Summary:
The structural, dynamical and functional characterization of the small
GTPase K-Ras has become a research area of intense focus due to its high
occurrence in human cancers. Ras proteins are only fully functional when they
interact with the plasma membrane. Here we present all atom molecular dynamics
simulations (totaling 5.8 μs) in order to investigate the K-Ras4A protein
at membranes that contain anionic lipids (POPS or PIP2). We find that similarly
to the homologous and highly studied K-Ras4B, K-Ras4A prefers a few distinct
orientations at the membrane. Remarkably, the protein surface charge and certain
lipids can strongly modulate the orientation preference. In a novel analysis, we
reveal that the electrostatic interaction (attraction but also repulsion)
between the protein’s charged residues and anionic lipids determines the
K-Ras4A orientation, but that this is also influenced by the topology of the
protein, reflecting the geometry of its surfaces.
miR-34a-5p knockdown attenuates intestinal I/R injury through promoting SIRT1-mediated suppression of epithelial ROS accumulation and apoptosis. This may represent a novel prophylactic approach to intestinal I/R injury. Antioxid. Redox Signal. 24, 961-973.
The inflammatory mediator high-mobility group box 1 (HMGB1) plays a critical role in the pathogenesis of non-alcoholic fatty liver disease (NAFLD). However, the regulation of HMGB1 in NAFLD, particularly through sirtuin 1 (SIRT1), remains unclear. In this study, we investigated the role of SIRT1-mediated inhibition of HMGB1 release in NAFLD and the effect of salvianolic acid B (SalB), which is a water-soluble phenolic acid extracted from Radix Salvia miltiorrhiza, on NAFLD through SIRT1/HMGB1 signaling. In vivo, SalB treatment significantly attenuated high-fat diet (HFD)-induced liver damage, hepatic steatosis, and inflammation. Importantly, SalB significantly inhibited HMGB1 nuclear translocation and release, accompanied by SIRT1 elevation. In HepG2 cells, palmitic acid (PA)-induced pro-inflammatory cytokines release were blocked by HMGB1 small interfering RNA (siRNA) transfection. Moreover, pharmacological SIRT1 inhibition by Ex527 induced HMGB1 translocation and release, whereas SIRT1 activation by resveratrol or SalB reversed this trend. SIRT1 siRNA abrogated the SalB-mediated inhibition of HMGB1 acetylation and release, suggesting that SalB-mediated protection occurs by SIRT1 targeting HMGB1 for deacetylation. We are the first to demonstrate that the SIRT1/HMGB1 pathway is a key therapeutic target for controlling NAFLD inflammation and that SalB confers protection against HFD- and PA-induced hepatic steatosis and inflammation through SIRT1-mediated HMGB1 deacetylation.
Understanding how cell-penetrating peptides translocate across cell membranes is of great importance in biomedicine. In this paper, we study the interactions between polyarginines and asymmetric membranes by using coarse-grained molecular dynamics simulations. It is found that a peptide has the probability to penetrate through the membrane because of the transmembrane potential difference; however, it is difficult for a single peptide to spontaneously penetrate through the membrane while multiple peptides can translocate across membranes by pore-mediated processes. Further, we also provide insights into the transporting ability of polyarginines, and find that the peptide can transport hydrophobic as well as hydrophilic particles through membranes, where the translocation of a hydrophobic particle is easier than that of a hydrophilic one. The present study can help to better understand the interactions of the peptides with cell membranes and may give some new suggestions on the design of future nanomaterials for drug delivery.
Association
of Raf kinase with activated Ras triggers downstream
signaling cascades toward regulating transcription in the cells’
nucleus. Dysregulation of Ras–Raf signaling stimulates cancers.
We investigate the C-Raf RBD and CRD regions when bound to oncogenic
K-Ras4B at the membrane. All-atom molecular dynamics simulations suggest
that the membrane plays an integral role in regulating the configurational
ensemble of the complex. Remarkably, the complex samples a few states
dynamically, reflecting a competition between C-Raf CRD- and K-Ras4B-
membrane interactions. This competition arises because the interaction
between the RBD and K-Ras is strong while the linker between the RBD
and CRD is short. Such a mechanism maintains a modest binding for
the overall complex at the membrane and is expected to facilitate
fast signaling processes. Competition of protein–membrane contacts
is likely a common mechanism for other multiprotein complexes, if
not multidomain proteins at membranes.
Resveratrol protects against sepsis-induced liver injury through the SIRT1-mediated HMGB1 nucleocytoplasmic translocation pathway, a new potential therapeutic target in sepsis-induced liver injury.
Edited by Henrik G. DohlmanRas genes potently drive human cancers, with mutated protooncogene GTPase KRAS4B (K-Ras4B) being the most abundant isoform. Targeted inhibition of oncogenic gene products is considered the "holy grail" of present-day cancer therapy, and recent discoveries of small-molecule KRas4B inhibitors were made thanks to a deeper understanding of the structure and dynamics of this GTPase. Because interactions with biological membranes are key for Ras function, Ras-lipid interactions have become a major focus, especially because such interactions evidently involve both the Ras C terminus for lipid anchoring and its G-protein domain. Here, using NMR spectroscopy and molecular dynamics simulations complemented by biophysicaland cell-biology assays, we investigated the interaction between K-Ras4B with the signaling lipid phosphatidylinositol (4,5)phosphate (PIP2). We discovered that the 2 and 3 strands as well as helices 4 and 5 of the GTPase G-domain bind to PIP2 and identified the specific residues in these structural elements employed in these interactions, likely occurring in two K-Ras4B orientation states relative to the membrane. Importantly, we found that some of these residues known to be oncogenic when mutated (D47K, D92N, K104M, and D126N) are critical for K-Ras-mediated transformation of fibroblast cells, but do not substantially affect basal and assisted nucleotide hydrolysis and exchange. Moreover, the K104M substitution abolished localization of K-Ras to the plasma membrane. The findings suggest that specific G-domain residues can critically regulate Ras function by mediating interactions with membrane-associated PIP2 lipids; these insights that may inform the future design of therapeutic reagents targeting Ras activity.
Autophagy is an essential cytoprotective response against pathologic stresses that selectively degrades damaged cellular components. Impaired autophagy contributes to organ injury in multiple diseases, including ischemia/reperfusion (I/R), but the exact mechanism by which impaired autophagy is regulated remains unclear. Several researchers have demonstrated that microRNAs (miRNAs) negatively regulate autophagy by targeting autophagy-related genes (ATGs). Therefore, the effect of ATG-related miRNAs on I/R remains a promising research avenue. In our study, we found that autophagy flux is impaired during intestinal I/R. A miRNA microarray analysis showed that miR-665-3p was highly expressed in the I/R group, which was confirmed by qRT-PCR. Then, we predicted and proved that miR-665-3p negatively regulates ATG4B expression in Caco-2 and IEC-6 cells. In ileum biopsy samples from patients with intestinal infarction, there was an inverse correlation between miR-665-3p and ATG4B expression, which supports the in vitro findings. Moreover, based on miR-665-3p regulation of autophagy in response to hypoxia/reoxygenation in vitro, gain-of-function and loss-of-function approaches were used to investigate the therapeutic potential of miR-665-3p. Additionally, we provide evidence that ATG4B is indispensable for protection upon inhibition of miR-665-3p. Finally, we observed that locked nucleic acid-modified inhibition of miR-665-3p in vivo alleviates I/R-induced systemic inflammation and apoptosis via recovery of autophagic flux. Our study highlights miR-665-3p as a novel small molecule that regulates autophagy by targeting ATG4B, suggesting that miR-665-3p inhibition may be a potential therapeutic approach against inflammation and apoptosis for the clinical treatment of intestinal I/R.
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