Pathogenesis Of Cutaneous T-cell Lymphoma Research Articles

Skin Barrier Dysfunction in Cutaneous T-Cell Lymphoma: From Pathogenic Mechanism of Barrier Damage to Treatment.

Cutaneous T-cell lymphoma (CTCL) is a group of non-Hodgkin lymphomas characterized by multiple erythematous patches, plaques, or even nodules on the skin. As the disease progresses, patients develop widespread pruritic skin lesions, leading to skin barrier dysfunction, which significantly impacts their quality of life, appearance, and social adaptation. The pathogenesis of CTCL is not fully understood. Recent studies have recognized the important role of skin barrier dysfunction in the development and progression of CTCL, yet a comprehensive review on this topic is lacking. This review summarizes recent findings on skin barrier dysfunction in CTCL, focusing on physical barrier dysfunction, chronic inflammation, and immune dysregulation. We also discuss current and potential therapies aimed at restoring barrier function in CTCL. By emphasizing the integration of barrier-centric approaches into CTCL management, this review provides valuable insights for improving treatment outcomes.

Stage-related increase in PIM2 expression in mycosisfungoides.

The oncogene PIM2 is upregulated in several malignancies but has never been investigated in mycosis fungoides (MF), the most common type of cutaneous T-cell lymphoma (CTCL). PIM2 is a well-known oncogene and is regulated by cell signaling pathways like the JAK/STAT- and NF-kB-pathway, key regulators in the pathogenesis of CTCL. The aim of this study was to examine the role of PIM2 in MF. PIM2 gene expression was measured in 81 formalin-fixed paraffin-embedded skin biopsies from patients with MF and 46 control biopsies from healthy skin (HS) and benign inflammatory skin disease (BID). Validation of PIM2 protein expression was performed on selected biopsies with immunohistochemical staining. We found a significant difference in gene expression levels between both early stage MF and HS (p < 0.0001), and BID (p < 0.0001). In addition, the PIM2 gene expression was higher in advanced-stage MF compared to early stage disease (p = 0.0001). No significant difference in gene expression levels was found between patients with and without disease progression. In conclusion, we found PIM2 expression is significantly increased in MF compared to controls, and in advanced-stage MF compared to early stage MF. These findings could potentially have diagnostic value in discriminating early stage MF from BID.

"Next top" mouse models advancing CTCL research.

This review systematically describes the application of in vivo mouse models in studying cutaneous T-cell lymphoma (CTCL), a complex hematological neoplasm. It highlights the diverse research approaches essential for understanding CTCL's intricate pathogenesis and evaluating potential treatments. The review categorizes various mouse models, including xenograft, syngeneic transplantation, and genetically engineered mouse models (GEMMs), emphasizing their contributions to understanding tumor-host interactions, gene functions, and studies on drug efficacy in CTCL. It acknowledges the limitations of these models, particularly in fully replicating human immune responses and early stages of CTCL. The review also highlights novel developments focusing on the potential of skin-targeted GEMMs in studying natural skin lymphoma progression and interactions with the immune system from onset. In conclusion, a balanced understanding of these models' strengths and weaknesses are essential for accelerating the deciphering of CTCL pathogenesis and developing treatment methods. The GEMMs engineered to target specifically skin-homing CD4+ T cells can be the next top mouse models that pave the way for exploring the effects of CTCL-related genes.

The Complex Role of Infectious Agents in Human Cutaneous T-Cell Lymphoma Pathogenesis: From Candidate Etiological Factors to Potential Therapeutics.

Cutaneous T-cell lymphoma (CTCL) is a devastating, potentially fatal T-lymphocyte malignancy affecting the skin. Despite all efforts, the etiology of this disease remains unknown. Infectious agents have long been suspected as factors or co-factors in CTCL pathogenesis. This review deals with the panel of bacterial and viral pathogens that have been investigated so far in an attempt to establish a potential link between infection/carriage and CTCL development. A special focus is given to a recently discovered human protoparvovirus, namely the cutavirus (CutaV), which has emerged as a plausible CTCL etiological agent. Available evidence in support of this hypothesis as well as alternative interpretations and uncertainties raised by some conflicting data are discussed. The complexity and multifacetedness of the Parvoviridae family of viruses are illustrated by presenting another protoparvovirus, the rat H-1 parvovirus (H-1PV). H-1PV belongs to the same genus as the CutaV but carries considerable potential for therapeutic applications in cutaneous lymphoma.

ATF5 promotes malignant T cell survival through the PI3K/AKT/mTOR pathway in cutaneous T cell lymphoma.

Cutaneous T cell lymphoma (CTCL) is a non-Hodgkin lymphoma characterized by skin infiltration of malignant T cells. The biological overlap between malignant T cells and their normal counterparts has brought obstacles in identifying tumor-specific features and mechanisms, limiting current knowledge of CTCL pathogenesis. Transcriptional dysregulation leading to abnormal gene expression profiles contributes to the initiation, progression and drug resistance of cancer. Therefore, we aimed to identify tumor-specific transcription factor underlying CTCL pathology. We analyzed and validated the differentially expressed genes (DEGs) in malignant T cells based on single-cell sequencing data. Clinical relevance was evaluated based on progression-free survival and time to next treatment. To determine the functional importance, lentivirus-mediated gene knockdown was conducted in two CTCL cell lines Myla and H9. Cell survival was assessed by examining cell viability, colony-forming ability, in-vivo tumor growth in xenograft models, apoptosis rate and cell-cycle distribution. RNA sequencing was employed to investigate the underlying mechanisms. Activating transcription factor 5 (ATF5) was overexpressed in malignant T cells and positively correlated with poor treatment responses in CTCL patients. Mechanistically, ATF5 promoted the survival of malignant T cells partially through the PI3K/AKT/mTOR pathway, and imparted resistance to endoplasmic reticulum (ER) stress-induced apoptosis. These findings revealed the tumor-specific overexpression of the transcription factor ATF5 with its underlying mechanisms in promoting tumor survival in CTCL, providing new insight into the understanding of CTCL's pathology.

Pathobiology and Targeting of CD38 in Cutaneous T-Cell Lymphoma

Introduction: Cutaneous T-cell lymphoma (CTCL) is a malignancy of mature CD4+ T-cells that primarily affects the skin. Despite a wide variety of topical and systemic therapies for patients, CTCL remains difficult to treat. Because of its high likelihood of relapse and resistance, new therapeutic approaches are needed. We recently showed strong CD38 expression on neoplastic T-cells from patients with mature T-cell neoplasms, including CTCL. In this study, we evaluated i) the role of CD38 in CTCL pathogenesis ii) strategies to enhance CD38 expression in CTCL and iii) tested efficacy of combination therapy in vivo. Methods: Skin and peripheral blood samples from patients and healthy donors were evaluated for CD38 expression by immunohistochemistry (N=7), microarray (N=82), single-cell RNA-sequencing (N=11), and flow cytometry (N=14). To investigate the role of CD38 in CTCL, we generated CD38 knockout cell lines (H9, HH, and HuT-78) using CRISPR/Cas9-mediated genomic deletion. The CD38 wild-type (CD38 WT) and knockout (CD38 KO) cells were purified, cultured, and used for downstream functional analysis. We evaluated the lines for growth, metabolic capacities (XFe24 Seahorse assay), and engraftment potential in vivo. For in vivo therapeutic studies, we transduced firefly-luciferase gene into H9 CD38 WT and CD38 KO cells, and engrafted them intravenously into immunodeficient NOD Rag -/-γc -/- mice. Mice were treated with anti-CD38 antibody daratumumab or IgG control and disease progression was monitored over time using an in vivo imaging system. For combination studies, we evaluated CD38 expression by flow cytometry in H9 cells treated with increasing doses of HDAC inhibitor, panobinostat (5nM, 10nM, 25nM) for 24, 48, and 72 hours. Next, we tested co-treatment with panobinostat and daratumumab in vivo in mice engrafted with H9 CD38 WT cells with four treatment groups (vehicle/IgG, panobinostat/IgG, vehicle/daratumumab, and panobinostat/daratumumab). Results: Patient skin biopsies showed increased CD38 expression at both protein and RNA levels (log fold change 4.8; p&amp;lt;0.0001 by Mann-Whitney test). Across nine days of tracking under standard cell culture conditions, CD38 KO CTCL cells showed minimal growth differences compared to CD38 WT (p=0.22 by linear regression). However, CD38 KO CTCL cells showed significantly increased basal and maximum oxygen consumption rates (OCR) via seahorse assay when compared to CD38 WT cells (basal OCR 2.26 fold increase, p&amp;lt;0.0001; max OCR 1.83 fold increase, p&amp;lt;0.0001 by Mann-Whitney test). Using IVIS luminescent imaging, we found significantly increased in vivo growth of CD38 KO CTCL cells compared to CD38 WT cells (CD38 WT=2.2e8 photons/sec average total flux, N=7; CD38 KO=1e9 photons/sec, N=5; p=0.003 by Mann-Whitney test). These data suggest that the loss of CD38 in CTCL cells can accelerate the development of tumors in mice. In order to study the effectiveness of a targeted drug against CD38 in CTCL, we used anti-CD38 antibody daratumumab in our H9 xenograft model. Daratumumab treatment had a significant therapeutic effect on CD38 WT tumors compared to isotype control, reducing tumor burden by 84% (daratumumab average total flux=1.4e7 photons/sec, N=4; IgG average total flux=9.0e7 photons/sec, N=3; p=0.0002). Additionally, we explored methods to increase CD38 expression on CTCL cells. We found that panobinostat significantly increased CD38 expression on H9 CTCL cells in a dose dependent manner across multiple time points (max 85% increase in CD38 expression with 25nM panobinostat vs. DMSO at 72 hours; p&amp;lt;0.0001 by 2way ANOVA). In vivo testing demonstrated a statistically significant improved survival benefit in mice treated with the combination of panobinostat and daratumumab compared to mice that received daratumumab alone (vehicle median survival 23 days, N=4; daratumumab alone median survival 32 days N=4; panobinostat alone median survival 27.5 days, N=4; combination median survival 39 days, N=4; p=0.01 by log-rank test). The prolonged average survival benefit amounted to approximately one quarter of their entire overall lifespan. Conclusion: Our studies demonstrate strong evidence for further study into how CD38 regulates the growth and survival of CTCL cells. Our data also provide preliminary evidence for the clinical usefulness of combination therapies that increase CD38 expression to enhance tumor cell immunotherapeutic targeting.

New JAK3-INSL3 Fusion Transcript-An Oncogenic Event in Cutaneous T-Cell Lymphoma.

Constitutively activated tyrosine kinase JAK3 is implicated in the pathogenesis of cutaneous T-cell lymphomas (CTCL). The mechanisms of constitutive JAK3 activation are unknown although a JAK3 mutation was reported in a small portion of CTCL patients. In this study, we assessed the oncogenic roles of a newly identified JAK3-INSL3 fusion transcript in CTCL. Total RNA from malignant T-cells in 33 patients with Sézary syndrome (SS), a leukemic form of CTCL, was examined for the new JAK3-INSL3 fusion transcript by RT-PCR followed by Sanger sequencing. The expression levels were assessed by qPCR and correlated with patient survivals. Knockdown and/or knockout assays were conducted in two CTCL cell lines (MJ cells and HH cells) by RNA interference and/or CRISPR/Cas9 gene editing. SS patients expressed heterogeneous levels of a new JAK3-INSL3 fusion transcript. Patients with high-level expression of JAK3-INSL3 showed poorer 5-year survival (n = 19, 42.1%) than patients with low-level expression (n = 14, 78.6%). CTCL cells transduced with specific shRNAs or sgRNAs had decreased new JAK3-INSL3 fusion transcript expression, reduced cell proliferation, and decreased colony formation. In NSG xenograft mice, smaller tumor sizes were observed in MJ cells transduced with specific shRNAs than cells transduced with controls. Our results suggest that the newly identified JAK3-INSL3 fusion transcript confers an oncogenic event in CTCL.

Sézary syndrome originates from heavily mutated hematopoietic progenitors

AbstractThe pathogenesis of cutaneous T-cell lymphoma (CTCL) remains unclear. Using single-cell RNA or T-cell receptor (TCR) sequencing of 32 619 CD3+CD4+ and CD26+/CD7+ and 29 932 CD3+CD4+ and CD26−/CD7− lymphocytes from the peripheral blood of 7 patients with CTCL, coupled to single-cell ATAC-sequencing of 26,411 CD3+CD4+ and CD26+/CD7+ and 33 841 CD3+CD4+ and CD26−/CD7− lymphocytes, we show that tumor cells in Sézary syndrome and mycosis fungoides (MF) exhibit different phenotypes and trajectories of differentiation. When compared to MF, Sézary cells exhibit narrower repertoires of TCRs and exhibit clonal enrichment. Surprisingly, we identified ≥200 mutations in hematopoietic stem cells from multiple patients with Sézary syndrome. Mutations in key oncogenes were also present in peripheral Sézary cells, which also showed the hallmarks of recent thymic egression. Together our data suggest that CTCL arises from mutated lymphocyte progenitors that acquire TCRs in the thymus, which complete their malignant transformation in the periphery.

New Molecular and Biological Markers in Cutaneous T Cell Lymphoma: Therapeutic Implications.

Cutaneous T cell lymphomas (CTCLs) exhibit a wide variety of clinical features, histologic characteristics, and genetic drivers. We review novel molecular findings that inform our understanding of the pathogenesis of CTCL, with a focus on the tumor microenvironment (TME). There is increasing evidence challenging the model of TCM:mycosis fungoides (MF) and TEM:Sézary syndrome (SS) phenotype. Phylogenetic analysis performed using whole-exome sequencing (WES) raises the possibility that MF can arise without a common ancestral T cell clone. The detection of ultraviolet (UV) marker signature 7 mutations in the blood of patients with SS raises questions about the role of UV exposure in CTCL pathogenesis. There is also increasing interest on the role of the TME in CTCL. Existing therapies such as the RXR retinoid bexarotene and the anti-CCR4 monoclonal antibody mogamulizumab may act through the CTCL TME by impacting the CCL22:CCR4 axis, while cancer-associated fibroblasts (CAFs) in the CTCL TME contribute to drug resistance, as well as a Th2 milieu and tumor growth via secretion of pro-tumorigenic cytokines. Staphylococcus aureus (SA) is a frequent cause of morbidity among CTCL patients. SA may positively select for malignant T cells through adaptive downregulation of alpha-toxin surface receptors and promotion of tumor growth via upregulation of the JAK/STAT pathway. Recent molecular advancements have contributed to our understanding of the pathogenesis of CTCL and shed light into the potential mechanisms of existing therapies. Further understanding of the CTCL TME may fuel the discovery of novel therapies for CTCL.

Some New Aspects of Genetic Variability in Patients with Cutaneous T-Cell Lymphoma.

Cutaneous T-cell lymphoma (CTCL) is a group of T-cell malignancies that develop in the skin. Though studied intensively, the etiology and pathogenesis of CTCL remain elusive. This study evaluated the survival of CTCL patients in the 1st Department of Dermatovenereology of St. Anne's University Hospital Brno. It included analysis of 19 polymorphic gene variants based on their expected involvement in CTCL severity. 75 patients with CTCL, evaluated and treated at the 1st Department of Dermatovenereology of St. Anne´s University Hospital Brno, Faculty of Medicine, Masaryk University, were recruited for the study over the last 28 years (44 men and 31 women, average age 58 years, range 20-82 years). All patients were genotyped for 19 chosen gene polymorphisms by the conventional PCR method with restriction analysis. A multivariate Cox regression model was calculated to reveal genetic polymorphisms and other risk factors for survival. The model identified MDR Ex21 2677 (rs2032582) as a significant genetic factor influencing the survival of the patients, with the T-allele playing a protective role. A multivariate stepwise Cox regression model confirmed the following as significant independent risk factors for overall survival: increased age at admission, clinical staging of the tumor, and male sex. We showed that the TT genotype at position 2677 of the MDR1 gene exhibited statistically significant longer survival in CTCL patients. As such, the TT genotype of MDR1 confers a significant advantage for the CTCL patients who respond to treatment.

Advances in the understanding and treatment of Cutaneous T-cell Lymphoma.

Cutaneous T-cell lymphomas (CTCL) are a heterogeneous group of non-Hodgkin's lymphomas (NHL) characterised by the clonal proliferation of malignant, skin homing T-cells. Recent advances have been made in understanding the molecular pathogenesis of CTCL. Multiple deep sequencing studies have revealed a complex genomic landscape with large numbers of novel single nucleotide variants (SNVs) and copy number variations (CNVs). Commonly perturbed genes include those involved in T-cell receptor signalling, T-cell proliferation, differentiation and survival, epigenetic regulators as well as genes involved in genome maintenance and DNA repair. In addition, studies in CTCL have identified a dominant UV mutational signature in contrast to systemic T-cell lymphomas and this likely contributes to the high tumour mutational burden. As current treatment options for advanced stages of CTCL are associated with short-lived responses, targeting these deregulated pathways could provide novel therapeutic approaches for patients. In this review article we summarise the key pathways disrupted in CTCL and discuss the potential therapeutic implications of these findings.

Therapeutic Potential and Role of CD38 in Cutaneous T-Cell Lymphoma Pathogenesis

Therapeutic Potential and Role of CD38 in Cutaneous T-Cell Lymphoma Pathogenesis

Leveraging Pre-Clinical Animal Model of CTCL to Explore Therapeutic Potential of a Novel STAT3 Degrader

STAT3 enhances pro-survival signaling essential for T cell expansion, but when this pathway is not appropriately regulated, aberrant STAT3 signaling contributes to T cell lymphomagenesis. Cutaneous T cell lymphoma (CTCL) is a type of mature T cell lymphoma characterized by the accumulation of malignant T cells in the skin. Our analysis, along with other recently published sequencing studies, identified upregulation of the STAT3 cytokine signaling pathway as a key driver of CTCL pathogenesis. In normal processes, STAT3 activity is transient, but dysregulation of this pathway is observed in several human malignancies, including CTCL. Aberrant STAT3 activity in malignant cells promotes transcription of target genes that promote proliferation and survival of transformed T cells. Translocations resulting in STAT3 duplications, activating mutations in the SH2 domain of STAT3 and activating mutations in kinases upstream of STAT3 all contribute to hyperactivation of this JAK/STAT signaling pathway in CTCL. STAT3 signaling in bystander cells within the tumor microenvironment may further contribute to tumor progression, although the precise role of this signaling pathway in malignant disease is context dependent. We have used conditional gene targeting to develop a fully penetrant STAT3-dependent small animal model of CTCL that recapitulates many key features of human disease. In this model, a constitutively active form of STAT3 is expressed exclusively in T lymphocytes. The autochthonous mouse model is characterized by progressive accumulation of malignant T cells in the skin and secondary lymphoid organs. Our molecular analysis of T cells from this mouse model revealed a transcriptional signature that largely mirrored the one found in malignant cells from patients. We have now taken advantage of this tractable animal model of CTCL to evaluate the therapeutic potential of a potent and selective E3 ubiquitin ligase-based novel STAT3 heterobifunctional degrader for targeting this difficult-to-treat hematologic malignancy. Weekly intravenous administration of the degrader was well tolerated and led to significant reduction of STAT3 levels in circulating and skin-resident T lymphocytes. Progression of disease in our preclinical model was notably blunted upon administration of the STAT3 degrader with dramatic reduction in T cell accumulation in the skin and lymph nodes. We will report on pre-clinical evaluation of the degrader and the impact on disease progression, T cell accumulation, activation and proliferation in vivo following weekly drug administration. Targeted protein degradation represents a novel therapeutic modality enabling direct targeting of previously undruggable oncoproteins such as STAT3. These data provide a rationale for selective STAT3 degradation as a therapeutic strategy for malignancies such as CTCL that are associated with constitutive activation of STAT3 signaling. Fig Legend:Treatment of mice exhibiting CTCL phenotypes starting at ~3mo of age. Phenotype score reflects presentation of fur loss, scaling/flaking of the skin, appearance of lesions and death. Figure 1View largeDownload PPTFigure 1View largeDownload PPT Close modal

T cells in the skin: Lymphoma and inflammatory skin disease

T cells are established contributors to the pathogenesis of atopic dermatitis and psoriasis; yet, whether they are the key drivers or simply unwitting participants remains incompletely understood. Conversely, malignant T cells are the undisputed culprits of cutaneous T-cell lymphoma (CTCL), a group of diseases that share key clinical, histopathologic, and molecular features with inflammatory skin disease (ISD). Here, we compare the pathogenesis of ISD and CTCL and discuss the resulting insights. Recurrent, skin-limited disease implicates skin-resident memory T cells in both ISD and CTCL. In CTCL, malignant T cells recruit benign T cells into inflammatory skin lesions, a disease-amplifying function that has also been proposed for pathogenic T cells in ISD. Mechanistically, cytokines produced by malignant T cells in CTCL and by pathogenic T cells in ISD, respectively, are likely both necessary and sufficient to drive skin inflammation and pruritus, which in turn promotes skin barrier dysfunction and dysbiosis. Therapies for ISD target T-cell effector functions but do not address the chronicity of disease, whereas treatments for CTCL target malignant T cells but not primarily the symptoms of the disease. Integrating our understanding of ISD and CTCL can result in important insights into pathogenesis and therapy that may improve the lives of patients in both of these disease groups.

Understanding Cell Lines, Patient-Derived Xenograft and Genetically Engineered Mouse Models Used to Study Cutaneous T-Cell Lymphoma.

Cutaneous T cell lymphoma (CTCL) is a spectrum of lymphoproliferative disorders caused by the infiltration of malignant T cells into the skin. The most common variants of CTCL include mycosis fungoides (MF), Sézary syndrome (SS) and CD30+ Lymphoproliferative disorders (CD30+ LPDs). CD30+ LPDs include primary cutaneous anaplastic large cell lymphoma (pcALCL), lymphomatoid papulosis (LyP) and borderline CD30+ LPD. The frequency of MF, SS and CD30+ LPDs is ~40–50%, <5% and ~10–25%, respectively. Despite recent advances, CTCL remains challenging to diagnose. The mechanism of CTCL carcinogenesis still remains to be fully elucidated. Hence, experiments in patient-derived cell lines and xenografts/genetically engineered mouse models (GEMMs) are critical to advance our understanding of disease pathogenesis. To enable this, understanding the intricacies and limitations of each individual model system is highly important. Presently, 11 immortalized patient-derived cell lines and different xenograft/GEMMs are being used to study the pathogenesis of CTCL and evaluate the therapeutic efficacy of various treatment modalities prior to clinical trials. Gene expression studies, and the karyotyping analyses of cell lines demonstrated that the molecular profile of SeAx, Sez4, SZ4, H9 and Hut78 is consistent with SS origin; MyLa and HH resemble the molecular profile of advanced MF, while Mac2A and PB2B represent CD30+ LPDs. Molecular analysis of the other two frequently used Human T-Cell Lymphotropic Virus-1 (HTLV-1)+ cell lines, MJ and Hut102, were found to have characteristics of Adult T-cell Leukemia/Lymphoma (ATLL). Studies in mouse models demonstrated that xenograft tumors could be grown using MyLa, HH, H9, Hut78, PB2B and SZ4 cells in NSG (NOD Scid gamma mouse) mice, while several additional experimental GEMMs were established to study the pathogenesis, effect of drugs and inflammatory cytokines in CTCL. The current review summarizes cell lines and xenograft/GEMMs used to study and understand the etiology and heterogeneity of CTCL.

Transcriptional Heterogeneity and the Microbiome of Cutaneous T-Cell Lymphoma.

Cutaneous T-Cell Lymphomas (CTCL) presents with substantial clinical variability and transcriptional heterogeneity. In the recent years, several studies paved the way to elucidate aetiology and pathogenesis of CTCL using sequencing methods. Several T-cell subtypes were suggested as the source of disease thereby explaining clinical and transcriptional heterogeneity of CTCL entities. Several differentially expressed pathways could explain disease progression. However, exogenous triggers in the skin microenvironment also seem to affect CTCL status. Especially Staphylococcus aureus was shown to contribute to disease progression. Only little is known about the complex microbiome patterns involved in CTCL and how microbial shifts might impact this malignancy. Nevertheless, first hints indicate that the microbiome might at least in part explain transcriptional heterogeneity and that microbial approaches could serve in diagnosis and prognosis. Shaping the microbiome could be a treatment option to maintain stable disease. Here, we review current knowledge of transcriptional heterogeneity of and microbial influences on CTCL. We discuss potential benefits of microbial applications and microbial directed therapies to aid patients with CTCL burden.

Lack of PRAME Expression in Cutaneous T-Cell Lymphomas.

Cutaneous T-cell lymphomas (CTCLs) are rare tumors with no established markers that can reliably distinguish between benign and malignant lesions. Preferentially Expressed Antigen in Melanoma (PRAME) is a cancer/testis antigen that is found in many solid and hematologic malignancies. PRAME overexpression typically portends a poor prognosis and lower chemotherapeutic response. To date, no studies have established a role for PRAME in CTCL. An analysis was performed on 47 cases definitively diagnosed as CTCL: 25 cases of mycosis fungoides, 2 of Sezary syndrome, 5 of CD30+ lymphoproliferative disorder, 7 of primary cutaneous anaplastic large T-cell lymphoma, 3 of primary cutaneous CD4+ small/medium T-cell lymphoproliferative disorder, 1 of subcutaneous panniculitis-like T-cell lymphoma, and 4 of angiocentric T-cell lymphoma. PRAME immunohistochemistry was completely negative in all cases. PRAME expression was not found in any CTCL subtypes, suggesting that the pathogenesis of CTCL is not mediated by PRAME. Further study is required to identify biomarkers that might aid in the diagnosis and prognostication of CTCLs.

Malignant and Benign T Cells Constituting Cutaneous T-Cell Lymphoma.

Cutaneous T-cell lymphoma (CTCL) is a heterogeneous group of non-Hodgkin lymphoma, including various clinical manifestations, such as mycosis fungoides (MF) and Sézary syndrome (SS). CTCL mostly develops from CD4 T cells with the skin-tropic memory phenotype. Malignant T cells in MF lesions show the phenotype of skin resident memory T cells (TRM), which reside in the peripheral tissues for long periods and do not recirculate. On the other hand, malignant T cells in SS represent the phenotype of central memory T cells (TCM), which are characterized by recirculation to and from the blood and lymphoid tissues. The kinetics and the functional characteristics of malignant cells in CTCL are still unclear due, in part, to the fact that both the malignant cells and the T cells exerting anti-tumor activity possess the same characteristics as T cells. Capturing the features of both the malignant and the benign T cells is necessary for understanding the pathogenesis of CTCL and would lead to new therapeutic strategies specifically targeting the skin malignant T cells or benign T cells.

Bio-P-03 - Bioinformatics insights in etiopathogenesis, diagnosis and therapy of cutaneous T-cell lymphoma

<h3>Introduction:</h3> The pathogenesis of cutaneous T-cell lymphoma (CTCL) remains poorly understood and the histologic diagnosis of early MF is one of the most vexing problems in dermatopathology. Our aim was to apply state-of-the-art bioinformatic tools in order to unravel the mechanisms of CTCL pathobiology, to address new therapeutic possibilities as well as to identify potential biomarkers. <h3>Materials and methods:</h3> Datasets selection: we searched the GEO (http://www.ncbi.nlm.nih.gov/geo/) for gene (GSE143382) and miRNA (GSE109421) expression datasets containing early-stage MF samples and reactive skin lesions (inflammatory dermatosis) as control. Differential expression data analysis: was performed in R programming language using the LIMMA R package. Differentially expressed genes (DEGs) were selected by applying selection thresholds of adjusted p-value < 0.05 and absolute (log2FC) ≥1 (i.e. FC ≥2 or FC ≤0.5). For the case of differentially expressed miRNAs (DEMs) we used as selection criteria the p-value <0.05 and the FC ≥1.2 for the overexpressed miRNAs and FC ≤0.83 for the under-expressed ones. Pathway Enrichment Analysis using DEGs: was performed using the Enrichr, a web-based tool for analyzing gene sets that returns any enrichment of common annotated biological features (https://maayanlab.cloud/Enrichr/). Pathway Enrichment Analysis using DEMs: was performed using the DIANA-mirPath which is a miRNA pathway analysis web-server, which can utilize experimentally validated miRNA interactions derived from DIANA-TarBase v6.0. The enrichment was obtained using information from KEGG Human and the most significantly enriched pathways were selected based on the p-value <0.05. <h3>Results:</h3> Our bioinformatics analysis detected: A list of DEGs in CTCL which are associated with increased cell proliferation decreased apoptosis, increased Th2 differentiation and immune activation leading to generation of malignant CD4+ T-cells clones, propagating the disease. A list of DEMs in CTCL. A more restricted set of overexpressed miRNAs (miR-26a, miR-92a, miR-106b, miR-142, miR-146a, miR-155, miR-181a, miR-222 and miR-494) were selected and could be therefore used as biomarkers. A number of pathways that have been extracted from the genes and miRNAs implicated in the pathogenesis of CTCL and can enlighten its etiopathogenesis. Fourteen percent (14%) of the pathways were common in both analyses including TGF-beta signaling pathway, Pathways in cancer, PI3K-Akt signaling pathway and p53 signaling pathway. <h3>Conclusion:</h3> In this project, the tools of bioinformatics were used as a stepping-stone in a combined approach highlighting differentially expressed genes and miRNAs as well as the implicated pathways involved in CTCL development. These findings formed a resource of genes and miRNAs that will be further tested in vitro and in vivo in order to identify the etiopathogenesis of the disease, discover biomarkers for diagnosis and highlight new therapeutic targets.

Bio-P-08 - Mode-of-action of HDAC inhibitor resminostat in CTCL

Cutaneous T cell lymphoma (CTCL) is a non-Hodgkin lymphoma characterized by malignant skin-homing T cells with an increasing bias towards the T helper cell type 2 (Th2) during disease progression. Patients with advance CTCL have a high disease burden and the majority of CTCL patients suffer from severe itching (pruritus). A key challenge in the treatment of advanced CTCL is to maintain and to stabilize initial therapeutic responses after systemic treatment. Addressing this clinical need, the oral class I, IIb, IV HDAC inhibitor resminostat is currently under clinical evaluation for disease control after systemic therapy (RESMAIN, NCT02953301). Here, the mode-of-action of resminostat was explored. Several CTCL cell lines representing mycosis fungoides (MF) and Sézary syndrome (SS) were used in cell biological and molecular assays. HDAC inhibitors are epigenetic drugs that alter the chromatin landscape and the expression of genes. Indicating an interference with epigenetic processes, resminostat induced hyperacetylation on specific histone residues linked with transcriptional regulation. Whole transcriptome analysis upon resminostat treatment uncovered changes in oncogenic signaling pathways and in the expression of genes associated with the pathogenesis of CTCL. The expression of several skin-homing receptors, which mediate the infiltration of malignant T cells into the skin, was reduced by resminostat. Furthermore, resminostat up-regulated a gene expression signature representative of Th1 cell type and down-regulated genes of the Th2 cell type, thus favoring the beneficial Th1 T cell phenotype. In agreement with this observation, resminostat decreased the mRNA level and protein secretion of the Th2 and itch-mediating cytokine IL-31 suggesting that resminostat might improve pruritus. Moreover, resminostat treatment resulted in anti-proliferative and pro-apoptotic effects in both MF and SzS cells. In addition to counteracting intrinsic pathogenic pathways in malignant CTCL cells, we found that resminostat enhanced natural killer cell-mediated lysis, thus promoting the innate immune response towards malignant cells. In contrast to reports for other HDAC inhibitors, resminostat did not reduce the viability or function of NK cells but directly positively affected their cytolytic function. Moreover, resminostat up-regulated the expression NKG2D-ligands on cancer cells and, thereby, facilitates the recognition of cancer cells by NK cells. Interestingly, the combination of resminostat with opsonizing antibodies (e.g. Mogamulizumab, IPH4102) improved the lysis of CTCL cells in NK cell assays, suggesting a potential of resminostat's combinations with opsonizing antibodies. Taken together, these data corroborate that resminostat has the potential to counteract the malignant T cell population in CTCL. In conclusion, our preclinical data support the hypothesis that resminostat treatment will improve or stabilize CTCL and its symptoms.