THE KINETICS OF HIV-1 LONG TERMINAL REPEAT TRANSCRIPTIONAL ACTIVATIONRESEMBLE THOSE OF HSP70 PROMOTER IN HEAT-SHOCK TREATED HELA-CELLS (VOL 351, PG 191, 1994)
C. Kretzremy et Ap. Arrigo, THE KINETICS OF HIV-1 LONG TERMINAL REPEAT TRANSCRIPTIONAL ACTIVATIONRESEMBLE THOSE OF HSP70 PROMOTER IN HEAT-SHOCK TREATED HELA-CELLS (VOL 351, PG 191, 1994), FEBS letters, 353(3), 1994, pp. 338-338
The long terminal repeat (LTR) of human immunodeficiency virus type 1
(HIV-1) is activated under different conditions including heat shock.
By using transient transfection assays, we have compared the thermal a
ctivation of HIV-1 LTR to that of the promoter of the gene encoding th
e human stress protein hsp70 which is under the control of the heat sh
ock transcription factor HSF. In these assays, the chloramphenicol ace
tyl transferase (Cat) gene was used as a reporter gene. Several parame
ters of the heat stress were analyzed such as the temperature, the dur
ation of heat stress and that of the recovery period. Under every cond
ition tested, we have found that the kinetics of activation of both pr
omoters were very similar. In addition, both showed a similar inhibiti
on by actinomycin D. These results were compared to those obtained wit
h a DNA construct containing the early promoter of SV-40 virus coupled
to the Cat gene. In this case, no heat-mediated accumulation of CAT p
rotein was observed, indicating that the transcriptional activation of
HIV-1 LTR by heat shock is specific. HIV-1 LTR contains two NF-kappa
B binding elements, involved in the activation of this promoter during
oxidative stress, which are sequence related to the heat shock elemen
t HSE. However, under all the heat shock conditions tested, we have be
en unable to detect the binding of any protein to kappa B elements, su
ggesting that this site is not directly involved in the thermal activa
tion of HIV-1 LTR. These results indicate that the thermal transcripti
onal activation of HIV-1 LTR and hsp70 promoters occurs through differ
ent mechanisms that are triggered by similar heat shock conditions.