Attenuation of Soft-Tissue Sarcomas Resistance to the Cytotoxic Action of TNF-α by Restoring p53 Function

BACKGROUND: Isolated limb perfusion with TNF-α and melphalan is used with remarkable efficiency to treat unresectable limb sarcomas. Here we tested the ability of TNF-α to directly induce apoptosis of sarcoma cells. In addition, we investigated the impact of p53 in the regulation of such effect. METHODOLOGY/PRINCIPAL FINDINGS: We first analysed the ability of TNF-α to induce apoptosis in freshly isolated tumour cells. For this purpose, sarcoma tumours (n = 8) treated ex vivo with TNF-α were processed for TUNEL staining. It revealed substantial endothelial cell apoptosis and levels of tumour cell apoptosis that varied from low to high. In order to investigate the role of p53 in TNF-α-induced cell death, human sarcoma cell lines (n = 9) with different TP53 and MDM2 status were studied for their sensitivity to TNF-α. TP53(Wt) cell lines were sensitive to TNF-α unless MDM2 was over-expressed. However, TP53(Mut) and TP53(Null) cell lines were resistant. TP53 suppression in TP53(Wt) cell lines abrogated TNF-α sensitivity and TP53 overexpression in TP53(Null) cell lines restored it. The use of small molecules that restore p53 activity, such as CP-31398 or Nutlin-3a, in association with TNF-α, potentiated the cell death of respectively TP53(Mut) and TP53(Wt)/MDM2(Ampl). In particular, CP-31398 was able to induce p53 as well as some of its apoptotic target genes in TP53(Mut) cells. In TP53(Wt)/MDM2(Ampl) cells, Nutlin-3a effects were associated with a decrease of TNF-α-induced NF-κB-DNA binding and correlated with a differential regulation of pro- and anti-apoptotic genes such as TP53BP2, GADD45, TGF-β1 and FAIM. CONCLUSION/SIGNIFICANCE: More effective therapeutic approaches are critically needed for the treatment of unresectable limb sarcomas. Our results show that restoring p53 activity in sarcoma cells correlated with increased sensitivity to TNF-α, suggesting that this strategy may be an important determinant of TNF-α-based sarcomas treatment

Mirc11 Disrupts Inflammatory but Not Cytotoxic Responses of NK Cells

Natural killer (NK) cells generate proinflammatory cytokines that are required to contain infections and tumor growth. However, the posttranscriptional mechanisms that regulate NK cell functions are not fully understood. Here, we define the role of the microRNA cluster known as Mirc11 (which includes miRNA-23a, miRNA-24a, and miRNA-27a) in NK cell–mediated proinflammatory responses. Absence of Mirc11 did not alter the development or the antitumor cytotoxicity of NK cells. However, loss of Mirc11 reduced generation of proinflammatory factors in vitro and interferon-γ–dependent clearance of Listeria monocytogenes or B16F10 melanoma in vivo by NK cells. These functional changes resulted from Mirc11 silencing ubiquitin modifiers A20, Cbl-b, and Itch, allowing TRAF6-dependent activation of NF-κB and AP-1. Lack of Mirc11 caused increased translation of A20, Cbl-b, and Itch proteins, resulting in deubiquitylation of scaffolding K63 and addition of degradative K48 moieties on TRAF6. Collectively, our results describe a function of Mirc11 that regulates generation of proinflammatory cytokines from effector lymphocytes

The Role of microRNAs in NK Cell Development and Function

The clinical use of natural killer (NK) cells is at the forefront of cellular therapy. NK cells possess exceptional antitumor cytotoxic potentials and can generate significant levels of proinflammatory cytokines. Multiple genetic manipulations are being tested to augment the anti-tumor functions of NK cells. One such method involves identifying and altering microRNAs (miRNAs) that play essential roles in the development and effector functions of NK cells. Unique miRNAs can bind and inactivate mRNAs that code for cytotoxic proteins. MicroRNAs, such as the members of the Mirc11 cistron, downmodulate ubiquitin ligases that are central to the activation of the obligatory transcription factors responsible for the production of inflammatory cytokines. These studies reveal potential opportunities to post-translationally enhance the effector functions of human NK cells while reducing unwanted outcomes. Here, we summarize the recent advances made on miRNAs in murine and human NK cells and their relevance to NK cell development and functions

Potentiel anti-leucémique des cellules NK allogéniques

Les cellules tueuses naturelles (NK pour Natural Killer) sont une population lymphoïde dotées d’une activité cytotoxique contre les cellules infectées ou les cellules cancéreuses. Les cellules NK ont un potentiel thérapeutique considérable en tant que thérapie cellulaire anti-tumorale, particulièrement dans le cadre des leucémies. Ces approches sont basées sur une amélioration de la production de cellules NK à partir de cellules souches hématopoïétiques (quantitative et qualitative en améliorant leur activité lytique), mais aussi sur une manipulation de la sensibilité des cellules leucémiques à la lyse par les cellules NK. L’amélioration de ces approches nécessite une compréhension plus approfondie des différents mécanismes de résistance leucémique et leur relation avec la sensibilité à la lyse. Dans ce contexte, nous avons étudié le rôle de HOXB4 dans la différenciation des cellules NK et leur fonction lytique. Nous avons montré que les cellules CD34+ différenciées en cellules NK en présence de HOXB4 ont un potentiel lytique plus important par rapport aux cellules différenciées en l’absence de HIOXB4. Cette augmentation est associée à une augmentation de la dégranulation des cellules NK en présence de cellules cibles. L’analyse transcriptionnelle globale basé sur un microréseau d'ADN montre une régulation positive de l’expression de granzyme B par HOXB4. Ces résultats démontrent que HOXB4 est un régulateur crucial dans la différenciation et la fonction des cellules NK. Ils soulignent également l’intérêt de son utilisation dans la production de cellules NK fonctionnelles dotées d’un plus grand potentiel lytique pour les stratégies d'immunothérapie anticancéreuse. Nous avons également essayé de comprendre comment l'acquisition de la résistance aux chimiothérapies par les cellules de leucémie aigüe myéloïde (LAM) influence leur reconnaissance et leur sensibilité aux cellules NK. Nous avons montré que l'acquisition de la résistance in vitro des cellules AML à la cytarabine induit une augmentation de leur susceptibilité à la cytotoxicité dépendante des cellules NK. Cette sensibilité accrue est en corrélation avec l’induction d’ULBP (UL-16 binding proteins) 1/2/3, ligands des récepteurs NKG2D, sur les cellules leucémiques résistantes. Cette induction est régulée par un mécanisme impliquant l'induction de c-Myc. Le test d’immunoprécipitation de la chromatine (ChIP) a révélé qu’ULBP1 et ULBP3 sont des cibles directes de c-Myc. L’utilisation de cellules AML primaires résistants à la chimiothérapie comme les cellules cibles, combinée à l'inhibition de c-Myc a entraîné une diminution de l'expression des ligands NKG2D et l'altération de la lyse par les cellules NK. Les propriétés d’alloréactivité des cellules NK pourraient être utilisées pour améliorer les résultats de la transplantation de cellules souches hématopoïétiques allogéniques chez les patients atteints d’AML. Cependant, la résistance croisée (chimiothérapie et NK) des blastes AML reste un problème majeur. Nous avons étudié la relation entre résistance des cellules leucémiques à la daunorubicine, la susceptibilité de ces cellules à la lyse par les cellules NK et l'expression putative des micro-RNAs. Nos résultats indiquent que l'acquisition de la résistance à la daunorubicine par les lignées de cellules parentales induit une résistance croisée à la cytotoxicité naturelle à médiation cellulaire. L'analyse des microréseaux de microRNAs a révélé que cette résistance croisée est associée à une diminution du miR-181a et une augmentation des gènes de la famille tyrosine kinase (MAP3K10 et MAP2K1) et de la famille Bcl-2 (Bcl-2 et Mcl-1). La surexpression de miR-181a dans les blastes AML entraîne l'atténuation de leur résistance à la daunorobucine et à la lyse par les cellules NK.Natural Killer (NK) cells are a lymphoid population with potent cytotoxic activity against virus-infected or cancer cells, and which hold considerable potential for cell based therapies targeting human malignancies. Potential approaches include not only enhancing the generation of NK cells in number and improving their lytic activity, but also manipulating the susceptibility of blast cells to NK-mediated killing. Pursuing these approaches will require a more thorough understanding of the different mechanisms of resistance and their relationship with susceptibility to NK-mediated killing. In this context, we studied the role of HOXB4 in NK cells differentiation and lytic function. We showed that HOXB4 transduced MS-5 cells as compared with GFP-transduced MS-5 cells induced highly differentiated cytotoxic NK cells. This difference was associated with an increased induction of granzyme B degranulation in response to stimulation with NK cell susceptible targets. DNA microarray-based global transcriptional profiling confirmed the upregulation of granzyme B. These findings provide further evidence that HOXB4 is a crucial regulator of NK function and that its use in generating functional NK cells with increased lytic potential may be significant for cancer immunotherapy. We attempted to elucidate how acquisition of drug resistance in AML cells influences NK cell recognition and the killing of drug-resistant blasts. We showed that the in vitro acquisition of AML cell resistance to cytarabine resulted in an increase in their susceptibility to NK-mediated cell cytotoxicity. The increased susceptibility correlates with the induction of UL-16 binding proteins (ULBP) 1/2/3 and NK group 2, member (NKG2D) ligands on target cells by a mechanism involving c-Myc induction. More importantly, chromatin immunoprecipitation assay revealed that ULBP1/3 are direct targets of c-Myc. Using drug resistant primary AML blasts as target cells, inhibition of c-Myc resulted in decreased expression of NKG2D ligands and the subsequent impairment of NK cell lysis. This study provides for the first time, the c-Myc dependent regulation of NKG2D ligands in AML. Manipulating NK-cell alloreactivity might improve outcomes after hematopoietic stem-cell transplantation; however, cross-resistance among blasts remains a drawback. We attempted to investigate the relationship between AML to daunorubicin, the susceptibility to NK cellmediated cell lysis and the putative expression of miRs. Our results indicate that the acquisition of resistance to daunorubicin by the parental cell lines resulted in the acquisition of a cross-resistance to natural cell-mediated cytotoxicity. miR microarray analysis revealed that this cross-resistance was associated with miR-181a down regulation and the subsequent regulation of the tyrosine kinase (MAP3K10 and MAP2K1) and the BCL-2 (BCL-2 andMCL-1) families. Overexpression of miR-181a in AML blasts resulted in the attenuation of their resistance to daunorobucin and to NK-cell-mediated killing

Enhanced Cytotoxic Activity of Ex Vivo-differentiated Human Natural Killer Cells in the Presence of HOXB4

International audienceWe have previously shown that human umbilical cord blood CD34 progenitor cells undergo in vitro differentiation into functional natural killer (NK) cells and that their coculture in the presence of HOXB4-transduced stromal MS-5 cells resulted in an increase in differentiated NK number. The present study was conducted to compare the stromal effect on NK lytic potential in the presence and absence of HOXB4. Our results provide evidence that HOXB4-transduced MS-5 cells as compared with transduced GFP (+) MS-5 cells induced highly differentiated cytotoxic NK cells. Importantly, this difference was not because of the expression of activating NK receptors but was associated with an increased induction of granzyme B degranulation in response to stimulation with NK cell susceptible targets. DNA microarray-based global transcriptional profiling confirmed the upregulation of granzyme B. These findings provide further evidence that HOXB4 is a crucial regulator of NK function and that its use in generating functional NK cells with increased lytic potential may be significant for cancer immunotherapy

Hypoxic tumor-derived microvesicles negatively regulate NK cell function by a mechanism involving TGF-β and miR23a transfer

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Effects of p53 silencing and overexpression on TNF-α-induced cell death.

<p><i>A</i>, <i>TP53^Wt</i>/<i>MDM2^Wt</i> cell lines (HT1080) were transfected with expression vectors encoding shRNA specific for either luciferase (shRNA-luc) or p53 (shRNA–p53) and efficiency was controlled by Western-blot. <i>B,</i> Apoptosis induction after 72 h TNF-α treatment in non-transfected and transfected (shRNA) HT1080 cell lines. Representative results of induced apoptosis from two experiments are shown. *p<0.05 <i>versus</i> p53 expressing cells transfected and non-transfected by shRNA-Luc. <i>C</i>, MFH95 <i>TP53^Null</i> cell lines were transfected with p53-encoding plasmid pC53-SN3 and efficiency was controlled by Western-blot. <i>D,</i> Cell cycle analysis of control and p53-expressing MFH95 cell lines treated or not by TNF-α. Percent of cells in each phase of the cell cycle is indicated at the upper right corner.</p

Differential NF-κB-DNA-binding and apoptotic gene expression are involved in the potentiating effect of TNF-α and Nutlin-3a treatment.

<p>A, NF-κB DNA binding activity after treatment of the TP53Wt/MDM2Ampl cell lines with TNF-α or/and Nutlin-3a. Nuclear extracts from monolayers of T449, T778 and T1000 cells, untreated or treated with either TNF-α, or Nutlin-3a or both for 72 h, were analyzed for NF-κB activity by EMSA. B, Differentially regulated apoptotic genes in TP53Wt/MDM2Ampl cell lines treated with the combination of TNF-α and Nutlin-3a compared to Nutlin-3a-only treated cells. T449, T778 and T1000 cell lines were treated 16 h with 50 ng/ml TNF-α and/or 5 µmol Nutlin-3a. Total RNA was extracted and analyzed by qRT-PCR. Results are expressed as mean ± SD from two independent experiments performed in duplicate. * p<0.05 in TNF-α + Nutlin-3a treated cells as compared to Nutlin-3a alone.</p

TNF-α induced cell death in nine sarcoma cell lines with different p53 status.

<p><i>A,</i> Western blot analysis of p53, MDM2 and p21 expression in <i>TP53^Wt</i>/<i>MDM2^Wt</i> (KYM-1 and HT1080), <i>TP53^Wt</i>/<i>MDM2^Ampl</i> (T449, T778 and T1000), <i>TP53^Mut</i> (MFH100 and MFH152) and <i>TP53^Null</i> (MFH95 and LMS148) cell lines studied after irradiation. Lysates were prepared 2 h after exposure to 15 Gy. <i>B</i>, Impact of TNF-α on cell survival assessed by DiOC₆/PI method after 72 h treatment. The percentage of specific apoptosis is shown as an increase of apoptotic cells (early and late apoptosis) in comparison to untreated cells. Results from four experiments are shown. *p<0.05 <i>versus</i> all cell lines. <i>C,</i> Cell surface expression of TNF receptor type 1 detected by flow cytometry following staining with TNFR1-specific monoclonal antibody (filled histograms) and isotype-matched control (open histograms). Percentages of positive cells and of mean fluorescence intensity are indicated; representative results from three experiments are shown.</p