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Abstract

Objective

Human mesothelial cells (HMC) are a major source of intraperitoneal vascular endothelial growth factor (VEGF) and by that are presumably involved in complications of long-term peritoneal dialysis (PD), such as ultrafiltration failure. This prompted us to look for agents that reduce basic mesothelial VEGF production and abrogate VEGF-overproduction induced by proinflammatory cytokines such as tumor necrosis factor alpha (TNF-α) and interleukin-1α (IL-1α). Angiotensin-converting enzyme (ACE) inhibition was found to preserve peritoneal function and ameliorate morphologic changes in a rat PD model. The present in vitro study was designed to investigate the effect of the ACE inhibitors captopril and enalapril, and the angiotensin II type 1-receptor (AT1) antagonist losartan on mesothelial VEGF synthesis.

Methods

HMC were isolated from omental tissue and taken into culture. VEGF antigen concentrations were measured in the cell supernatant by ELISA. VEGF mRNA levels were determined by real-time polymerase chain reaction.

Results

Incubation of HMC with captopril (100 - 1000 μmol/L) resulted in a concentration-dependent attenuation of VEGF synthesis. Incubation with captopril (500 - 1000 – μmol/L), enalapril (100 - 1000 μmol/L), and losartan (1 100 μmol/L) significantly decreased inflammatory mediator (TNF-α, IL-1α)-induced mesothelial VEGF overproduction.

Conclusion

The results indicate that ACE inhibitors and AT1-receptor blockers are capable of effectively attenuating the overproduction of VEGF due to proinflammatory cytokine stimuli. These data suggest that locally produced angiotensin II in the peritoneal cavity may be a potential therapeutic target in ultrafiltration failure during long-term PD.

Keywords

Mesothelial cells vascular endothelial growth factor ACE inhibitor AT1-receptor blocker

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References

Mandl-Weber

, Cohen

C.D.

, Haslinger

, Kretzler

, Sitter

Vascular endothelial growth factor production and regulation in human peritoneal mesothelial cells.

Kidney Int 2002; 61: 570–8.

Senger

D.R.

, Brown

L.F.

, Claffey

K.P.

, Dvorak

H.F.

Vascular permeability factor, tumor angiogenesis and stroma generation.

Invasion Metastasis 1994; 14: 385–94.

Horowitz

J.R.

, Rivard

, van der Zee

, Hariavala

, Sheriff

D.D.

, Esakof

D.D.

Vascular endothelial growth factor/ vascular permeability factor produces nitric oxide-dependent hypotension. Evidence for a maintenance role in quiescent adult endothelium.

Arterioscler Thromb Vasc Biol 1997; 17: 2793–800.

Leung

D.W.

, Cachianes

, Kuang

W.J.

, Goeddel

D.V.

, Ferrara

Vascular endothelial growth factor is a secreted angiogenic mitogen.

Science 1989; 246: 1306–9.

Duman

, Gunal

A.I.

, Sen

, Asci

, Ozkahya

, Terzioglu

Does enalapril prevent peritoneal fibrosis induced by hypertonic (3.86%) peritoneal dialysis solution?

Perit Dial Int 2001; 21: 219–24.

Duman

, Wieczorowska-Tobis

, Styszynski

, Kwiatkowska

, Breborowicz

, Oreopoulos

D.G.

Intraperitoneal enalapril ameliorates morphologic changes induced by hypertonic peritoneal dialysis solutions in rat peritoneum.

Adv Perit Dial 2004; 20: 31–6.

Noh

, Ha

, Yu

M.R.

, Kim

Y.O.

, Kim

J.H.

, Lee

H.B.

Angiotensin II mediates high glucose-induced TGF-beta1 and fibronectin upregulation in HPMC through reactive oxygen species.

Perit Dial Int 2005; 25: 38–47.

Takahashi , Hata

, Mukai

, Sawasaki

Close similarity between cultured human omental mesothelial cells and endothelial cells in cytochemical markers and plasminogen activator production.

In Vitro Cell Dev Biol 1991; 27A: 542.

van Hinsbergh

V.W.

, Kooistra

, Scheffer

M.A.

, Hajo van Bockel

, van Muijen

G.N.

Characterization and fibrinolytic properties of human omental tissue mesothelial cells. Comparison with endothelial cells.

Blood 1990; 75: 1490–7.

10.

Fink

, Seeger

, Ermert

, Hanze

, Stahl

, Grimminger

Real-time quantitative RT-PCR after laser-assisted cell picking.

Nat Med 1998; 4: 1329–33.

11.

Heimburger

, Waniewski

, Werynski

, Park

M.S.

, Lindholm

Peritoneal transport in CAPD patients with permanent loss of ultrafiltration capacity.

Kidney Int 1990; 38: 495–506.

12.

Honda

, Nitta

, Horita

, Yumura

, Niehei

Morphological changes in the peritoneal vasculature of patients on CAPD with ultrafiltration failure.

Nephron 1996; 72: 171–6.

13.

Rubin

, Herrera

G.A.

, Collins

An autopsy study of the peritoneal cavity from patients on continuous ambulatory peritoneal dialysis.

Am J Kidney Dis 1991; 18: 97–102.

14.

Stompor

, Zdzienicka

, Mottyka

, Dembinska-Kiec

, Davies

S.J.

, Sulowicz

Selected growth factors in peritoneal dialysis: their relationship to markers of inflammation, dialysis adequacy, residual renal function, and peritoneal membrane transport.

Perit Dial Int 2002; 22: 670–6.

15.

Zweers

M.M.

, de Waart

D.R.

, Smit

, Struijk

D.G.

, Krediet

R.T.

Growth factors VEGF and TGF-beta1 in peritoneal dialysis.

J Lab Clin Med 1999; 134: 124–32.

16.

Combet

, Miyata

, Moulin

, Pouthier

, Goff in

, Devuyst

Vascular proliferation and enhanced expression of endothelial nitric oxide synthase in human peritoneum exposed to long-term peritoneal dialysis.

J Am Soc Nephrol 2000; 11: 717–28.

17.

de Vriese

A.S.

, Tilton

R.G.

, Elger

, Stephan

C.C.

, Kriz

, Lameire

N.H.

Antibodies against vascular endothelial growth factor improve early renal dysfunction in experimental diabetes.

J Am Soc Nephrol 2001; 12: 993–1000.

18.

Davies

S.J.

, Bryan

, Phillips

, Russell

G.I.

Longitudinal changes in peritoneal kinetics: the effects of peritoneal dialysis and peritonitis.

Nephrol Dial Transplant 1996; 11: 498–506.

19.

Ferrara

Molecular and biological properties of vascular endothelial growth factor.

J Mol Med 1999; 77: 527–43.

20.

Dvorak

H.F.

, Brown

L.F.

, Detmar

, Dvorak

A.M.

Vascular permeability factor/vascular endothelial growth factor, microvascular hyperpermeability, and angiogenesis.

Am J Pathol 1995; 146: 1029–39.

21.

Duman

, Sen

, Duman

, Oreopoulos

D.G.

Effect of valsartan versus lisinopril on peritoneal sclerosis in rats.

Int J Artif Organs 2005; 28: 156–63.

22.

Bulbuller

, Ilhan

Y.S.

, Kirkil

, Oreopoulos

D.G.

Can angiotensin converting enzyme inhibitors prevent postoperative adhesions?

J Surg Res 2005; 125: 94–7.

23.

Noh

, Kim

J.S.

, Han

K.H.

, Lee

G.T.

, Song

J.S.

, Chung

S.H.

Oxidative stress during peritoneal dialysis: implications in functional and structural changes in the membrane.

Kidney Int 2006; 69: 2022–8.

24.

Kyuden

, Ito

, Masaki

, Yorioka

, Kohno

TGF-beta1 induced by high glucose is controlled by angiotensin-converting enzyme inhibitor and angiotensin II receptor blocker on cultured human peritoneal mesothelial cells.

Perit Dial Int 2005; 25: 483–91.

25.

Moises

R.S.

, Carvalho

C.R.

, Shiota

, Saad

M.J.

Evidence for a direct effect of captopril on early steps of insulin action in BC3H-1 myocytes.

Metabolism 2003; 52: 273–8.

26.

Andersson

, Cederholm

, Johannson

A.S.

, Palmblad

Captopril-impaired production of tumor necrosis factor-alpha-induced interleukin-1beta in human monocytes is associated with altered intracellular distribution of nuclear factor-kappaB.

J Lab Clin Med 2002; 140: 103–9.

ACE Inhibitor and At1-Receptor Blocker Attenuate the Production of Vegf in Mesothelial Cells

Abstract

Objective

Methods

Results

Conclusion

Keywords

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References