SEPALLATA-driven MADS transcription factor tetramerization is required for inner whorl floral organ development.

MADS transcription factors are master regulators of plant reproduction and flower development. The SEPALLATA (SEP) subfamily of MADS transcription factors is required for the development of floral organs and plays roles in inflorescence architecture and development of the floral meristem. SEPALLATAs act as organizers of MADS complexes, forming both heterodimers and heterotetramers in vitro. To date, the MADS complexes characterized in angiosperm floral organ development contain at least one SEPALLATA protein. Whether DNA-binding by SEPALLATA-containing dimeric MADS complexes is sufficient for launching floral organ identity programs, however, is not clear as only defects in floral meristem determinacy were observed in tetramerization--impaired SEPALLATA mutant proteins. Here, we used a combination of genome-wide binding studies, high resolution structural studies of the SEP3/AGAMOUS (AG) tetramerization domain, structure-based mutagenesis and complementation experiments in Arabidopsis (Arabidopsis thaliana) sep1 sep2 sep3 and sep1 sep2 sep3 ag-4 plants transformed with versions of SEP3 encoding tetramerization mutants. We demonstrate that while SEP3 heterodimers can bind DNA both in vitro and in vivo and recognize the majority of SEP3 wild-type binding sites genome-wide, tetramerization is required not only for floral meristem determinacy, but also for floral organ identity in the second, third and fourth whorls.

Both NPY-Expressing and CART-Expressing Neurons Increase Energy Expenditure and Trabecular Bone Mass in Response to AP1 Antagonism, But Have Opposite Effects on Bone Resorption.

Energy metabolism and bone homeostasis share several neuronal regulatory pathways. Within the ventral hypothalamus (VHT), the orexigenic neurons co-express Agouti-related peptide (AgRP) and neuropeptide Y (NPY) and the anorexigenic neurons co-express, α-melanocyte stimulating hormone derived from proopiomelanocortin (POMC), and cocaine and amphetamine-regulated transcript (CART). These neurons regulate both processes, yet their relative contribution is unknown. Previously, using genetically targeted activator protein (AP1) alterations as a tool, we showed in adult mice that AgRP or POMC neurons are capable of inducing whole-body energy catabolism and bone accrual, with different effects on bone resorption. Here, we investigated whether co-residing neurons exert similar regulatory effects. We show that AP1 antagonists targeted to NPY-producing or CART-producing neurons in adult mice stimulate energy expenditure, reduce body weight gain and adiposity and promote trabecular bone formation and mass, yet again via different effects on bone resorption, as measured by serum level of carboxy-terminal collagen type I crosslinks (CTX). In addition, AP1 antagonists promote neurite expansion, increasing neurite number, length, and surface area in primary hypothalamic neuronal cultures. Overall, our data demonstrate that the orexigenic NPY and anorexigenic CART neurons both have the capacity to stimulate energy burning state and increase bone mass. © 2020 American Society for Bone and Mineral Research.

Structural Basis for Plant MADS Transcription Factor Oligomerization.

MADS transcription factors (TFs) are DNA binding proteins found in almost all eukaryotes that play essential roles in diverse biological processes. While present in animals and fungi as a small TF family, the family has dramatically expanded in plants over the course of evolution, with the model flowering plant, Arabidopsis thaliana, possessing over 100 type I and type II MADS TFs. All MADS TFs contain a core and highly conserved DNA binding domain called the MADS or M domain. Plant MADS TFs have diversified this domain with plant-specific auxiliary domains. Plant type I MADS TFs have a highly diverse and largely unstructured Carboxy-terminal (C domain), whereas type II MADS have added oligomerization domains, called Intervening (I domain) and Keratin-like (K domain), in addition to the C domain. In this mini review, we describe the overall structure of the type II "MIKC" type MADS TFs in plants, with a focus on the K domain, a critical oligomerization module. We summarize the determining factors for oligomerization and provide mechanistic insights on how secondary structural elements are required for oligomerization capability and specificity. Using MADS TFs that are involved in flower organ specification as an example, we provide case studies and homology modeling of MADS TFs complex formation. Finally, we highlight outstanding questions in the field.