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   https://doi.org/10.1124/jpet.050.979950  

   Ghoshal, Sarbani; Manisha, FNU; Khan, Sana; Fath, Karl; Pathak, Sanjai K (May 2024, American Society for Pharmacology and Experimental Therapeutics)
2. Uncertainty quantification in the radiogenomics modeling of EGFR amplification in glioblastoma

   https://doi.org/10.1038/s41598-021-83141-z  

   Hu, Leland S.; Wang, Lujia; Hawkins-Daarud, Andrea; Eschbacher, Jennifer M.; Singleton, Kyle W.; Jackson, Pamela R.; Clark-Swanson, Kamala; Sereduk, Christopher P.; Peng, Sen; Wang, Panwen; et al (December 2021, Scientific Reports)

   null (Ed.)

   Abstract Radiogenomics uses machine-learning (ML) to directly connect the morphologic and physiological appearance of tumors on clinical imaging with underlying genomic features. Despite extensive growth in the area of radiogenomics across many cancers, and its potential role in advancing clinical decision making, no published studies have directly addressed uncertainty in these model predictions. We developed a radiogenomics ML model to quantify uncertainty using transductive Gaussian Processes (GP) and a unique dataset of 95 image-localized biopsies with spatially matched MRI from 25 untreated Glioblastoma (GBM) patients. The model generated predictions for regional EGFR amplification status (a common and important target in GBM) to resolve the intratumoral genetic heterogeneity across each individual tumor—a key factor for future personalized therapeutic paradigms. The model used probability distributions for each sample prediction to quantify uncertainty, and used transductive learning to reduce the overall uncertainty. We compared predictive accuracy and uncertainty of the transductive learning GP model against a standard GP model using leave-one-patient-out cross validation. Additionally, we used a separate dataset containing 24 image-localized biopsies from 7 high-grade glioma patients to validate the model. Predictive uncertainty informed the likelihood of achieving an accurate sample prediction. When stratifying predictions based on uncertainty, we observed substantially higher performance in the group cohort (75% accuracy, n = 95) and amongst sample predictions with the lowest uncertainty (83% accuracy, n = 72) compared to predictions with higher uncertainty (48% accuracy, n = 23), due largely to data interpolation (rather than extrapolation). On the separate validation set, our model achieved 78% accuracy amongst the sample predictions with lowest uncertainty. We present a novel approach to quantify radiogenomics uncertainty to enhance model performance and clinical interpretability. This should help integrate more reliable radiogenomics models for improved medical decision-making. 

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3. IGEG-2 is a C. elegans EGFR ligand

   https://doi.org/10.17912/micropub.biology.001821  

   Mailhot, Melissa M; Jones, Jesse G; Castro, Dylan L; Van_Buskirk, Cheryl (September 2025, microPublication biology)

   Across species, Epidermal Growth Factor (EGF) family ligands and their receptors participate in developmental and physiological cell-cell signaling events. C. elegans possesses a single EGF receptor, LET-23/EGFR, and two characterized EGF ligands. LIN-3/EGF is well-known for its role in vulval induction, and SISS-1/EGF mediates stress-induced sleep. The C. elegans genome harbors another predicted EGF family member, igeg-2, which has not been characterized. To determine if IGEG-2 is a functional EGFR ligand, we examined whether it can activate known LET-23-dependent processes. We found that ubiquitous overexpression of IGEG-2 promotes both vulval induction and sleep, indicating that it is a functional EGF family ligand. The endogenous role of IGEG-2 remains unknown. 

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4. Quantification of ligand and mutation-induced bias in EGFR phosphorylation in direct response to ligand binding

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   Wirth, Daniel; Özdemir, Ece; Hristova, Kalina (December 2023, Nature Communications)

   Signaling bias is the ability of a receptor to differentially activate downstream signaling pathways in response to different ligands. Bias investigations have been hindered by inconsistent results in different cellular contexts. Here we introduce a methodology to identify and quantify bias in signal transduction across the plasma membrane without contributions from feedback loops and system bias. We apply the methodology to quantify phosphorylation efficiencies and determine absolute bias coefficients. We show that the signaling of epidermal growth factor receptor (EGFR) to EGF and TGFα is biased towards Y1068 and against Y1173 phosphorylation, but has no bias for epiregulin. We further show that the L834R mutation found in non-small-cell lung cancer induces signaling bias as it switches the preferences to Y1173 phosphorylation. The knowledge gained here challenges the current understanding of EGFR signaling in health and disease and opens avenues for the exploration of biased inhibitors as anti-cancer therapies. 

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5. EGFR-targeted ionizable lipid nanoparticles enhance in vivo mRNA delivery to the placenta

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   Geisler, Hannah C; Ghalsasi, Aditi A; Safford, Hannah C; Swingle, Kelsey L; Thatte, Ajay S; Mukalel, Alvin J; Gong, Ningqiang; Hamilton, Alex G; Han, Emily L; Nachod, Benjamin E; et al (July 2024, Journal of Controlled Release)