prostaglandin-d2 and HTLV-I-Infections

prostaglandin-d2 has been researched along with HTLV-I-Infections* in 2 studies

Other Studies

2 other study(ies) available for prostaglandin-d2 and HTLV-I-Infections

Article	Year
Antiproliferative activity of cyclopentenone prostaglandins in early HTLV-1 infection is independent of IL-2 and is associated with HSP70 induction. Leukemia, 1994, Volume: 8, Issue:6 Cyclopentenone prostaglandins PGA1 and PGJ2 can inhibit the growth of HTLV-1 infected cord blood-derived human mononuclear cells (CBMC), both after acute infection and in chronically infected, immortalized cells. When CBMC were exposed to HTLV-1 infection by coculturing with lethally irradiated, virus-donor allogeneic MT-2 cells, they underwent a proliferative response, that peaked within the first week and then declined. PG treatment did not inhibit the initial proliferation (day 4) of cocultured CBMC, while multiple treatments with PGA1 and more efficiently with PGJ2, suppressed the late cell proliferation (from day 8 onward). The pharmacological effects of PGA1 and PGJ2 were reversible and therefore multiple treatments were required to maintain their antiproliferative activity. Increasing concentrations (20, 40, 80 IU/ml) of recombinant IL-2 did not affect the virus-associated proliferative response of CBMC, and exogenous IL-2 did not revert the antiproliferative effect of both PGs. Arrest of proliferation in cocultured CBMC occurred concomitantly with expression of high levels of HSP70 in the cells. In fact, though HSP70 expression was induced early (day 5) after exposure to HTLV-1, its expression was further increased after multiple PG treatments and high levels were found when the antiproliferative effect of PGs became manifest. Since HSP70 protein family is involved in the control of cell cycle as well as in antigen processing and presentation during the immune response against tumor cells and pathogens, the persistent expression of this protein in PG-treated cocultures suggested that, beside inhibiting the growth of virus-infected cells, HSP70 expression might play a role in modulating the immune function of CBMC. However, unlike in most virus infection models, in which cyclopentenone PGs exert clear antiviral effects by inhibiting the synthesis and maturation of virus proteins, no antiviral activity was found in this model of infection. This strongly suggests that the main effect of these PGs against HTLV-1 infected cells consists in inhibiting proliferation in vitro without affecting viral expression. Topics: Antiviral Agents; Blood Proteins; Cell Division; Cell Survival; Cells, Cultured; Down-Regulation; Heat-Shock Proteins; HTLV-I Infections; Human T-lymphotropic virus 1; Humans; Interleukin-2; Leukocytes, Mononuclear; Prostaglandin D2; Prostaglandins; Prostaglandins A; RNA; Time Factors	1994
Comparative anti-viral and anti-proliferative activity of PGA1 and PGJ2 against HTLV-I-infected MT-2 cells. International journal of cancer, 1992, May-28, Volume: 51, Issue:3 Prostaglandin (PG) A and J exert anti-viral and anti-proliferative effects in a number of experimental models. In particular, multiple treatments with PGAs prevent in vitro the clonal selection of HTLV-I-infected and potentially transformed cord-blood-derived mononuclear cells. Proliferation of HTLV-I-infected leukemic T cells is refractory in most cases to conventional anti-blastic therapy. We examined whether these cyclopentenone PGs might control cell proliferation and/or alter virus replication also in HTLV-I-transformed cells. We show that PGA1 and PGJ2 can exert powerful control of proliferation of the HTLV-I-immortalized, virus-producing MT-2 cell line, in a concentration-dependent fashion. Cells were preferentially arrested at the G1/S interface by treatment with PGA1 or PGJ2 without any detectable cellular toxicity. The anti-proliferative effect of PG treatment was independent of the growth phase of MT-2 cells, since both asynchronous and synchronous cells were sensitive to treatment. This effect was accompanied by an increase in the synthesis of a 70 kDa heat-shock protein (HSP70). However, synthesis of HSP70 was induced to a much greater extent by PGJ2 than by PGA1 at the same concentration. Neither PGA1 or PGJ2 inhibited the transcription of HTLV-I in MT-2 cells, but treatment with PGJ2, and not with PGA1, moderately inhibited the synthesis of viral proteins, i.e., p40 Tax and p19 core proteins. Moreover, infection of recipient K562 cells was significantly inhibited after pre-treatment of MT-2 cells with PGJ2 14 hr before or co-treatment at the onset of the co-culture with K562 cells. This effect was not obtained when MT-2 cells were repeatedly pre-treated with PGJ2 for 1 week before co-culturing. This suggests that reduced infection could be related to impairment of some step in virus-transmission phase. Topics: Cell Division; Cell Line; Heat-Shock Proteins; HTLV-I Infections; Human T-lymphotropic virus 1; Prostaglandin D2; Prostaglandins A; Viral Proteins; Virus Replication	1992

Article

Year

Antiproliferative activity of cyclopentenone prostaglandins in early HTLV-1 infection is independent of IL-2 and is associated with HSP70 induction.

Leukemia, 1994, Volume: 8, Issue:6

Cyclopentenone prostaglandins PGA1 and PGJ2 can inhibit the growth of HTLV-1 infected cord blood-derived human mononuclear cells (CBMC), both after acute infection and in chronically infected, immortalized cells. When CBMC were exposed to HTLV-1 infection by coculturing with lethally irradiated, virus-donor allogeneic MT-2 cells, they underwent a proliferative response, that peaked within the first week and then declined. PG treatment did not inhibit the initial proliferation (day 4) of cocultured CBMC, while multiple treatments with PGA1 and more efficiently with PGJ2, suppressed the late cell proliferation (from day 8 onward). The pharmacological effects of PGA1 and PGJ2 were reversible and therefore multiple treatments were required to maintain their antiproliferative activity. Increasing concentrations (20, 40, 80 IU/ml) of recombinant IL-2 did not affect the virus-associated proliferative response of CBMC, and exogenous IL-2 did not revert the antiproliferative effect of both PGs. Arrest of proliferation in cocultured CBMC occurred concomitantly with expression of high levels of HSP70 in the cells. In fact, though HSP70 expression was induced early (day 5) after exposure to HTLV-1, its expression was further increased after multiple PG treatments and high levels were found when the antiproliferative effect of PGs became manifest. Since HSP70 protein family is involved in the control of cell cycle as well as in antigen processing and presentation during the immune response against tumor cells and pathogens, the persistent expression of this protein in PG-treated cocultures suggested that, beside inhibiting the growth of virus-infected cells, HSP70 expression might play a role in modulating the immune function of CBMC. However, unlike in most virus infection models, in which cyclopentenone PGs exert clear antiviral effects by inhibiting the synthesis and maturation of virus proteins, no antiviral activity was found in this model of infection. This strongly suggests that the main effect of these PGs against HTLV-1 infected cells consists in inhibiting proliferation in vitro without affecting viral expression.

Topics: Antiviral Agents; Blood Proteins; Cell Division; Cell Survival; Cells, Cultured; Down-Regulation; Heat-Shock Proteins; HTLV-I Infections; Human T-lymphotropic virus 1; Humans; Interleukin-2; Leukocytes, Mononuclear; Prostaglandin D2; Prostaglandins; Prostaglandins A; RNA; Time Factors

1994

Comparative anti-viral and anti-proliferative activity of PGA1 and PGJ2 against HTLV-I-infected MT-2 cells.

International journal of cancer, 1992, May-28, Volume: 51, Issue:3

Prostaglandin (PG) A and J exert anti-viral and anti-proliferative effects in a number of experimental models. In particular, multiple treatments with PGAs prevent in vitro the clonal selection of HTLV-I-infected and potentially transformed cord-blood-derived mononuclear cells. Proliferation of HTLV-I-infected leukemic T cells is refractory in most cases to conventional anti-blastic therapy. We examined whether these cyclopentenone PGs might control cell proliferation and/or alter virus replication also in HTLV-I-transformed cells. We show that PGA1 and PGJ2 can exert powerful control of proliferation of the HTLV-I-immortalized, virus-producing MT-2 cell line, in a concentration-dependent fashion. Cells were preferentially arrested at the G1/S interface by treatment with PGA1 or PGJ2 without any detectable cellular toxicity. The anti-proliferative effect of PG treatment was independent of the growth phase of MT-2 cells, since both asynchronous and synchronous cells were sensitive to treatment. This effect was accompanied by an increase in the synthesis of a 70 kDa heat-shock protein (HSP70). However, synthesis of HSP70 was induced to a much greater extent by PGJ2 than by PGA1 at the same concentration. Neither PGA1 or PGJ2 inhibited the transcription of HTLV-I in MT-2 cells, but treatment with PGJ2, and not with PGA1, moderately inhibited the synthesis of viral proteins, i.e., p40 Tax and p19 core proteins. Moreover, infection of recipient K562 cells was significantly inhibited after pre-treatment of MT-2 cells with PGJ2 14 hr before or co-treatment at the onset of the co-culture with K562 cells. This effect was not obtained when MT-2 cells were repeatedly pre-treated with PGJ2 for 1 week before co-culturing. This suggests that reduced infection could be related to impairment of some step in virus-transmission phase.

Topics: Cell Division; Cell Line; Heat-Shock Proteins; HTLV-I Infections; Human T-lymphotropic virus 1; Prostaglandin D2; Prostaglandins A; Viral Proteins; Virus Replication

1992