MAPK phosphatase AP2C3 induces ectopic proliferation of epidermal cells leading to stomata development in Arabidopsis

In plant post-embryonic epidermis mitogen-activated protein kinase (MAPK) signaling promotes differentiation of pavement cells and inhibits initiation of stomata. Stomata are cells specialized to modulate gas exchange and water loss. Arabidopsis MAPKs MPK3 and MPK6 are at the core of the signaling cascade; however, it is not well understood how the activity of these pleiotropic MAPKs is constrained spatially so that pavement cell differentiation is promoted only outside the stomata lineage. Here we identified a PP2C-type phosphatase termed AP2C3 (Arabidopsis protein phosphatase 2C) that is expressed distinctively during stomata development as well as interacts and inactivates MPK3, MPK4 and MPK6. AP2C3 co-localizes with MAPKs within the nucleus and this localization depends on its N-terminal extension. We show that other closely related phosphatases AP2C2 and AP2C4 are also MAPK phosphatases acting on MPK6, but have a distinct expression pattern from AP2C3. In accordance with this, only AP2C3 ectopic expression is able to stimulate cell proliferation leading to excess stomata development. This function of AP2C3 relies on the domains required for MAPK docking and intracellular localization. Concomitantly, the constitutive and inducible AP2C3 expression deregulates E2F-RB pathway, promotes the abundance and activity of CDKA, as well as changes of CDKB1;1 forms. We suggest that AP2C3 downregulates the MAPK signaling activity to help maintain the balance between differentiation of stomata and pavement cells.     

Ligand chirality effects on the dynamics of human 3-phosphoglycerate kinase: comparison between D- and L-nucleotides

l-nucleoside analogues are now largely used as antiviral drugs for the treatment of viral infections like HBV, HCV and HIV. However, in order to be fully active, they need to be phosphorylated by cellular or viral kinases. Human 3-phosphogycerate kinase (hPGK) was shown to catalyze the last step of activation of l-enantiomers and thus constitutes an attractive target for theoretical predictions of its phosphorylation efficiency. Molecular dynamics simulations were carried out with four different nucleotides (d-/l-ADP and d-/l-CDP) in complex with hPGK and 1,3-bisphospho-d-glycerate (bPG). The binding affinities of CDPs (both enantiomers) for hPGK were found very weak while d- and l-ADP were better substrates. Interestingly, the binding affinity of the bPG substrate was found to be lower in presence of d-ADP than l-ADP which indicates a potential antagonistic effect on one substrate to the other. A detailed analysis of the simulations unravels important dynamic conditions for efficient phosphorylation. Indeed, as previously described for the natural substrate, the hinge bending motion of the domains upon substrates binding should be more correlated and directional. Interestingly, the unforeseen finding was the larger dynamics freedoms observed for the substrates that was favored by the protein atoms flexibility around the nucleobase binding site.     

An Acidophilic Bacterial-Archaeal-Fungal Ecosystem Linked to Formation of Ferruginous Crusts and Stalactites

The presence of specialized microbial associations between populations of chemoautotrophic bacteria and archaea with ascomycetous fungi was observed inside stalactite-shaped mineral formations in a highly acidic cave environment. Metagenomic, chemical and electron microscopy analyses were used to investigate the relevance of these microbial ecosystems in the formation of stalactites. Ferric hydroxide produced by acidophilic bacteria and archaea was shown to be deposited onto fungal hyphae, resulting in complex mineralized stalactite-shaped structures. Thus, both archaeal-bacterial and fungal members of the ecosystem were shown to play an active role in the formation of stalactites.     

Biocatalytic asymmetric hydroxylation of hydrocarbons by free and immobilized Bacillus megaterium cells

Screening of soil bacteria with allylbenzene resulted in a Bacillus megaterium strain, which hydroxylates simple hydrocarbons in high enantiomeric excess (ee up to 99%). Benzylic and nonbenzylic hydroxylation products were obtained, without the usually observed high preference for the benzylic position. The immobilization of the B. megaterium cells in alginate gel effectively improved the stability of the cells and increased the amounts of products formed, without loss of enantioselectivity. The product ratio ( vs. β hydroxylation) was shifted towards benzylic hydroxylation, which suggests that at least two hydroxylating enzymes with distinct regioselectivity are involved. Comparison to free-cell fermentations in small- and large-scale bioreactors (up to 2000 ml) showed that the use of immobilized cells is advantageous, as they are easier to handle and yield higher amounts of oxidation products.