Antonella Bresin

Comprehensive analysis of PTEN status in Sezary syndrome.

Sézary syndrome (SS) is an incurable leukemic variant of cutaneous T-cell lymphoma characterized by recurrent chromosomal alterations, among which, chromosome 10q deletion is very frequent. In this study, we investigated the PTEN status, on locus 10q23, in 44 SS patients; our findings show that PTEN is deleted in 36% of SS cases, whereas PTEN downregulation is observed in almost all of the samples evaluated by quantitative reverse-transcriptase polymerase chain reaction and Western blotting analysis. Neither DNA sequence mutation nor promoter hypermethylation were found at the PTEN locus, but we demonstrate that PTEN level can be also reduced by a group of miRs previously found upregulated and of prognostic relevance in SS; particularly, miR-21, miR-106b, and miR-486 were able to control PTEN abundance either in vitro or in vivo. Finally, because reduced PTEN activates the PI3/AKT-mediated pathway of cell growth and survival, we demonstrate that PTEN deficiency is associated with activated AKT in skin resident but not circulating SS cells, suggesting that the cutaneous milieu may strongly contribute to the SS cell growth. To our knowledge, this is the first study fully exploring the PTEN status in a large cohort of SS patients, unveiling potential elements of clinical utility in this malignancy.

TCL1 transgenic mouse model as a tool for the study of therapeutic targets and microenvironment in human B-cell chronic lymphocytic leukemia

Chronic lymphocytic leukemia (CLL) is a B-cell malignancy with a mature phenotype. In spite of its relatively indolent nature, no radical cure is as yet available. CLL is not associated with either a unique cytogenetic or a molecular defect, which might have been a potential therapeutic target. Instead, several factors are involved in disease development, such as environmental signals which interact with genetic abnormalities to promote survival, proliferation and an immune surveillance escape. Among these, PI3-Kinase signal pathway alterations are nowadays considered to be clearly important. The TCL1 gene, an AKT co-activator, is the cause of a mature T-cell leukemia, as well as being highly expressed in all B-CLL. A TCL1 transgenic mouse which reproduces leukemia with a distinct immunophenotype and similar to the course of the human B-CLL was developed several years ago and is widely used by many groups. This is a review of the CLL biology arising from work of many independent investigators who have used TCL1 transgenic mouse model focusing on pathogenetic, microenviroment and therapeutic targets.

The Tcl1 oncogene defines secondary hair germ cells differentiation at catagen–telogen transition and affects stem-cell marker CD34 expression

Overexpression of the TCL1 gene family plays a role in the onset of T-cell leukemias in mice and in humans. The Tcl1 gene is tightly regulated during early embryogenesis in which it participates in embryonic stem (ES)-cells proliferation and during lymphoid differentiation. Here, we provide evidences that Tcl1 is also important in mouse hair follicle (HF) and skin homeostasis. We found that Tcl1−/− adult mice exhibit hair loss, leading to alopecia with extensive skin lesions. By analysing Tcl1 expression in the wild-type (wt) skin through different stages of hair differentiation, we observe high levels in the secondary hair germ (HG) cells and hair bulges, during early anagen and catagen–telogen transition phases. The loss of Tcl1 does not result in apparent skin morphological defects during embryonic development and at birth, but its absence causes a reduction of proliferation in anagen HFs. Importantly, we show the that absence of Tcl1 induces a significant loss of the stem-cell marker CD34 (but not α6-integrin) expression in the bulge cells, which is necessary to maintain stem-cell characteristics. Therefore, our findings indicate that Tcl1 gene(s) might have important roles in hair formation, by its involvement in cycling and self-renewal of transient amplifying (TA) and stem-cell (SC) populations.

Anti-leukemic activity of microRNA-26a in a chronic lymphocytic leukemia mouse model

Dysregulation of microRNAs (miRNAs) plays an important role in the pathogenesis of chronic lymphocytic leukemia (CLL). The Eμ-TCL1 transgenic mouse develops a form of leukemia that is similar to the aggressive type of human B-CLL, and this valuable model has been widely used for testing novel therapeutic approaches. Here, we adopted this model to investigate the potential effects of miR-26a, miR-130an and antimiR-155 in CLL therapy. Improved delivery of miRNA molecules into CLL cells was obtained by developing a novel system based on lipid nanoparticles conjugated with an anti-CD38 monoclonal antibody. This methodology has proven to be highly effective in delivering miRNA molecules into leukemic cells. Short- and long-term experiments showed that miR-26a, miR-130a and anti-miR-155 increased apoptosis after in vitro and in vivo treatment. Of this miRNA panel, miR-26a was the most effective in reducing leukemic cell expansion. Following long-term treatment, apoptosis was readily detectable by analyzing cleavage of PARP and caspase-7. These effects could be directly attributed to miR-26a, as confirmed by significant downregulation of its proven targets, namely cyclin-dependent kinase 6 and Mcl1. The results of this study are relevant to two distinct areas. The first is related to the design of a technical strategy and to the selection of CD38 as a molecular target on CLL cells, both consenting efficient and specific intracellular transfer of miRNA. The original scientific finding inferred from the above approach is that miR-26a can elicit in vivo anti-leukemic activities mediated by increased apoptosis.

T Cell Leukemia/Lymphoma 1A is essential for mouse epidermal keratinocytes proliferation promoted by insulin-like growth factor 1

T Cell Leukemia/Lymphoma 1A is expressed during B-cell differentiation and, when over-expressed, acts as an oncogene in mouse (Tcl1a) and human (TCL1A) B-cell chronic lymphocytic leukemia (B-CLL) and T-cell prolymphocytic leukemia (T-PLL). Furthermore, in the murine system Tcl1a is expressed in the ovary, testis and in pre-implantation embryos, where it plays an important role in blastomere proliferation and in embryonic stem cell (ESC) proliferation and self-renewal. We have also observed that Tcl1-/- adult mice exhibit alopecia and deep ulcerations. This finding has led us to investigate the role of TCL1 in mouse skin and hair follicles. We have found that TCL1 is expressed in the proliferative structure (i.e. the secondary hair germ) and in the stem cell niche (i.e. the bulge) of the hair follicle during regeneration phase and it is constitutively expressed in the basal layer of epidermis where it is required for the correct proliferative–differentiation program of the keratinocytes (KCs). Taking advantage of the murine models we have generated, including the Tcl1-/- and the K14-TCL1 transgenic mouse, we have analysed the function of TCL1 in mouse KCs and the molecular pathways involved. We provide evidence that in the epidermal compartment TCL1 has a role in the regulation of KC proliferation, differentiation, and apoptosis. In particular, the colony-forming efficiency (CFE) and the insulin-like growth factor 1 (IGF1)-induced proliferation are dramatically impaired, while apoptosis is increased, in KCs from Tcl1-/- mice when compared to WT. Moreover, the expression of differentiation markers such as cytokeratin 6 (KRT6), filaggrin (FLG) and involucrin (IVL) are profoundly altered in mutant mice (Tcl1-/-). Importantly, by over-expressing TCL1A in basal KCs of the K14-TCL1 transgenic mouse model, we observed a significant rescue of cell proliferation, differentiation and apoptosis of the mutant phenotype. Finally, we found TCL1 to act, at least in part, via increasing phospho-ERK1/2 and decreasing phospho-P38 MAPK. Hence, our data demonstrate that regulated levels of Tcl1a are necessary for the correct proliferation and differentiation of the interfollicular KCs.

Abstract 936: Skin microenvironment enhances proliferation index and activates mTORC 1 signaling in sezary syndrome

Introduction Sezary Syndrome (SS) is a rare and aggressive variant of Cutaneous-T-Cell Lymphoma (CTCL) characterized by the presence of malignant lymphocytes named Sezary (SS) cells in the skin, lymph nodes, and peripheral blood. With a poor prognosis, SS has not a specific therapy still available. As a role of skin in SS pathogenesis is not elucidated yet, here we study the contribution of this microenvironment by comparing matched skin and blood derived SS cells for tumor cell proliferation and activation levels of PI3k/AKT pathway. Using our previous SNP array data we also verified the genomic status of members belonging to this pathway in a large cohort of SS patients. Methods Expression of Ki67 proliferation marker was evaluated in perfect-paired blood and skin-paraffin biopsies obtained from eleven SS patients by flow cytometry analysis and immunohistochemistry respectively. KI67+ neoplastic cells were calculated as percentage within neoplastic CD4+ cells recognized by a co-staining with the specific TCRVb rearrangement. Phosphorylation levels of members of PI3k/AKT pathway were compared between matched circulating and skin resident SS cells proteins derived from 2 SS patients using an AKT kinase array (Cell Signaling). Affymetrix SNP6.0 arrays was used to investigate the copy number (CN) status of members of mTORC 1 pathway in a cohort in 37 SS samples derived from 23 SS patients and 3 cell lines. Results Skin derived SS cells showed a significant higher proliferation index (PI) respect to SS cells obtained from blood (12%±11 vs 1,24%+1,18; P = 0,00025). In order to identify the signals responsible for SS proliferation, we used a PI3K/AKT kinase array that revealed an enhanced phosphorylation levels of many components of this cascade, particularly of PRAS40 with a Fold change (Fc) of 6,15; GSK3a (Fc = 4.83), mTOR (Fc = 4.61) mP70S6K (Fc = 4.64) BAD (Fc = 7.09) and 4EBP1 (Fc = 5.40)in skin-SS cells respect to circulating ones. We next deepen our observations in mTORC1 signaling because of this and earlier observations made in CTCL cell lines. Using our SNP6 array data we have verified the genomic status of members of this pathway. Results obtained showed that P70S6K, the kinase downstream TORC1 that plays a crucial role in protein synthesis, showed a mono-allelic gain in 9 out 23 patients (39%) whereas PDCD4, a protein that inhibits protein translation displayed a mono-allelic loss in 10 of 23 individuals (43%). 4 of these patients showed a concomitant P70S6K gain and PDCD4 loss. Overall these genetic defects suggest that an abnormal protein synthesis can occur in these patients.. Conclusion: Our data demonstrate that skin microenvironment enhances SS cell proliferation index and activates mTORC1 signaling, an unbalanced pathway that reveals novel potential therapeutic targets for Sezary Syndrome. Citation Format: Cristina Cristofoletti, Mario Picozza, Antonella Bresin, Maria Cristina Picchio, Enrico Scala, Giuseppe A. Lombardo, Francesca Passarelli, Elisabetta Caprini, Giandomenico Russo, Maria Grazia Narducci. Skin microenvironment enhances proliferation index and activates mTORC 1 signaling in sezary syndrome. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 936.

Abstract 4178: Tcl1 enhances keratinocytes’ survival/proliferation by promoting erk and jnk/sap phosphorylation at the expense of p38 and by controlling c-fos expression through miR-29b and miR-181a-1

Proceedings: AACR 103rd Annual Meeting 2012‐‐ Mar 31‐Apr 4, 2012; Chicago, IL The Tcl1 oncogene has been initially isolated for its involvement in chromosomal translocations of T-prolymphocytic leukemias and overexpression in B chronic lymphocytic leukemia by enhancing AKT nuclear translocation and allowing the Ser-473 transphosphorylation. Tcl1, also, acts as AP-1 transcriptional inhibitor, by interacting with c-fos and c-jun. More recent works have associated Tcl1 to proliferation and self-renewal ability of ES cells under the direct activation of OCT3/4, Zfx, KLF5 transcription factors, being Tcl1 expressed in preimplantation embryos where it allows the progression beyond the 4-cells stage. We have recently shown that the Tcl1 oncogene is expressed in epidermis and defines secondary hair germ (transient-amplifying, TA) cells differentiation at catagen-telogen (the degenerative-resting phase of the hair follicle (HF)) transition, allowing the proliferation of TA cells in anagen (regenerative phase of the HF), giving the slow-cycling stem cells, the ability to incorporate BrdU. In fact, Tcl1 mutant (Tcl1-/-) affects stem-cell marker CD34 expression and BrdU incorporation in the bulge and TA cells, resulting in skin defects in adults with the onset of alopecia followed by skin wounding. Phenomena that are almost completely rescued by K14-TCL1 transgenic expression, in vivo. Since Tcl1 has a role in maintenance of a normal skin homeostasis in mice, involving both hair growth and epidermis, we used the approach of the expression chip analysis to unravel the pathways that are affected by loss of function and overexpression of Tcl1 in epidermal keratinocytes, by using Tcl1-/- and K14-TCL1;Tcl1-/- mice models. Our findings show that Tcl1 function involves the MAPK pathway, since Tcl1-/- shows increasing in p38MAPK phosphorylation linked to terminal differentiation/senescence/apoptosis of keratinocytes, while K14-driven overexpression shows increasing of p-Erk and p-Sapk/p-Jnk phosphorylations, linked to proliferation/commitment of keratinocytes. These signals flow through the MAPK cascade lead to altered AP1 factor function. In particular, the phosphorylation of AP-1 subunit c-Jun and c-fos transcriptional regulation and cellular localization result also affected. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 4178. doi:1538-7445.AM2012-4178