Jochen T. Schaefer scite author profile

Immune cells infiltrating the microenvironment of melanoma metastases may either limit or promote tumor progression, but the characteristics that distinguish these effects are obscure. In this study, we systematically evaluated the composition and organization of immune cells that infiltrated melanoma metastases in human patients. Three histologic patterns of immune cell infiltration were identified, designated immunotypes A, B and C. Immunotype A was characterized by no immune cell infiltrate. Immunotype B was characterized by infiltration of immune cells limited only to regions proximal to intratumoral blood vessels. Immunotype C was characterized by a diffuse immune cell infiltrate throughout a metastatic tumor. These immunotypes represented 29%, 63%, and 8% of metastases with estimated median survival periods of 15, 23, and 130 months, respectively. Notably, all three immunotypes showed increasing proportions of B cells and decreasing proportions of macrophages. Overall, the predominant immune cells were T cells (53%), B cell lineage cells (33%), and macrophages (13%), with NK and mature dendritic cells only rarely present. While higher densities of CD8+ T cells correlated best with survival, a higher density of CD45+ leukocytes, T cells, and B cells also correlated with increased survival. Together, our findings reveal striking differences in the immune infiltrate in melanoma metastases in patients, suggesting microenvironmental differences in immune homing receptors and ligands that affect immune cell recruitment. These findings are important, not only by revealing how the immune microenvironment can affect outcomes but also because they reveal characteristics that may help improve individualized therapy for patients with metastatic melanoma.

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Imaging mass spectrometry assists in the classification of diagnostically challenging atypical Spitzoid neoplasms

Lazova

Seeley²,

Kutzner

et al. 2016

Journal of the American Academy of Dermatology

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Dynamic changes in cellular infiltrates with repeated cutaneous vaccination: a histologic and immunophenotypic analysis

et al. 2010

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BackgroundMelanoma vaccines have not been optimized. Adjuvants are added to activate dendritic cells (DCs) and to induce a favourable immunologic milieu, however, little is known about their cellular and molecular effects in human skin. We hypothesized that a vaccine in incomplete Freund's adjuvant (IFA) would increase dermal Th1 and Tc1-lymphocytes and mature DCs, but that repeated vaccination may increase regulatory cells.MethodsDuring and after 6 weekly immunizations with a multipeptide vaccine, immunization sites were biopsied at weeks 0, 1, 3, 7, or 12. In 36 participants, we enumerated DCs and lymphocyte subsets by immunohistochemistry and characterized their location within skin compartments.ResultsMature DCs aggregated with lymphocytes around superficial vessels, however, immature DCs were randomly distributed. Over time, there was no change in mature DCs. Increases in T and B-cells were noted. Th2 cells outnumbered Th1 lymphocytes after 1 vaccine 6.6:1. Eosinophils and FoxP3+ cells accumulated, especially after 3 vaccinations, the former cell population most abundantly in deeper layers.ConclusionsA multipeptide/IFA vaccine may induce a Th2-dominant microenvironment, which is reversed with repeat vaccination. However, repeat vaccination may increase FoxP3+T-cells and eosinophils. These data suggest multiple opportunities to optimize vaccine regimens and potential endpoints for monitoring the effects of new adjuvants.Trail RegistrationClinicalTrials.gov Identifier: NCT00705640

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The Vaccine-site Microenvironment Induced by Injection of Incomplete Freund's Adjuvant, With or Without Melanoma Peptides

Harris

Chianese‐Bullock²,

Petroni³

et al. 2012

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Cancer vaccines have not been optimized. They depend on adjuvants to create an immunogenic microenvironment for antigen presentation. However, remarkably little is understood about cellular and molecular changes induced by these adjuvants in the vaccine microenvironment. We hypothesized that vaccination induces dendritic cell activation in the dermal vaccination microenvironment but that regulatory processes may also limit the effectiveness of repeated vaccination. We evaluated biopsies from immunization sites in two clinical trials of melanoma patients. In one study (Mel38), patients received one injection with an adjuvant mixture alone, comprised of incomplete Freund's adjuvant (IFA) plus granulocyte-macrophage colony stimulating factor (GM-CSF). In a second study, patients received multiple vaccinations with melanoma peptide antigens plus IFA. Single injections with adjuvant alone induced dermal inflammatory infiltrates consisting of B cells, T cells, mature dendritic cells (DC) and vessels resembling high endothelial venules (HEV). These cellular aggregates usually lacked organization and were transient. In contrast, multiple repeated vaccinations with peptides in adjuvant induced more organized and persistent lymphoid aggregates containing separate B and T cell areas, mature DC, HEV-like vessels, and lymphoid chemokines. Within these structures, there are proliferating CD4+ and CD8+ T lymphocytes, as well as FoxP3+CD4+ lymphocytes, suggesting a complex interplay of lymphoid expansion and regulation within the dermal immunization microenvironment. Further study of the physiology of the vaccine site microenvironment promises to identify opportunities for enhancing cancer vaccine efficacy by modulating immune activation and regulation at the site of vaccination.

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