Presence Of Endothelial Cells Research Articles

Squid Suckerin-Spider Silk Fusion Protein Hydrogel for Delivery of Mesenchymal Stem Cell Secretome to Chronic Wounds.

Chronic wounds are non-healing wounds characterized by a prolonged inflammation phase. Excessive inflammation leads to elevated protease levels and consequently to a decrease in growth factors at wound sites. Stem cell secretome therapy has been identified as a treatment strategy to modulate the microenvironment of chronic wounds via supplementation with anti-inflammatory/growth factors. However, there is a need to develop better secretome delivery systems that are able to encapsulate the secretome without denaturation, in a sustained manner, and that are fully biocompatible. To address this gap, a recombinant squid suckerin-spider silk fusion protein is developed with cell-adhesion motifs capable of thermal gelation at physiological temperatures to form hydrogels for encapsulation and subsequent release of the stem cell secretome. Freeze-thaw treatment of the protein hydrogel results in a modified porous cryogel that maintains slow degradation and sustained secretome release. Chronic wounds of diabetic mice treated with the secretome-laden cryogel display increased wound closure, presence of endothelial cells, granulation wound tissue thickness, and reduced inflammation with no fibrotic scar formation. Overall, these in vivo indicators of wound healing demonstrate that the fusion protein hydrogel displays remarkable potential as a delivery system for secretome-assisted chronic wound healing.

The combination of mesoglycan and VEGF promotes skin wound repair by enhancing the activation of endothelial cells and fibroblasts and their cross-talk

Skin wound healing requires accurate therapeutic topical managements to accelerate tissue regeneration. Here, for the first time, we found that the association mesoglycan/VEGF has a strong pro-healing activity. In detail, this combination induces angiogenesis in human endothelial cells promoting in turn fibroblasts recruitment. These ones acquire a notable ability to invade the matrigel coating and to secrete an active form of metalloproteinase 2 in presence of endothelial cells treated with mesoglycan/VEGF. Next, by creating intrascapular lesions on the back of C57Bl6 mice, we observed that the topical treatments with the mesoglycan/VEGF promotes the closure of wounds more than the single substances beside the control represented by a saline solution. As revealed by eosin/hematoxylin staining of mice skin biopsies, treatment with the combination mesoglycan/VEGF allows the formation of a well-structured matrix with a significant number of new vessels. Immunofluorescence analyses have revealed the presence of endothelial cells at the closed region of wounds, as evaluated by CD31, VE-cadherin and fibronectin staining and of activated fibroblasts assessed by vimentin, col1A and FAP1α. These results encourage defining the association mesoglycan/VEGF to activate endothelial and fibroblast cell components in skin wound healing promoting the creation of new vessels and the deposition of granulation tissue.

Abstract 6041: Perfusion-based bioreactor preserves microenvironment of hepatocellular carcinoma ex vivo

Abstract Background: Hepatocellular carcinoma (HCC) accounts for 75-85% of all primary liver malignancies. HCC represents an attractive target for immune checkpoint inhibitors (ICI) and tumor microenvironment (TME) agents. The development and success of ICI therapies requires a comprehensive model to study interactions of immune networks in the TME. Patient-derived organoids (PDO) have emerged as promising individualized models for ex vivo drug testing. While PDO are superior to previous models, due to their inherent heterogeneity and their enhanced capacity to capture tumor characteristics, the lack of mesenchymal and immune components limit their use for testing drug classes such as ICI or study tumor-TME interaction. Here, we developed and characterized a perfusion-based cultivated ex vivo HCC tissue model that preserves the tumor tissue architecture and maintains the pathophysiological microenvironment of human tissue for testing of TME-related treatments. Materials and methods: Fresh tumor tissue was obtained from surgical specimens of six patients undergoing liver resection for HCC. Tissue fragments of 2x2x2 mm were installed between two discs of collagen type 1 porous scaffold and placed in a perfusion-based bioreactor (U-shaped Culture Under Perfusion; U-CUP) for tissue engineering or cultured in static condition. At different time points, cultured tissue fragments were formalin-fixed and paraffin-embedded for downstream analysis. Cell viability and morphology was monitored on day 0, 5 and 7 by using hematoxylin and eosin staining. The changes in TME composition were monitored by immunohistochemistry using cell-type specific antibodies like CD34 for endothelial cells, CD3 for T-cells, alpha-smooth muscle actin (a-SMA) for fibroblasts and arginase-L for urea cycle. Results: Microscopic analysis revealed that, compare to static culture, the morphology and the viability of the cells were preserved during the culture period in the U-CUP. Tissue histology as well as the immunophenotypic pattern observed in the original tissue was maintained. Similarly, the presence of endothelial cells (CD34+) and fibroblasts (a-SMA+) were detected in the U-CUP cultured samples in a similar proportion to the original tumor samples. The presence of T-cells (CD3+) was stable at all time points. Compared to the samples cultured under static conditions, the U-CUP tended to show less necrosis during the seven-day course. Conclusion: Compared to PDO, U-CUP bioreactor tumor culture seems to preserve mesenchymal and immune components. This enables further investigation and assessment of TME-related treatments, such as ICI. Citation Format: Gabriel Fridolin Hess, Manuele Giuseppe Muraro, Mairene Coto-Llerena, Silvio Däster, Caner Ercan, Simone Muenst, Otto Kollmar, Salvatore Piscuoglio, Savas Deniz Soysal. Perfusion-based bioreactor preserves microenvironment of hepatocellular carcinoma ex vivo [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6041.

Multi‐scale Computational Model of Endothelial Cell‐Pericyte Coupling in Idiopathic Pulmonary Fibrosis

IntroductionMicrovascular stability is highly dependent on endothelial cell‐pericyte coupling. In fibrotic diseases, such as idiopathic pulmonary fibrosis (IPF), extracellular matrix stiffening and elevated concentrations of profibrotic factors, such as TGF‐β, can disrupt this cell‐cell communication. Treatment of IPF with the antifibrotic drug Nintedanib, which targets PDGF‐βR, FGF‐R, and VEGF‐R signaling, may counteract these effects to strengthen endothelial cell‐pericyte coupling and promote microvessel stability1,2. We have developed a multi‐scale computational model that simulates intracellular signaling in endothelial cells and pericytes, heterotypic cell‐cell communication, and the dynamic lung microenvironment to study how Nintedanib2 and other drugs affect microvascular network remodeling in IPF. We hypothesize that blocking PDGF‐βR and FGF‐R signaling with Nintedanib is sufficient to rescue TGF‐β‐induced endothelial cell‐pericyte decoupling.Materials and MethodsThe multi‐scale model is comprised of logic‐based ordinary differential equations representing intracellular signaling networks in both endothelial cells and pericytes integrated into an agent‐based model representing the lung environment wherein the simulated cells interact with one another, sensing and dynamically altering their microenvironment (Figure 1). The logic‐based network signaling models were developed using the Netflux3 toolkit in MATLAB. The agent‐based model of the spatiotemporal 2D lung environment was constructed in NetLogo4. The multi‐scale model was created by linking the logic‐based network models with the agent‐based model using the NL4Py5 package in Python.Results and DiscussionEndothelial cell‐pericyte decoupling was signified by decreased N‐cadherin expression in pericytes, increased αSMA and Col1mRNA (indicating possible pericyte‐to‐myofibroblast transition), and increased physical separation and distances between endothelial cells and pericytes. The multi‐scale model predicted that increasing TGF‐β concentrations significantly elevated αSMA and Col1mRNA expression in simulated pericytes. N‐cadherin levels did not change in response to TGF‐β or Nintedanib treatment in the network model of the pericyte alone but were affected by the presence of endothelial cells in the agent‐based model, highlighting the importance of endothelial cell‐pericyte interactions in determining pericyte behaviors.ConclusionsOur multi‐scale model demonstrates the importance of considering endothelial cell‐pericyte communication in predicting cellular responses to pro‐fibrotic environments. By representing intracellular biochemical signaling networks, heterotypic cell interactions, and the dynamic multi‐cell microenvironment, we were able to demonstrate a potential mechanism through which Nintedanib treatment affects endothelial cell‐pericyte coupling in IPF.References1) Hanumegowda, C., et al.; Chest. 2012 2) Wollin, L., et al.; Eur Respir J. 2015 3) Kraeutler, MJ., et al.; BMC Syst Biol. 2010 4) Sklar, E., Artif. Life 2007 5) Gunaratne, C.; 2018. NL4Py.

Polysucrose hydrogel and nanofiber scaffolds for skin tissue regeneration: Architecture and cell response

Scaffolds capable of mediating overlapping multi-cellular activities to support the different phases of wound healing while preventing scarring are essential for tissue regeneration. The potential of polysucrose as hydrogels and electrospun mats for wound healing was evaluated in vitro by seeding fibroblasts, endothelial cells and macrophages either singly or in combination. It was found that the scaffold architecture impacted cell behaviour. Electrospun mats promoted fibroblasts flattened morphology while polysucrose methacrylate (PSucMA) hydrogels promoted fibroblast spheroids formation, accentuated in the presence of endothelial cells. Hydrogels exhibited lower inflammatory response than mats and curcumin loaded scaffolds reduced TNF-α production. In vivo biocompatibility of the hydrogels tested on Wistar rats was superior to electrospun mats. In vivo wound healing studies indicated that PSucMA hydrogels integrated the surrounding tissue with better cellular infiltration and proliferation throughout the entire wound region. PSucMA hydrogels led to scarless wound closure comparable with commercially available gels.

Influence of Liver Extracellular Matrix in Predicting Drug-Induced Liver Injury: An Alternate Paradigm.

In vitro drug-induced liver injury (DILI) models are promising tools for drug development to predict adverse events during clinical usage. However, the currently available DILI models are not specific or not able to predict the injury accurately. This is believed to be mainly because of failure to conserve the hepatocyte phenotype, lack of longevity, and difficulty in maintaining the tissue-specific microenvironment. In this study, we have assessed the potential of decellularized liver extracellular matrix (DLM) in retaining the hepatic cellular phenotype and functionality in the presence of a tissue-specific microenvironment along with its role in influencing the effect of the drug on hepatic cells. We show that DLM helps maintain the phenotype of the hepatic cell line HepG2, a well-known cell line for secretion of human proteins that is easily available. Also, the DLM enhanced the expression of a metabolic marker carbamoyl phosphate synthetase I (CPS1), a regulator of urea cycle, and bile salt export pump (BSEP), a marker of hepatocyte polarity. We further validated the DLM for its influence on the sensitivity of cells toward different classes of drugs. Interestingly, the coculture model, in the presence of endothelial cells and stellate cells, exhibited a higher sensitivity for both acetaminophen and trovafloxacin, a toxic compound that does not show any toxicity on preclinical screening. Thus, our results demonstrate for the first time that a multicellular combination along with DLM can be a potential and reliable DILI model to screen multiple drugs.

Antiproliferative and antiangiogenic effects of ammonium tetrathiomolybdate in a model of endometriosis

AimsCopper (Cu) is involved in the endometriosis progression. Herein, an experimental endometriosis model was used to evaluate whether its chelation with ammonium tetrathiomolybdate (TM) affects the proliferation and angiogenesis in endometriotic-like lesions and the participation of oxidative stress in these processes. Main methodsFemale C57BL/6 mice were divided into three groups: sham-operated mice, endometriosis-induced mice, and TM-treated endometriosis-induced mice. Each animal in the third group received 0.3 mg of TM/day in their drinking water from the postoperative 15th day. The samples were collected after one month of induced pathology. In peritoneal fluids, Cu and estradiol levels were determined by electrothermal atomic absorption spectrometry and electrochemiluminescence, respectively. Endometriotic-like lesions were processed for the analysis of cell proliferation by PCNA immunohistochemistry, the expression of angiogenic markers by RT-qPCR, the presence of endothelial cells by immunofluorescent staining, and oxidative stress applying spectrophotometric methods. Key findingsTM treatment decreased Cu and estradiol levels, which were increased by this pathology. In lesions, TM induced: (a) a decrease in tissue weight and volume, (b) a decrease in PCNA-positive cells, (c) antiangiogenic effects by decreasing the number of blood vessels, the mRNA expression of fibroblast growth factor 2 (Fgf2) and platelet-derived growth factor subunit B (Pdgfb), and the presence of endothelial cells, (d) a decrease in antioxidant activity and an increase in lipid peroxidation. SignificanceTM is a highly effective antiproliferative and antiangiogenic agent, modulating oxidative imbalance in endometriosis. Its anti-endometriotic potential is an attractive feature of TM as a possible non-hormonal treatment.

Facile Fabrication of Hollow Hydrogel Microfiber via 3D Printing-Assisted Microfluidics and Its Application as a Biomimetic Blood Capillary

Simulating the structure and function of blood capillaries is very important for an in-depth insight into their role in the human body and treatment of capillary-related diseases. Due to the similar composition and structure, hollow hydrogel microfibers are well-recognized as potential biomimetic blood capillaries. In this paper, we report a novel, facile, and reproducible method to fabricate coaxial microfluidic chips via 3D printing-assisted soft lithography and then hollow hydrogel microfibers using the as-prepared coaxial microfluidic chips. Instead of traditional photoresist-based lithography, 3D printing of gelatin hydrogel under various extrusion pressures is used to construct sacrificial templates of coaxial microfluidic chips. Various solid and hollow hydrogel microfibers with complicated and hierarchical structures can be obtained via multitype coaxial microfluidic chips or a combination of coaxial microfluidic fabrication and post-treatment. The as-formed hollow hydrogel microfibers are evaluated in detail as biomimetic blood capillaries, including physicochemical and cytological properties. Our results prove that the hollow hydrogel microfibers exhibit excellent mass transport capacity, hemocompatibility, semipermeability, and mechanical strength, and their barrier function can be further enhanced in the presence of endothelial cells. Overall, our 3D printing-assisted fabrication strategy provides a new technique to construct microfluidic chips with complicated 3D microchannels, and the resulting hollow hydrogel microfibers are promising candidates for blood capillaries.

High Matrix Metalloproteinase 28 Expression is Associated with Poor Prognosis in Pancreatic Adenocarcinoma

PurposePancreatic adenocarcinoma (PAAD) is a devastating disease with high mortality and morbidity. Matrix metalloproteinase 28 (MMP28) has been associated with carcinogenesis of many human cancers. However, little is known about the potential prognostic value and underlying regulatory mechanisms of MMP28 in PAAD.MethodsThe relationship between MMP28 expression level and various clinicopathological parameters was analyzed in TCGA-PAAD cohorts. MMP28-correlated genes in the TCGA-PAAD cohort were identified and enrichment analysis according to the Gene Ontology and Kyoto Encyclopedia of Genes and Genomes was conducted using LinkedOmics. Protein–protein interaction and transcription factors-miRNA co-regulatory networks were constructed with the use of NetworkAnalyst. Then, the distribution of immune cells related to MMP28 expression in blood was analyzed using the Human Protein Atlas, and the tumor microenvironment of PAAD was analyzed by the TIMER 2.0 database. To investigate the biological function of MMP28 in PAAD, siRNA was constructed to knock down the MMP28 gene in vitro.ResultsHigh MMP28 expression is associated with poor overall survival and disease-free survival in PAAD patients. The expression of MMP28 in PAAD is most significantly correlated with KRT19, IL1RN, and ANXA2 genes. Network analysis revealed that MIR-181 family, TAFs, and CDC6 are potential regulators of MMP28. Furthermore, naive CD4+ T cell, naive CD8+ T cell, and mucosal-associated invariant T cell enrichment in blood were correlated with MMP28 expression. Furthermore, high MMP28 expression was correlated with a decrease in B cell, naive CD4+ T cell, naive CD8+ T cell, and endothelial cell presence in the tumor microenvironment in PAAD. Finally, genetic knockdown of MMP28 could restrain the proliferation, migration, and invasion of PAAD cells.ConclusionOur findings indicate that high MMP28 expression in PAAD is associated with cancer progression, invasion, and metastasis. Hence, MMP28 might serve as an independent prognostic biomarker and a prospective therapeutic target for PAAD.

Mueller polarimetric imaging for fast macroscopic mapping of microscopic collagen matrix remodeling by smooth muscle cells

Smooth muscle cells (SMCs) are critical players in cardiovascular disease development and undergo complex phenotype switching during disease progression. However, SMC phenotype is difficult to assess and track in co-culture studies. To determine the contractility of SMCs embedded within collagen hydrogels, we performed polarized light imaging and subsequent analysis based on Mueller matrices. Measurements were made both in the absence and presence of endothelial cells (ECs) in order to establish the impact of EC-SMC communication on SMC contractility. The results demonstrated that Mueller polarimetric imaging is indeed an appropriate tool for assessing SMC activity which significantly modifies the hydrogel retardance in the presence of ECs. These findings are consistent with the idea that EC-SMC communication promotes a more contractile SMC phenotype. More broadly, our findings suggest that Mueller polarimetry can be a useful tool for studies of spatial heterogeneities in hydrogel remodeling by SMCs.

Abstract LT018: The perivascular niche protects ALK+ lymphoma cells from ALK inhibition through the CCL19/21-CCR7 axis

Abstract The ALK inhibitor crizotinib showed promising therapeutic efficacy for relapsed/refractory Anaplastic Large Cell Lymphoma (R/R ALCL). However, a fraction of ALK+ R/R ALCL patients do not achieve complete remission due to crizotinib resistance that develops within the first 3 months of therapy. In patients that achieve complete remission, crizotinib discontinuation causes rapid disease relapses due to the expansion of persister lymphoma cells never completely eradicated by the ALK inhibitor. There is, in fact, growing evidence that ALK+ ALCL can persist for years in patients being undetectable. ALCL grows around blood and lymphatic vessels in the lymph node. We hypothesize that this perivascular niche provides pro-survival signals contributing to ALK+ ALCL persistence and TKI resistance. By RNA-seq analysis on ALK+ ALCL cells and scRNA-seq analysis in one ALK+ ALCL primary sample, we found that ALK+ cells expressed the C-C chemokine receptor type 7 (CCR7), while endothelial cells and fibroblasts expressed the unique CCR7 ligands, the chemokine (C-C motif) ligand 19 (CCL19) and 21 (CCL21). Therefore, we explored whether the CCL19/21-CCR7 chemokine-receptor signaling axis could be involved in the persistence of ALK+ ALCL cells during ALK inhibitor treatment. We show that treatment with crizotinib caused upregulation of CCR7 in ALK+ ALCL cells via STAT3, as demonstrated by ChIP-seq data. Besides, stimulation of ALK+ ALCL cells with both CCL19/21 potently activated the MAPK signaling and sustained MAPK activation during ALK inhibition by crizotinib. Mechanistically, we demonstrate that this MAPK activation was mediated by PI3Kγ-dependent CCR7 signaling. This effect was more marked in human ALK+ ALCL cells that express high levels of PI3Kγ, while it was strongly reduced in murine lymphoma PI3KγKO cells, generated from NPM-ALK transgenic mice crossed with PI3KγKO mice. Treatment with the PI3Kγ/δ dual inhibitor duvelisib abrogated the MAPK phosphorylation induced by CCL19/21. When we knocked-out the CCR7 gene via CRISPR/Cas9, human ALK+ ALCL showed markedly reduced activation of the MAPK pathway upon stimulation with CCL19/21. Next, we developed a microphysiological model of ALCL cells in the perivascular niche with a 3D vasculature using a microfluidic chip. In this model, ALCL cells circulate inside the chip in continuous contact with a perfusable vasculature. We, then, demonstrated that the presence of endothelial cells conferred resistance to crizotinib and sustained cell viability of CCR7WT cells, whereas the protective effect was lost in CCR7KO cells. In in vivo experiments, CCR7 was required for lymphoma cell survival and diffusion to the brain during crizotinib treatment. Overall, our results suggest that the perivascular niche could promote the survival of ALK+ ALCL persister cells and protect them from the effect of ALK TKIs via the CCL19/21-CCR7 axis. The disruption of this survival axis could contribute to eradicating minimal residual disease in combination with ALK TKI. Citation Format: Cristina Mastini, Marco Campisi, Carlotta Costa, Chiara Ambrogio, Giulia Germena, Silvia Peola, Cinzia Martinengo, Enrico Patrucco, Ines Mota, Maddalena Arrigoni, Martina Olivero, Raffaele Calogero, Valeria Chiono, Roger D. Kamm, Emilio Hirsch, Jon C. Aster, Claudia Voena, Roberto Chiarle. The perivascular niche protects ALK+ lymphoma cells from ALK inhibition through the CCL19/21-CCR7 axis [abstract]. In: Proceedings of the AACR Virtual Special Conference on the Evolving Tumor Microenvironment in Cancer Progression: Mechanisms and Emerging Therapeutic Opportunities; in association with the Tumor Microenvironment (TME) Working Group; 2021 Jan 11-12. Philadelphia (PA): AACR; Cancer Res 2021;81(5 Suppl):Abstract nr LT018.

The effect of hydroxychloroquine on platelet activation in model experiments.

Hydroxychloroquine (HCQ) is an antimalarial agent with pleiotropic effects and now represents a cornerstone in the management of patients with autoimmune conditions. While clinical series suggest anti-thrombotic properties, the way in which HCQ exerts this effect remains to be fully explained. Following a 24-h incubation of human umbilical vein endothelial cells (HUVEC) and human umbilical arterial endothelial cells (HUAEC) with HCQ (concentration 500, 1000 and 2000ng/ml), these cells were then stimulated for an hour with tumor necrosis factor alpha (TNF-α) and were subsequently incubated in direct contact with thrombin-activated platelets. The expression of CD40L on platelets was measured by flow cytometry. The expression of CD40L on platelets significantly increased after direct incubation with 1000ng/ml and 2000ng/ml concentrations of HCQ. In contrast, after pre-incubation of HUAECs with 1000ng/ml HCQ and following stimulation with platelets the expression of CD40L was significantly reduced also after stimulation with thrombin and TNF-α activated platelets. It was shown that the expression of CD40L on the platelets was not significantly reduced by different HCQ concentrations after contact with HCQ pre-incubated HUVECs. HCQ reduces the stimulatory effect of thrombin and TNF-α on platelet activation in the presence of endothelial cells. Our experiments suggest that HCQ pre-incubated HUAEC cells result in a reduced platelets activation measured by means of CD40L expression. Further, our results show that direct HCQ incubation of platelets (without the presence of EC) increased the expression of CD40L suggesting that the observed effect of HCQ on platelet activation may be EC mediated.

Hydrogel microfluidic-based liver-on-a-chip: Mimicking the mass transfer and structural features of liver.

Liver is fed by nutrition via diffusion across the vascular wall from blood flow. However, hepatocytes in liver models are directly exposed to the perfusion culture medium, where the shear stress reduces the cell viability and liver-specific functions. By mimicking the mass transfer and structural features of hepatic lobule, we designed a microfluidic liver-on-a-chip based on the di-acrylated pluronic F127 hydrogel. In the hydrogel chip, hepatocellular carcinoma HepG2 and human hepatic stellate cell LX-2 were statically cultured inside the microwells on the outer channel. These hepatic cells were fed by the diffused medium from the adjacent but separated inner channel with endothelial cell monolayers, which was perfused by the medium with physiologically relevant shear stress. As found, the hepatic cells in the liver-on-a-chip rapidly formed spheroids within 1-dayincubation and expressed about one to two-fold higher viability/liver-specific functions than the corresponding static culture for at least 8 days. Moreover, the presence of endothelial cells also contributed to the expression of liver-specific functions in the liver-on-a-chip. Therefore, the proposed liver-on-a-chip provides a new concept for construction of 3D liver models in vitro, and shows the potential value for a variety of applications including bio-artificial livers and drug toxicity screening.

COVID-19: Could Aspirin Be of Any Help in the Early Stage?

Here is discussed the current scientific background for starting antiaggregation with Aspirin in the very initial phase of COVID-19 infection for preventing thrombotic infarctions before irreversible damage occurs in the target organs. Several authors are now describing the presence of endothelial cells into the bloodstream. This might indeed represent an epiphenomenon of the underlying mechanisms explaining the incidence of fatal systemic thrombotic complications. Antiaggregation with ASA would potentially have a significant prophylactic role, ideally before than anticoagulation and/or intensive care be the only options left: therefore dedicated trials should urgently be addressed to confirm this hypothesis.

Endothelial cell crosstalk improves browning but hinders white adipocyte maturation in 3D engineered adipose tissue.

Central to the development of adipose tissue (AT) engineered models is the supporting vasculature. It is a key part of AT function and long-term maintenance, but the crosstalk between adipocytes and endothelial cells is not well understood. Here, we directly co-culture the two cell types at varying ratios in a 3D Type I collagen gel. Constructs were evaluated for adipocyte maturation and function and vascular network organization. Further, these constructs were treated with forskolin, a beta-adrenergic agonist, to stimulate lipolysis and browning. Adipocytes in co-cultures were found to be less mature than an adipocyte-only control, shown by smaller lipid droplets and downregulation of key adipocyte-related genes. The most extensive vascular network formation was found in the 1:1 co-culture, supported by vascular endothelial growth factor (VEGF) upregulation. After forskolin treatment, the presence of endothelial cells was shown to upregulate PPAR coactivator 1 alpha (PGC-1α) and leptin, but not uncoupling protein 1 (UCP1), suggesting a specific crosstalk that enhances early stages of browning.

Targeting vasculogenic mimicry by phytochemicals: A potential opportunity for cancer therapy.

Vasculogenic mimicry (VM) is regarded as a process where very aggressive cancer cells generate vascular-like patterns without the presence of endothelial cells. It is considered as the main mark of malignant cancer and has pivotal role in cancer metastasis and progression in various types of cancers. On the other hand, resistance to the antiangiogenesis therapies leads to the cancer recurrence. Therefore, development of novel chemotherapies and their combinations is urgently needed for abolition of VM structures and also for better tumor therapy. Hence, identifying compounds that target VM structures might be superior therapeutic factors for cancers treatment and controlling the recurrence and metastasis. In recent times, naturally occurring compounds, especially phytochemicals have obtained great attention due to their safe properties. Phytochemicals are also capable of targeting VM structure and also their main signaling pathways. Consequently, in this review article, we illustrated key signaling pathways in VM, and the phytochemicals that affect these structures including curcumin, genistein, lycorine, luteolin, columbamine, triptolide, Paris polyphylla, dehydroeffusol, jatrorrhizine hydrochloride, grape seed proanthocyanidins, resveratrol, isoxanthohumol, dehydrocurvularine, galiellalactone, oxacyclododecindione, brucine, honokiol, ginsenoside Rg3, and norcantharidin. The recognition of these phytochemicals and their safety profile may lead to new therapeutic agents' development for VM elimination in different types of tumors.

Diabetes affects endothelial cell function and alters fibrin clot formation in a microvascular flow model: A pilot study.

Diabetes is a proinflammatory and prothrombotic condition that increases the risk of vascular complications. The aim of this study was to develop a diabetic microvascular flow model that allows to study the complex interactions between endothelial cells, blood cells and plasma proteins and their effects on clot formation. Primary human cardiac microvascular endothelial cells from donors without diabetes or donors with diabetes (type 1 or type 2) were grown in a microfluidic chip, perfused with non-diabetic or diabetic whole blood, and clot formation was assessed by measuring fibrin deposition in real time by confocal microscopy. Clot formation in non-diabetic whole blood was significantly increased in the presence of endothelial cells from donors with type 2 diabetes compared with cells from donors without diabetes. There was no significant difference in clot formation between non-diabetic and diabetic whole blood. We present for the first time a diabetic microvascular flow model as a new tool to study clot formation as a result of the complex interactions between endothelial cells, blood cells and plasma proteins in a diabetes setting. We show that endothelial cells affect clot formation in whole blood, attributing an important role to the endothelium in the development of atherothrombotic complications.

Zinc Treatment Stimulates Thymic Regeneration after Bone Marrow Transplant

Prolonged T cell reconstitution after allogeneic hematopoietic stem cell transplant (allo-HSCT) is an important contributor to transplant-related morbidity and mortality due to infection and malignant relapse. Therefore, strategies to enhance thymic reconstitution in allo-HSCT recipients are clinically desirable, although currently limited. Zinc, the second most abundant trace metal in the body, plays an important role in T cell homeostasis and thymic function. In a mouse model of allo-HSCT (Fig. a), we demonstrated that zinc supplementation can significantly improve thymic regeneration (Fig. b). Importantly, these findings in thymus were translated to the periphery as mice that received zinc supplementation showed increased numbers of naïve T cells as well as increased recent thymic emigrants (demonstrated using RAG2-GFP BM donors) model (Fig. c-d) 5-8 weeks after allo-HSCT. We have previously demonstrated that endothelial cells (EC), which are extremely resistant to damage, can promote endogenous thymic regeneration after acute injury via their production of BMP4, a growth factor that targets thymic epithelial cells (TECs), a key population crucial for T cell development. Interestingly, when stimulated in vitro for 24 hours with zinc sulphate, ECs could be directly induced to produce BMP4, but not when exposed to increased zinc import with the cell-permeable zinc pyrithione (Fig. e). This latter finding suggests a role for extracellular zinc in stimulating the endogenous response to damage. To explore this, we first measured the content of zinc in whole mouse thymus by mass spectrometry. Interestingly, when we examined a lysate of the entire thymus, total zinc concentration sharply declined early after total body radiation (TBI), followed by a steady increase that mirrored the reconstitution of the thymic cellularity (Fig. f). However, if we looked at zinc in the extracellular fraction of thymic dissociation (referred to as supernatants, SN), we saw that zinc increased significantly after TBI, revealing an inverse correlation with thymic cellularity (Fig. g), and providing a rationale for how zinc might contribute to the endogenous regenerative response. Given these findings, we hypothesized that zinc is normally used and stored in the T-cell precursors, a population of highly-replicating cells that account for approximately 98% of thymic cellularity in young mice and require the import of intracellular zinc for their proliferation. T-cell precursors are radio-sensitive and might release zinc in the extracellular space after cell death due to TBI, thereby triggering the production of regenerating factors from radio resistant cells, such as EC. Zinc supplementation could help this loop by increasing endogenous zinc levels. This hypothesis was confirmed when we co-cultured EC in presence of thymic SN there was no difference in BMP4 expression in cocultures with SN from control and zinc-treated mice at day 0, whereas BMP4 increased in presence of SN harvested from mice that had previously received TBI and even more when mice also received zinc supplement (Fig h). In conclusion, our findings demonstrate that zinc supplementation can improve T-cell regeneration in mice receiving allo-HSCT by reinforcing endogenous mechanisms of thymic regeneration. These results could be readily clinically translated into better outcomes for recipients of allo-HCT. Figure Disclosures No relevant conflicts of interest to declare.

Harnessing Macrophages for Vascularization in Tissue Engineering.

In this review, we explore the roles of macrophages both in vessel development and in vascularization of tissue engineered constructs. Upon the implantation of tissue engineered constructs into the body, macrophages respond, invade and orchestrate the host's immune response. By altering their phenotype, macrophages can adopt a variety of roles. They can promote inflammation at the site of the implanted construct; they can also promote tissue repair. Macrophages support tissue repair by promoting angiogenesis through the secretion of pro-angiogenic cytokines and by behaving as support cells for nascent vasculature. Thus, the ability to manipulate the macrophage phenotype mayyield macrophages capable ofsupporting vessel development. Moreover, macrophages are an easily isolated autologous cell source. For the generation of vascularized constructs outside of the body, these isolated macrophages can also be skewed to adopt a pro-angiogenic phenotype and enhance blood vessel development in the presence of endothelial cells. To assess the influence of macrophages on vessel development, both in vivo and in vitro models have been developed. Additionally, several groups have demonstrated the pro-angiogenic roles of macrophages in vascularization of tissue engineered constructs through the manipulation of macrophage phenotypes. This review comments on the roles of macrophages in promoting vascularization within these contexts.

Trophoblast-endothelium signaling involves angiogenesis and apoptosis in a dynamic bioprinted placenta model.

Trophoblast invasion and remodeling of the maternal spiral arteries are required for pregnancy success. Aberrant endothelium-trophoblast crosstalk may lead to preeclampsia, a pregnancy complication that has serious effects on both the mother and the baby. However, our understanding of the mechanisms involved in this pathology remains elementary because the current in vitro models cannot describe trophoblast-endothelium interactions under dynamic culture. In this study, we developed a dynamic three-dimensional (3D) placenta model by bioprinting trophoblasts and an endothelialized lumen in a perfusion bioreactor. We found the 3D printed perfusion bioreactor system significantly augmented responses of endothelial cells by encouraging network formations and expressions of angiogenic markers, cluster of differentiation 31 (CD31), matrix metalloproteinase-2 (MMP2), matrix metalloproteinase-9 (MMP9), and vascular endothelial growth factor A (VEGFA). Bioprinting favored colocalization of trophoblasts with endothelial cells, similar to in vivo observations. Additional analysis revealed that trophoblasts reduced the angiogenic responses by reducing network formation and motility rates while inducing apoptosis of endothelial cells. Moreover, the presence of endothelial cells appeared to inhibit trophoblast invasion rates. These results clearly demonstrated the utility and potential of bioprinting and perfusion bioreactor system to model trophoblast-endothelium interactions in vitro. Our bioprinted placenta model represents a crucial step to develop advanced research approach that will expand our understanding and treatment options of preeclampsia and other pregnancy-related pathologies.