Project description:The intricate anatomical structure and high cellular density of the myocardium significantly complicate the bioengineering of vascular networks within cardiac tissues, creating challenges in establishing a perfusable and stable vasculature within these tissues. Emerging evidence from murine in vivo studies underscores the significant role of resident cardiac macrophages in facilitating cardiac regeneration post-injury, specifically their role in enhancing angiogenesis processes. Here, for the first time, we integrate human pluripotent stem cell derived macrophages, resembling primitive yolk-sac derived macrophages, within human in vitro vascularized heart-on-chip platforms. The incorporation of primitive macrophages had a profound impact on the long term functionality of microvascularized cardiac tissue, particularly in enabling formation of perusable vasculature with a stable barrier function. These effects were contingent on physical cell-cell interactions and significantly diminished in transwell culture. The inclusion of primitive macrophages mitigated tissue cytotoxicity and curtailed the release of cell-free mitochondrial-DNA, underscoring their indispensable role for bioengineered human cardiac tissues. Furthermore, their incorporation upregulated the secretion of pro-angiogenic, matrix remodeling and cardioprotective cytokines such as MMP-12, MMP-2, Angiopoietin-like 1, NRG-3, SIGIRR and Adiponectin. RNA sequencing disclosed upregulation of cardiac maturation (TTNI3, SCN5A, MYL2, and RYR2), and endothelial cells genes (PDGF-B, PECAM-1 and CDH5) indicating a decrease in endothelial cells death. Collectively, our results offer valuable insights into the integral role of primitive macrophages in directing long-term functional vascularization of cardiac tissues, paving the way for novel therapeutic strategies and advancing heart-on-a-chip systems.

Project description:The intricate anatomical structure and high cellular density of the myocardium significantly complicate the bioengineering of vascular networks within cardiac tissues, creating challenges in establishing a perfusable and stable vasculature within these tissues. Emerging evidence from murine in vivo studies underscores the significant role of resident cardiac macrophages in facilitating cardiac regeneration post-injury, specifically their role in enhancing angiogenesis processes. Here, for the first time, we integrate human pluripotent stem cell derived macrophages, resembling primitive yolk-sac derived macrophages, within human in vitro vascularized heart-on-chip platforms. The incorporation of primitive macrophages had a profound impact on the long term functionality of microvascularized cardiac tissue, particularly in enabling formation of perusable vasculature with a stable barrier function. These effects were contingent on physical cell-cell interactions and significantly diminished in transwell culture. The inclusion of primitive macrophages mitigated tissue cytotoxicity and curtailed the release of cell-free mitochondrial-DNA, underscoring their indispensable role for bioengineered human cardiac tissues. Furthermore, their incorporation upregulated the secretion of pro-angiogenic, matrix remodeling and cardioprotective cytokines such as MMP-12, MMP-2, Angiopoietin-like 1, NRG-3, SIGIRR and Adiponectin. RNA sequencing disclosed upregulation of cardiac maturation (TTNI3, SCN5A, MYL2, and RYR2), and endothelial cells genes (PDGF-B, PECAM-1 and CDH5) indicating a decrease in endothelial cells death. Collectively, our results offer valuable insights into the integral role of primitive macrophages in directing long-term functional vascularization of cardiac tissues, paving the way for novel therapeutic strategies and advancing heart-on-a-chip systems.

Project description:Obesity-induced secretory disorder of adipose tissue-derived factors is important for cardiac damage. However, whether platelet-derived growth factor-D (PDGF-D), a newly identified adipokine, regulates cardiac remodeling in Angiotensin II (AngII)-infused obese mice is unclear. Here, we found obesity induced PDGF-D expression in adipose tissue, as well as more severe cardiac remodeling compared to control lean mice after AngII infusion. Adipocyte-specific PDGF-D knockout attenuated hypertensive cardiac remodeling in obese mice. Consistently, adipocyte-specific PDGF-D overexpression transgenic mice (PA-Tg) showed exacerbated cardiac remodeling after AngII infusion without high-fat diet treatment. Mechanistic studies indicated that AngII-stimulated macrophages produce urokinase plasminogen activator (uPA) that activates PDGF-D by splicing full-length PDGF-D into the active PDGF-DD. Moreover, bone marrow specific uPA knockdown decreased active PDGF-DD level in the heart and improved cardiac remodeling in HFD hypertensive mice. Together, our data provide for the first time a new interaction pattern between macrophage and adipocyte, that macrophage-derived uPA activates adipocyte-secreted PDGF-D, which finally accelerates AngII-induced cardiac remodeling in obese mice.

Project description:The first macrophages that seed the developing heart originate from the yolk sac during fetal life. While murine studies reveal important homeostatic and reparative functions in adults, we know little about their roles in the earliest stages of human heart development due to a lack of accessible tissue. Generation of bioengineered human cardiac microtissues from pluripotent stem cells models these first steps in cardiac tissue development, however macrophages have not been included in these studies. To bridge these gaps, we differentiated human embryonic stem cells (hESCs) into primitive LYVE1+ macrophages (hESC-macrophages; akin to yolk sac macrophages) that stably engrafted within cardiac microtissues composed of hESC-cardiomyocytes and fibroblasts to study reciprocal interactions. Engraftment induced a tissue resident macrophage gene program resembling human fetal cardiac macrophages, enriched in efferocytic pathways. Functionally, hESC-macrophages induced production and maturation of cardiomyocyte sarcomeric proteins, and enhanced contractile force, relaxation kinetics, and electrical properties. Mechanistically, the primary effect of hESC-macrophages was during the stressful events surrounding early microtissue formation, where they engaged in phosphatidylserine dependent ingestion of apoptotic cardiomyocyte cargo, which reinforced core resident macrophage identity, reduced microtissue stress and drove hESC-cardiomyocytes to become more similar to human ventricular cardiomyocytes found in early development, both transcriptionally and metabolically. Inhibiting efferocytosis of hESC-cardiomyocytes by hESC-macrophages led to increased cell stress, impaired sarcomeric protein maturation and reduced cardiac microtissue function (contraction and relaxation). Taken together, macrophage-engineered human cardiac microtissues represent a considerably improved model for human heart development, and reveal a major beneficial, yet previously unappreciated role for human primitive macrophages in enhancing cardiac tissue function.

Project description:The first macrophages that seed the developing heart originate from the yolk sac during fetal life. While murine studies reveal important homeostatic and reparative functions in adults, we know little about their roles in the earliest stages of human heart development due to a lack of accessible tissue. Generation of bioengineered human cardiac microtissues from pluripotent stem cells models these first steps in cardiac tissue development, however macrophages have not been included in these studies. To bridge these gaps, we differentiated human embryonic stem cells (hESCs) into primitive LYVE1+ macrophages (hESC-macrophages; akin to yolk sac macrophages) that stably engrafted within cardiac microtissues composed of hESC-cardiomyocytes and fibroblasts to study reciprocal interactions. Engraftment induced a tissue resident macrophage gene program resembling human fetal cardiac macrophages, enriched in efferocytic pathways. Functionally, hESC-macrophages induced production and maturation of cardiomyocyte sarcomeric proteins, and enhanced contractile force, relaxation kinetics, and electrical properties. Mechanistically, the primary effect of hESC-macrophages was during the stressful events surrounding early microtissue formation, where they engaged in phosphatidylserine dependent ingestion of apoptotic cardiomyocyte cargo, which reinforced core resident macrophage identity, reduced microtissue stress and drove hESC-cardiomyocytes to become more similar to human ventricular cardiomyocytes found in early development, both transcriptionally and metabolically. Inhibiting efferocytosis of hESC-cardiomyocytes by hESC-macrophages led to increased cell stress, impaired sarcomeric protein maturation and reduced cardiac microtissue function (contraction and relaxation). Taken together, macrophage-engineered human cardiac microtissues represent a considerably improved model for human heart development, and reveal a major beneficial, yet previously unappreciated role for human primitive macrophages in enhancing cardiac tissue function.

Project description:Objective: Insights about differences in tumor vasculature and how it reacts to VEGF inhibition is limited, but nevertheless of major relevance to anti-angiogenic therapy. In this study we therefore characterize the effect of bevacizumab combined with chemoradiotherapy (CRT), and explore molecular and genetic markers for response prediction to this combination treatment. Material and Methods: In an academic multicentric randomized phase II study, patients with advanced rectal cancer have been treated with bevacizumab (5mg/kg) in combination with capecitabine (1650mg/m2/day) and radiotherapy (45Gy; 1.8Gy/day) with (50mg/m2) or without oxaliplatin prior to surgery. Of 59 patients, tumor tissue and blood samples were collected before treatment and after the first loading dose of bevacizumab but before CRT (week 3). First, cDNA micro-arrays were performed on the biopsies to investigate differences in gene expression of tumors from patients with and without a pathological complete response (pCR) before start of treatment and to identify biological processes affected by bevacizumab delivery. The paraffin embedded tissue was stained for blood vessels (CD31/CD34) combined with α-SMA (pericytes) and CA-IX (hypoxia). To explore candidate blood-based biomarkers ELISA’s were performed for PDGF-AA, PDGF-BB, THBS-1, IL-8, CYR61 and Ang-2. The expression of all markers was correlated with the pathological response of the patients. Results: Differences in tumoral gene expression are observed between patients with and without a pCR, with the first response group presenting a more angiogenic phenotype before start of treatment and changes in angiogenic processes after bevacizumab delivery. One dose of bevacizumab leads to a decrease in the number of pericyte covered blood vessels, a decrease in circulating PDGF-AA, PDGF-BB and Thrombospondin-1. Patients showing a pCR having less pericyte covered blood vessels, more hypoxia, and less circulating PDGF-BB compared to patients who did not have a pCR after bevacizumab treatment with chemoradiation and bevacizumab. Conclusions: The translational data demonstrate that tumors with an angiogenic expression profile respond better to bevacizumab combined with CRT and points towards a possible role for PDGF, CA-IX and pericyte covered blood vessels for the early response prediction to this treatment. Our findings suggest a role for mural cell recruitment and vessel maturation for the susceptibility of the tumor vasculature to bevacizumab treatment. Further validation of our biological observations and hypothesis generating data in randomized trials is needed.

Project description:Objective: Insights about differences in tumor vasculature and how it reacts to VEGF inhibition is limited, but nevertheless of major relevance to anti-angiogenic therapy. In this study we therefore characterize the effect of bevacizumab combined with chemoradiotherapy (CRT), and explore molecular and genetic markers for response prediction to this combination treatment. Material and Methods: In an academic multicentric randomized phase II study, patients with advanced rectal cancer have been treated with bevacizumab (5mg/kg) in combination with capecitabine (1650mg/m2/day) and radiotherapy (45Gy; 1.8Gy/day) with (50mg/m2) or without oxaliplatin prior to surgery. Of 59 patients, tumor tissue and blood samples were collected before treatment and after the first loading dose of bevacizumab but before CRT (week 3). First, cDNA micro-arrays were performed on the biopsies to investigate differences in gene expression of tumors from patients with and without a pathological complete response (pCR) before start of treatment and to identify biological processes affected by bevacizumab delivery. The paraffin embedded tissue was stained for blood vessels (CD31/CD34) combined with α-SMA (pericytes) and CA-IX (hypoxia). To explore candidate blood-based biomarkers ELISA’s were performed for PDGF-AA, PDGF-BB, THBS-1, IL-8, CYR61 and Ang-2. The expression of all markers was correlated with the pathological response of the patients. Results: Differences in tumoral gene expression are observed between patients with and without a pCR, with the first response group presenting a more angiogenic phenotype before start of treatment and changes in angiogenic processes after bevacizumab delivery. One dose of bevacizumab leads to a decrease in the number of pericyte covered blood vessels, a decrease in circulating PDGF-AA, PDGF-BB and Thrombospondin-1. Patients showing a pCR having less pericyte covered blood vessels, more hypoxia, and less circulating PDGF-BB compared to patients who did not have a pCR after bevacizumab treatment with chemoradiation and bevacizumab. Conclusions: The translational data demonstrate that tumors with an angiogenic expression profile respond better to bevacizumab combined with CRT and points towards a possible role for PDGF, CA-IX and pericyte covered blood vessels for the early response prediction to this treatment. Our findings suggest a role for mural cell recruitment and vessel maturation for the susceptibility of the tumor vasculature to bevacizumab treatment. Further validation of our biological observations and hypothesis generating data in randomized trials is needed. This study involves samples of patients enrolled in the AXEbeam trail that were analysed by Primeview microarray (Affymetrix). Biopsies were taken at two different timepoints: before treatment (tumor and normal mucosa) and after the first loading dose of bevacizumab but before chemoradiation (only tumor, week 3). Patients were classified into two groups: with a complete pathological response at time of surgery (Responders=R) or non-responders (NR). For the responders, we collected 21 samples in total (7 tumor samples and 8 normal mucosa samples taken before treatment and 6 tumor samples collected at week 3). From the non-responders we had 26 samples in total (9 tumor and 10 mucosa samples before treatment and 7 tumor samples at week 3 after a single dose of bevacizumab). Microarrays were run in two batches (15xxx versus 16xxx CEL file samples; indicated in the description field). Three samples (NJ 04/003 T1, RVS 09/002 M and NJ 04/003 W3) were put twice on the array (15897+16789; 15893+16790; 15898+16791) to verify and exclude batch effects. Please note that, due to these three technical repeats the total number of microarray CEL files is 50 (21 Responders, 26 Non-responders and 3 repeats).

Project description:A better understanding of the pathways that regulate regeneration of the coronary vasculature is of fundamental importance for the advancement of strategies to treat patients with heart disease. By analyzing single cell transcriptome of resident cardiac endothelial cells (ECs) in adult mouse hearts under both healthy and myocardial infarction (MI) settings, we provide molecular definitions of murine cardiac endothelial heterogeneity and characterizations of pro-angiogenic resident ECs.

Project description:human induced pluripotent stem cell (hiPSC)-derived primitive macrophages (hiPMs) and their conditioned medium (hiPM-CM) promote human cardiomyocyte proliferation and to enhance cardiac regeneration in infarcted adult mouse hearts. To identify the components underlying the pro-proliferative effects hiPM-CM, and the conditioned medium of hiPM precursors (hiPMpre-CM) were collected and the protein components were analyzed by mass spectrometry.

Project description:Resident cardiac macrophages, derived from primitive yolk sac precursors during embryogenesis, have increasingly been recognized for their distinct phenotype and functions in regulating homeostasis of the human heart. However, the profile of their extracellular vesicles (EVs) in cardiac signalling and regulation remains uncharted. Here, we employ differentiation of human pluripotent stem cell (hPSC)-derived primitive macrophages (Mac) for isolation of their secreted EVs and in-depth characterization of EV-miRNA cargo. Primitive macrophages secreted nanoscale EVs that expressed canonical EV markers, and miRNA sequencing highlighted a diverse and unique profile of miRNAs when compared to EVs sourced from other principal cardiac cell lineages and published data from monocyte-derived cells. In particular, we noted the abundance and enrichment of vascular-modulatory let-7 miRNAs and miR-126-3p. Functional screening of Mac-EVs in a 3D model of in vitro cardiac vasculogenesis confirmed enhanced early endothelial cell organization and branching. Establishing a reference for the human Mac-EV miRNome enables further hypothesis-driven mechanistic tests of Mac-EV miRNAs in mediating cardiac physiology and disease, opening the door to identification of therapeutic targets and modalities for cardiac repair.