Hui Yu scite author profile

NF-κB pathway consists of canonical and non-canonical pathways. The canonical NF-κB is activated by various stimuli, transducing a quick but transient transcriptional activity, to regulate the expression of various proinflammatory genes and also serve as the critical mediator for inflammatory response. Meanwhile, the activation of the non-canonical NF-κB pathway occurs through a handful of TNF receptor superfamily members. Since the activation of this pathway involves protein synthesis, the kinetics of non-canonical NF-κB activation is slow but persistent, in concordance with its biological functions in the development of immune cell and lymphoid organ, immune homeostasis and immune response. The activation of the canonical and non-canonical NF-κB pathway is tightly controlled, highlighting the vital roles of ubiquitination in these pathways. Emerging studies indicate that dysregulated NF-κB activity causes inflammation-related diseases as well as cancers, and NF-κB has been long proposed as the potential target for therapy of diseases. This review attempts to summarize our current knowledge and updates on the mechanisms of NF-κB pathway regulation and the potential therapeutic application of inhibition of NF-κB signaling in cancer and inflammatory diseases.

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Repression of arterial genes in hemogenic endothelium is sufficient for haematopoietic fate acquisition

Lizama

et al. 2015

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Changes in cell fate and identity are essential for endothelial-to-haematopoietic transition (EHT), an embryonic process that generates the first adult populations of haematopoietic stem cells (HSCs) from hemogenic endothelial cells. Dissecting EHT regulation is a critical step towards the production of in vitro derived HSCs. Yet, we do not know how distinct endothelial and haematopoietic fates are parsed during the transition. Here we show that genes required for arterial identity function later to repress haematopoietic fate. Tissue-specific, temporally controlled, genetic loss of arterial genes (Sox17 and Notch1) during EHT results in increased production of haematopoietic cells due to loss of Sox17-mediated repression of haematopoietic transcription factors (Runx1 and Gata2). However, the increase in EHT can be abrogated by increased Notch signalling. These findings demonstrate that the endothelial haematopoietic fate switch is actively repressed in a population of endothelial cells, and that derepression of these programs augments haematopoietic output.

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Hematopoietic stem cell exhaustion impacted by p18INK4C and p21Cip1/Waf1 in opposite manners

et al. 2006

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Transplantation-associated stress can compromise the hematopoietic potential of hematopoietic stem cells (HSCs). As a consequence, HSCs may undergo "exhaustion" in serial transplant recipients, for which the cellular and molecular bases are not well understood. Hematopoietic exhaustion appears to be accelerated in the absence of p21 Cip1/Waf1 (p21), a cyclindependent kinase inhibitor (CKI) in irradiated hosts. Our recent study demonstrated that unlike loss of p21, deletion of p18 INK4C (p18), a distinct CKI, results in improved long-term engraftment, largely because of increased self-renewing divisions of HSCs in vivo. We show here that HSCs deficient in p18 sustained their competitiveness to wild-type HSCs from unmanipulated young mice, and retained multilineage differentiation potential after multiple rounds of serial bone marrow transfer over a period of more than 3 years. Further, p18 absence significantly decelerated hematopoietic exhaustion caused by p21 deficiency. Such an effect was shown to occur at the stem cell level, likely by a counteracting mechanism against the cellular senescence outcome. Our current study provides new insights into the distinct impacts of these cellcycle regulators on HSC exhaustion and possibly HSC aging as well under proliferative stress, thereby offering potential pharmacologic targets for sustaining the durability of stressed HSCs in transplantation or elderly patients. (Blood. 2006;

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Deletion of Puma protects hematopoietic stem cells and confers long-term survival in response to high-dose γ-irradiation

et al. 2010

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Molecular paradigms underlying the death of hematopoietic stem cells (HSCs) induced by ionizing radiation are poorly defined. We have examined the role of Puma (p53 up-regulated mediator of apoptosis) in apoptosis of HSCs after radiation injury. In the absence of Puma, HSCs were highly resistant to ␥-radiation in a cell autonomous manner. As a result, Puma-null mice or the wild-type mice reconstituted with Puma-null bone marrow cells were strikingly able to survive for a long term after high-dose ␥-radiation that normally would pose 100% lethality on wild-type animals. Interestingly, there was no increase of malignancy in the exposed animals. Such profound beneficial effects of Puma deficiency were likely associated with better maintained quiescence and more efficient DNA repair in the stem cells. This study demonstrates that Puma is a unique mediator in radiation-induced death of HSCs. Puma may be a potential target for developing an effective treatment aimed to protect HSCs from lethal radiation. (Blood. 2010;115(17):3472-3480)

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Hui Yu

Targeting NF-κB pathway for the therapy of diseases: mechanism and clinical study

Repression of arterial genes in hemogenic endothelium is sufficient for haematopoietic fate acquisition

Hematopoietic stem cell exhaustion impacted by p18INK4C and p21Cip1/Waf1 in opposite manners

Deletion of Puma protects hematopoietic stem cells and confers long-term survival in response to high-dose γ-irradiation

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