Ultrastructure and molecular histology of rabbit hind-limb collateral artery growth (arteriogenesis).

Previous studies in the canine heart had shown that the growth of collateral arteries occurs via proliferative enlargement of pre-existing arteriolar connections (arteriogenesis). In the present study, we investigated the ultrastructure and molecular histology of growing and remodeling collateral arteries that develop after femoral artery occlusion in rabbits as a function of time from 2 h to 240 days after occlusion. Pre-existent arteriolar collaterals had a diameter of about 50 microm. They consisted of one to two layers of smooth muscle cells (SMCs) and were morphologically indistinguishable from normal arterioles. The stages of arteriogenesis consisted of arteriolar thinning, followed by transformation of SMCs from the contractile- into the proliferative- and synthetic phenotype. Endothelial cells (ECs) and SMCs proliferated, and SMCs migrated and formed a neo-intima. Intercellular adhesion molecule (ICAM-1) and vascular cell adhesion molecule (VCAM-1) showed early upregulation in ECs, which was accompanied by accumulation of blood-derived macrophages. Mitosis of ECs and SMCs started about 24 h after occlusion, whereas adhesion molecule expression and monocyte adhesion occurred as early as 12 h after occlusion, suggesting a role of monocytes in vascular cell proliferation. Treatment of rabbits with the pro-inflammatory cytokine MCP-1 increased monocyte adhesion and accelerated vascular remodeling. In vitro shear-stress experiments in cultured ECs revealed an increased phosphorylation of the focal contacts after 30 min and induction of ICAM-1 and VCAM-1 expression between 2 h and 6 h after shear onset, suggesting that shear stress may be the initiating event. We conclude that the process of arteriogenesis, which leads to the positive remodeling of an arteriole into an artery up to 12 times its original size, can be modified by modulators of inflammation.

Hypoxia induces permeability in brain microvessel endothelial cells via VEGF and NO.

In this study, an in vitro model of the blood-brain barrier, consisting of porcine brain-derived microvascular endothelial cells (BMEC), was used to evaluate the mechanism of hypoxia-induced hyperpermeability. We show that hypoxia-induced permeability in BMEC was completely abolished by a neutralizing antibody to vascular endothelial growth factor (VEGF). In contrast, under normoxic conditions, addition of VEGF up to 100 ng/ml did not alter monolayer barrier function. Treatment with either hypoxia or VEGF under normoxic conditions induced a twofold increase in VEGF binding sites and VEGF receptor 1 (Flt-1) mRNA expression in BMEC. Hypoxia-induced permeability also was prevented by the nitric oxide (NO) synthase inhibitor NG-monomethyl-L-arginine, suggesting that NO is involved in hypoxia-induced permeability changes, which was confirmed by measurements of the cGMP level. During normoxia, treatment with VEGF (5 ng/ml) increased permeability as well as cGMP content in the presence of several antioxidants. These results suggest that hypoxia-induced permeability in vitro is mediated by the VEGF/VEGF receptor system in an autocrine manner and is essentially dependent on reducing conditions stabilizing the second messenger NO as the mediator of changes in barrier function of BMEC.

Hypothermia abolishes hypoxia-induced hyperpermeability in brain microvessel endothelial cells.

The effect of mild (32 degrees C) and deep (22 degrees C) hypothermia on hypoxia-induced hyperpermeability was examined using an in vitro model of brain derived microvascular endothelial cells (BMEC). It was shown that hypoxia-induced hyperpermeability to inulin across the BMEC monolayer was completely abolished at 32 degrees C and 22 degrees C for up to 24 h of hypoxia. During normoxia, no influence of hypothermia on BMEC monolayer permeability was observed. The hypoxia-induced decrease of the cyclic AMP level after 6 h was abolished at 32 degrees C as well as at 22 degrees C of hypoxia. But after 24 h of hypoxia, hypothermia did no longer prevent the hypoxia-induced decrease of the cAMP level, which suggests that the effect of hypothermia on hypoxia-induced hyperpermeability is not caused by maintenance of the cAMP level. Because vascular endothelial growth factor (VEGF) has been shown to be the mediator of hypoxia-induced permeability changes of BMEC via the release of nitric oxide (NO), the effect of hypothermia on the VEGF expression was evaluated. During normoxia, hypothermia did not change the VEGF expression significantly but the hypoxia-induced increase in VEGF mRNA and protein expression was completely abolished at 32 degrees C and 22 degrees C respectively. Accordingly, the hypoxia-induced increase of the cGMP level was depressed by hypothermia, which demonstrates that also the amount of NO released during hypoxia is decreased at lower temperatures. Results suggest that deep as well as mild hypothermia decreased hypoxia-induced hyperpermeability by lowering the expression of the permeability-increasing protein VEGF and with it the release of NO.

CD3- large granular lymphocytes recognize a heat-inducible immunogenic determinant associated with the 72-kD heat shock protein on human sarcoma cells.

Traditionally, heat shock proteins (HSPs) are believed to be located intracellularly, where they perform a variety of chaperoning functions. Recently, evidence has accumulated that some tumor cells express HSPs on the cell surface. The present study confirms this finding and correlates HSP72 cell surface expression, induced by nonlethal heat shock, with an increased sensitivity to interleukin-2-stimulated CD3-natural killer (NK) cells. After nonlethal heat shock, a monoclonal antibody directed against the major heat-inducible 72-kD HSP (HSP72) stains the cell surface of sarcoma cells (ie, Ewing's sarcoma cells or osteosarcoma cells) but not that of normal cells (ie, peripheral blood lymphocytes, fibroblasts, phytohemagglutin-stimulated blasts, B-lymphoblastoid cell lines) or of mammary carcinoma cell line MX-1 carcinoma cells. In this study, we show for the first time a correlation of HSP72 cell surface expression with an increased susceptibility to lysis by NK effector cells. This finding is supported by the following points: (1) HLA-disparate effector cells show similar, elevated lysis of HSP72+ heat-treated sarcoma cells; (2) CD(3-) NK cells, but not CD3+ cytotoxic T lymphocytes, are responsible for the recognition of heat-shocked sarcoma cells; (3) by antibody-blocking studies, an immunogenic HSP72 determinant, which is expressed selectively on the cell surface of heat-treated sarcoma cells could be correlated with NK recognition; (4) the reported phenomenon is independent of a heat-induced, transient downregulation of major histocompatibility complex (MHC) class-I expression; and (5) blocking of MHC class-I-restricted recognition, using either MHC class-I-specific monoclonal antibody W6/32 on the target cells or alpha/beta T-cell receptor monoclonal antibody WT31 on effector cells, also has no inhibitory effect on the lysis of HSP72+ tumor cells. Finally, our in vitro data might have further clinical implications with respect to HSP72 as a stress-inducible, sarcoma-specific NK recognition structure.

Differential effects of ifosfamide on the capacity of cytotoxic T lymphocytes and natural killer cells to lyse their target cells correlate with intracellular glutathione levels.

We established an in vitro model to study the influence of ifosfamide treatment on intracellular glutathione (GSH) levels in activated human effector cells with specific phenotypes and immunologic functions. Besides its role as the major intracellular reductant, GSH has been shown to affect the initiation and progression of lymphocyte activation after stimulation with lectins. An incubation of activated human peripheral blood lymphocytes (PBL) with 4-hydroxyifosfamide, the activated form of ifosfamide (4-OH-IF), resulted in a depletion of the intracellular GSH levels and a significant inhibition of the proliferative capacity in a dose-dependent manner. The cytotoxic activity of separated CD3- natural killer (NK) cells and CD3+ allospecific, cytotoxic T lymphocytes (CTL), either untreated or treated with 4-OH-IF at different concentrations, was compared in a standard 51chromium release assay (CML). There were three major findings. (1) The capacity of CD3+ major histocompatibility complex (MHC)-restricted CTL to lyse their specific allogeneic target cells was substantially reduced by preincubation of the effector cells with 4-OH-IF. This inhibition of the lytic activity in CD3+ CTL correlated with a substantial depletion of the intracellular GSH levels in this population. Rapid reconstitution of depleted GSH levels and restoration of cytotoxic activity of CTL was achieved by incubation of the effector cells with thiols, eg, glutathione ester (GSH-ester) or 2-mercaptoethanesulfonate (mesna). (2) In contrast, the lytic activity in CD3- NK cells was not substantially affected (up to 100 mumol/L 4-OH-IF). This result correlates with the capacity of NK cells to maintain their intracellular GSH levels after an ifosfamide treatment. (3) In comparison with CD3+ CTL, CD3- NK cells are more resistant to an ifosfamide treatment because they have higher initial GSH levels and a more than fourfold higher relative rate of GSH synthesis.

A stress-inducible 72-kDa heat-shock protein (HSP72) is expressed on the surface of human tumor cells, but not on normal cells.

It is suggested that members of the heat-shock protein (HSP) 70 and 90 families are involved in intracellular antigen processing and the presentation of cell-membrane-anchored antigens. We show that non-lethal heat shock (41.8 degrees C) causes comparable rates of HSP72 (about 20x) and HSP73 (about 3x) synthesis in both tumor (including human Ewing's sarcoma, ES and osteosarcoma cells, HOS58) and normal cells (including EBV-transformed B-LCL, PBL and fibroblasts derived from healthy human volunteers). However, following non-lethal heat stress and a recovery period at 37 degrees C, flow cytometric analysis with a specific MAb showed HSP72 to be expressed only on the cell surface of tumor cells. The cell-surface localization of HSP72 was confirmed by Western-blot analysis of separated membranes and by immunoprecipitation with the HSP72-specific MAb. In addition, co-incubation of untreated tumor cells with supernatants from lethally heat-shocked cells, which contain HSP72, did not lead to HSP72 cell-surface expression. Thus, non-specific association of HSP72 molecules with the outer plasma membrane is unlikely. In conclusion, despite comparable cytoplasmic HSP72 induction, human tumor cells differ from normal cells in their capacity to express HSP72 on their surface. This might imply clinical application as a means to target a stress-inducible, tumor-specific immune response.

Ifosfamide induced depletion of glutathione in human peripheral blood lymphocytes and protection by mesna.

We studied the effects of ifosfamide and major metabolites on intracellular glutathione (GSH) levels in human peripheral blood lymphocytes (PBL). In vitro exposure of PBL to 4-hydroperoxyifosfamide (4-OOH-IF), acrolein or chloroacetaldehyde at 37 degrees C for 60 min led to a concentration dependent depletion of intracellular GSH. The concentration of the three metabolites to cause a 50% depletion of GSH in PBL was in the micromolar range (acrolein: 16 +/- 4 microM; 4-OOH-IF: 22 +/- 9 microM; chloroacetaldehyde: 30 +/- 7 microM). Exposure to ifosfamide, the non-activated drug, had no effects on the intracellular GSH levels. Pretreatment with 4-OOH-IF suppressed dose-dependently the interleukin-2-induced proliferation of PBL. Incubation of PBL together with 2-mercaptoethanesulfonate (mesna) and 4-OOH-IF, acrolein or chloroacetaldehyde prevented the GSH depletion. The protecting effect of mesna in combination with 4-OOH-IF was independent of GSH biosynthesis, because addition of buthionine sulfoximine had no significant influence on this effect. These findings indicate a novel protective mechanism of mesna against intracellular GSH depletion of PBL during exposure to metabolites of ifosfamide.