Marie-Françoise Dubois

The Transcriptional Inhibitors, Actinomycin D and α-Amanitin, Activate the HIV-1 Promoter and Favor Phosphorylation of the RNA Polymerase II C-terminal Domain

Actinomycin D and α-amanitin are commonly used to inhibit transcription. Unexpectedly, however, the transcription of the human immunodeficiency virus (HIV-1) long terminal repeats (LTR) is shown to be activated at the level of elongation, in human and murine cells exposed to these drugs, whereas the Rous sarcoma virus LTR, the human cytomegalovirus immediate early gene (CMV), and the HSP70 promoters are repressed. Activation of the HIV LTR is independent of the NFκB and TAR sequences and coincides with an enhanced average phosphorylation of the C-terminal domain (CTD) from the largest subunit of RNA polymerase II. Both the HIV-1 LTR activation and the bulk CTD phosphorylation enhancement are prevented by several CTD kinase inhibitors, including 5,6-dichloro-1-β-d-ribofuranosylbenzimidazole. The efficacies of the various compounds to block CTD phosphorylation and transcription in vivo correlate with their capacities to inhibit the CDK9/PITALRE kinase in vitro. Hence, the positive transcription elongation factor, P-TEFb, is likely to contribute to the average CTD phosphorylation in vivo and to the activation of the HIV-1 LTR induced by actinomycin D.

Heat-induced Relocalization of Protein Kinase CK2 IMPLICATION OF CK2 IN THE CONTEXT OF CELLULAR STRESS

Among various other roles described so far, protein kinase CK2 has been involved in cell cycle, proliferation, and development. Here, we show that in response to specific stresses (heat shock or UV irradiation), a pool of the cellular CK2 content relocalizes in a particular nuclear fraction, increasing the activity of the kinase there. Electron microscopic analysis shows that upon heat shock, CK2α and CK2β subunits are both detected in similar speckle structures occurring in the interchromatin space but are differentially targeted inside the nucleolus. This CK2 relocalization process takes place in a time- and dose-dependent manner and is reversible upon recovery at 37 °C. Altogether, this work suggests CK2 be involved in the response to physiological stress in higher eukaryotic cells.

Enhanced phosphorylation of the C-terminal domain of RNA polymerase II upon serum stimulation of quiescent cells: possible involvement of MAP kinases.

The largest subunit of RNA polymerase (RNAP) II contains at it C‐terminus an unusual domain comprising tandem repeats of the consensus sequence Tyr‐Ser‐Pro‐Thr‐Ser‐Pro‐Ser. This C‐terminal domain (CTD) can undergo phosphorylation at multiple sites giving rise to a form of the enzyme designated RNAP IIO. The unphosphorylated form is designated RNAP IIA. The largest subunits of RNAPs IIO and IIA are designated IIo and IIa, respectively. In quiescent NIH 3T3 fibroblasts, subunits IIo and IIa are present in comparable amounts. Upon serum stimulation, the amount of subunit IIo increases markedly and remains elevated for several hours. The increase of subunit IIo also occurs in transcription‐inhibited cells and, therefore, is not a consequence of serum‐activated transcription. This observation suggests that serum stimulation activates a CTD kinase and/or inhibits a CTD phosphatase. This hypothesis is supported by the finding that serum stimulates phosphorylation of a beta‐galactosidase‐CTD fusion protein expressed in these cells. Furthermore, an enhanced CTD kinase activity was discovered in lysates from serum‐stimulated fibroblasts and was found to copurify with MAP kinases on a Mono Q column and to bind to anti‐MAP kinase antibodies. The idea that MAP kinases phosphorylate the CTD in vivo is supported by the observation that subunit IIa, but not subunit IIb which lacks the CTD, is phosphorylated at multiple sites by purified MAP kinase. Consequently, the MAP kinases are a new class of CTD kinases which appear to be involved in the phosphorylation of RNAP II following serum stimulation. This phosphorylation may contribute to the transcriptional activation of serum‐stimulated genes.

MAP kinase activation during heat shock in quiescent and exponentially growing mammalian cells

In numerous cases of signal transduction, the mitogen‐activated protein kinases (MAP kinases) or extracellular regulated kinases (ERKs) are found to be activated by phosphorylations which result in electrophoretic mobility changes. Activities of MAP kinases in cytosolic extracts can also be monitored by the capacity of such extracts to phosphorylate myelin basic protein. These two assays were used to demonstrate that MAP kinases were rapidly activated during heat shock of both quiescent and exponentially growing mammalian (hamster, rat, mouse and human) cells. Thus, the MAP kinase cascade is likely to also ensure heat‐shock signal transduction and contribute to the regulation of the complex array of metabolic changes designated as the heat‐shock response.

Phosphorylation of the RNA polymerase II largest subunit during Xenopus laevis oocyte maturation.

Xenopus laevis oogenesis is characterized by an active transcription which ceases abruptly upon maturation. To survey changes in the characteristics of the transcriptional machinery which might contribute to this transcriptional arrest, the phosphorylation status of the RNA polymerase II largest subunit (RPB1 subunit) was analyzed during oocyte maturation. We found that the RPB1 subunit accumulates in large quantities from previtellogenic early diplotene oocytes up to fully grown oocytes. The C-terminal domain (CTD) of the RPB1 subunit was essentially hypophosphorylated in growing oocytes from Dumont stage IV to stage VI. Upon maturation, the proportion of hyperphosphorylated RPB1 subunits increased dramatically and abruptly. The hyperphosphorylated RPB1 subunits were dephosphorylated within 1 h after fertilization or heat shock of the matured oocytes. Extracts from metaphase II-arrested oocytes showed a much stronger CTD kinase activity than extracts from prophase stage VI oocytes. Most of this kinase activity was attributed to the activated Xp42 mitogen-activated protein (MAP) kinase, a MAP kinase of the ERK type. Making use of artificial maturation of the stage VI oocyte through microinjection of a recombinant stable cyclin B1, we observed a parallel activation of Xp42 MAP kinase and phosphorylation of RPB1. Both events required protein synthesis, which demonstrated that activation of p34(cdc2)off kinase was insufficient to phosphorylate RPB1 ex vivo and was consistent with a contribution of the Xp42 MAP kinase to RPB1 subunit phosphorylation. These results further support the possibility that the largest RNA polymerase II subunit is a substrate of the ERK-type MAP kinases during oocyte maturation, as previously proposed during stress or growth factor stimulation of mammalian cells.

Heat-shock induced protein modifications and modulation of enzyme activities

Upon heat stress, the cell physiology is profoundly altered. The extent of the alterations depends on the severity of the stress and may lead to cell death. The heat shock response is an array of metabolic changes characterized by the impairment of major cellular functions and by an adaptative reprogramming of the cell metabolism. The enhanced synthesis of the HSPs is a spectacular manifestation of this reprogramming. Numerous post translational modifications of proteins occur in response to heat stress and can be related to altered cellular functions. Some proteins are heat-denatured and temporarily inactivated. Heat-denaturation is reversible, chaperones may contribute to the repair. The extent of heat-denaturation depends on the cell metabolism: (a) it is attenuated in thermotolerant cells or in cells overexpressing the appropriate chaperones (b) it is enhanced in energy-deprived cells. Covalent modifications may also rapidly alter protein function. Changes in protein glycosylation, methylation, acetylation, farnesylation, ubiquitination have been found to occur during stress. But protein phosphorylation is the most studied modification. Several protein kinase cascades are activated, among which the various mitogen activated protein kinase (MAP kinase) cascades which are also triggered by a wide range of stimuli. As a possible consequence, stress modifies the phosphorylation status and the activity of components from the transcriptional and translational apparatuses. The same kinases also target key enzymes of the cellular metabolism. Protein denaturation results in constitutive hsp titration, this titration is a signal to trigger the heat-shock gene transcription and to activate some of the protein kinase cascades.