Three-dimensional quantitative analysis of the Arabidopsis quiescent centre

Quiescent centre (QC) cells represent an integral part of the root stem cell niche. They typically display a low division frequency that has been reported to be controlled by hormone signaling and different regulators, including the ETHYLENE RESPONSE FACTOR 115 (ERF115) transcription factor and D-type cyclins. Here, we applied a three-dimensional (3D) imaging to visualize the Arabidopsis QC cell number, volume and division patterns, including visualization of anticlinal divisions that cannot be deduced from longitudinal 2D imaging. We found that 5-day-old seedlings possess on average eight QC cells which are organized in a monolayered disc. In a period of 7 d, half of the QC cells undergo anticlinal division in a largely invariant space. Ectopic expression of ERF115 and CYCLIN D1;1 (CYCD1;1) promote both anticlinal and periclinal QC cell divisions, the latter resulting in a dual-layered QC zone holding up to 2-fold more QC cells compared with the wild type. In contrast, application of cytokinin or ethylene results in an increase in the number of periclinal, but a decrease in anticlinal QC divisions, suggesting that they control the orientation of QC cell division. Our data illustrate the power of 3D visualization in revealing unexpected QC characteristics.

Fzr1 Preserves Hematopoietic Stem Cell Quiescence through Inhibiting Runx1

Regulated blood production is achieved through the hierarchical organization of dormant hematopoietic stem cell (HSC) subsets that differ in self-renewal potential and division frequency, with long-term (LT)-HSCs dividing the least. FZR1, as a regulatory subunit of anaphase promoting complex/cyclosome (APC), is a master regulator of cell cycle, but little is known with regard to its role in HSC quiescence. Thus, we examined the function of Fzr1 in HSCs during steady-state hematopoiesis and under stress. We demonstrate that Fzr1 deletion led to perturbed hematopoiesis with an approximately 2-fold decrease in HSC pool size, as consequence of Fzr1 loss driving HSC from quiescence into rapid cycling (~70.1% to ~28.4%), elevating proliferation (~4.58% to ~18.5%) and apoptosis (~0.23% to ~2.86%) in HSC. As shown by serial bone marrow transplantation and competitive repopulation assays, self-renewal capacity and regenerative capacity were impaired, but differentiation of HSCs was not affected post Fzr1 deletion. Mechanistically, Fzr1 loss led to upregulation of Runx1 expression, in line with the protein expression, the ubiquitin sites of the gene was also obviouly decreased, knockdown Runx1 can rescue the Fzr1-deficient phenotype in HSC. Together, our data therefore support that Fzr1 acts a positive regulator of HSC quiescence and self-renewal capacity through inhibiting Runx1 expression. Disclosures No relevant conflicts of interest to declare.

Defining compartmentalized stem and progenitor populations with distinct cell division frequency in the ocular surface epithelium

SummaryAdult tissues contain label-retaining cell (LRC)s, which are relatively slow-cycling and considered to represent a unique property of tissue stem cell (SC)s. In the ocular surface epithelium, LRCs are detected in the limbus, a boundary between cornea and conjunctiva, and the fornix of the conjunctiva; however, the character of LRCs and identity of SCs remain unclear due to lack of appropriate molecular markers. Here we show that the ocular surface epithelium accommodates spatially distinct stem/progenitor populations with different cell division frequency. By combining EdU pulse-chase analysis and lineage tracing with three CreER transgenic mouse lines: Slc1a3CreER, Dlx1CreER and K14CreER, we detect distinct dynamics of epithelial SCs in the cornea and conjunctiva. In the limbus, long-lived SCs are labeled with Slc1a3CreER and they either migrate centripetally toward the central cornea or laterally expand their clones within the limbal region. In the central cornea, cells are mostly non-LRCs, labeled by Dlx1CreER and K14CreER, and the number of clones declines after a short period of time with rare long-lasting clones, suggesting their properties as short-lived progenitor cells. In the conjunctival epithelium, which consists of bulbar, fornix and palpebral conjunctiva, each territory is regenerated by compartmentalized, distinct SC populations without migrating one region to another. The severe damage of the cornea leads to the cancellation of SC compartments, causing conjunctivalization of the eye, whereas milder limbal injury induces a rapid increase of laterally-expanding clones in the limbus. Taken together, our work provides lineage tracing tools of the eye and defines compartmentalized, multiple SC/progenitor populations in homeostasis and their behavioral changes in response to injury.

Multiple modulation synthesis with high spatial resolution for noninvasive deep neurostimulation

ABSTRACTNoninvasive neurostimulation plays a pivotal role in direct control of neural circuit and modulating neuronal function. However, it is difficult to balance both spatial focality and depth of penetration in stimulating deep neurons. Here, we designed time-division, frequency & polarity modulation synthesis (TMFPMS) for stimulating deep neurons noninvasively with low-frequency envelope. We demonstrated its spatial resolution: mm-level via computational simulation including finite element analysis and Hodgkin-Huxley action potential model. Taken together, the results of this study indicate that TMFPMS neurostimulation with high spatial resolution is steerable and may replace traditional implanted electrode.