Allomorphy as a mechanism of post-translational control of enzyme activity

Enzyme regulation is vital for metabolic adaptability in living systems. Fine control of enzyme activity is often delivered through post-translational mechanisms, such as allostery or allokairy. β-phosphoglucomutase (βPGM) from Lactococcus lactis is a phosphoryl transfer enzyme required for complete catabolism of trehalose and maltose, through the isomerisation of β-glucose 1-phosphate to glucose 6-phosphate via β-glucose 1,6-bisphosphate. Surprisingly for a gatekeeper of glycolysis, no fine control mechanism of βPGM has yet been reported. Herein, we describe allomorphy, a post-translational control mechanism of enzyme activity. In βPGM, isomerisation of the K145-P146 peptide bond results in the population of two conformers that have different activities owing to repositioning of the K145 sidechain. In vivo phosphorylating agents, such as fructose 1,6-bisphosphate, generate phosphorylated forms of both conformers, leading to a lag phase in activity until the more active phosphorylated conformer dominates. In contrast, the reaction intermediate β-glucose 1,6-bisphosphate, whose concentration depends on the β-glucose 1-phosphate concentration, couples the conformational switch and the phosphorylation step, resulting in the rapid generation of the more active phosphorylated conformer. In enabling different behaviours for different allomorphic activators, allomorphy allows an organism to maximise its responsiveness to environmental changes while minimising the diversion of valuable metabolites

Co-Simulation for Design, Optimization and Analysis of All-Electric Aircraft Systems

The current need to reduce emissions from air traffic leads to a rapid transition from ponderous and squandering to lightweight and energy efficient aircraft. Within this development many aircraft systems are electrified in order to eliminate pneumatic and hydraulic power sources. Furthermore, not having to bleed air from the engine compressor increases engine efficiency and the removal of hydraulic fluid contributes to reduce the environmental impact. Such an aircraft design requires all on-board systems be electric and share a common power source. This necessitates evaluating the electrical performance of the complete aircraft system in order to correctly specify generators, distribution networks and algorithms to reliably manage the distribution of electrical power in various load cases. To test and validate said energy management, static and dynamic performances of on-board systems need to be assessed with particular focus on electrical loads. These measures must be done early in the design process, ideally through simulations. However, different subsystems are often implemented in various simulation environments, each specifically suited to the task at hand. Consequently, the evaluation of the entire aircraft system requires a shared simulation environment (SSE) integrating individual sub-systems. For this purpose, we have developed detailed models of different on-board systems (EBird project) as well as an SSE connecting the different components (iSSE project). This work was performed within the framework of the CleanSky Green Regional Aircraft (GRA) research programme

Folding of class A beta-lactamases is rate-limited by peptide bond isomerization and occurs via parallel pathways.

Class A beta-lactamases (M(r) approximately 29000) provide good models for studying the folding mechanism of large monomeric proteins. In particular, the highly conserved cis peptide bond between residues 166 and 167 at the active site of these enzymes controls important steps in their refolding reaction. In this work, we analyzed how conformational folding, reactivation, and cis/trans peptide bond isomerizations are interrelated in the folding kinetics of beta-lactamases that differ in the nature of the cis peptide bond, which involves a Pro167 in the BS3 and TEM-1 enzyme, a Leu167 in the NMCA enzyme, and which is missing in the PER-1 enzyme. The analysis of folding by spectroscopic probes and by the regain of enzymatic activity in combination with double-mixing procedures indicates that conformational folding can proceed when the 166-167 bond is still in the incorrect trans form. The very slow trans --> cis isomerization of the Glu166-Xaa167 peptide bond, however, controls the final step of folding and is required for the regain of the enzymatic activity. This very slow phase is absent in the refolding of PER-1, in which the Glu166-Ala167 peptide bond is trans. The double-mixing experiments revealed that a second slow kinetic phase is caused by the cis/trans isomerization of prolines that are trans in the folded proteins. The folding of beta-lactamases is best described by a model that involves parallel pathways. It highlights the role of peptide bond cis/trans isomerization as a kinetic determinant of folding