These preliminary and shor-term data demonstrate that factors associated with T2DM in kidney donors are similar to those in the general population and donors this website screened carefully at the time of donation do not appear to have an acceleration of diabetic kidney disease.”
“Stress response and adaptation are important physiological mechanisms in plants. As plants are not able to avoid stressful environments by moving away, as animals, they have developed diverse mechanisms to respond to stressful situations. One of the genes involved in these mechanisms is NRP (Asparagine-rich protein or N-rich protein). In this study, NRP expression, protein localization
and nip knockout plants were investigated for further understanding of NRP function. NaCl-induced salt stress, oxidative stress (ozone exposure) and mechanical perturbation (touch treatment) were used to induce abiotic stress. NRP expression was up-regulated in the early phase of stress response to all three elicitors. Stressed nrp knockout seedlings revealed a more pronounced growth inhibition compared to wildtype (salt and osmotic stress). Seedlings showed NRP-GFP expression in the apical meristem, leaf veins, central cylinder, root hair zone and root
tip. Analyses of NRP-GFP localization in root cells and protoplasts revealed cytosolic distribution under non-stress conditions and translocation of NRP GFP to mitochondria due to stress response. Summarizing, our findings point to a contribution of NRP in signal transduction of the initial phase of general stress response click here in Arabidopsis thaliana. (C) 2011 Elsevier Masson SAS. All rights reserved.”
“P>ARF-GTPases are important proteins that control membrane trafficking events. Their activity is largely influenced by the interplay between guanine nucleotide exchange factors (GEFs) and GTPase-activating proteins (GAPs), which facilitate the activation or inactivation of ARF-GTPases, respectively. There are 15 predicted proteins that contain an Ricolinostat mw ARF-GAP domain within the Arabidopsis thaliana genome, and these are classified as ARF-GAP domain (AGD) proteins.
The function and subcellular distribution of AGDs, including the ability to activate ARF-GTPases in vivo, that remain largely uncharacterized to date. Here we show that AGD5 is localised to the trans-Golgi network (TGN), where it co-localises with ARF1, a crucial GTPase that is involved in membrane trafficking and which was previously shown to be distributed on Golgi and post-Golgi structures of unknown nature. Taking advantage of the in vivo AGD5-ARF1 interaction at the TGN, we show that mutation of an arginine residue that is critical for ARF-GAP activity of AGD5 leads to longer residence of ARF1 on the membranes, as expected if GTP hydrolysis on ARF1 was impaired due to a defective GAP. Our results establish the nature of the post-Golgi compartments in which ARF1 localises, as well as identifying the role of AGD5 in vivo as a TGN-localised GAP.