Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Proteolysis targeting chimeric (PROTAC) technology is an effective endogenous protein degradation tool developed in recent years that can ubiquitinate the target proteins through the ubiquitin-proteasome system (UPS) to achieve an effect on tumor growth. A number of literature studies on PROTAC technology have proved an insight into the feasibility of PROTAC technology to degrade target proteins. Additionally, the first oral PROTACs (ARV-110 and ARV-471) have shown encouraging results in clinical trials for prostate and breast cancer treatment, which inspires a greater enthusiasm for PROTAC research. Here we focus on the structures and mechanisms of PROTACs and describe several classes of effective PROTAC degraders based on E3 ligases.

Project description:We investigate the effects of modular and temporal connectivity patterns on epidemic spreading. To this end, we introduce and analytically characterise a model of time-varying networks with tunable modularity. Within this framework, we study the epidemic size of Susceptible-Infected-Recovered, SIR, models and the epidemic threshold of Susceptible-Infected-Susceptible, SIS, models. Interestingly, we find that while the presence of tightly connected clusters inhibits SIR processes, it speeds up SIS phenomena. In this case, we observe that modular structures induce a reduction of the threshold with respect to time-varying networks without communities. We confirm the theoretical results by means of extensive numerical simulations both on synthetic graphs as well as on a real modular and temporal network.

Project description:We study the standard SIS model of epidemic spreading on networks where individuals have a fluctuating number of connections around a preferred degree ?. Using very simple rules for forming such preferred degree networks, we find some unusual statistical properties not found in familiar Erdös-Rényi or scale free networks. By letting ? depend on the fraction of infected individuals, we model the behavioral changes in response to how the extent of the epidemic is perceived. In our models, the behavioral adaptations can be either 'blind' or 'selective'--depending on whether a node adapts by cutting or adding links to randomly chosen partners or selectively, based on the state of the partner. For a frozen preferred network, we find that the infection threshold follows the heterogeneous mean field result ?(c)/? = <?>/<?2> and the phase diagram matches the predictions of the annealed adjacency matrix (AAM) approach. With 'blind' adaptations, although the epidemic threshold remains unchanged, the infection level is substantially affected, depending on the details of the adaptation. The 'selective' adaptive SIS models are most interesting. Both the threshold and the level of infection changes, controlled not only by how the adaptations are implemented but also how often the nodes cut/add links (compared to the time scales of the epidemic spreading). A simple mean field theory is presented for the selective adaptations which capture the qualitative and some of the quantitative features of the infection phase diagram.

Project description:Migration plays a crucial role in epidemic spreading, and its dynamic can be studied by metapopulation model. Instead of the uniform mixing hypothesis, we adopt networked metapopulation to build the model of the epidemic spreading and the individuals' migration. In these populations, individuals are connected by contact network and populations are coupled by individuals migration. With the network mean-field and the gravity law of migration, we establish the N-seat intertwined SIR model and obtain its basic reproduction number ℛ0 . Meanwhile, we devise a non-markov Node-Search algorithm for model statistical simulations. Through the static network migration ansatz and ℛ0 formula, we discover that migration will not directly increase the epidemic replication capacity. But when ℛ0>1 , the migration will make the susceptive population evolve from metastable state (disease-free equilibrium) to stable state (endemic equilibrium), and then increase the influence area of epidemic. Re-evoluting the epidemic outbreak in Wuhan, top 94 cities empirical data validate the above mechanism. In addition, we estimate that the positive anti-epidemic measures taken by the Chinese government may have reduced 4 million cases at least during the first wave of COVID-19, which means those measures, such as the epidemiological investigation, nucleic acid detection in medium-high risk areas and isolation of confirmed cases, also play a significant role in preventing epidemic spreading after travel restriction between cities.

Project description:BRAF V600 mutation influences cellular signaling pathways for melanoma development. Here, we show that mutated BRAF plays an essential role in the adaptive stress response following activation of general control non-derepressible 2 (GCN2) kinase. In parallel with GCN2, BRAF ensures ATF4 induction by utilizing mTOR and eIF4B as downstream regulators during nutrient stress and BRAF-targeted, therapeutic stress. Upon pharmacological BRAF inhibition, this signaling pathway exhibits temporal resistance, compared with the MEK-ERK pathway, thereby enabling transient induction of ATF4 under GCN2 activation. Notably, the prevention of GCN2 activation, using a chemical inhibitor that we identified, produces synergistic cell killing with BRAF inhibition. Thus, oncogenic BRAF can collaborate with the GCN2–ATF4 pathway, promoting stress adaptation for cell survival.

Project description:Many real-world networks display a community structure. We study two random graph models that create a network with similar community structure as a given network. One model preserves the exact community structure of the original network, while the other model only preserves the set of communities and the vertex degrees. These models show that community structure is an important determinant of the behavior of percolation processes on networks, such as information diffusion or virus spreading: the community structure can both enforce as well as inhibit diffusion processes. Our models further show that it is the mesoscopic set of communities that matters. The exact internal structures of communities barely influence the behavior of percolation processes across networks. This insensitivity is likely due to the relative denseness of the communities.

Project description:BRAF V600 mutation influences cellular signaling pathways for melanoma development. Here, we show that mutated BRAF plays an essential role in the adaptive stress response following activation of general control non-derepressible 2 (GCN2) kinase. In parallel with GCN2, BRAF ensures ATF4 induction by utilizing mTOR and eIF4B as downstream regulators during nutrient stress and BRAF-targeted, therapeutic stress. Upon pharmacological BRAF inhibition, this signaling pathway exhibits temporal resistance, compared with the MEK-ERK pathway, thereby enabling transient induction of ATF4 under GCN2 activation. Notably, the prevention of GCN2 activation, using a chemical inhibitor that we identified, produces synergistic cell killing with BRAF inhibition. Thus, oncogenic BRAF can collaborate with the GCN2–ATF4 pathway, promoting stress adaptation for cell survival.

Project description:Mesangial cells-mediated glomerulonephritis is a frequent cause of end-stage renal disease. Here, we show that celastrol is effective in treating both reversible and irreversible mesangioproliferative glomerulonephritis in rat models, but find that its off-target distributions cause severe systemic toxicity. We thus target celastrol to mesangial cells using albumin nanoparticles. Celastrol-albumin nanoparticles crosses fenestrated endothelium and accumulates in mesangial cells, alleviating proteinuria, inflammation, glomerular hypercellularity, and excessive extracellular matrix deposition in rat anti-Thy1.1 nephritis models. Celastrol-albumin nanoparticles presents lower drug accumulation than free celastrol in off-target organs and tissues, thereby minimizing celastrol-related systemic toxicity. Celastrol-albumin nanoparticles thus represents a promising treatment option for mesangioproliferative glomerulonephritis and similar glomerular diseases.Mesangial cell-mediated glomerulonephritis is a frequent cause of kidney disease. Here the authors show that celastrol loaded in albumin nanoparticles efficiently targets mesangial cells, and is effective in rat models.

Project description:BRAF V600 mutation influences cellular signaling pathways for melanoma development. However, the role of oncogenic BRAF in adaptive stress response pathways is not fully understood. Here, we show that oncogenic BRAF plays an essential role in the induction of ATF4 following the activation of general control non-derepressible 2 (GCN2) kinase during nutrient stress and BRAF-targeted, therapeutic stress. Under GCN2 activation, BRAF ensures ATF4 induction by utilizing mTOR and eIF4B as downstream regulators. In contrast to the MEK-ERK pathway, this signaling pathway remains temporarily active even during treatment with BRAF inhibitors, thereby enabling the transient induction of ATF4. We also identify a chemical compound that prevents BRAF inhibitor-induced activation of the GCN2-ATF4 pathway and produces synergistic cell killing with BRAF inhibitors. Our findings establish a collaborative relationship between oncogenic BRAF and the GCN2-ATF4 signaling pathway, which may provide a novel therapeutic approach to target the adaptive stress response.