Localized concentration reversal of lithium during intercalation into nanoparticles.

Nanoparticulate electrodes, such as Li x FePO4, have unique advantages over their microparticulate counterparts for the applications in Li-ion batteries because of the shortened diffusion path and access to nonequilibrium routes for fast Li incorporation, thus radically boosting power density of the electrodes. However, how Li intercalation occurs locally in a single nanoparticle of such materials remains unresolved because real-time observation at such a fine scale is still lacking. We report visualization of local Li intercalation via solid-solution transformation in individual Li x FePO4 nanoparticles, enabled by probing sub-angstrom changes in the lattice spacing in situ. The real-time observation reveals inhomogeneous intercalation, accompanied with an unexpected reversal of Li concentration at the nanometer scale. The origin of the reversal phenomenon is elucidated through phase-field simulations, and it is attributed to the presence of structurally different regions that have distinct chemical potential functions. The findings from this study provide a new perspective on the local intercalation dynamics in battery electrodes.

Evolution of vitamin B2 biosynthesis: eubacterial RibG and fungal Rib2 deaminases.

Eubacterial RibG and yeast Rib2 possess a deaminase domain for pyrimidine deamination in the second and third steps, respectively, of riboflavin biosynthesis. These enzymes are specific for ribose and ribitol, respectively. Here, the crystal structure of Bacillus subtilis RibG in complex with a deaminase product is reported at 2.56 Å resolution. Two loops move towards the product on substrate binding, resulting in interactions with the ribosyl and phosphate groups and significant conformational changes. The product carbonyl moiety is bent out of the pyrimidine ring to coordinate to the catalytic zinc ion. Such distortions in the bound substrate and product may play an essential role in enzyme catalysis. The yeast Rib2 structure was modelled and a mutational analysis was carried out in order to understand the mechanism of substrate recognition in these two enzymes. Detailed structural comparisons revealed that the two consecutive carbonyl backbones that occur prior to the PCXXC signature constitute a binding hole for the target amino group of the substrate. This amino-binding hole is essential in B. subtilis RibG and is also conserved in the RNA/DNA-editing deaminases.

New phenotypes generated by the G57R mutation of BUD23 in Saccharomyces cerevisiae.

BUD23 in Saccharomyces cerevisiae encodes for a class I methyltransferase, and deletion of the gene results in slow growth and random budding phenotypes. Herein, two BUD23 mutants defective in methyltransferase activity were generated to investigate whether the phenotypes of the null mutant might be correlated with a loss in enzymatic activity. Expression at the physiological level of both D77A and G57R mutants was able to rescue the phenotypes of the bud23-null mutant. The result implied that the methyltransferase activity of the protein was not necessary for supporting normal growth and bud site selection of the cells. High-level expression of Bud23 (G57R), but not Bud23 or Bud23 (D77A), in BUD23 deletion cells failed to complement these phenotypes. However, just like Bud23, Bud23 (G57R) was localized in a DAPI-poor region in the nucleus. Distinct behaviour in Bud23 (G57R) could not be originated from a mislocalization of the protein. Over-expression of Bud23 (G57R) in null cells also produced changes in actin organization and additional septin mutant-like phenotypes. Therefore, the absence of Bud23, Bud23 (G57R) at a high level might affect the cell division of yeast cells through an as yet unidentified mechanism.

Tracking lithium transport and electrochemical reactions in nanoparticles.

Expectations for the next generation of lithium batteries include greater energy and power densities along with a substantial increase in both calendar and cycle life. Developing new materials to meet these goals requires a better understanding of how electrodes function by tracking physical and chemical changes of active components in a working electrode. Here we develop a new, simple in-situ electrochemical cell for the transmission electron microscope and use it to track lithium transport and conversion in FeF(2) nanoparticles by nanoscale imaging, diffraction and spectroscopy. In this system, lithium conversion is initiated at the surface, sweeping rapidly across the FeF(2) particles, followed by a gradual phase transformation in the bulk, resulting in 1-3 nm iron crystallites mixed with amorphous LiF. The real-time imaging reveals a surprisingly fast conversion process in individual particles (complete in a few minutes), with a morphological evolution resembling spinodal decomposition. This work provides new insights into the inter- and intra-particle lithium transport and kinetics of lithium conversion reactions, and may help to pave the way to develop high-energy conversion electrodes for lithium-ion batteries.

Complex structure of Bacillus subtilis RibG: the reduction mechanism during riboflavin biosynthesis.

Bacterial RibG is a potent target for antimicrobial agents, because it catalyzes consecutive deamination and reduction steps in the riboflavin biosynthesis. In the N-terminal deaminase domain of Bacillus subtilis RibG, structure-based mutational analyses demonstrated that Glu51 and Lys79 are essential for the deaminase activity. In the C-terminal reductase domain, the complex structure with the substrate at 2.56-A resolution unexpectedly showed a ribitylimino intermediate bound at the active site, and hence suggested that the ribosyl reduction occurs through a Schiff base pathway. Lys151 seems to have evolved to ensure specific recognition of the deaminase product rather than the substrate. Glu290, instead of the previously proposed Asp199, would seem to assist in the proton transfer in the reduction reaction. A detailed comparison reveals that the reductase and the pharmaceutically important enzyme, dihydrofolate reductase involved in the riboflavin and folate biosyntheses, share strong conservation of the core structure, cofactor binding, catalytic mechanism, even the substrate binding architecture.