Mapping the Single-cell Differentiation Landscape of Osteosarcoma.

PURPOSE: The genetic intratumoral heterogeneity observed in human osteosarcomas (OS) poses challenges for drug development and the study of cell fate, plasticity, and differentiation, processes linked to tumor grade, cell metastasis, and survival. EXPERIMENTAL DESIGN: To pinpoint errors in OS differentiation, we transcriptionally profiled 31,527 cells from a tissue-engineered model that directsMSCs toward adipogenic and osteoblastic fates. Incorporating pre-existing chondrocyte data, we applied trajectory analysis and non-negative matrix factorization (NMF) to generate the first human mesenchymal differentiation atlas. RESULTS: This 'roadmap' served as a reference to delineate the cellular composition of morphologically complex OS tumors and quantify each cell's lineage commitment. Projecting a bulk RNA-seq OS dataset onto this roadmap unveiled a correlation between a stem-like transcriptomic phenotype and poorer survival outcomes. CONCLUSIONS: Our study quantifies OS differentiation and lineage, a prerequisite to better understanding lineage-specific differentiation bottlenecks that might someday be targeted therapeutically.

Reprogramming Megakaryocytes for Controlled Release of Platelet-like Particles Carrying a Single-Chain Thromboxane A2 Receptor-G-Protein Complex with Therapeutic Potential.

In this study, we reported that novel single-chain fusion proteins linking thromboxane A2 (TXA2) receptor (TP) to a selected G-protein α-subunit q (SC-TP-Gαq) or to α-subunit s (SC-TP-Gαs) could be stably expressed in megakaryocytes (MKs). We tested the MK-released platelet-linked particles (PLPs) to be used as a vehicle to deliver the overexpressed SC-TP-Gαq or the SC-TP-Gαs to regulate human platelet function. To understand how the single-chain TP-Gα fusion proteins could regulate opposite platelet activities by an identical ligand TXA2, we tested their dual functions-binding to ligands and directly linking to different signaling pathways within a single polypeptide chain-using a 3D structural model. The immature MKs were cultured and transfected with cDNAs constructed from structural models of the individual SC-TP-Gαq and SC-TP-Gαs, respectively. After transient expression was identified, the immature MKs stably expressing SC-TP-Gαq or SC-TP-Gαs (stable cell lines) were selected. The stable cell lines were induced into mature MKs which released PLPs. Western blot analysis confirmed that the released PLPs were carrying the recombinant SC-TP-Gαq or SC-TP-Gαs. Flow cytometry analysis showed that the PLPs carrying SC-TP-Gαq were able to perform the activity by promoting platelet aggregation. In contrast, PLPs carrying SC-TP-Gαs reversed Gq to Gs signaling to inhibit platelet aggregation. This is the first time demonstrating that SC-TP-Gαq and SC-TP-Gαs were successfully overexpressed in MK cells and released as PLPs with proper folding and programmed biological activities. This bio-engineering led to the formation of two sets of biologically active PLP forms mediating calcium and cAMP signaling, respectively. As a result, these PLPs are able to bind to identical endogenous TXA2 with opposite activities, inhibiting and promoting platelet aggregation as reprogrammed for therapeutic process. Results also demonstrated that the nucleus-free PLPs could be used to deliver recombinant membrane-bound GPCRs to regulate cellular activity in general.

Differential expression of microRNA and arachidonic acid metabolism in aspirin-treated human cardiac and peri-cardiac fat-derived mesenchymal stem cells.

Aspirin is a widely used drug with anti-coagulating and anti-inflammatory effects on atherosclerotic vascular disease. The goal of this study was to investigate expression of microRNA (miR) in association with changes in arachidonic acid (AA) metabolism in cardiac and surrounding fat mesenchymal stem cells (MSCs) treated with or without aspirin. Aspirin-targeted endogenous lipid metabolites that impact specific miRNA expression were examined by mass spectrometry. The pattern of miR expression was characterized using a microarray of 1100 miRs. There were a dozen miRs expressed differentially in MSCs from human myocardium and peri-myocardial fat tissue at baseline, including hsa-miR-1307-3p, 765, 4739, 3613-3p, 4281, 6816-5p, 2861, and 146b-5p. After exposure to aspirin, cardiac MSCs expressed an array of of miRs (eg, hsa-miR-4734, 10a-5p, 4267, 3197, and 3182), while generation of their endogenous AA metabolites was depressed. However, in the peri-cardiac adipose tissue-derived MSCs, treatment with the same doses of aspirin caused mild changes in the miR expression levels. In conclusion, MSCs from human myocardium and peri-myocardial fat tissue respond differentially to aspirin treatment by alterations in miR expression and AA metabolism. The study further raises an intriguing issue as to whether the copious amounts of aspirin taken worldwide by patients with cardiovascular disease may have direct impacts on their heart repair processes by regulation of stromal cell miR expression and AA metabolism.

Novel method to detect, isolate, and culture prostate culturing circulating tumor cells.

BACKGROUND: Effectively detecting and culturing circulating tumor cells (CTCs), is critical for diagnosis of early metastasis, monitoring anti-cancer therapeutic efficacy, and drug screening. However, most current FDA approved CTC detection methods are based on antibody binding, which has limitations due to the nature of variations in antibody preparation and antibody-CTC size mismatches. Thus, searching for alternative and advanced methods is urgent and necessary. METHODS: Prostate cancer tissue was digested by collagenase and cultured. Cancer stromal cells were identified and labelled with 4',6-diamidino-2-phenylindole (DAPI) before incubation with whole blood of cancer mice (bearing a later stage of prostate cancer). The attached blood CTCs on the DAPI-labeled cancer stromal cells were detected, isolated, cultured and produced into individual cancer cell lines. RESULTS: Five clones of prostate cancer cells isolated from cancer tissue were successfully cultured. One (Clone-1) of the five clones showed positive staining for all three cancer stromal cell markers (CD133, α2ß1 integrin and CD44). Clone-1 cells rich with epithelial cell adhesion molecule (EpCAM) on the cell surface were further identified. The Clone-1 stromal cells labeled as "bait" attracted and caught a trace number of CTCs from the whole blood of mice with advanced stage cancer. Efficient culturing of the caught CTCs from single cell to forming of individual cancer cell line(s) were established. CONCLUSIONS: We present a fundamental advancement of CTC detection and culturing using a different mechanism (cell-cell interaction) rather than the traditional antibody-based immune-binding, such as CellSearchTM system. This study has potential to be fully developed into a novel approach for early cancer metastasis detection, and chemotherapy efficacy monitoring. The efficiently cultured CTCs could be used for single-clone CTC analysis and anti-cancer drug screening to further advance the development of individualized medicine.