matrix interactions
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Biomedicines ◽  
2022 ◽  
Vol 10 (1) ◽  
pp. 102
Author(s):  
Matteo Gasparotto ◽  
Yuriko Suemi Hernandez Gomez ◽  
Daniele Peterle ◽  
Alessandro Grinzato ◽  
Federica Zen ◽  
...  

Homo- and heterophilic binding mediated by the immunoglobulin (Ig)-like repeats of cell adhesion molecules play a pivotal role in cell-cell and cell-extracellular matrix interactions. L1CAM is crucial to neuronal differentiation, in both mature and developing nervous systems, and several studies suggest that its functional interactions are mainly mediated by Ig2–Ig2 binding. X-linked mutations in the human L1CAM gene are summarized as L1 diseases, including the most diagnosed CRASH neurodevelopmental syndrome. In silico simulations provided a molecular rationale for CRASH phenotypes resulting from mutations I179S and R184Q in the homophilic binding region of Ig2. A synthetic peptide reproducing such region could both mimic the neuritogenic capacity of L1CAM and rescue neuritogenesis in a cellular model of the CRASH syndrome, where the full L1CAM ectodomain proved ineffective. Presented functional evidence opens the route to the use of L1CAM-derived peptides as biotechnological and therapeutic tools.


Author(s):  
Andrea Mazzocchi ◽  
Kyung Min Yoo ◽  
Kylie Nairon ◽  
L. Madison Kirk ◽  
Elaheh Rahbar ◽  
...  

Abstract Current in vitro 3D models of liver tissue have been limited by the inability to study the effects of specific extracellular matrix (ECM) components on cell phenotypes. This is in part due to limitations in the availability of chemical modifications appropriate for this purpose. For example, hyaluronic acid (HA), which is a natural ECM component within the liver, lacks key ECM motifs (e.g., RGD peptides) that support cell adhesion. However, the addition of maleimide (Mal) groups to HA could facilitate the conjugation of ECM biomimetic peptides with thiol-containing end groups. In this study, we characterized a new crosslinkable hydrogel (i.e., HA-Mal) that yielded a simplified ECM-mimicking microenvironment supportive of 3D liver cell culture. We then performed a series of experiments to assess the impact of physical and biochemical signaling in the form of RGD peptide incorporation and TGF- ß supplementation, respectively, on hepatic functionality. Hepatic stellate cells (i.e., LX-2) exhibited increased cell-matrix interactions in the form of cell spreading and elongation within HA-Mal matrices containing RGD peptides, enabling physical adhesions, whereas hepatocyte-like cells (HepG2) had reduced albumin and urea production. We further exposed the encapsulated cells to soluble TGF-ß to elicit a fibrosis-like state. In the presence of TGF-ß biochemical signals, LX-2 cells became activated and HepG2 functionality significantly decreased in both RGD-containing and RGD-free hydrogels. Altogether, in this study we have developed a hydrogel biomaterial platform that allows for discrete manipulation of specific ECM motifs within the hydrogel to better understand the roles of cell-matrix interactions on cell phenotype and overall liver functionality.


2021 ◽  
Vol 11 ◽  
Author(s):  
Gulimirerouzi Fnu ◽  
Georg F. Weber

We have previously reported that metastases from all malignancies are characterized by a core program of gene expression that suppresses extracellular matrix interactions, induces vascularization/tissue remodeling, activates the oxidative metabolism, and alters ion homeostasis. Among these features, the least elucidated component is ion homeostasis. Here we review the literature with the goal to infer a better mechanistic understanding of the progression-associated ionic alterations and identify the most promising drugs for treatment. Cancer metastasis is accompanied by skewing in calcium, zinc, copper, potassium, sodium and chloride homeostasis. Membrane potential changes and water uptake through Aquaporins may also play roles. Drug candidates to reverse these alterations are at various stages of testing, with some having entered clinical trials. Challenges to their utilization comprise differences among tumor types and the involvement of multiple ions in each case. Further, adverse effects may become a concern, as channel blockers, chelators, or supplemented ions will affect healthy and transformed cells alike.


2021 ◽  
Author(s):  
Iain Muntz ◽  
Michele Fenu ◽  
Gerjo J V M van Osch ◽  
Gijsje Koenderink

Abstract Living tissue is able to withstand large stresses in everyday life, yet it also actively adapts to dynamic loads. This remarkable mechanical behaviour emerges from the interplay between living cells and their non-living extracellular environment. Here we review recent insights into the biophysical mechanisms involved in the reciprocal interplay between cells and the extracellular matrix and how this interplay determines tissue mechanics, with a focus on connective tissues. We first describe the roles of the main macromolecular components of the extracellular matrix in regards to tissue mechanics. We then proceed to highlight the main routes via which cells sense and respond to their biochemical and mechanical extracellular environment. Next we introduce the three main routes via which cells can modify their extracellular environment: exertion of contractile forces, secretion and deposition of matrix components, and matrix degradation. Finally we discuss how recent insights in the mechanobiology of cell-matrix interactions are furthering our understanding of the pathophysiology of connective tissue diseases and cancer, and facilitating the design of novel strategies for tissue engineering.


Author(s):  
Jinglei Wu ◽  
Jiazhu Xu ◽  
Yi-hui Huang ◽  
Liping Tang ◽  
Yi Hong

Abstract Decellularized meniscal extracellular matrix (ECM) material holds great potential for meniscus repair and regeneration. Particularly, injectable ECM hydrogel is highly desirable for the minimally invasive treatment of irregularly shaped defects. Although regional-specific variations of the meniscus are well documented, no ECM hydrogel has been reported to simulate zonally specific microenvironments of the native meniscus. To fill the gap, different (outer, middle, and inner) zones of porcine menisci were separately decellularized. Then the regionally decellularized meniscal ECMs were solubilized by pepsin digestion, neutralized, and then form injectable hydrogels. The hydrogels were characterized in gelation behaviors and mechanical properties and seeded with bovine fibrochondrocytes to evaluate the regionally biochemical effects on the cell-matrix interactions. Our results showed that the decellularized inner meniscal ECM (IM) contained the greatest glycosaminoglycan (GAG) content and the least collagen content compared with the decellularized outer meniscal ECM (OM) and middle meniscal ECM (MM). The IM hydrogel showed lower compressive strength than the OM hydrogel. When encapsulated with fibrochondrocytes, the IM hydrogel accumulated more GAG, contracted to a greater extent and reached higher compressive strength than that of the OM hydrogel at 28 days. Our findings demonstrate that the regionally specific meniscal ECMs present biochemical variation and show various effects on the cell behaviors, thus providing information on how meniscal ECM hydrogels may be utilized to reconstruct the microenvironments of the native meniscus.


Antioxidants ◽  
2021 ◽  
Vol 10 (11) ◽  
pp. 1825
Author(s):  
Łukasz Sęczyk ◽  
Urszula Gawlik-Dziki ◽  
Michał Świeca

This model study aimed to evaluate the effect of phenolic–food matrix interactions on the in vitro bioaccessibility and antioxidant activity of selected phenolic compounds (gallic acid, ferulic acid, chlorogenic acid, quercetin, apigenin, and catechin) as well as protein and starch digestibility in fortified white bean paste. The magnitude of food matrix effects on phenolics bioaccessibility and antioxidant activity was estimated based on “predicted values” and “combination indexes”. Furthermore, the protein–phenolics interactions were investigated using electrophoretic and chromatographic techniques. The results demonstrated phenolic–food matrix interactions, in most cases, negatively affected the in vitro bioaccessibility and antioxidant activity of phenolic compounds as well as nutrient digestibility. The lowest in vitro bioaccessibility of phenolic compounds in fortified paste was found for quercetin (45.4%). The most negative impact on the total starch digestibility and relative digestibility of proteins was observed for catechin–digestibility lower by 14.8%, and 21.3% (compared with control), respectively. The observed phenolic–food matrix interactions were strictly dependent on the applied phenolic compound, which indicates the complex nature of interactions and individual affinity of phenolic compounds to food matrix components. In conclusion, phenolic–food matrix interactions are an important factor affecting the nutraceutical and nutritional potential of fortified products.


Blood ◽  
2021 ◽  
Vol 138 (Supplement 1) ◽  
pp. 1137-1137
Author(s):  
Ishnoor Sidhu ◽  
Sonali P. Barwe ◽  
Kristi Lynn Kiick ◽  
E. Anders Kolb ◽  
Anilkumar Gopalakrishnapillai

Abstract The generation of hematopoietic stem and progenitor cells (HSPCs) from induced pluripotent stem cells (iPSCs) provides an extraordinary tool for hematological disease modeling of rare disorders such as Down syndrome (DS) associated transient myeloproliferative disorder (TMD). TMD is a preleukemic condition observed in 10-20% of children with trisomy 21 possessing the pathognomonic mutation in the transcription factor GATA1. Hematopoiesis in the bone marrow (BM) is affected by cell-cell and cell-matrix interactions. The current methods for iPSC differentiation into HSPCs utilize either 2-dimensional (2D) monolayer of mouse stromal cells or animal tissue derived extracellular matrices. Generation of a 3-dimensional (3D) culture environment attempts to facilitate both cell-cell and cell-matrix interactions during iPSC differentiation. This study reports the development of a 3D culture system for hematopoietic differentiation of iPSCs to model TMD. iPSC colonies were encapsulated in 3D polyethylene glycol (PEG) based hydrogels containing synthetic integrin binding peptide (GRGDSPC) and enzymatically degradable peptide (GGPQGIWGQGKG) (Fig. 1A) and cultured in maintenance medium (mTeSR1™, Stem Cell Technology) without feeder cells. There were notable morphological differences between the 3D encapsulated and 2D cultured iPSC colonies (Fig. 1B). The 3D encapsulation did not have an adverse effect on the viability of the iPSC colonies evaluated by in situ staining with viability dye (Fig. 1C). The 3D encapsulated colonies were more compact with a spheroid morphology in PEG whereas colonies in 2D were more flattened (Fig. 1D). The pluripotency of the 3D encapsulated iPSCs was confirmed alkaline phosphatase staining (purple colonies) and by the presence of >96% population expressing pluripotency markers, Tra-1-60 and SSEA-4 (Fig. 1E). To test the efficiency of the 3D model system to generate HSPCs, the encapsulated iPSCs were subjected to hematopoietic differentiation using STEMdiff Hematopoietic Kit. Following differentiation, immunophenotype analysis of single cells by flow cytometry revealed a 1.7-fold higher CD34+CD45+CD38-CD45RA- cell percentage in 3D hydrogels compared to 2D. Further delineation of sub-populations in HSPC compartment from 2D and 3D hydrogel revealed a 1.9-fold and 2.1-fold higher population of early HSPCs and multipotent progenitors (MPPs) in 3D compared to 2D respectively (Fig 1F, *P<0.05). In colony forming unit (CFU) assay, the 3D generated HSPCs gave rise to a 2.0-fold higher number of CFU-GEMM (granulocyte, erythrocyte, monocyte, megakaryocyte) colonies compared to 2D, with 2.0-fold decreased number of BFU-E (erythroid) colonies and a similar number of CFU-GM (granulocyte, macrophage) colonies (Fig. 1G). Thus, the low modulus synthetic matrix promoted hematopoietic differentiation producing higher percentage of early HSPCs as compared to the 2D culture system. We used this 3D system to model TMD by utilizing isogenic iPSCs with disomy 21 (D21), trisomy 21 (T21), and trisomy 21 bearing pathologic mutation in GATA1 (T21-G1). The megakaryoid population in the HSPCs generated by hematopoietic differentiation of 3D encapsulated iPSCs was characterized by the percentage of CD34+CD41+ population within the total CD41+ population, myeloid population as CD18+CD45+ and erythroid population as CD71+CD235+. T21 HSPCs showed increased erythroid and megakaryoid populations as compared to isogenic D21, consistent with the role of trisomy 21 in perturbing hematopoiesis. T21-G1 had elevated megakaryoid (93±6% vs 71±1%,) and myeloid (32±16% vs 8±4%) populations with reduced erythroid (27±12% vs 79±6%) population as compared to T21 HSPCs implicating GATA1s in altered hematopoiesis (Fig. 1H). T21-G1 HSPCs only produced CFU-GM colonies as compared to a high number of CFU-GEMM and BFU-E in T21 and D21 HSPCs (Fig. 1I). The expression of GATA1s in T21-G1 megakaryoid population was confirmed (Fig. 1J). The immunophenotype marker analysis of T21-G1 megakaryoid blasts showed expression of megakaryoid/erythroid antigens (CD41, CD61, CD42b, CD71) along with myeloid markers (CD11b, CD33, CD13) and increased expression of CD56 and CD117 consistent with TMD patients (Fig. 1K). In conclusion, our cost-effective tunable 3D hydrogel system promoted hematopoietic differentiation of iPSCs and generated TMD model mimicking the salient features of the disease. Figure 1 Figure 1. Disclosures Barwe: Prelude Therapeutics: Research Funding. Gopalakrishnapillai: Geron: Research Funding.


2021 ◽  
pp. 225-256
Author(s):  
Maik Liebl ◽  
Dietmar Eberbeck ◽  
Annelies Coene ◽  
Jonathan Leliaert ◽  
Philine Jauch ◽  
...  

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