Studying microRNA function in vivo requires genetic strategies to generate loss-of-function phenotypes. We used lentiviral vectors to stably and specifically knock down microRNA by overexpressing microRNA target sequences from polymerase II promoters. These vectors effectively inhibited regulation of reporter constructs and natural microRNA targets. We used bone marrow reconstitution with hematopoietic stem cells stably overexpressing miR-223 target sequence to phenocopy the genetic miR-223 knockout mouse, indicating robust interference of microRNA function in vivo.
Globoid cell leukodystrophy (GLD; also known as Krabbe disease) is an invariably fatal lysosomal storage disorder caused by mutations in the galactocerebrosidase (GALC) gene. Hematopoietic stem cell (HSC)-based gene therapy is being explored for GLD; however, we found that forced GALC expression was toxic to HSCs and early progenitors, highlighting the need for improved regulation of vector expression. We used a genetic reporter strategy based on lentiviral vectors to detect microRNA activity in hematopoietic cells at single-cell resolution. We report that miR-126 and miR-130a were expressed in HSCs and early progenitors from both mice and humans, but not in differentiated progeny. Moreover, repopulating HSCs could be purified solely on the basis of miRNA expression, providing a new method relevant for human HSC isolation. By incorporating miR-126 target sequences into a GALC-expressing vector, we suppressed GALC expression in HSCs while maintaining robust expression in mature hematopoietic cells. This approach protected HSCs from GALC toxicity and allowed successful treatment of a mouse GLD model, providing a rationale to explore HSC-based gene therapy for GLD.
Induced pluripotent stem cell (iPSC) technology has provided researchers with a unique tool to derive disease-specific stem cells for the study and possible treatment of degenerative disorders with autologous cells. The low efficiency and heterogeneous nature of reprogramming is a major impediment to the generation of personalized iPSC lines. Here, we report the generation of a lentiviral system based on a microRNA-regulated transgene that enables for the efficient selection of mouse and human pluripotent cells. This system relies on the differential expression pattern of the mature form of microRNA let7a in pluripotent versus committed or differentiated cells. We generated microRNA responsive green fluorescent protein and Neo reporters for specific labeling and active selection of the pluripotent cells in any culture condition. We used this system to establish Rett syndrome and Parkinson's disease human iPSCs. The presented selection procedure represents a straightforward and powerful tool for facilitating the derivation of patient-specific iPSCs.
On the basis of these data and also of data available in the literature, it seems reasonable to adapt the dose of fosamprenavir and/or ritonavir exclusively in the presence of adverse events, possibly related to protease inhibitors (i.e. liver toxicity), in subjects with high drug plasma levels. Therapeutic drug monitoring is advised in the management of these patients.
2631 Little is known about microRNA function in hematopoietic stem and progenitor cells (HSPC). Using a lentivector genetic reporter strategy to functionally detect miRNA activity in hematopoietic cells at single cell resolution, we identified several miRNAs which were specifically expressed in mouse and human HSC and early progenitors, defined according to cell surface phenotype and functional repopulation assays. One of these HSPC-specific miRNAs, miR-126, was further studied. We generated a stable miR-126 knockdown (kd) or forced its expression (“knock-in”, ki) in mouse HSPC using lentiviral vectors. Kd or ki cells were competitively transplanted with congenic, control vector-transduced cells, and hematopoietic chimerism was followed for >1 year in both primary and secondary recipients. miR-126 kd HSPC displayed enhanced myeloid and/or lymphoid contribution during the early phases of reconstitution, while they subsequently contributed similarly as the control cells. When this steady state bone marrow (BM) was transplanted into secondary recipients, we noted an even more pronounced over-contribution of miR-126 kd cells to hematopoiesis. In the long run, however, some secondary mice showed signs of exhaustion of miR-126 kd cells. These data suggest that miR-126 kd enhances hematopoiesis, likely at the stem/early progenitor level and in particular under stress conditions. On the other hand, forced expression of miR-126 (ki) resulted in an early competitive disadvantage in vivo, with progressively decreasing contribution to all hematopoietic lineages, paralleled by a nearly complete depletion of Kit+Sca+Lin- (KSL) miR-126 ki cells in the BM at 6 weeks after transplant. At 3 weeks post-transplant, when miR-126 ki KSL cells could still be detected, we found an increased proliferative index in these cells as judged by EdU incorporation in vivo, paralleled by a higher hematopoietic output respect to control cells at week 2–4 after transplant. These data suggest that miR-126 ki might favor HSC commitment at the cost of self-renewal. This phenotype was specific for miR-126 and not due to vector toxicity, as we demonstrate stable, long term overexpression of several control miRNAs in vivo. Moreover, miR-126 ki cells showed normal clonogenic activity in vitro. We then optimized a protocol to stably knock down miR-126 in human cord blood (huCB) HSPC, and validated this approach by demonstrating upregulation of previously described miR-126 targets including the beta subunit of phosphoinositide-3-kinase. Manipulation of miR-126 activity changed cell growth and differentiation of huCB, and we show altered activation of key signal transduction pathways upon miR-126 kd. Identification of additional miR-126 targets is ongoing using unbiased proteomic and transcriptomic approaches. In summary, these data suggest that a narrow range of miR-126 activity is required for robust and sustained HSC function, and that its manipulation may provide novel insights into stem cell biology. Disclosures: No relevant conflicts of interest to declare.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.