Nucleotide excision repair is a potential therapeutic target in multiple myeloma.

Despite the development of novel drugs, alkylating agents remain an important component of therapy in multiple myeloma (MM). DNA repair processes contribute towards sensitivity to alkylating agents and therefore we here evaluate the role of nucleotide excision repair (NER), which is involved in the removal of bulky adducts and DNA crosslinks in MM. We first evaluated NER activity using a novel functional assay and observed a heterogeneous NER efficiency in MM cell lines and patient samples. Using next-generation sequencing data, we identified that expression of the canonical NER gene, excision repair cross-complementation group 3 (ERCC3), significantly impacted the outcome in newly diagnosed MM patients treated with alkylating agents. Next, using small RNA interference, stable knockdown and overexpression, and small-molecule inhibitors targeting xeroderma pigmentosum complementation group B (XPB), the DNA helicase encoded by ERCC3, we demonstrate that NER inhibition significantly increases sensitivity and overcomes resistance to alkylating agents in MM. Moreover, inhibiting XPB leads to the dual inhibition of NER and transcription and is particularly efficient in myeloma cells. Altogether, we show that NER impacts alkylating agents sensitivity in myeloma cells and identify ERCC3 as a potential therapeutic target in MM.

Human monocytes possess a serine protease activity capable of degrading HIV-1 reverse transcriptase in vitro.

Human immunodeficiency virus type-1 (HIV-1) reverse transcriptase (RT) plays a central role in the virus replication cycle. We found that HIV-1 RT was rapidly degraded when incubated with cell extracts obtained from human peripheral blood cells. The proteolytic activity responsible for the in vitro degradation of RT was present in monocytes and their precursors. Interestingly, this activity was downregulated upon cell activation or differentiation along the macrophage pathway. The proteolytic process appears specific for HIV-1 RT since other HIV-1 proteins were not degraded upon incubation in the same extracts. Although the degradation of RT was unaffected by specific proteasome inhibitors, it could be inhibited by PMSF and aprotinin, suggesting the involvement of a serine protease. Upon cell fractionation, this serine protease was found to be associated with the microsomal fraction and displayed an apparent molecular weight of approximately 2000 kDa, as determined by gel filtration. Our results suggest that a giant serine protease, different from tripeptidyl peptidase II, is involved in the in vitro degradation of HIV-1 RT. The possibility of an in vivo interaction between HIV-1 RT and a cell-type-specific serine protease is discussed.

Phosphorylation of AZT-resistant human immunodeficiency virus type 1 reverse transcriptase by casein kinase II in vitro: effects on inhibitor sensitivity.

Casein kinase II (CKII) phosphorylates wild-type (WT) recombinant reverse transcriptase (RT) mainly in the p66 subunit in vitro. Phosphorylation of T215F RT and D67N/K70R/T215F/K219Q RT (AZT-resistant RT) in vitro increases discrimination against AZTTP 2. 5- and 3.6-fold, respectively. This in vitro resistance can be reversed by treatment of phosphorylated AZT-resistant RT with phosphatase. Phosphorylation has no effect on WT RT. Terminal transferase activity of RT is selectively suppressed on phosphorylated AZT-resistant RT. Resistance to phosphonoformic acid (PFA, foscarnet) increases 3-fold upon phosphorylation of AZT-resistant RT. Although T215, the most important residue for AZT-resistance, is part of a CKII consensus target site, serines are primarily phosphorylated relative to threonines. Mutational analysis shows that phosphorylation can be reduced to 10% that of WT when amino-acid changes are introduced both in the "fingers" subdomain and motif D. These results suggest that phosphorylation of RT might be one factor involved in drug resistance in vivo.

[Role of the multifunctional Trio protein in the control of the Rac1 and RhoA gtpase signaling pathways]. / Rôle de la protéine multifonctionnelle Trio dans le contrôle des voies de signalisation des GTPases Rac1 et RhoA.

The small GTPases Cdc42, Rac and RhoA have important regulatory roles in mediating cytoskeletal rearrangements, MAP kinase cascades and induction of G1 cell cycle progression. The activity of the GTPases is regulated by guanine nucleotide exchange factors (GEFs) which accelerate their GDP/GTP exchange rate, and thereby activate them. All the GEFs for the Rho-GTPases family share two conserved domains: the DH domain (for Dbl-homology domain) responsible for the enzymatic activity, and the PH domain, probably responsible for the proper localization of the molecule. Trio is a multifunctional protein that is comprised of two functional Rho-GEFs domains and a serine/threonine kinase domain. We have shown in vitro and in vivo that the first GEF domain (GEFD1) activates Rac1, while the second GEF domain (GEFD2) acts on RhoA. Moreover, the co-expression of both domains induces simultaneously the activation of both GTPases. To our knowledge, this is the first example of a member of the Rho-GEF family, that contains two functional exchange factor domains, with restricted and different specificity. We are currently investigating how these GEF domains are activated, by addressing the role of the PH domains in GTPases activation by Trio. We have shown that: 1) the PH1 of Trio is necessary for Rac activation by the GEFD1; 2) the PH1 of Trio targets the molecule to the cytoskeleton; 3) the GEFD1 domain of Trio binds, in a two-hybrid screen, the actin binding protein filamin. These data suggest that the PH1 targets Trio to the cytoskeleton close to Rac and its effectors, probably via interaction with the actin-binding protein filamin, consistent with a role of Trio in actin cytoskeleton remodeling.

The two guanine nucleotide exchange factor domains of Trio link the Rac1 and the RhoA pathways in vivo.

Trio contains two functional guanine nucleotide exchange factors (GEF) domains for the Rho-like GTPases and a serine/threonine kinase domain. In vitro, GEF domain 1(GEFD1) is specifically active on Rac1, while GEF domain 2 (GEFD2) targets RhoA. To determine whether Trio could activate Rac1 and RhoA in vivo, we measured the effect of Trio on Mitogen Activated Protein Kinase (MAPK) pathways and cytoskeletal rearrangements events mediated by the two GTPases. We show that: (i) the GEFD1 domain of Trio triggers the MAPK pathway leading to Jun kinase (JNK) activation and the production of membrane ruffles; (ii) co-expression of the TrioGEFD1 domain with a dominant-negative form of Rac blocked JNK induction, whereas a dominant-negative form of Cdc42 did not; (iii) a deletion mutant of TrioGEFD1 lacking a region important for exchange activity could not stimulate JNK activity; (iv) in contrast, the TrioGEFD2 domain does not stimulate JNK activity and induces the formation of stress fibers, as does activated RhoA; (v) furthermore, co-expression of both GEF domains induces simultaneously the formation of ruffles and stress fibers. Trio, therefore represents a unique member of the Rho-GEFs family possessing two functional domains of distinct specificities, that allow it to link Rho and Rac signaling pathway in vivo.

Cyclin dependent kinase 5, cdk5, is a positive regulator of myogenesis in mouse C2 cells.

We have examined the expression, activity and localization of cyclin dependent kinase 5 (cdk5), during myogenesis. Cdk5 protein was found expressed in adult mouse muscle. In murine C2 cells, both the protein level and kinase activity of cdk5 showed a marked increase during early myogenesis with a peak between 36 and 48 hours of differentiation, decreasing as myotubes fuse after 60 to 72 hours. This increase in cdk5 protein level was specific for differentiation and not simply related to cell cycle arrest since it was not observed in fibroblasts grown for 48 hours in low serum medium. Indirect immunofluorescence using monospecific purified anti-cdk5 antibodies showed a low level cytoplasmic staining in proliferative myoblasts, a rapid increase in nuclear staining during the initial 12 hours of differentiation and a predominant nuclear staining in myotubes. Microinjection of plasmids encoding wild-type cdk5 into C2 myoblasts enhanced differentiation as assessed by both myogenin and troponin T expression after 48 hours of differentiation. In contrast, microinjection of plasmids encoding a dominant negative mutant of cdk5 inhibited the onset of differentiation. These data imply a previously unsuspected role for cdk5 protein kinase as a positive modulator of early myogenesis.

cdk5 expression and association with p35nck5a in early stages of rat cerebellum neurogenesis; tyrosine dephosphorylation and activation in post-mitotic neurons.

We have examined the expression of cyclin dependent kinase (cdk) 5 protein kinase and p35nck5a, its activator subunit, during postnatal neurogenesis in rat cerebellum, using mono-specific antibodies. Both cdk5 and p35nck5a are present and associated in proliferative stages, although cdk5-p35 kinase activity is barely detectable. Cdk5-p35 activity, but not the expression of either subunit, increases up to 6-fold during neuronal differentiation. Since we observe that cdk5 is phosphorylated on tyrosine in proliferative, but not in post-mitotic stages, we suggest that post-translational regulatory mechanisms control cdk5-p35 protein kinase activity during neurogenesis.

Thyroid hormone promotes BCL-2 expression and prevents apoptosis of early differentiating cerebellar granule neurons.

Programmed cell death is a basic cellular process that has aroused much interest in recent years. Like immune cells, cultures of cerebellar granule neurons are very homogeneous and provide a unique opportunity for quantifying by flow cytometry one form of programmed cell death in the CNS, the apoptosis, and for studying its regulation by neurotrophic factors. We found that thyroid hormone promoted postmitotic survival by preventing the apoptosis of newly formed and early differentiated granule neurons in a dose-dependent manner. This regulation could be through the protein bcl-2, which is known to prevent cell death. This protein was present at all stages of granule neuron differentiation and appeared to be developmentally regulated. It was underexpressed in apoptotic granule neurons. The protein content of the cerebellum in hypothyroid rats was drastically reduced. In contrast, thyroid hormone caused a marked dose-dependent increase in the amounts of this protein in granule neuron cultures. The possibility that thyroid hormone may be directly or indirectly required to promote cell survival is discussed, in terms of the hormone control of the local delivery of neurotrophins, such as NGF and NT-3, as well as the expression of their low affinity receptors, gp75. We suggest that thyroid hormone has a permissive action on the developing CNS.

Rapid changes in somatostatin and TRH mRNA in whole rat hypothalamus in response to acute cold exposure.

Acute cold stimulus induces activation of the thyreotropic axis characterized by a rapid increase in plasma thyrotropin (TSH). Since pituitary TSH release is mainly regulated by two hypothalamic hormones: thyrotropin-releasing hormone (TRH) and somatostatin, the aim of this study was to analyse whether changes in the steady state mRNA levels and peptide content of these neurohormones occur under acute cold stimulation in rats. Northern blot analysis of hypothalamic somatostatin mRNA levels after 15, 30, 60 or 180 min of cold exposure revealed a 2.0-fold increase after 15 min at 4 degrees C. This augmentation was followed by a return to control values at 30 min. However, the hypothalamic content of somatostatin was not significantly modified at any cold exposure time. TRH mRNA showed a similar pattern to somatostatin, with a 2.5-fold increase after 15 min at 4 degrees C. In contrast, hypothalamic TRH content was significantly decreased after 15 min cold exposure, returning to control values at 30 min. The increase in mRNA levels was specific for the two hypothalamic hormones, since there was no concomitant variation in GAPDH mRNA used as negative control. These results suggest that the organism is quickly aroused by cold stimulus, triggering rapid activation in transcription of the two neurohormones involved in the regulation of the thyreotrope axis. Since the peptide contents did not show the same pattern, a quantitative change in transcription or in mRNA stability does not appear to be a prerequisite for increased peptide expression, suggesting that somatostatin and TRH gene expressions could be regulated at translational or post-translational steps.

Cyclin A-Cys41 does not undergo cell cycle-dependent degradation in Xenopus extracts.

Truncated cyclin A and cyclin B lacking the N-terminal domain comprising the 'destruction box' escape from proteolysis and arrest cells at metaphase. Mutation of a conserved arginine residue of the destruction domain makes cyclin B resistant to proteolysis. Here we show that mutation of the same residue also makes cyclin A resistant to proteolysis, in either of two situations in which the cyclin degradation pathway is turned on: (i) in Xenopus extracts of activated eggs where the degradation pathway has been permanently turned on by adding a recombinant undegradable cyclin B in which the arginine residue of the destruction box has been substituted by alanine; (ii) in extracts of metaphase II-arrested oocytes after Ca(2+)-dependent inactivation of the cytostatic factor (CSF).