The science behind the hypoxic niche of hematopoietic stem and progenitors

Nombela‐Arrieta, César; Silberstein, Leslie E.

doi:10.1182/asheducation-2014.1.542

Cited by 40 publications

(42 citation statements)

References 29 publications

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“…Culture conditions under hypoxia switched the metabolism of the cells from aerobic to anaerobic and reduced the mitochondrial respiration, which correlates with increased glycolysis rates and reduced ROS production (Saito et al ., ). Therefore, an increase in the acidification of the cell culture medium that we observed under hypoxia conditions (data not shown) could be related to this metabolic switch without affecting cell proliferation (data not shown), which correlates with previous studies (Nombela‐Arrieta and Silberstein, ; Turner et al ., ; Wang et al ., ). Other molecules could also play a role in regulating cell stemness in response to hypoxia.…”

Section: Discussionsupporting

confidence: 91%

Urothelial cell expansion and differentiation are improved by exposure to hypoxia

Chabaud

Saba

Baratange

et al. 2017

J Tissue Eng Regen Med

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Cells obtained from a patient's biopsy have to be expanded after extraction to produce autologous tissues, but standard cell culture conditions often limit their growth or lifespan and could induce early and inadequate cell differentiation. Moreover, it has previously been reported that the air-liquid interface, that induces maturation of the urothelium, stimulated inadequate differentiation associated with aberrant keratin-14 expression. The aim of this study was to test the benefits of hypoxia during expansion of urothelial cells and maturation of the bladder epithelium in the context of tissue engineering. Bladder mucosa substitutes were reconstructed using the self-assembly method with urothelial cells (UCs) expanded in normoxia or hypoxia. Hypoxia improved UCs expansion until passage P7, whereas normoxic conditions limited the use of UCs to passage P4. Maturation of the urothelium was also compared in normoxic vs. hypoxic conditions. Using laminin V, p63, Ki-67, keratin-5 and -14, Claudin-4 and zonula occludens protein-1, we show a better organization of the basal UC layer in hypoxia despite a thinner intermediate layer. Finally, barrier function was assessed by permeation tests. Cell culture in hypoxia allowed the generation of bioengineered urological tissue closer to native bladder characteristics, which represents a promising avenue to circumvent the lack of adequate tissues for reconstructive surgery. Copyright © 2017 John Wiley & Sons, Ltd.

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Section: Discussionsupporting

confidence: 91%

Urothelial cell expansion and differentiation are improved by exposure to hypoxia

Chabaud

Saba

Baratange

et al. 2017

J Tissue Eng Regen Med

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“…Many of the niches are constructed around diverse microvessel types, which distinctly regulate access to nutrients, oxygen, and metabolites derived from circulating blood. [64][65][66] Nevertheless, for the most part, available data on BM subcompartments remain fragmentary, and a broader picture integrating comprehensive spatial patterns and number of niches in an organ-wide context is lacking. In fact, only a limited number of studies have analyzed cell subset localization at a global scale and thus explored the hypothesis that hematopoietic cells distribute in a nonarbitrary fashion in accordance to a defined zonation of the BM landscape.…”

Section: Org Frommentioning

confidence: 99%

Quantification and three-dimensional microanatomical organization of the bone marrow

Nombela‐Arrieta

Manz

2017

Blood Advances

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Bone marrow (BM) constitutes one of the largest organs in mice and humans, continuously generating, in a highly regulated manner, red blood cells, platelets, and white blood cells that together form the majority of cells of the body. In this review, we provide a quantitative overview of BM cellular composition, we summarize emerging knowledge on its structural organization and cellular niches, and we argue for the need of multidimensional approaches such as recently developed imaging techniques to uncover the complex spatial logic that underlies BM function in health and disease.Since Neumann and Bizzozero independently proposed in 1868 that the origin of blood cells was to be found in soft tissues contained inside bone cavities, the bone marrow (BM) has continued to fascinate scientists and clinicians alike. 1,2 Yet more than a century later, our understanding of how the hematopoietic, immune, and bone-forming tasks of the BM are tightly controlled and integrated in the context of one common anatomical space is still incomplete. Methodological approaches and advances to study BM tissuesEarly studies on BM cellular composition and microarchitecture date back to the 19th century when the first biopsies of marrow content were performed in living individuals. 3 Microscopic observation of BM smears and examination of histological sections became the standard technique, which is still used to this day to study, diagnose, and classify hematologic disorders. The realization in the post-World War II era that transplantation of BM cells from healthy individuals could rescue the lethal effects of high-dose irradiation on hematopoiesis galvanized scientific interest in BM and lead to the development of methods to detect and measure hematopoietic stem and progenitor cell (HSPC) activity, absolute cellularity, lineage-specific half-lives, and kinetics of cell production in the BM of humans and in laboratory animals. 4,5 Gradual improvements in light and electron microscopy further refined the understanding of the quantitative composition and ultrastructural features of BM tissues. 6 The biggest leap in the fields of immunology and hematology came with the advent of recombinant antibody technology and flow cytometry in the 1960s. These breakthroughs permitted the identification, quantification, and isolation of diverse populations from highly heterogeneous cell suspensions through detection of phenotypic traits. 5 Indeed, to this day, flow cytometry remains the technological mainstay for the study and dissection of the hematopoietic system.Immunolabeling methods were further adopted in modern fluorescence-based microscopy to discriminate cellular phenotypes in tissue sections and study cellular organization in the BM. In recent years, confocal microscopy has become the most popular modality to define spatial relationships and study developmental-stage specific localization patterns, with a keen interest of many groups in the dissection of HSPC niches. 7 In addition, intravital multiphoton microscopy is employed to obtain dyna...

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“…The h-Niche is irrigated with a heterogeneous network of arterioles, which carry oxygenated blood and are most abundant near the endosteum, and sinusoids, which carry less oxygenated blood and are abundant in the central BM (20, 47–49). This creates an oxygen gradient in the BM, from ≈4% O 2 near the endosteum to ≈2% in the central marrow (50, 51). However, the distribution of HSCs throughout the BM suggests that HSC maintain a hypoxic profile regardless of their location and external O 2 tension (24, 47, 48, 50–52).…”

Section: Oxidative Stress and Changing Metabolic Needsmentioning

confidence: 99%

“…This creates an oxygen gradient in the BM, from ≈4% O 2 near the endosteum to ≈2% in the central marrow (50, 51). However, the distribution of HSCs throughout the BM suggests that HSC maintain a hypoxic profile regardless of their location and external O 2 tension (24, 47, 48, 50–52). Although it is formally possible that super-low O 2 levels might exist in tight regions proximal to HSCs (50).…”

Section: Oxidative Stress and Changing Metabolic Needsmentioning

confidence: 99%

Hematopoietic stem cells under pressure

Ganuza

McKinney‐Freeman

2017

Current Opinion in Hematology

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Purpose of review Hematopoietic stem cells (HSCs) and progenitors are tasked with maintaining hematopoietic homeostasis in the face of numerous insults and challenges, including infection, inflammation and exsanguination. HSCs possess the remarkable ability to reconstitute the entire hematopoietic system of an organism whose own hematopoietic system has been ablated. This ability is exploited routinely in the clinic via HSC transplantation (HSCT). Here, we focus on the physiological and molecular bottlenecks overcome by HSCs during transplantation. Recent findings Upon transplantation, HSCs need to encounter a damaged bone marrow (BM) niche, characterized molecularly by increases in oxygen concentrations and an altered cytokine milieu. New mechanisms and pathways have been recently implicated during HSCT, including transplanted HSC-dependent secretion of conditioning molecules that facilitate engraftment and pathways that protect HSCs from perturbed organelle homeostasis. Summary Better understanding the molecular processes HSCs employ to withstand the stress of transplant will illuminate novel targets for further improving conditioning regimens and engraftment during HSCT.

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The science behind the hypoxic niche of hematopoietic stem and progenitors

Cited by 40 publications

References 29 publications

Urothelial cell expansion and differentiation are improved by exposure to hypoxia

Urothelial cell expansion and differentiation are improved by exposure to hypoxia

Quantification and three-dimensional microanatomical organization of the bone marrow

Hematopoietic stem cells under pressure

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