T cells in testicular germ cell tumors: new evidence of fundamental contributions by rare subsets.

BACKGROUND: Immune cell infiltration is heterogeneous but common in testicular germ cell tumors (TGCT) and pre-invasive germ cell neoplasia in situ (GCNIS). Tumor-infiltrating T cells including regulatory T (Treg) and follicular helper T (Tfh) cells are found in other cancer entities, but their contributions to TGCT are unknown. METHODS: Human testis specimens from independent patient cohorts were analyzed using immunohistochemistry, flow cytometry and single-cell RNA sequencing (scRNA-seq) with special emphasis on delineating T cell subtypes. RESULTS: Profound changes in immune cell composition within TGCT, shifting from macrophages in normal testes to T cells plus B and dendritic cells in TGCT, were documented. In most samples (96%), the CD4+ T cell frequency exceeded that of CD8+ cells, with decreasing numbers from central to peripheral tumor areas, and to tumor-free, contralateral testes. T cells including Treg and Tfh were most abundant in seminoma compared to mixed tumors and embryonal carcinoma. CONCLUSION: Despite considerable heterogeneity between patients, T cell subtypes form a key part of the TGCT microenvironment. The novel finding of rare Treg and Tfh cells in human testis suggests their involvement in TGCT pathobiology, with implications for understanding tumor progression, to assess patients' prognosis, and as putative targets for personalized immunotherapy.

The changing landscape of immune cells in the fetal mouse testis.

Fetal testis growth involves cell influx and extensive remodeling. Immediately after sex determination in mouse, macrophages enable normal cord formation and removal of inappropriately positioned cells. This study provides new information about macrophages and other immune cells after cord formation in fetal testes, including their density, distribution, and close cellular contacts. C57BL6J mouse testes from embryonic day (E) 13.5 to birth (post-natal day 0; PND0), were examined using immunofluorescence, immunohistochemistry, and RT-qPCR to identify macrophages (F4/80, CD206, MHCII), T cells (CD3), granulocytes/neutrophils (Ly6G), and germ cells (DDX4). F4/80+ cells were the most abundant, comprising 90% of CD45+ cells at E13.5 and declining to 65% at PND0. Changes in size, shape, and markers (CD206 and MHCII) documented during this interval align with the understanding that F4/80+ cells have different origins during embryonic life. CD3+ cells and F4/80-/MHCII+ were absent to rare until PND0. Ly6G+ cells were scarce at E13.5 but increased robustly by PND0 to represent half of the CD45+ cells. These immunofluorescence data were in accord with transcript analysis, which showed that immune marker mRNAs increased with testis age. F4/80+ and Ly6G+ cells were frequently inside cords adjacent to germ cells at E13.5 and E15.5. F4/80+ cells were often in clusters next to other immune cells. Macrophages inside cords at E13.5 and E15.5 (F4/80Hi/CD206+) were different from macrophages at PND0 (F4/80Dim/CD206-), indicating that they have distinct origins. This histological quantification coupled with transcript information identifies new cellular interactions for immune cells in fetal testis morphogenesis, and highlights new avenues for studies of their functional significance.

Cytokines in Male Fertility and Reproductive Pathologies: Immunoregulation and Beyond.

Germline development in vivo is dependent on the environment formed by somatic cells and the differentiation cues they provide; hence, the impact of local factors is highly relevant to the production of sperm. Knowledge of how somatic and germline cells interact is central to achieving biomedical goals relating to restoring, preserving or restricting fertility in humans. This review discusses the growing understanding of how cytokines contribute to testicular function and maintenance of male reproductive health, and to the pathologies associated with their abnormal activity in this organ. Here we consider both cytokines that signal through JAKs and are regulated by SOCS, and those utilizing other pathways, such as the MAP kinases and SMADs. The importance of cytokines in the establishment and maintenance of the testis as an immune-privilege site are described. Current research relating to the involvement of immune cells in testis development and disease is highlighted. This includes new data relating to testicular cancer which reinforce the understanding that tumorigenic cells shape their microenvironment through cytokine actions. Clinical implications in pathologies relating to local inflammation and to immunotherapies are discussed.

Specific immune cell and cytokine characteristics of human testicular germ cell neoplasia.

STUDY QUESTION: Which immune cells and cytokine profiles are characteristic for testicular germ cell neoplasia and what consequences does this have for the understanding of the related testicular immunopathology? SUMMARY ANSWER: The unique immune environment of testicular germ cell neoplasia comprises B cells and dendritic cells as well as high transcript levels of IL-6 and other B cell supporting or T helper cell type 1 (Th1)-driven cytokines and thus differs profoundly from normal testis or inflammatory lesions associated with hypospermatogenesis. WHAT IS KNOWN ALREADY: T cells are known to be the major component of inflammatory infiltrates associated with either hypospermatogenesis or testicular cancer. It has previously been reported that B cells are only involved within infiltrates of seminoma samples, but this has not been investigated further. STUDY DESIGN, SIZE, DURATION: Immunohistochemical characterisation (IHC) of infiltrating immune cells and RT-qPCR-based analysis of corresponding cytokine microenvironments was performed on different testicular pathologies. Testicular biopsies, obtained from men undergoing andrological work-up of infertility or taken during surgery for testicular cancer, were used in this study. Samples were grouped as follows: (i) normal spermatogenesis (n = 18), (ii) hypospermatogenesis associated with lymphocytic infiltrates (n = 10), (iii) samples showing neoplasia [germ cell neoplasia in situ (GCNIS, n = 26) and seminoma, n = 18]. PARTICIPANTS/MATERIALS, SETTING, METHODS: IHC was performed using antibodies against T cells (CD3+), B cells (CD20cy+), dendritic cells (CD11c+), macrophages (CD68+) and mast cells (mast cell tryptase+). Degree and compartmental localisation of immune cells throughout all groups analysed was evaluated semi-quantitatively. RT-qPCR on RNA extracted from cryo-preserved tissue samples was performed to analyse mRNA cytokine expression, specifically levels of IL-1ß, IL-6, IL-17a, tumour necrosis factor (TNF)-α (pro-inflammatory), IL-10, transforming growth factor (TGF)-ß1 (anti-inflammatory), IL-2, IL-12a, IL-12b, interferon (IFN)-γ (Th1-driven), IL-4, IL-5, IL-13, IL-23a (Th2-driven), CXCL-13, CXCL-10 and CCL-5 (chemokines). MAIN RESULTS AND THE ROLE OF CHANCE: This is the first study showing a direct linkage between the distribution pattern of immune cells in hypospermatogenesis versus testicular cancer and analysis of a wide range of 17 related cyto- and chemokines. A fundamental difference between testicular inflammation patterns associated with different testicular inflammatory conditions either containing or lacking neoplastic cells was demonstrated. In hypospermatogenesis, T cells were detected, whereas B cells and dendritic cells were almost absent. Within GCNIS and seminoma, in addition to T cells, high numbers of dendritic cells and B cells were found, the latter additionally organised in cell clusters, whereas mast cells were absent. Transcripts encoding pro-inflammatory cytokines (IL-1ß, IL-6 and TNF-α), anti-inflammatory cytokines (TGF-ß1), Th1-driven cytokines (IL-2 and IFN-γ) as well as chemokines (CXCL-13, CXCL-10 and CCL-5) were all significantly increased in testicular germ cell neoplasia (P ≤ 0.01), suggesting the presence of a pro-tumorigenic environment. In contrast, Th2-related cytokines (IL-5, IL-13 and IL-23a) characterised the environment within samples showing normal spermatogenesis as well as hypospermatogenesis. One of the most important outcomes is the pivotal role of IL-6 in testicular cancer that opens potential novel diagnostic and/or immune-therapeutic perspective for testis cancer. LIMITATIONS, REASONS FOR CAUTION: Testicular tissue composed of immune cells as well as other somatic cells and germ cells does not allow identification of specific cytokine sources or single cell types, being responsible for establishing the overall cytokine environment. In this study, laser-assisted microdissection did not reach the required efficiency for RT-qPCR analyses. Therefore, in vitro models would be suggested for addressing the above-mentioned issue. Conclusions about cytokine levels in testes with GCNIS are based on a small number of samples. WIDER IMPLICATIONS OF THE FINDINGS: The unique B cell presence and the significantly increased expression level of IL-6 in testicular germ cell neoplasia (P < 0.001) strengthen its special role in this disease. In line with current knowledge on other types of cancer, these results underline the relevance of further investigating the potential of IL-6 as early biomarker and target for therapeutic intervention in testicular germ cell neoplasia. STUDY FUNDING/COMPETING INTERESTS: This study (and B.K. in person) was supported by the Deutsche Forschungsgemeinschaft (DFG) as part of the International Research Training Group between Justus Liebig University of Giessen and Monash University, Melbourne (GRK 1871/1) on 'Molecular pathogenesis on male reproductive disorders'. T.H., H.-C.S. and M.B. were supported by the LOEWE focus group 'MIBIE' (male infertility during infection & inflammation)-an excellence initiative of the German state government of Hessen. From the Australian side, K.L. was supported by NHMRC grants (Fellowship, ID1079646 and Project, ID1081987); K.L., S.I. and M.H. received scholarship (S.I.) and research funding (K.L., M.H.) from Monash University. The project also drew support from the Victorian Government's Operational Infrastructure Support Program. The authors have no competing interests to declare.

Cardiomyocyte apoptosis vs autophagy with prolonged doxorubicin treatment: comparison with osteosarcoma cells.

OBJECTIVE: Doxorubicin (Dox) is a frontline chemotherapeutic against osteosarcoma (OS) that is plagued by side effects, particularly in the heart. The specific objective of this article is to investigate whether low-dose Dox treatment had pro-autophagic effects in cardiomyocytes as well as osteosarcoma cells. METHODS: This study characterises apoptotic (Bax) and autophagic (Beclin-1) biomarker levels in human OS and cardiomyocyte cell lines as well as in various tissues when mice are exposed to low (1 mg/kg, thrice weekly) and high (3 mg/kg thrice weekly) dose Dox for a month. KEY FINDINGS: There was a decrease in Bax and increase in Beclin-1 in cardiac tissue in the high-dose group. Dox decreased Beclin-1 in the skin and liver, with no clear indication in the stomach, small intestine and testis. At low Dox doses of 10 and 100 nm in cardiomyocytes and OS cells, there is a pro-apoptotic effect, with a quicker response in the 100-nm condition, and a slower but steady increase of a pro-apoptotic response at the lower 10-nm dose. However, electron microscopy images revealed changes to human OS cells that resembled autophagy. Human prostate, breast and colorectal cells treated with 10-nm Dox showed ∼ 40% reduction in cell viability after 24 h. CONCLUSION: In culture, cells of both cardiomyocytes and OS revealed a predominant pro-apoptotic response at the expense of autophagy, although both seemed to be occurring in vivo.

The potential role of free chitosan in bone trauma and bone cancer management.

Bone defects caused by fractures or cancer-mediated destruction are debilitating. Chitosan is commonly used in scaffold matrices for bone healing, but rarely as a free drug. We demonstrate that free chitosan promotes osteoblast proliferation and osteogenesis in mesenchymal stem cells, increases osteopontin and collagen I expression, and reduces osteoclastogenesis. Chitosan inhibits invasion of endothelial cells, downregulating uPA/R, MT1-MMP, cdc42 and Rac1. Better healing of bone fractures with greater trabecular bone formation was observed in mice treated with chitosan. Chitosan induces apoptosis in osteotropic prostate and breast cancer cells via caspase-2 and -3 activation, and reduces their establishment in bone. Chitosan is pro-apoptotic in osteosarcoma cells, but not their normal counterpart, osteoblasts, or chondrosarcoma cells. Systemic delivery of chitosan does not perturb angiogenesis, bone volume or instinctive behaviour in pregnant mice, but decreases foetal length and changes pancreatic secretory acini. With certain controls in place, chitosan could be useful for bone trauma management.

Finding chemo: the search for marine-based pharmaceutical drugs active against cancer.

OBJECTIVES: Cancer affects the health of many people globally. The most common treatment that is used for cancer is chemotherapy, which has shown promising results but not without side effects. Some of these side effects jeopardise further treatment, and this eventually leads to advanced stages of malignancy and mortality. As a result, there is a need for better and safer anticancer compounds such as those found naturally. One of the most abundant natural environments to find such compounds is the sea, and this vast resource has been biomined since the 1950s. KEY FINDINGS: There are currently three marine anticancer agents marketed (Yondelis, Cytosar-U and Halaven), with several others undergoing clinical trials. This review discusses marine-derived products in clinical use and in clinical trials, and discusses available literature on the growth suppression or pro-apoptotic properties of these compounds, and the molecular mechanisms underpinning these cell biological phenomena. SUMMARY: The marine environment may hold promising anticancer compounds within its depths, warranting further research to be performed in this area, albeit with respect for the natural ecosystems that are being explored for drug discover and subsequently used for drug development.