Differential inhibition by alpha- and beta-tocopherol of human erythroleukemia cell adhesion: role of integrins.

The effect of alpha- and beta-tocopherol on human erythroleukemia cell (HEL) adhesion induced by phorbol 12-myristate 13-acetate (PMA) has been studied. Adhesion induced by PMA stimulation was prevented by 44.5% by physiological concentrations of alpha-tocopherol. Under the same experimental conditions, beta-tocopherol, an analogue of alpha-tocopherol, produced 11% inhibition of adhesion. Cell response gradually increased from 0 to 24 h of alpha-tocopherol treatment. Only a slight time dependency of beta-tocopherol inhibition was observed. Another human erythroleukemia cell line (K562) and the human monocyte tumor cell line U937 showed 5.0 and 11.2% inhibition, respectively. Similar to alpha-tocopherol, the protein kinase C inhibitor, Calphostin C, and the MAPK inhibitor, PD98059, prevented PMA-induced cell adhesion. An inhibition of ERK-1 phosphorylation was observed for alpha-tocopherol only in HEL, implying that MAP kinase pathway is involved in this cell line. Fluorescence-activated cell sorting (FACS), by using various integrin-specific monoclonal antibodies, has shown that alpha (1-6), beta1, and alphav integrins are less expressed at the cell surface after alpha-tocopherol treatment. Beta-tocopherol treatment was less effective.

Nonantioxidant functions of alpha-tocopherol in smooth muscle cells.

Most tocopherols and tocotrienols, with the exception of alpha-tocopherol, are not retained by humans. This suggests that alpha-tocopherol is recognized uniquely; therefore, it may exert an exclusive function. alpha-Tocopherol possesses distinct properties that are independent of its prooxidant, antioxidant or radical-scavenging ability. alpha-Tocopherol specifically inhibits protein kinase C, the growth of certain cells and the transcription of the CD36 and collagenase genes. Activation events have also been seen on the protein phosphatase 2A (PP(2)A) and on the expression of other genes (alpha-tropomyosin and connective tissue growth factor). Neither ss-tocopherol nor probucol possessed the same specialty functions as alpha-tocopherol. Recently, we isolated a new ubiquitous cytosolic alpha-tocopherol binding protein (TAP). Its motifs suggest that it is a member of the hydrophobic ligand-binding protein family (CRAL-TRIO). TAP may also be involved in the regulation of cellular alpha-tocopherol concentration and alpha-tocopherol-mediated signaling.

Specific cellular responses to alpha-tocopherol.

In the last 10 years precise cellular functions of alpha-tocopherol, some of which are independent of its antioxidant/radical-scavenging ability, have been revealed. Absorption of alpha-tocopherol from the gut is a selective process. Other tocopherols are not absorbed or are absorbed to a lesser extent. At the post-translational level, alpha-tocopherol inhibits protein kinase C and 5-lipoxygenase and activates protein phosphatase 2A and diacylglycerol kinase. Some genes [platelet glycoprotein IV/thrombospondin receptor/class B scavenger receptor (CD36), alpha-tocopherol transfer protein (alpha-TTP), alpha-tropomyosin, connective tissue growth factor and collagenase] are affected by alpha-tocopherol at the transcriptional level. alpha-Tocopherol also inhibits cell proliferation, platelet aggregation, monocyte adhesion and the oxygen burst in neutrophils. Other antioxidants, such as beta-tocopherol and probucol, do not mimic these effects, suggesting a nonantioxidant, alpha-tocopherol-specific molecular mechanism.

The down-regulation of FcgammaRII and FcgammaRIIIB by N-formyl-methionyl-leucyl-phenylalanine (FMLP) depends on secretory events in human neutrophils.

We have previously demonstrated that N-formyl-methionyl-leucyl-phenylalanine (FMLP) induces down-regulation of FcgammaRs on human neutrophils (PMN) modifying different FcgammaR-dependent functions. The aim of this work was to assess the cellular mechanisms by which FMLP exerts this effect on FcgammaRs. The role of the microfilament and cytoskeletal apparatus in this process was evaluated using cytochalasin B (CB), an inhibitor of microfilament functions. The expression of FcgammaRIIIB and FcgammaRII after CB + FMLP treatment was drastically diminished when compared to FMLP-treated cells. Neutrophil degranulation induced by FMLP affect only 22% of the cells in response to FMLP. However, the FcgammaRs of the whole PMN population were reduced, suggesting that secretory products could be responsible for the down-regulation induced by FMLP or FMLP + CB. In fact, supernatants from FMLP-treated PMN also induced FcyRs down-regulation on naive neutrophils. Moreover, supernatants from FMLP + CB-treated PMNs exerted a higher effect. Data obtained from permeabilized PMN show that after FMLP treatment there is an intracellular depletion of both FcgammaRIIIB and FcgammaRII. In addition, the FcgammaR down-regulation is abrogated by phenyl methyl sulfonyl fluoride (PMSF) but not by other protease inhibitors such as pepstatin, thiorphan, phosphoramidon and leupeptin, suggesting a role for serine protease(s) in this process.

Modulation of alpha-tropomyosin expression by alpha-tocopherol in rat vascular smooth muscle cells.

The effect of alpha-tocopherol (vitamin E) on gene expression in rat vascular smooth muscle cells was studied by the differential display technique. One gene out of about 1000 genes analyzed, identified as alpha-tropomyosin, showed an increased transcription level caused by alpha-tocopherol treatment. Northern and Western blot analysis revealed a time-dependent transient up-regulation of the amount of mRNA (peak between 2 and 3 h) and protein (peak at 5 h) in alpha-tocopherol-treated cells. No effect was observed in cells treated with beta-tocopherol.

[Human polymorphonuclear neutrophils (PMN) induce lipopolysaccharide (LPS) liberation from gram-negative bacteria]. / Neutrófilos humanos (PMN) inducen la liberación de lipopolisacáridos (LPS) de bacterias Gram negativas.

Bacterial lipopolysacharride (LPS) is the major membrane component of Gram negative bacteria. It is a potent pleiotropic stimulus for the immune system frequently associated with septic syndrome or septic shock. The detoxification of LPS in Gram negative sepsis is one of the important problems to resolve in clinical treatments. In this study we compare the capacity of polymorphonuclear neutrophils (PMN) in LPS detoxification in two different situations: a) when LPS is offered to PMN as an isolated molecule; b) when the LPS offered is part of the whole Gram negative bacteria (E. coli 0111:B4). Our results show that PMN are able to inhibit the capacity of LPS to produce TNF-alpha. However, when whole bacteria, instead of LPS, are incubated with PMN, an enhancement in the production of tumor necrosis factor alpha (TNF-alpha) is observed. The bacterial overburden of PMN is not the reason for the spread of LPS after PMN incubation. Our conclusion is that PMN have a dual capacity to deal with LPS, either inactivating or releasing it depending on how it is offered.

Hydroxyl radical scavengers inhibit TNF-alpha production in mononuclear cells but not in polymorphonuclear leukocytes.

The hydroxyl radical (HO*) scavengers dimethylthiourea (DMTU), tetramethylthiourea (TMTU), dimethylsulfoxide (DMSO) and deferoxamine (DFX), the latter being an iron chelator which prevents HO* formation by blocking the Fenton reaction, were found to inhibit TNF-alpha production in LPS-stimulated human PBMC but not in PMN. Furthermore, this effect was not LPS-specific, as TNF-alpha production was reduced by HO* radical scavengers to a similar extent upon stimulation of PBMC with immune complexes (IC), concanavalin A (Con A) and phorbol myristate acetate (PMA). Other scavengers such as glutathione (GSH), N-acetylcysteine (NAC), ascorbic acid (ASC) and mannitol (MAN) do not have effect on the production of TNF-alpha either in PBMC or PMN. These results provide evidence that the participation of ROI in the regulation of TNF-alpha production differ in different cell types. Particularly, the data presented in this work indicate that HO* radicals have a central role in the production of this inflammatory cytokine by human PBMC.