Human embryonic stem cells (hESC) have potential applications as tools for drug screening to identify small molecule regulators of self-renewal or differentiation. Elucidating the mechanisms governing lineage commitment in hESC will allow for efficient derivation of specified cell types for clinical use. Recognizing the early steps in loss of pluripotency is key to achieving both goals of drug screening and derivation of therapeutically relevant cell types. Here we report the use of a real time cell cycle fluorescent reporter for the first time in hESC that indicates onset of differentiation in a lineage unbiased manner. Pluripotent hESC possess a short cell cycle length, due primarily to a truncated G1 phase. G1 lengthens concomitant with differentiation. Stable hESC lines expressing the live cell cycle reporter exhibit fluorescence only during G1. Due to the short length of pluripotent G1 phase, G1 fluorescence is only weakly and transiently detected, however it is quickly increased to easily detectable levels upon onset of differentiation. We hypothesize that lengthened G1 phase can be used as an indicator of differentiation status of individual human embryonic stem cells. Cells with lengthened G1 are typically negative for pluripotency markers OCT4, Tra-1-60 and SSEA-3 following differentiation. Differentiated cells with lengthened G1 also demonstrate increased levels of lineage-specific differentiation markers at both the protein and mRNA level. Automated image analysis of hESC indicates this mutually exclusive relationship between lengthened G1 and pluripotency exists both on the cellular level and in colonies as a whole. Here we have shown that lengthened G1 indicates both loss of pluripotency and gain of lineage markers.
Uptake of bacterial filaments by macrophages is characterized by a prolonged phagocytic cup stage and diminished microbicidal activity during phagosome maturation.
Misregulation of long non-coding RNA (lncRNA) genes has been linked to a wide variety of cancer types. Here we report on Mammary Tumor Associated RNA 25 (MaTAR25), a nuclear enriched and chromatin associated lncRNA that plays a role in mammary tumor cell proliferation, migration, and invasion, both in vitro and in vivo. MaTAR25 functions by interacting with purine rich element binding protein B (PURB), and associating with a major downstream target gene Tensin1 (Tns1) to regulate its expression in trans. The Tns1 protein product is a critical component of focal adhesions linking signaling between the extracellular matrix and the actin cytoskeleton. Knockout of MaTAR25 results in down-regulation of Tns1 leading to a reorganization of the actin cytoskeleton, and a reduction of focal adhesions and microvilli. We identify LINC01271 as the human ortholog of MaTAR25, and importantly, increased expression of LINC01271 is associated with poor patient prognosis and metastasis. Our findings demonstrate that LINC01271 represents a potential therapeutic target to alter breast cancer progression.
Summary Legionella, the aetiological agent responsible for Legionellosis, is an opportunistic pathogen that infects humans upon the inhalation of contaminated aerosolized water droplets. Legionella is pleomorphic and its different morphotypes exhibit varying degrees of virulence. While the filamentous forms of Legionella pneumophila (Lp) have been reported in patient samples since the first description of legionellosis, their role in disease has not been studied. Our results show that both E‐cadherin and β1 integrin receptors mediate filamentous Lp (FLp) attachment to lung epithelial cells (LECs). The activation of these receptors induces the formation of actin enriched membrane surface structures that we designated ‘hooks’ and ‘membrane wraps’. These structures entrap the filaments on the cell surface leading to their gradual internalization through a zipper mechanism of phagocytosis dependent on actomyosin activity. The supply of E‐cadherin receptors from the recycling pathway and β1 integrins released from focal adhesion turnover are required to sustain this process. Intracellular FLp inhabits a vacuolar compartment where filaments differentiate into short rods and replicate to produce infective progeny. Here we are reporting a first description of the invasion mechanism used by FLp to invade LECs. Therefore, filamentous morphotype of Lp can induce its own uptake by LECs and has the potential ability to cause disease.
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