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Exploring the Molecular Landscape of Cutaneous Melanoma

Mitra, Shamik LU (2020) In Lund University, Faculty of Medicine Doctoral Dissertation Series
Abstract
Cutaneous malignant melanoma (CMM) is one of the most aggressive skin malignancies with poor prognosis
for the patients with metastatic disease. Earlier studies have highlighted the existing molecular diversity
amongst CMM tumors. Such diversity does not result from the malignant cells alone but a product of multitude
of complex interactions among the melanoma and non-melanoma cells in the tumor microenvironment. The
studies included in this thesis aims to shed light on some aspects of this observed diversity, chiefly the roles of
the tumor-enriching immune cells and melanoma cell phenotypes.
In study I, we have identified immune cell-type associated DNA methylation patterns that have offered important
molecular... (More)
Cutaneous malignant melanoma (CMM) is one of the most aggressive skin malignancies with poor prognosis
for the patients with metastatic disease. Earlier studies have highlighted the existing molecular diversity
amongst CMM tumors. Such diversity does not result from the malignant cells alone but a product of multitude
of complex interactions among the melanoma and non-melanoma cells in the tumor microenvironment. The
studies included in this thesis aims to shed light on some aspects of this observed diversity, chiefly the roles of
the tumor-enriching immune cells and melanoma cell phenotypes.
In study I, we have identified immune cell-type associated DNA methylation patterns that have offered important
molecular and prognostic information for the metastatic melanoma (MM) tumors. Additionally, these immune-methylation
patterns highlighted the existing microenvironmental resemblance among tumor types with diverse
tissue-of-origin. We further explored the immune-microenvironment of MM tumors using single-cell RNAsequencing
derived marker genes and devised transcriptomic scores for the underlying major immune celltypes
in study II. These immune cell-type scores were found to have prognostic implications and were predictive
of treatment benefit from immunotherapy. In study III, we investigated predictive biomarkers for the treatment
benefit to adoptive T cell (ACT) therapy. Our analyses revealed that tumor mutational and putative neoantigen
burden together with immune enrichment, could work as a composite biomarker to predict treatment benefit
and patient survival upon treated with ACT.
Plasticity of the melanoma cell phenotypes has garnered significant attention in recent times, especially as a
possible mechanism of secondary resistance to targeted treatments. Epigenetic mechanisms such as DNA
methylation is well-known to play a major role in the transcriptional process and their involvement have been
highlighted in context of cancers as well. In study IV, we analyzed the possible contribution of the DNA
methylation to modulate expression of the important melanoma-associated genes such as MITF and SOX10.
Our results indicated that both these genes are likely to be transcriptionally modulated through DNA hypermethylation
of their promoter regions and subsequently help the underlying cells to exhibit a more proliferative,
invasive and treatment-resistant phenotype.
Studies in this thesis have helped to unravel the existing molecular diversity in the CMM tumors and could
potentially motivate the exploration of new therapeutic strategies. (Less)
Please use this url to cite or link to this publication:
author
supervisor
opponent
  • Dr. Robles Espinoza, Carla Daniela, LIIGH-UNAM, Santiago de Queretaro, Mexico
organization
publishing date
type
Thesis
publication status
published
subject
keywords
Melanoma, Immune System, Tumor Microenvironment, Epigenetics, MITF, SOX10
in
Lund University, Faculty of Medicine Doctoral Dissertation Series
issue
2020:66
pages
92 pages
publisher
Lund University, Faculty of Medicine
defense location
Föreläsningssal E24, Medicon Village, Scheleevägen 2, Byggnad 404, Lund
defense date
2020-05-25 13:00:00
ISSN
1652-8220
ISBN
978-91-7619-927-5
project
BioMEL
language
English
LU publication?
yes
id
1484c56d-57aa-4d7b-ad00-4e7dc4444abb
date added to LUP
2020-04-28 10:59:25
date last changed
2020-05-19 13:09:10
@phdthesis{1484c56d-57aa-4d7b-ad00-4e7dc4444abb,
  abstract     = {{Cutaneous malignant melanoma (CMM) is one of the most aggressive skin malignancies with poor prognosis<br/>for the patients with metastatic disease. Earlier studies have highlighted the existing molecular diversity<br/>amongst CMM tumors. Such diversity does not result from the malignant cells alone but a product of multitude<br/>of complex interactions among the melanoma and non-melanoma cells in the tumor microenvironment. The<br/>studies included in this thesis aims to shed light on some aspects of this observed diversity, chiefly the roles of<br/>the tumor-enriching immune cells and melanoma cell phenotypes.<br/>In study I, we have identified immune cell-type associated DNA methylation patterns that have offered important<br/>molecular and prognostic information for the metastatic melanoma (MM) tumors. Additionally, these immune-methylation<br/>patterns highlighted the existing microenvironmental resemblance among tumor types with diverse<br/>tissue-of-origin. We further explored the immune-microenvironment of MM tumors using single-cell RNAsequencing<br/>derived marker genes and devised transcriptomic scores for the underlying major immune celltypes<br/>in study II. These immune cell-type scores were found to have prognostic implications and were predictive<br/>of treatment benefit from immunotherapy. In study III, we investigated predictive biomarkers for the treatment<br/>benefit to adoptive T cell (ACT) therapy. Our analyses revealed that tumor mutational and putative neoantigen<br/>burden together with immune enrichment, could work as a composite biomarker to predict treatment benefit<br/>and patient survival upon treated with ACT.<br/>Plasticity of the melanoma cell phenotypes has garnered significant attention in recent times, especially as a<br/>possible mechanism of secondary resistance to targeted treatments. Epigenetic mechanisms such as DNA<br/>methylation is well-known to play a major role in the transcriptional process and their involvement have been<br/>highlighted in context of cancers as well. In study IV, we analyzed the possible contribution of the DNA<br/>methylation to modulate expression of the important melanoma-associated genes such as MITF and SOX10.<br/>Our results indicated that both these genes are likely to be transcriptionally modulated through DNA hypermethylation<br/>of their promoter regions and subsequently help the underlying cells to exhibit a more proliferative,<br/>invasive and treatment-resistant phenotype.<br/>Studies in this thesis have helped to unravel the existing molecular diversity in the CMM tumors and could<br/>potentially motivate the exploration of new therapeutic strategies.}},
  author       = {{Mitra, Shamik}},
  isbn         = {{978-91-7619-927-5}},
  issn         = {{1652-8220}},
  keywords     = {{Melanoma; Immune System; Tumor Microenvironment; Epigenetics; MITF; SOX10}},
  language     = {{eng}},
  number       = {{2020:66}},
  publisher    = {{Lund University, Faculty of Medicine}},
  school       = {{Lund University}},
  series       = {{Lund University, Faculty of Medicine Doctoral Dissertation Series}},
  title        = {{Exploring the Molecular Landscape of Cutaneous Melanoma}},
  url          = {{https://lup.lub.lu.se/search/files/78946493/Shamik_Mitra_PhD_thesis_wo_papers.pdf}},
  year         = {{2020}},
}