegetative to the reproductive phase in Arabidopsis, whereas its closest paralog AtTTM1 is not. Rational design of mutations based on the 3D structure demonstrates that both the P-loop kinase and TTM tunnel mod-ules of AtTTM2 are required for the developmental switch.
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