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1. Resolving plant development in space and time with single-cell genomics

   https://doi.org/10.1016/j.pbi.2023.102444  

   Nolan, Trevor M.; Shahan, Rachel (September 2023, Current Opinion in Plant Biology)

   Single-cell genomics technologies are ushering in a new research era. In this review, we summarize the benefits and current challenges of using these technologies to probe the transcriptional regulation of plant development. In addition to profiling cells at a single snapshot in time, researchers have recently produced time-resolved datasets to map cell responses to stimuli. Live-imaging and spatial transcriptomic techniques are rapidly being adopted to link a cell's transcriptional profile with its spatial location within a tissue. Combining these technologies is a powerful spatiotemporal approach to investigate cell plasticity and developmental responses that contribute to plant resilience. Although there are hurdles to overcome, we conclude by discussing how single-cell genomics is poised to address developmental questions in the coming years. 

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2. Morphological profiling for drug discovery in the era of deep learning

   https://doi.org/10.1093/bib/bbae284  

   Tang, Qiaosi; Ratnayake, Ranjala; Seabra, Gustavo; Jiang, Zhe; Fang, Ruogu; Cui, Lina; Ding, Yousong; Kahveci, Tamer; Bian, Jiang; Li, Chenglong; et al (May 2024, Briefings in Bioinformatics)

   Abstract Morphological profiling is a valuable tool in phenotypic drug discovery. The advent of high-throughput automated imaging has enabled the capturing of a wide range of morphological features of cells or organisms in response to perturbations at the single-cell resolution. Concurrently, significant advances in machine learning and deep learning, especially in computer vision, have led to substantial improvements in analyzing large-scale high-content images at high throughput. These efforts have facilitated understanding of compound mechanism of action, drug repurposing, characterization of cell morphodynamics under perturbation, and ultimately contributing to the development of novel therapeutics. In this review, we provide a comprehensive overview of the recent advances in the field of morphological profiling. We summarize the image profiling analysis workflow, survey a broad spectrum of analysis strategies encompassing feature engineering– and deep learning–based approaches, and introduce publicly available benchmark datasets. We place a particular emphasis on the application of deep learning in this pipeline, covering cell segmentation, image representation learning, and multimodal learning. Additionally, we illuminate the application of morphological profiling in phenotypic drug discovery and highlight potential challenges and opportunities in this field. 

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3. A heterogeneous pharmaco-transcriptomic landscape induced by targeting a single oncogenic kinase

   https://doi.org/10.1101/2024.04.08.587960  

   Giglio, Ross M; Hou, Nicholas; Wyatt, Adeya; Hong, Justin; Shi, Lingting; Vaikunthan, Mathini; Fuchs, Henry; Nima, Jose Pomarino; Malinowski, Seth W; Ligon, Keith L; et al (April 2024, bioRxiv)

   Abstract Over-activation of the epidermal growth factor receptor (EGFR) is a hallmark of glioblastoma. However, EGFR-targeted therapies have led to minimal clinical response. While delivery of EGFR inhibitors (EGFRis) to the brain constitutes a major challenge, how additional drug-specific features alter efficacy remains poorly understood. We apply highly multiplex single-cell chemical genomics to define the molecular response of glioblastoma to EGFRis. Using a deep generative framework, we identify shared and drug-specific transcriptional programs that group EGFRis into distinct molecular classes. We identify programs that differ by the chemical properties of EGFRis, including induction of adaptive transcription and modulation of immunogenic gene expression. Finally, we demonstrate that pro-immunogenic expression changes associated with a subset of tyrphostin family EGFRis increase the ability of cytotoxic T-cells to eradicate tumor cells. Our study provides a framework that considers each agent’s unique and often unknown poly-pharmacology to prioritize compounds that induce clinically favorable molecular responses. 

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4. Advancing Targeted Drug Delivery in Glioblastoma Multiforme Through Biomimetic Nanomedicine Using 3D Tumor‐On‐a‐Chip Model

   https://doi.org/10.1002/adhm.202502454  

   Manoharan, Twinkle_Jina Minette; Wang, Ting‐Yun; Mantri, Shivani; Alarnous, Hanan; Mehta, Shwetal; Wang, Kuei‐Chun; Nikkhah, Mehdi (September 2025, Advanced Healthcare Materials)

   Abstract The prognosis of glioblastoma multiforme (GBM) remains dismal, despite standard treatment regimens. A key challenge in treating GBM is the persistence of glioma stem cells (GSCs) within the perivascular niche (PVN) – a protective tumor microenvironment (TME) that is often associated with inadequate drug penetration. Current preclinical models do not capture complexity of the human TME, particularly the vasculature and niche‐specific interactions that drive GBM progression. To overcome these limitations, an innovative 3Dex‐vivotumor‐on‐a‐chip (TOC) platform is engineered to accurately replicate the structural and functional characteristics of the PVN. Using this platform, this study demonstrates that monocyte membrane‐coated nanoparticles (MoNP) effectively target the abnormal tumor microvasculature, offering a promising approach to enhance drug delivery to these hard‐to‐reach GSCs. The results show that the therapeutic agent verteporfin, when delivered via MoNP, significantly inhibited GSC growth and invasiveness, while the free‐form drug showed minimal efficacy. Comprehensive transcriptomic profiling and cytokine analysis validated the TOC model's ability to reflect authentic GSC responses and confirmed that MoNP‐mediated verteporfin delivery effectively modulates key tumor‐related signaling pathways. This integrated TOC‐MoNP platform represents a clinically relevant tool that bridges the gap between traditional preclinical models and human disease, providing new opportunities for developing more effective GBM therapies. 

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5. Leveraging Single-Cell Populations to Uncover the Genetic Basis of Complex Traits

   https://doi.org/10.1146/annurev-genet-022123-110824  

   Minow, Mark A.A.; Marand, Alexandre P.; Schmitz, Robert J. (November 2023, Annual Review of Genetics)

   The ease and throughput of single-cell genomics have steadily improved, and its current trajectory suggests that surveying single-cell populations will become routine. We discuss the merger of quantitative genetics with single-cell genomics and emphasize how this synergizes with advantages intrinsic to plants. Single-cell population genomics provides increased detection resolution when mapping variants that control molecular traits, including gene expression or chromatin accessibility. Additionally, single-cell population genomics reveals the cell types in which variants act and, when combined with organism-level phenotype measurements, unveils which cellular contexts impact higher-order traits. Emerging technologies, notably multiomics, can facilitate the measurement of both genetic changes and genomic traits in single cells, enabling single-cell genetic experiments. The implementation of single-cell genetics will advance the investigation of the genetic architecture of complex molecular traits and provide new experimental paradigms to study eukaryotic genetics. 

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