Alexander Weidemann scite author profile

The increase in body size of humans and other vertebrates requires a physiological infrastructure to provide adequate delivery of oxygen to tissues and cells to maintain oxygen homeostasis. The heart, lungs and the vasculature are all part of a highly regulated system that ensures the distribution of the precise amount of oxygen needed throughout the mammalian organism. Given its fundamental impact on physiology and pathology, it is no surprise that the response of cells to a lack of oxygen, termed hypoxia, has been the focus of many research groups worldwide for many decades now. The transcriptional complex hypoxiainducible factor has emerged as a key regulator of the molecular hypoxic response, mediating a wide range of physiological and cellular mechanisms necessary to adapt to reduced oxygen.

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Differential activation and antagonistic function of HIF-α isoforms in macrophages are essential for NO homeostasis

Takeda

et al. 2010

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Hypoxic response and inflammation both involve the action of the hypoxia-inducible transcription factors HIF-1a and HIF-2a. Previous studies have revealed that both HIF-a proteins are in a number of aspects similarly regulated post-translationally. However, the functional interrelationship of these two isoforms remains largely unclear. The polarization of macrophages controls functionally divergent processes; one of these is nitric oxide (NO) production, which in turn is controlled in part by HIF factors. We show here that the HIF-a isoforms can be differentially activated: HIF-1a is induced by Th1 cytokines in M1 macrophage polarization, whereas HIF-2a is induced by Th2 cytokines during an M2 response. This differential response was most evident in polarized macrophages through HIF-a isoform-specific regulation of the inducible NO synthase gene by HIF-1a, and the arginase1 gene by HIF-2a. In silico modeling predicted that regulation of overall NO availability is due to differential regulation of HIF-1a versus HIF-2a, acting to, respectively, either increase or suppress NO synthesis. An in vivo model of endotoxin challenge confirmed this; thus, these studies reveal that the two homologous transcription factors, HIF-1a and HIF-2a, can have physiologically antagonistic functions, but that their antiphase regulation allows them to coordinately regulate NO production in a cytokine-induced and transcription-dependent fashion.

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Deletion of vascular endothelial growth factor in myeloid cells accelerates tumorigenesis

Stockmann¹,

Doedens²,

Weidemann³

et al. 2008

Nature

418

348

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Angiogenesis and the development of a vascular network is required for tumor progression, and involves release of angiogenic factors, including vascular endothelial growth factor (VEGF), from both malignant and stromal cell types1. Infiltration by cells of the myeloid lineage is a hallmark of many tumors, and in many cases the macrophages in these infiltrates express VEGF2. Here we show that deletion of inflammatory cell-derived VEGF attenuates the formation of a typical high-density vessel network, thus blocking the angiogenic switch in solid tumors. Vasculature in tumors lacking myeloid cell-derived VEGF was less tortuous, with increased pericyte coverage and decreased vessel length, indicating vascular normalization. In addition, loss of myeloid-derived VEGF decreases VEGFR2 phosphorylation in tumors, even though overall VEGF levels in the tumors are unaffected. However, myeloid deletion of VEGF resulted in an accelerated tumor progression in multiple subcutaneous isograft models and an autochthonous transgenic model of mammary tumorigenesis, with less overall tumor cell death and decreased tumor hypoxia. Furthermore, loss of myeloid cell VEGF increased tumor susceptibility to chemotherapeutic cytotoxicity. This demonstrates that myeloid-derived VEGF is essential for tumorigenic alteration of vasculature and signaling to VEGFR2, and that these changes act to retard, not promote, tumor progression.

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Preconditional Activation of Hypoxia-Inducible Factors Ameliorates Ischemic Acute Renal Failure

Câmpean²,

et al. 2006

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Activation of hypoxia-inducible transcription factor (HIF) has been identified as an important mechanism of cellular adaptation to low oxygen. Normoxic degradation of HIF is mediated by oxygen-dependent hydroxylation of specific prolyl residues of the regulative ␣-subunits by HIF prolyl hydroxylases (PHD). It was hypothesized that inhibition of HIF degradation by either hypoxia or pharmacologic inhibition of PHD would confer protection against subsequent ischemic injury. For testing this hypothesis ischemic acute renal failure was induced in rats by 40 min of clamping of the left renal artery after right-sided nephrectomy. Before surgery, pretreatment with either carbon monoxide, leading to tissue hypoxia, or the novel PHD inhibitor FG-4487 was applied. No toxic effects of FG-4487 were observed. Both pretreatments strongly induced the accumulation of HIF-1␣ and HIF-2␣ in tubular and peritubular cells, respectively, as well as HIF target gene expression. The course of subsequent ischemic injury was significantly ameliorated by both strategies of preconditioning, as evident from a significant improvement of serum creatinine and serum urea after 24 and 72 h. Furthermore, tissue injury and apoptosis were less severe, which were quantified by application of a standardized histologic scoring system in a blinded manner. In conclusion, the data provide proof of principle that preconditional activation of the HIF system protects against ischemic injury. Inhibiting the activity of HIF hydroxylases therefore seems to have considerable clinical perspectives.

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Role of hypoxia in the pathogenesis of renal disease

Eckardt

Bernhardt

Weidemann

et al. 2005

Kidney International

264

188

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