Enzymology in vivo using NMR and molecular genetics

Models of metabolic flux regulation are frequently based on an extrapolation of the kinetic properties of enzymes measured in vitro to the intact cell. Such an extrapolation assumes a detailed knowledge of the intracellular environment of these enzymes in terms of their free substates and effectors concentrations and possible interaction with other cellular macromolecules, which may modify their kinetic properties. These is a considerable incentive, therefore, to study the properties of enzymes directly in vivo. We have been using non-invasive NMR techniques, in conjunction with molecular genetic manipulation of enzyme levels, to study the kinetic properties of individual enzymes in vivo. We have also developed a novel strategy which has allowed us to monitor, by NMR, the ligand binding properties and mobilities of enzymes in the intact cell. This technique may also allow us to measured the diffusion coefficients of these proteins in the cell. These studies should give new insight into the properties of enzymes in vivo     

Oxide-Based Solid-State Batteries: A Perspective on Composite Cathode Architecture

The garnet-type phase Li₇La₃Zr₂O₁₂ (LLZO) attracts significant attention as an oxide solid electrolyte to enable safe and robust solid-state batteries (SSBs) with potentially high energy density. However, while significant progress has been made in demonstrating compatibility with Li metal, integrating LLZO into composite cathodes remains a challenge. The current perspective focuses on the critical issues that need to be addressed to achieve the ultimate goal of an all-solid-state LLZO-based battery that delivers safety, durability, and pack-level performance characteristics that are unobtainable with state-of-the-art Li-ion batteries. This perspective complements existing reviews of solid/solid interfaces with more emphasis on understanding numerous homo- and heteroionic interfaces in a pure oxide-based SSB and the various phenomena that accompany the evolution of the chemical, electrochemical, structural, morphological, and mechanical properties of those interfaces during processing and operation. Finally, the insights gained from a comprehensive literature survey of LLZO–cathode interfaces are used to guide efforts for the development of LLZO-based SSBs.     

Particle size influences decay rates of environmental DNA in aquatic systems

Environmental DNA (eDNA) analysis is a powerful tool for remote detection of target organisms. However, obtaining quantitative and longitudinal information from eDNA data is challenging, requiring a deep understanding of eDNA ecology. Notably, if the various size components of eDNA decay at different rates, and we can separate them within a sample, their changing proportions could be used to obtain longitudinal dynamics information on targets. To test this possibility, we conducted an aquatic mesocosm experiment in which we separated fish-derived eDNA components using sequential filtration to evaluate the decay rate and changing proportion of various eDNA particle sizes over time. We then fit four alternative mathematical decay models to the data, building towards a predictive framework to interpret eDNA data from various particle sizes. We found that medium-sized particles (1–10 μm) decayed more slowly than other size classes (i.e., <1 and > 10 μm), and thus made up an increasing proportion of eDNA particles over time. We also observed distinct eDNA particle size distribution (PSD) between our Common carp and Rainbow trout samples, suggesting that target-specific assays are required to determine starting eDNA PSDs. Additionally, we found evidence that different sizes of eDNA particles do not decay independently, with particle size conversion replenishing smaller particles over time. Nonetheless, a parsimonious mathematical model where particle sizes decay independently best explained the data. Given these results, we suggest a framework to discern target distance and abundance with eDNA data by applying sequential filtration, which theoretically has both metabarcoding and single-target applications.     

THE SARCOTUBULAR SYSTEM OF FROG SKELETAL MUSCLE : A Morphological and Biochemical Study

In the frog skeletal muscle cell a well defined and highly organized system of tubular elements is located in the sarcoplasm between the myofibrils. The sarcoplasmic component is called the sarcotubular system. By means of differential centrifugation it has been possible to isolate from the frog muscle homogenate a fraction composed of small vesicles, tubules, and particles. This fraction is without cytochrome oxidase activity, which is localized in the mitochondrial membranes. This indicates that the structural components of this fraction do not derive from the mitochondrial fragmentation, but probably from the sarcotubular system. This fraction, called sarcotubular fraction, has a Mg⁺⁺-stimulated ATPase activity which differs from that of muscle mitochondria in that it is 3 to 4 times higher on the protein basis as compared with the mitochondrial ATPase, and is inhibited by Ca⁺⁺ and by deoxycholate like the Kielley and Meyerhof ATPase. We therefore conclude that the "granules" of the Kielley and Meyerhof ATPase, which were shown to have a relaxing effect, are fragments of the sarcotubular system. The isolated sarcotubular fraction has a high RNA content and demonstrable activity in incorporating labeled amino acids, even in the absence of added supernatant.     

Tracking interactions that stabilize the dimer structure of starch phosphorylase from Corynebacterium callunae. Roles of Arg234 and Arg242 revealed by sequence analysis and site-directed mutagenesis.

Glycogen phosphorylases (GPs) constitute a family of widely spread catabolic alpha1,4-glucosyltransferases that are active as dimers of two identical, pyridoxal 5'-phosphate-containing subunits. In GP from Corynebacterium callunae, physiological concentrations of phosphate are required to inhibit dissociation of protomers and cause a 100-fold increase in kinetic stability of the functional quarternary structure. To examine interactions involved in this large stabilization, we have cloned and sequenced the coding gene and have expressed fully active C. callunae GP in Escherichia coli. By comparing multiple sequence alignment to structure-function assignments for regulated and nonregulated GPs that are stable in the absence of phosphate, we have scrutinized the primary structure of C. callunae enzyme for sequence changes possibly related to phosphate-dependent dimer stability. Location of Arg234, Arg236, and Arg242 within the predicted subunit-to-subunit contact region made these residues primary candidates for site-directed mutagenesis. Individual Arg-->Ala mutants were purified and characterized using time-dependent denaturation assays in urea and at 45 degrees C. R234A and R242A are enzymatically active dimers and in the absence of added phosphate, they display a sixfold and fourfold greater kinetic stability of quarternary interactions than the wild-type, respectively. The stabilization by 10 mm of phosphate was, however, up to 20-fold greater in the wild-type than in the two mutants. The replacement of Arg236 by Ala was functionally silent under all conditions tested. Arg234 and Arg242 thus partially destabilize the C. callunae GP dimer structure, and phosphate binding causes a change of their tertiary or quartenary contacts, likely by an allosteric mechanism, which contributes to a reduced protomer dissociation rate.     

Production and regeneration of protoplasts from the mycorrhizal fungus Suillus granulatus

Experiments were performed with the mycorrhizal fungus Suillus granulatus to define the parameters for production and regeneration of protoplasts. Protoplasts were released at frequencies between 1 and 3×10⁷/ml from mycelium 3 to 7 days old. The best osmotic stabilizer for protoplast release was MgSO₄ (0.7 m). To optimize protoplast release and regeneration an enzyme (Novozym 234) concentration 1.7 mg/ml was chosen, with a digestion time of 1 to 2 h. Regenerated colonies formed mycorrhizae within 60 days after inoculation in Pinus caribaea var. hondurensis seedlings.     

Glyptal as a support for enzyme immobilisation

Glyptal, a polyester obtained from phthalic anhydride and glycerol, was used as a support for protein immobilisation. Hydrazide groups were introduced in the polymer and then converted to azide groups, through which protein was covalently immobilised. Amyloglucosidase was used as a model and an insoluble water derivative was synthesised retaining 24 % of the specific activity of the native enzyme. Some properties of this immobilised enzyme were studied: Km (4.54 g.l^–1 using starch as substrate), optimal temperature (55°C) and half life (8 days). Furthermore, ferromagnetic-azide-glyptal derivative showed to be useful for the amyloglucosidase immobilisation.     

Manipulating photosynthesis

The levels of individual photosynthetic proteins can be independently decreased by theAgrobacterium-mediated transformation of plants with antisens RNA constructs. Protocols for the introduction of such constructs intoAgrobacterium, theAgrobacterium-mediated transformation of tobacco leaf disks, and the screening and analysis of the transgenic plants produced are described.     

Plant regeneration from stem and petiole-derived callus ofHumulus lupulus L. (hop) clone Bragança and var. Brewer’s Gold

Summary Plant regeneration was achieved from both a spontaneous clone (Bragan?a) and Brewer's Gold variety ofHumulus lupulus. The results obtained for these two different genotypes were compared. The organogenic ability of petiole and stem segments was tested on three different basal media supplemented with 0.025 mg (0.14 μM) indole-3-acetic acid/L and 2 mg (8.87 μM) 6-benzylaminopurine (N⁶-benzyladenine)/L. These conditions induced rather heterogeneous responses, which depended mainly on the explant source and the genotype. Because of the high organogenic competence revealed by the spontaneous clone on modified Murashige and Skoog medium, several hormones in different combinations were tested to optimize conditions for adventitious shoot regeneration in this clone. The best relation between the average shoot number/callus and the regeneration rate was achieved with 0.025 mg (0.14 μM) indole-3-acetic acid/L and 2 mg (8.87 μM) 6-benzylaminopurine/L or with 0.02 mg (0.11 μM) indole-3-acetic acid/L and 1.5 mg (6.97 μM) kinetin/L, which enabled 72 and 59% of regeneration, respectively. The regenerated plantlets could be acclimatized with 90% success.