John Ramunas scite author profile

The immortal strand hypothesis proposes that asymmetrically dividing stem cells (SCs) selectively segregate chromosomes that bear the oldest DNA templates. We investigated cosegregation in neural stem cells (NSCs). After exposure to the thymidine analogue 5-bromo-2-deoxyuridine (BrdU), which labels newly synthesized DNA, a subset of neural precursor cells were shown to retain BrdU signal. It was confirmed that some BrdU-retaining cells divided actively, and that these cells exhibited some characteristics of SCs. This asymmetric partitioning of DNA then was demonstrated during mitosis, and these results were further supported by real time imaging of SC clones, in which older and newly synthesized DNA templates were distributed asymmetrically after DNA synthesis. We demonstrate that NSCs are unique among precursor cells in the uneven partitioning of genetic material during cell divisions.

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High-resolution video monitoring of hematopoietic stem cells cultured in single-cell arrays identifies new features of self-renewal

Dykstra

Ramunas²,

Kent³

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

109

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To search for new indicators of self-renewing hematopoietic stem cells (HSCs), highly purified populations were isolated from adult mouse marrow, micromanipulated into a specially designed microscopic array, and cultured for 4 days in 300 ng͞ml Steel factor, 20 ng͞ml IL-11, and 1 ng͞ml flt3-ligand. During this period, each cell and its progeny were imaged at 3-min intervals by using digital time-lapse photography. Individual clones were then harvested and assayed for HSCs in mice by using a 4-month multilineage repopulation endpoint (>1% contribution to lymphoid and myeloid lineages). In a first experiment, 6 of 14 initial cells (43%) and 17 of 61 clones (28%) had HSC activity, demonstrating that HSC self-renewal divisions had occurred in vitro. Characteristics associated with HSC activity included longer cell-cycle times and the absence of uropodia on a majority of cells within the clone during the final 12 h of culture. Combining these criteria maximized the distinction of clones with HSC activity from those without and identified a subset of 27 of the 61 clones. These 27 clones included all 17 clones that had HSC activity; a detection efficiency of 63% (2.26 times more frequently than in the original group). The utility of these characteristics for discriminating HSC-containing clones was confirmed in two independent experiments where all HSCcontaining clones were identified at a similar 2-to 3-fold-greater efficiency. These studies illustrate the potential of this monitoring system to detect new features of proliferating HSCs that are predictive of self-renewal divisions.video microscopy ͉ time-lapse imaging ͉ cell-cycle kinetics ͉ cell behavior ͉ lineage tracking T ime-lapse video imaging offers unique opportunities to determine how specific physical properties of individual living cells change with respect to one another over time and under different conditions. Time-lapse micrography has been used for more than half a century (1-4) to study cell morphology during attachment and migration (5, 6), cell lifetimes (7, 8), growth (9), death (2, 10), contact inhibition (11), clonal heterogeneity (12), and mitosis (13). Software for extracting and analyzing cell lineage (14) Here, we asked whether time-lapse video imaging could be used to identify previously unidentified behavioral traits of hematopoietic stem cells (HSCs) with functionally validated long-term multilineage repopulating activity in vivo. A number of groups have reported methods for obtaining highly purified (Ͼ20% pure) populations of HSCs from normal adult mouse bone marrow (23-28). One of these methods involves isolating cells lacking surface markers characteristic of mature blood cells (i.e., lineage marker-negative, or lin Ϫ cells) and able to efflux the fluorescent dyes, Rhodamine-123 (Rho Ϫ cells) and Hoechst 33342 (25). Efflux of Hoechst 33342 results in the appearance of a side population of cells (SP cells) in two-dimensional plots of fluorescent events (29). In mouse bone marrow (BM), the subset of lin Ϫ Rho Ϫ SP cells represents Ϸ0.004...

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Transient delivery of modified mRNA encoding TERT rapidly extends telomeres in human cells

et al. 2015

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Telomere extension has been proposed as a means to improve cell culture and tissue engineering and to treat disease. However, telomere extension by nonviral, nonintegrating methods remains inefficient. Here we report that delivery of modified mRNA encoding TERT to human fibroblasts and myoblasts increases telomerase activity transiently (24-48 h) and rapidly extends telomeres, after which telomeres resume shortening. Three successive transfections over a 4 d period extended telomeres up to 0.9 kb in a cell type-specific manner in fibroblasts and myoblasts and conferred an additional 28 6 1.5 and 3.4 6 0.4 population doublings (PDs), respectively. Proliferative capacity increased in a dose-dependent manner. The second and third transfections had less effect on proliferative capacity than the first, revealing a refractory period. However, the refractory period was transient as a later fourth transfection increased fibroblast proliferative capacity by an additional 15.2 6 1

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High-resolution, serial intravital microscopic imaging of nanoparticle delivery and targeting in a small animal tumor model

Zavaleta

Rosenberg

et al. 2013

Nano Today

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Nanoparticles are under active investigation for the detection and treatment of cancer. Yet our understanding of nanoparticle delivery to tumors is limited by our ability to observe the uptake process on its own scale in living subjects. We chose to study single-walled carbon nanotubes (SWNTs) because they exhibit among the highest levels of tumor uptake across the wide variety of available nanoparticles. We target them using RGD (arginine-glycine-aspartic acid) peptide which directs them to integrins overexpressed on tumor vasculature and on the surface of some tumor cells (e.g., U87MG as used here). We employ intravital microscopy (IVM) to quantitatively examine the spatiotemporal framework of targeted SWNT uptake in a murine tumor model. IVM provided a dynamic microscale window into nanoparticle circulation, binding to tumor blood vessels, extravasation, binding to tumor cells, and tumor retention. RGD-SWNTs bound to tumor vasculature significantly more than controls (P<0.0001). RGD-SWNTs extravasated similarly compared to control RAD-SWNTs, but post-extravasation we observed as RGD-SWNTs eventually bound to individual tumor cells significantly more than RAD-SWNTs (p<0.0001) over time. RGD-SWNTs and RAD-SWNTs displayed similar signal in tumor for a week, but over time their curves significantly diverged (p<0.001) showing increasing RGD-SWNTs relative to untargeted SWNTs. We uncovered the complex spatiotemporal interplay between these competing uptake mechanisms. Specific uptake was delimited to early (1–6 hours) and late (1–4 weeks) time-points, while non-specific uptake dominated from 6 hours to 1 week. Our analysis revealed critical, quantitative insights into the dynamic, multifaceted mechanisms implicated in ligand-targeted SWNT accumulation in tumor using real-time observation.

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John Ramunas

Support for the immortal strand hypothesis: neural stem cells partition DNA asymmetrically in vitro

High-resolution video monitoring of hematopoietic stem cells cultured in single-cell arrays identifies new features of self-renewal

Transient delivery of modified mRNA encoding TERT rapidly extends telomeres in human cells

High-resolution, serial intravital microscopic imaging of nanoparticle delivery and targeting in a small animal tumor model

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