Ubiquitous activation of TLOG1 uncovered a developmentally suppressed tuber-forming potential within tomato axillary meristems. Other meristems in other plants may also carry hidden, suppressed organogenesis potentials. The unlocking of this potential by the activity of a single gene represents a prime example of an evolutionary novelty in the making and suggests that CKs may function as universal regulators of storage-organ formation in plants.
Our previous studies have found that expression of p27 in oligodendrocytes enhances myelin basic protein (MBP) gene expression through a mechanism that involves the transcription factor Sp1. In this study we show that this activation only requires the N-terminal 45 amino acids of p27 containing a functional cyclin-binding motif. In an effort to identify other cofactors that are involved in the p27-mediated activation of MBP gene expression, a yeast two-hybrid assay was performed using an N-terminal truncated p27 and a mouse embryo cDNA library. Galectin-4 was found to interact with p27 in the yeast two-hybrid assay. This novel interaction was also confirmed using a glutathione-S-transferase interaction assay and immunoprecipitation assays. Expression of galectin-4 in primary oligodendrocytes was confirmed by western blot. Additionally, the MBP promoter could be activated by expression of galectin-4 in CG4 oligodendrocytes, similar to the effects of increased p27 levels. We also show that Sp1 and galectin-4 interact in cells, while a complex of all three proteins could not be found. We conclude that galectin-4 is involved in the p27-mediated activation of the MBP gene, possibly through modulation of the glycosylation status of the transcription factor Sp1.
Myelin basic protein (MBP), which helps form compact myelin sheets, is a major protein expressed during oligodendrocyte (OL) differentiation. Myelin basic protein expression is regulated mainly at the transcriptional level. Previous studies showed that the transcription factor Sp1 can activate the MBP promoter. Data from the laboratory also indicate that Sp1 is expressed highly in both growing and differentiated cells. Because this is true, we wanted to understand how Sp1 activity is regulated such that it increases MBP gene transcription only in differentiating cells. Phosphorylation is one major way to regulate transcription factor activity. Our results show that there is more Sp1 binding to the MBP promoter in differentiating OLs. Sp1 is also more phosphorylated in differentiating OLs than in precursor cells. Using inhibitors of different pathways, we found that the protein kinase C (PKC) modulator phorbol 12-myristate 13-acetate (PMA) can increase Sp1 phosphorylation when the cells are treated for 1 hr and can decrease Sp1 phosphorylation with long treatment (12 hr). The increased phosphorylation of Sp1 induced by PMA in short treatments could be abolished by the extracellular signal-regulated kinases (ERK) pathway inhibitor PD98059. This indicates that PKC phosphorylates Sp1 through the ERK pathway. Mutation of Sp1 threonines 453 and 739, which are phosphorylated by ERK, decreased MBP transcriptional activity. Furthermore, we found that PKC regulates Sp1 phosphorylation only in differentiating OLs. In conclusion, our results indicate that, in OLs, Sp1 phosphorylation can be regulated by PKC-ERK pathways. This phosphorylation is important for MBP transcription and oligodendrocyte differentiation.
Florigen, a proteinaceous hormone, functions as a universal long-range promoter of flowering and concurrently as a generic growth-attenuating hormone across leaf and stem meristems. In flowering plants, the transition from the vegetative phase to the reproductive phase entails the orchestration of new growth coordinates and a global redistribution of resources, signals, and mechanical loads among organs. However, the ultimate cellular processes governing the adaptation of the shoot system to reproduction remain unknown. We hypothesized that if the mechanism for floral induction is universal, then the cellular metabolic mechanisms underlying the conditioning of the shoot system for reproduction would also be universal and may be best regulated by florigen itself. To understand the cellular basis for the vegetative functions of florigen, we explored the radial expansion of tomato stems. RNA-Seq and complementary genetic and histological studies revealed that florigen of endogenous, mobile, or induced origins accelerates the transcription network navigating secondary cell wall biogenesis as a unit, promoting vascular maturation and thereby adapting the shoot system to the developmental needs of the ensuing reproductive phase it had originally set into motion. We then demonstrated that a remarkably stable and broadly distributed florigen promotes MADS and MIF genes, which in turn regulate the rate of vascular maturation and radial expansion of stems irrespective of flowering or florigen level. The dual acceleration of flowering and vascular maturation by florigen provides a paradigm for coordinated regulation of independent global developmental programs.
Developmental Highlights-Florigen accelerates SCWB: A prime case for a long-range regulation of a complete metabolic network by a plant hormone.-The dual acceleration of flowering and vascular maturation by Florigen provides a paradigm for a dynamic regulation of global, independent, developmental programs.-The growth termination functions of florigen and the auto-regulatory mechanism for its production and distribution provide a communication network enveloping the shoot system. -A stable florigen provides a possible mechanism for the quantitative regulation of flowering -Lateral stimulation of xylem differentiation links the phloem-travelling florigen with the annual rings in trunks. -MADS genes are common relay partners in Florigen circuits; vascular maturation in stems and reproductive transition in apical meristems. Abstract The protein hormone florigen is a universal systemic inducer of flowering and a generic growth terminator across meristems. To understand the developmental rational for its pleiotropic functions and to uncover the deep cellular systems mobilized by florigen beyond flowering we explored termination of radial expansion of stems. Employing the power of tomato genetics along with RNAseq and histological validations we show that endogenous, mobile, or induced florigen accelerates secondary cell wall biogenesis (SCWB), and hence vascular maturation, independently of flowering. This finding is supported by a systemic florigen antagonist from the non-floweringGinkgo biloba, which arrests SCWB and by MADS and MIF genes downstream of florigen that similarly suppress or enhance, respectively, vascular maturation independent of flowering. We also show that florigen is remarkably stable and distributed to all organs regardless of existing endogenous levels. By accelerating SCWB, florigen reprograms the distribution of resources, signals and mechanical loads required for the ensuing reproductive phase it had originally set into motion.
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