Search for: All records

Abstract Phosphopantetheinyl transferases (PPTases) play an essential role in primary and secondary metabolism. These enzymes facilitate the post-translational activation of acyl carrier proteins (ACPs) central to the biosynthesis of fatty acids and polyketides. Modulation of ACP-PPTase interactions is a promising approach to both increase access to desired molecular outputs and disrupt mechanisms associated with disease progression. However, such an approach requires understanding the molecular principles that govern ACP-PPTase interactions across diverse synthases. Through a multi-year, course-based undergraduate research experience (CURE), 17 ACPs representing a range of putative type II polyketide synthases, from actinobacterial and non-actinobacterial phyla, were evaluated as substrates for three PPTases (AcpS, Sfp, and vulPPT). The observed PPTase compatibility, sequence-level analyses, and predictive structural modelling suggest that ACP selectivity is driven by amino acids surrounding the conserved, modified serine on the ACP. We propose that vulPPT and Sfp are driven primarily by hydrophobic contacts, whereas AcpS may favor ACPs which exhibit high net-negative charge density, as well as a broad electronegative surface distribution. Furthermore, we report a plausible, hitherto unreported hydrophobic interaction between vulPPT and a conserved ACP crease, upstream of the invariant serine, which may facilitate docking. This work provides a catalog of compatible and incompatible ACP-PPTase partnerships, highlighting specific regions on the ACP and/or PPTase that show promise for future strategic engineering and inhibitor development efforts. 

Abstract Maize (Zea mays) kernels are the largest cereal grains, and their endosperm is severely oxygen deficient during grain fill. The causes, dynamics, and mechanisms of acclimation to hypoxia are minimally understood. Here, we demonstrate that hypoxia develops in the small, growing endosperm, but not the nucellus, and becomes the standard state, regardless of diverse structural and genetic perturbations in modern maize (B73, popcorn, sweet corn), mutants (sweet4c, glossy6, waxy), and non-domesticated wild relatives (teosintes and Tripsacum species). We also uncovered an interconnected void space at the chalazal pericarp, providing superior oxygen supply to the placental tissues and basal endosperm transfer layer. Modeling indicated a very high diffusion resistance inside the endosperm, which, together with internal oxygen consumption, could generate steep oxygen gradients at the endosperm surface. Manipulation of oxygen supply induced reciprocal shifts in gene expression implicated in controlling mitochondrial functions (23.6 kDa Heat-Shock Protein, Voltage-Dependent Anion Channel 2) and multiple signaling pathways (core hypoxia genes, cyclic nucleotide metabolism, ethylene synthesis). Metabolite profiling revealed oxygen-dependent shifts in mitochondrial pathways, ascorbate metabolism, starch synthesis, and auxin degradation. Long-term elevated oxygen supply enhanced the rate of kernel development. Altogether, evidence here supports a mechanistic framework for the establishment of and acclimation to hypoxia in the maize endosperm.