Tumor necrosis factor/cachectin increases permeability of endothelial cell monolayers by a mechanism involving regulatory G proteins.

Brett, Jerold; Gerlach, Herwig; Nawroth, Peter P.; Steinberg, Susan; Godman, Gabriel C.; Stern, David M.

doi:10.1084/jem.169.6.1977

Cited by 372 publications

(183 citation statements)

References 43 publications

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“…As presented here, neither cytokine modulates accumulation of the IL-6 mRNA by interacting with preexisting transcription factors (either repressors or activators) since both TNF alpha and LT require de novo protein synthesis to exert their effects. Induction of transcriptional activators such as AP-1, which has recently been shown to mediate TNF alpha-induced collagenase gene expression in fibroblasts [30] or of Gbinding proteins known to mediate effects of TNF alpha on endothelial cells [31], might also be involved in LT and TNF alpha-modulated IL-6 gene expression. In uninduced as in induced monocytes, IL-6 mRNA is under control of short-lived destabilizers leading to superinduction of IL-6 message as soon as protein synthesis is inhibited.…”

Section: Discussionmentioning

confidence: 99%

Mechanisms of differential regulation of interleukin‐6 mRNA accumulation by tumor necrosis factor alpha and lymphotoxin during monocytic differentiation

et al. 1990

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In the present report we compare the capacity of two related cytokines, tumor necrosis factor (TNF) alpha and lymphotoxin (LT), to modulate mRNA levels of interleukin-6 (IL-6) in cells representing different stages of monocytic differentiation including the human leukemia cell lines HL 60, U 937, THP-1, MonoMac l and peripheral blood monocytes. We show that the capacity of TNF alpha and LT to induce IL-6 mRNA accumulation increases as monocytic differentiation proceeds with TNF alpha being more potent than LT, suggesting that alternate pathways may be used by differentiating cells to control expression of IL-6. In contrast, in monocytes which constitutively synthesize IL-6 transcripts, TNF alpha and LT treatment had opposite effects on levels of IL-6 mRNA accumulation. In these cells TNF alpha enhanced steady state levels of IL-6 transcripts due to mRNA stabilization, whereas LT shortened IL-6 mRNA half-life, most likely due to induction of a RNA destabilizer since LT-mediated downregulation of levels of IL-6 mRNA in monocytes could be prevented by inhibition of protein synthesis. Neither TNF alpha nor LT altered IL-6 mRNA accumulation by interfering with preexisting transcription factors since both TNF alpha and LT required de novo protein synthesis to exert their effects.

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Section: Discussionmentioning

confidence: 99%

Mechanisms of differential regulation of interleukin‐6 mRNA accumulation by tumor necrosis factor alpha and lymphotoxin during monocytic differentiation

et al. 1990

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“…2 TNF-a induces tissue factor production and increases vascular permeability and procoagulant activity on endothelial cells. [3][4][5] Unfortunately, recombinant TNF-a has limited clinical utility because of predictable but severe systemic toxicity. At the maximum tolerated doses, there is no meaningful antitumor activity when TNF-a is delivered systemically.…”

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confidence: 99%

Tumor vasculature‐targeted delivery of tumor necrosis factor‐α*

Tandle

Hanna

Lorang

et al. 2008

Cancer

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BACKGROUND: Recently, considerable efforts have been directed toward antivascular therapy as a new modality to treat human cancers. However, targeting a therapeutic gene of interest to the tumor vasculature with minimal toxicity to other tissues remains the objective of antivascular gene therapy. Tumor necrosis factor‐α (TNF‐α) is a potent antivascular agent but has limited clinical utility because of significant systemic toxicity. At the maximum tolerated doses of systemic TNF‐α, there is no meaningful antitumor activity. Hence, the objective of this study was to deliver TNF‐α targeted to tumor vasculature by systemic delivery to examine its antitumor activity. METHODS: A hybrid adeno‐associated virus phage vector (AAVP) was used that targets tumor endothelium to express TNF‐α (AAVP‐TNF‐α). The activity of AAVP‐TNF‐α was analyzed in various in vitro and in vivo settings using a human melanoma tumor model. RESULTS: In vitro, AAVP‐TNF‐α infection of human melanoma cells resulted in high levels of TNF‐α expression. Systemic administration of targeted AAVP‐TNF‐α to melanoma xenografts in mice produced the specific delivery of virus to tumor vasculature. In contrast, the nontargeted vector did not target to tumor vasculature. Targeted AAVP delivery resulted in expression of TNF‐α, induction of apoptosis in tumor vessels, and significant inhibition of tumor growth. No systemic toxicity to normal organs was observed. CONCLUSIONS: Targeted AAVP vectors can be used to deliver TNF‐α specifically to tumor vasculature, potentially reducing its systemic toxicity. Because TNF‐α is a promising antivascular agent that currently is limited by its toxicity, the current results suggest the potential for clinical translation of this strategy. Cancer 2009. Published 2008 by the American Cancer Society.

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“…In contrast to the effects of MAb 32 on TNF, activity in WEHI-164 cells, the antibody has been shown to be significantly more inhibitory than MAb 47 on the induction of procoagulant activity in cultured endothelial cells. The greater inhibitory potency of MAb 32 in the procoagulant assay, as compared with MAb 47 in receptor binding, is still unclear; however, it has been shown (Brett et al, 1989) that endothelial cells may have more than one class of TNF<,, receptor, of which the functionally representative one is reflected in the bioassay rather than in the radioreceptor assay (see below).…”

Section: Animals and Tumour Cell Linesmentioning

confidence: 99%

“…The recent identification of a natural TNFCt binding protein (Engelmann et al, 1989), which may have regulatory effects on the cytokine in vivo and the existence of at least two structurally distinct receptors (Hohman et al, 1989;Engelmann et al, 1989;Loetscher et al, 1990;Espevik et al, 1990), would also lend support to the above hypothesis. Endothelial cells appear to express two TNF receptors which mediate different biological effects of TNF (Brett et al, 1989). It appears that expression of tissue factor in response to TNF is signalled by a non-G protein linked receptor while increased vascular permeability in response to TNF occurs via a G protein-linked receptor.…”

Section: Animals and Tumour Cell Linesmentioning

confidence: 99%

Selective enhancement of the tumour necrotic activity of TNF α with monoclonal antibody

Da¹,

Furphy²,

Aston³

1992

Br J Cancer

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Summary The binding and biological activity of human TNFm on endothelial and tumour cells has been studied in the presence of monoclonal antibodies (MAbs). In Tumour necrosis factor (TNFC,) is a product of activated macrophages in response to infection and during malignancy. Systemic administration of this cytokine results in haemorrhagic necrosis of tumours in vivo Green et al., 1977) whereas in vitro, it has cytostatic and cytolytic activity on tumour cells (Helson et al., 1975). In addition to its 'host-protective' effects, TNF, has been implicated as the causative agent in the pathology associated with septicemia, cachexia, cerebral malaria and cancer. Although recombinant TNF,,, has been used therapeutically in cancer patients, side-effects such as coagulopathy, thrombocytopaenia, lymphcytopaenia, hepatotoxicity and renal impairment have limited its application (Creaven et al., 1987;Kimura et al., 1987;Selby et al., 1987; Naworth & Stern, 1986). The systemic toxicity associated with the administration of TNFC, is believed to be, at least in part, a consequence of its interaction with the endothelium (Bevilacqua et al., 1986;Nawroth & Stern, 1986;Selby et al., 1987). Furthermore, reducing the ability of TNFC, to bind to endothelial cells whilst preserving its tumour cytotoxic activity may have a beneficial outcome in the use of this cytokine therapeutically. We describe here a monoclonal antibody to human TNFCt which significantly enhances the tumour regression activity of the cytokine (5-10-fold) whilst inhibiting some of the associated toxic side-effects. In particular, the antibody has been shown to inhibit the procoagulant activity of TNF, on endothelial cells whilst having no effect on the binding of the cytokine to WEHI-164 tumour cells. These observations may provide the basis for an improved approach to therapy with this cytokine. Materials and methods Animals and tumour cell linesAll experiments were performed using female BALB/c mice aged [10][11][12]

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Tumor necrosis factor/cachectin increases permeability of endothelial cell monolayers by a mechanism involving regulatory G proteins.

Cited by 372 publications

References 43 publications

Mechanisms of differential regulation of interleukin‐6 mRNA accumulation by tumor necrosis factor alpha and lymphotoxin during monocytic differentiation

Mechanisms of differential regulation of interleukin‐6 mRNA accumulation by tumor necrosis factor alpha and lymphotoxin during monocytic differentiation

Tumor vasculature‐targeted delivery of tumor necrosis factor‐α*

Selective enhancement of the tumour necrotic activity of TNF α with monoclonal antibody

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