key: cord-0922753-n40m9uya
authors: Jantuan, Eugeniu; Chiu, Brian; Chiu, Bonnie; Shen, Fan; Oudit, Gavin Y; Sergi, Consolato
title: The tumor microenvironment may trigger lymphoproliferation in cardiac myxoma
date: 2020-10-23
journal: Transl Oncol
DOI: 10.1016/j.tranon.2020.100911
sha: 1266a57f01e3a7dc6aa48ef311b9d33c7be3676b
doc_id: 922753
cord_uid: n40m9uya

Cardiac myxomas (CM) and primary cardiac lymphoproliferative disorders (LPD) are rare primary cardiac neoplasms. The composite occurrence of LPD in CM has been occasionally reported, and chronic inflammation in response to viral infection has been suggested to be at the basis of oncogenesis. Cancers can upregulate autophagy to endure microenvironmental stress and to increase local growth and aggressiveness. CM exhibit a dichotomous separation in low and high inflammatory grades (LIG vs. HIG). We studied 23 CMs using autophagy-related proteins and NanoString technology for gene expression. Autophagy-related proteins (Beclin-1, LAMP-1, LC3, and p62) were demonstrated in both tumor and stromal cells. ATG genes showed a progression of involvement in CM using an 8-gene signature. They were associated with Epstein-Barr virus (EBV) encoded latent membrane protein 1 (EBV LMP1) activation. We suggest that CM can upregulate autophagy, creating a favorable environment for EBV-driven oncogenesis. To the best of our knowledge, the present study is the first to report on the TME using the expression of autophagy-related genes and proteins in CM. The microenvironment of CM is dynamic, with a variety of cell types and different molecular pathways at play, and this study may clearly warrant further investigation.

Cardiac myxoma (CM) is the most common primary cardiac tumor [ 1-4 , 5] . Lepidic cells in a sparsely cellular myxoid stroma with cord-like, pseudo-vascular, or vasoformative growth patterns characterize this tumor [4] . Chronic inflammation, fibroblastic proliferation, dystrophic calcification, and even ossification within the CM have also been described [4] . These tumors are histologically benign, slow-growing neoplasms of unclear histogenesis, but may be associated with heart failure and/or cardiac arrhythmias [6 -9] . They are most commonly sporadic, but up to 10% are associated with the Carney complex with a familial inheritance pattern [10 -13] . Viral histogenesis has recently been entertained in some studies [14 , 15] , but refuted by others [16 -18] . Lymphoproliferative disorders (LPD) primarily involving the heart (primary cardiac lymphoma/lymphoproliferative disorders PC-LPD) are infrequent [19] , and such tumors arising in CM as composite tumors are unique.

Interestingly, all LPD were found incidentally on microscopic examination of excised CM specimens [19] [20] [21] [22] ( Supplemental Table 1 ). Lymphomas of B-cell phenotype may indeed co-exist with CM, the majority of which are diffuse large B-cell lymphoma (DLBCL). In up to 4/5 of patients, Epstein-Barr virus (EBV) infection can be detected. Despite the central nervous system (CNS) involvement due to tumor embolization [21] , these patients usually present with clinical-stage 1E (localized involvement of a single extra lymphatic/extranodal myxoma) [19] . These patients with post-surgical resection of the LPD arising in CM (LPD-CM) with or without chemotherapy or radiation therapy, on follow-up periods ranging from 3 months to 10 years, exhibit no evidence of lymphoma recurrence or dissemination [19 , 20 , 23] .

The pathogenetic mechanism of LPD-CM has not been substantially elucidated, but some dysregulation of the immune surveillance has been occasionally postulated [19 , 20 , 23] . The association of DLBCL with EBV infection but without underlying systemic immunosuppression may suggest an age-related decline of adaptive immunity or immune senes-cence, and an EBV has driven LPD transformation in a cytokine-rich milieu of a CM [20] . The presence of chronic inflammatory foci in LPD-CM is further supportive of the mechanistic explanation of local production of cytokines in stimulating the development of LPD associated with chronic inflammation [20 , 24] . Restriction of tumor cell proliferation to the CM environment with no evidence of lymphoma recurrence or dissemination is also intriguing. CM may create an enclosed microenvironment permitting accumulation of cytokines and EBVinfected B-cells that can evade T-cell immunosurveillance [21 , 25 -27] .

It is now well established that neoplasms co-evolve with the tumor microenvironment (TME) [28] . The TME includes stromal cells, including vasculature, fibroblasts, adipocytes, and different subsets of immune cells. It plays a crucial role in carcinogenesis, cancer progression, dissemination, and resistance to therapy [29 , 30] . There is a growing body of evidence to suggest that autophagy is a vital regulator of the TME and regulating tumor immunity [28 , 29 , 31 , 32] . The multifaceted role of autophagy in the complex cancer TME depends on a specific context. Autophagy may function as a tumor-suppressive mechanism during early tumorigenesis by the elimination of unhealthy intracellular components and proteins, and regulates antigen presentation to and by immune cells supporting anticancer immune response [29 , 31] . Dysregulation of autophagy is likely to contribute to tumor progression by promoting genome damage and instability, and autophagy in stromal cells supplying nutrients to cancer cells may fuel cancer growth in established tumors [31 , 33] . Cancers can upregulate autophagy to endure microenvironmental stress and to increase local growth and aggressiveness.

Autophagy is an evolutionarily conserved intracellular process that enables the degradation and recycling of long-lived large molecules or damaged organelles using the lysosomal-mediated pathway [34 -38] . Autophagy occurs constitutively at low basal levels and in the maintenance of normal cellular homeostasis but is induced in response to many types of stress [36 , 39] . Autophagy dysregulation has been linked to the development of heart failure, infection, tumorigenesis, neurodegeneration, and aging [32 , 34 , 36 , 37] . The molecular mechanisms of autophagy have been extensively reviewed, and the TME can be investigated targeting autophagy [28 , 34 , 35 , 37] . The induction of autophagy results in the recruitment of autophagy-related proteins (ATG) and isolation membranes to form a cup-shaped structure called the phagophore [35] . Expansion and sealing of the phagophore form a double-membrane vesicle termed the autophagosome. Delivery along microtubules to lysosome and fusion of their outer membranes form an autolysosome. Autophagy can be induced by different kinds of stress, including infection, inflammation, nutrient deprivation, and hypoxia. More than 30 ATG genes have been involved in the autophagy process [38] .

In this study, we aimed to assess the TME in cardiac myxomas. The NanoString R ○ gene expression platform was used for gene expression studies. NanoString is a digital counting technology without any enzymatic reactions and accurate for quantifying linear mRNAs. This method is suitable for analyzing highly degraded RNA isolated from formalinfixed paraffin-embedded (FFPE) tissues that are routinely stored in pathology departments as the probes target short RNA-sequences, and no reverse transcription (RT) or amplification steps are involved. Therefore, NanoString R ○ technology is not prone to artifacts and bias associated with RT and PCR amplification [40] .

Archival CM cases and histopathology . Twenty-eight formalin-fixed and paraffin-embedded (FFPE) human cardiac myxomas were retrieved from files of the University of Alberta Hospital over six years, 2010-2016, and were used for this study. The ethics committee of the University of Alberta (Edmonton, Canada) approved the study (REB Approval no. Pro00057260). We used serial deparaffinated sections (4 mthick) for staining procedures, including hematoxylin and eosin (H&E) and immunohistochemistry. On H&E sections, components of CM-TME were identified, and chronic inflammation was graded as low-and highinflammatory grade (LIG, HIG).

Immunohistochemistry . Four-m thick sections were obtained from each FFPE tissue block. The sections were placed on Aptex glass slides, dewaxed and rehydrated in a graded alcohol series, and stained using the streptavidin-biotin-peroxidase complex method and counterstained according to manufacturers' protocols. A mediastinal lymph node was used as a positive control for autophagy markers. A negative control slide was included in each immunostaining. The primary antibody replaced by the same isotype (IgG) antibody, targeting different antigens. We used the following antibodies 1. Autophagy markers: rabbit polyclonal anti -Beclin 1 (ab55878, 1:200 dilution; Abcam), rabbit polyclonal anti -LAMP 1 (ab24170, 1:1000 dilution; Abcam), rabbit polyclonal anti -LC3B (ab63817, 1:200 dilution; Abcam), SQSTM1/p62 (ab56416 at 1:1000 dilution, Abcam), 2. Myxoma cell markers: CD31, CD34, Calretinin, negative markers: smooth muscle (SM) actin, S100 and vimentin, and 3. Inflammatory cells and lymphoma markers: CD3 (T-cell), CD68 (macrophages), CD45 (leukocyte common antigen), CD20, PAX5, BCl2, BCL6, c-Myc, Ki67(MIB1), CD10, and CD5. 4. Viral markers: HSV1, HSV2, LMP1 (EBV), and EBER by in-situ hybridization (ISH).

Immunostaining results were evaluated, graded, and scored by extent (0 = none, 1 = 1-25%, 2 = 26-50%, 3 = 51-75%, 4 = 76-100% of the myxoma cells) and intensity (0 = negative, 1 = weak, 2 = moderate, and 3 = intense). An immunohistochemical score was calculated for each case in which the percentage of positive rating was multiplied by the intensity rating. The immunostaining was judged to be antibody-specific by following two criteria: staining use of normal serum produced no consistent immunostaining of any cells and signal intensity diminished as the dilution of antibody was increased.

Twenty-three CM blocks were selected for RNA extraction and gene expression analysis. Three successive 20-μm thick sections were obtained from each FFPE tissue block. RNA was obtained with RNeasy FFPE Kit (Qiagen, Toronto, ON), and its concentration and purity were studied with the NanoDrop 2000c spectrophotometer (Thermo Fischer Scientific, Waltham, MA). Oligonucleotide probes were produced for the following human genes: ATG9A, ATG12, ATG14, BECN1, EBV LMP1, LAMP1, MAP1LC3, SQSTM1 , and WIPI1 (Integrated DNA Technologies, Coralville, IA) ( Table 1 ) . For data normalization, three housekeeping human genes were included in the study: GAPDH, HPRT1 , and TBP . Gene expression was quantified with NanoString nCounter platform as per manufacturer recommendations (Nanostring Technologies, Seattle, WA). In detail, with regard to the code set design, a literature search was performed to identify genes involved in autophagy-related cancer biology. The genes selected as a result included three housekeeping genes: GAPDH, HPRT1 , and TBP . Custom nCounter probes for the gene set were designed by NanoString Technologies and manufactured by Integrated DNA Technologies [Coralville, IA, U.S.A.]. Details of the nCounter technology have been reported previously in a report on thyroid cancer by our University [41] . Briefly, a custom nCounter code set consisting of multiplexed probes targeting the gene set was used for gene expression analysis. Each code set included selected housekeeping genes to control for variations in RNA input and quality. Probe pairs with sequences specific to a 100-base region of each target messenger rna were designed using a 3 ′ biotinylated capture probe and a 5 ′ reporter probe tagged with a specific fluorescent barcode, thus creating 2 sequence-specific probes for each target transcript. Probes were hybridized with rna at 65 °C and then applied to the nCounter Preparation Station for automated removal of excess probe and immobilization of probe-transcript complexes on a streptavidin-coated cartridge. Data were collected using the nCounter Digital Analyzer by counting the individual barcodes. Raw gene expression counts were quality-controlled and normalized using the nSolver Analysis Software Table 1 Autophagy-related 8-gene Set (red), EBV LMP-1 (blue), and three housekeeping genes (black).

(version 4.0: NanoString Technologies) and manufacturer-included positive and negative controls. Quality control (qc) parameters include imaging qc, binding density qc, overall assay efficiency, assay linearity, and limit of detection. Data were normalized to the three housekeeping genes to correct for variation in rna input quantity.

Normalized transcript counts were used for individual gene analysis. Differential gene expression was assessed using Student's t -test. Statistical significance was considered at P < 0.05. SPSS version 26 was used.

Histologically, the CM exhibit unique heterogeneous features with myxoma cells scattered in a myxoid stroma. The tumor cells are in single cells, cord-like, pseudo-vascular or vasoformative patterns [42] . The spindle tumor cells without significant atypia surround small blood vessels and scattered lymphoplasmacytic, histiocytic cells, and fibroblastic cells in the myxoma tumor microenvironment ( Fig. 1 ) . The inflammatory infiltration was graded: LIG ( N = 12) and HIG ( N = 11). Two cases of lymphoproliferative disorders arising within CM were encountered in our series: chronic lymphocytic leukemia (CLL) and DLBCL.

Immunohistochemistry i) Cardiac myxoma. Myxoma cells were immune-positive for calretinin, vimentin, CD31, CD34, but negative for SM actin or S100. ii) Autophagy: LAMP 1, Beclin-1, LC3 were strongly immune-positive in the majority of cases (70-92.3%). Nine instances of CM have stained additionally for the SQSTM1/p62 marker. All these cases (100%) express the marker with weak to moderate intensity (1 to 2 + ). Inflammatory cells and vascular cells stained less intensely. CM with DLBCL was negative for the LC3 marker. However, it expressed a robust Beclin-1 intensity (3 + ) ( Fig. 2 ) . iii) Inflammatory cells, LPD, and autophagy: Mixed T-cells, B-cells, and macrophages were seen in the inflammatory infiltrates. Both LPD were confirmed with lymphoma markers as CLL/SLL and high-grade B-cell lymphoma (HG-BCL: MYC and BCL2 rearrangement). Beclin1 and p62 were strongly positive, LAMP1 focally and LC3 only rare cells were immune-positive ( Figs. 2 and 3 ) .

iv) Viral markers: In CLL/SLL, EBV by LMP1 staining was positive, but EBER by ISH was negative. In HG-BCL, EBV-ISH was positive. In selected cases, HSV1 and HSV2 staining was negative.

i) RNA and quality control Mean RNA yield for 23 FFPE samples was 68.2 ± 60.3 (mean ± SD) ng/μL (range 13.4-312.2 ng/μL) with a mean A260/A280 RNA purity ratio of 1.85 ± 0.07 (1.71-1.96). One case (1/24) was excluded from the study due to low 260/280 ratio (1.42) . No significant quality control or normalization issues were encountered. However, 2/8 genes (25%) demonstrated very low counts (close to negative controls) across all samples and were excluded from subsequent analysis: EBV LMP1 (2.9 ± 3.7) and ATG12 (7.4 ± 3.9). ii) All ATG genes were expressed in CM with marked accumulation of SQSTM1/p62, which was 2.5 to 46 folds higher than the remaining ATG genes. When HIG to LIG groups were compared, the HIG group was trending lower, and both MAP1/LC3B and WIPI1 were statistically significant with p -value < 0.05 using the Student's ttest ( Table 2 ) Both LC3B and WIPI1 were associated with autophagosome formation [43] .

Our study confirms that the CM tumor microenvironment (CM-TME) is very complex and dynamic. CM-TME consists of a variety of intrinsic and extrinsic cells and factors/elements: tumor cells, stromal and vascular cells, inflammatory cells, and infective components/organisms with multiple molecular pathways at play. These processes and events are expected as the CM are exposed continuously to circulating cellular or non-cellular elements and extrinsic elements, including infective organisms/factors [26 , 27 , 44 , 45] . LAMP 1, Beclin-1, LC3 were strongly immune-positive in the majority of cases and nine CMs demonstrated an additional expression of the SQSTM1/p62 marker. All these cases expressed this marker with weak to moderate intensity, while inflammatory cells and vascular cells stained less intensely. As indicated above, CM with DLBCL was negative for the LC3 marker, but it expressed strongly Beclin-1 intensity (3 + ). Mixed T-cells, B-cells, and macrophages were seen in the inflammatory infiltrates and both LPD were confirmed with lymphoma markers as CLL/SLL and high-grade B-cell lymphoma (HG-BCL with MYC and BCL2 rearrangement). Here, both Beclin1 and Notes: CM, cardiac myxoma; LIG, lower inflammation grade; HIG, high inflammation grade.

p62 were strongly positive, while LAMP1 was focally positive and LC3 was positive in only very few cells. Consistent with the immunohistochemical results of positive autophagy activity, all autophagy-related genes were expressed in the LIG and HIG groups. It seems that all steps in the autophagy process are active. However, there is marked p62 excessive expression (ranging from 2.5 to 46 folder increase compared with the other ATG studied). Further, p62 accumulates when autophagy is inhibited, and aberrant excessive p62 accumulation may result from autophagy defect, causing oxidative stress and has been linked to tumorigenesis [46 , 47] . Autophagy gene expressions are trending lower in high inflammatory grades than low inflammatory grade with LC3 and WIPI1, achieving statistical significance ( p < 0.05), further suggesting that autophagosome formation is at reduced levels with a high inflammatory degree. Viral histogenesis has been postulated in both CM and LPD in cardiac myxomas. The detection of herpesviruses (HSV1 and HSV2) and chronic inflammation in CM suggest a pathogenetic role in the tu-mor development [14 , 15] . However, other studies have found neither such association nor a detectable HSV viral protein or genomic DNA by both immunohistochemistry and polymerase chain reaction [16 -18] . Our study also detected no evidence of HSV infection, but EBV-LMP1 was detected in CLL-CM, and EBV-ISH was positive in HG-BCL. In "pre "-lymphomatous CM tissues, EBV-LPM1 gene expression was negative.

The above data suggest that the TME with a reduction of gene expression for autophagosome formation and aberrant excessive p62 accumulation in the presence of high inflammatory grade and perhaps viral infection may support the development of lymphoproliferative disorders. To the best of our knowledge, the present study is the first to report on the TME using the expression of autophagy-related genes and proteins in CM.

Our study on CM-TME with ATG-inflammation interplay has some limitations. This study is a single-center retrospective study with a limited but well-characterized number ( n = 28) of patients. Although the selection of specific areas with inflammation can theoretically lead to selection bias and depends on the number of tumor sections examined, quality controls were carried out for all tissue sections with optimal inter-and intraindividual k values. Immunohistochemical staining identified autophagic activity is present in all cell types, including CM cells. At the same time, Nanostring assay confirmed overall ATG gene expression activity, without identification of such events in specific cell types. The molecular machinery of autophagy is extraordinarily dynamic. Static analyses cannot distinguish between autophagy upregulation and degradation inhibition at a certain stage of the autophagic process. The mechanism underlying how autophagy proteins influence the TME in CM remains to be fully elucidated. Future studies may include in vivo research of a tumor, which may behave similarly as CM. More ATG genes relevant in the autophagy process to identify autophagy upregulation and degradation inhibition at a particular stage of the autophagic process may be highly relevant. The inclusion of inflammatory elements, including inflammasome and inflammatory cytokines, may elucidate the autophagy-inflammation interplay in the CM-TME as previously suggested in targeting NLRP3 inflammasome and currently for SARS -CoV -2 infection [48 , 49] . Intracardiac myxoma localization and restriction of LPD proliferation within the CM-TME environment is also intriguing and further studies on subsets of immune cells in CM-TME may shed some light on immuneevasion. The concept of tumor microenvironment includes many actors (cellular and acellular) and different conditions (stiffness, architecture) and we particularly focused on autophagy and viral infection. We are completely aware that our data should be correlated with other microenvironmental markers and the extracellular matrix components are usually involved in autophagy regulation as well as the deposition of integrin in the extracellular matrix, which will be the object of future studies.

In conclusion, we report for the first time on the TME using the expression of autophagy-related genes and proteins in CM and these data will be an avenue for further investigating the intriguing relationship between virus infection and cancer.

All authors have nothing to disclose with regard to any financial and personal relationships with other people or organizations that could inappropriately influence (bias) their work. 

Primary neoplasms of the heart. Clinical and histological presentation of 50 cases

Vrane š , A 30-year-single-center experience in atrial myxomas: from presentation to treatment and prognosis

Clinicopathologic features and outcomes of primary cardiac tumors: a 16-year-experience with 212 patients at a Chinese medical center

Clinical and histopathological analysis of 66 cases with cardiac myxoma, Asian Pac

Primary neoplasms of the heart. Clinical and histological presentation of 50 cases

Disparate remodeling of the extracellular matrix and proteoglycans in failing pediatric versus adult hearts

Differential impact of mechanical unloading on structural and nonstructural components of the extracellular matrix in advanced human heart failure

Determinants of ventricular arrhythmias in human explanted hearts with dilated cardiomyopathy

Immunity and stress responses are induced during ex situ heart perfusion

Genetic analysis in a patient with recurrent cardiac myxoma and endocrinopathy

Familial recurrent atrial myxoma: carney's complex

Clinical features and surgical results of cardiac myxoma in Carney complex

Inherited disposition to cardiac myxoma development

Herpes simplex virus Type 1 infection associated with atrial myxoma

Detection of herplex simplex virus-1 and -2 in cardiac myxomas

Association between herpes simplex virus Types 1 and 2 with cardiac myxoma

No association between herpes simplex virus 1 and cardiac myxoma

Glandular cardiacmyxomawith associated human papilloma virus infection: case report

Diffuse large B cell lymphoma associated with chronic inflammation arising within atrial myxoma: aggressive histological features but indolent clinical behaviour

EBV + diffuse large B-cell lymphoma arising within atrial myxoma. An example of a distinct primary cardiac EBV + DLBCL of immunocompetent patients

Epstein-Barr virus-associated diffuse large B-cell lymphoma arising in atrial myxoma: a proposal for a modified therapeutic approach

Fibrin-associated EBV-positive large B-cell lymphoma: an indolent neoplasm with features distinct from diffuse large Bcell lymphoma associated with chronic inflammation

Incidental Epstein-Barr virus associated atypical lymphoid proliferation arising in a left atrial myxoma: a case of long survival without any postsurgical treatment and review of the literature

Epstein-Barr virus in pyothorax-associated pleural lymphoma

Diffuse large B-cell lymphoma associated with chronic inflammation as an incidental finding and new clinical scenarios

Increased expression and activity of matrix metalloproteinases characterize embolic cardiac myxomas

Microenvironment in cardiac tumor development: what lies beyond the event horizon

Mitophagy in cancer: a tale of adaptation

Targeting autophagy in the tumor microenvironment: new challenges and opportunities for regulating tumor immunity

Role of tumor microenvironment in tumorigenesis

The multifaceted role of autophagy in cancer and the microenvironment

The interplay of autophagy and tumor microenvironment in colorectal cancer-ways of enhancing immunotherapy action

Autophagy: shaping the tumor microenvironment and therapeutic response

Autophagy-inflammasome interplay in heart failure: a systematic review on basics, pathways, and therapeutic perspectives

Mechanism and medical implications of mammalian autophagy

Emerging connections between RNA and autophagy

Biological functions of autophagy genes: a disease perspective

Autophagy regulation by nutrient signaling

The significance of macroautophagy in health and disease

Multiplexed color-coded probe-based gene expression assessment for clinical molecular diagnostics in formalin-fixed paraffin-embedded human renal allograft tissue

Digital gene expression analysis might aid in the diagnosis of thyroid cancer

Significance of 18 F-FDG PET and immunohistochemical GLUT-1 expression for cardiac myxoma

Detection of WIPI1 mRNA as an indicator of autophagosome formation

Autophagy-inflammasome interplay in heart failure: a systematic review on basics, pathways, and therapeutic perspectives

Dynamic regulation of macroautophagy by distinctive ubiquitin-like proteins

Autophagy suppresses tumorigenesis through elimination of p62

Autophagy suppresses tumor progression by limiting chromosomal instability

A balanced IL-1beta activity is required for host response to citrobacter rodentium infection

Targeting NLRP3 inflammasome in an animal model for Coronavirus Disease 2019 (COVID-19) caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2)

We are very grateful to Dr. B. Adam for the analysis and interpretation of the NanoString results. This research has been funded by the generosity of the Stollery Children's Hospital Foundation and supporters of the Lois Hole Hospital for Women through the Women and Children's Health Research Institute (WCHRI, Grant ID #: 2096 ) and Hubei Province Natural Science Funding for Hubei University of Technology ( 100-Talent Grant for Recruitment Program of Foreign Experts Total Funding). The funders had no role in study design, data collection, and analysis, decision to publish, or preparation of the manuscript.

Supplementary material associated with this article can be found, in the online version, at doi: 10.1016/j.tranon.2020.100911 .