Nadia Abutaleb scite author profile

Adult skeletal muscle has a robust capacity for self-repair, owing to synergies between muscle satellite cells and the immune system. In vitro models of muscle self-repair would facilitate the basic understanding of muscle regeneration and the screening of therapies for muscle disease. Here, we show that the incorporation of macrophages into muscle tissues engineered from adult-rat myogenic cells enables near-complete structural and functional repair after cardiotoxic injury in vitro. First, we show that—in contrast with injured neonatal-derived engineered muscle—adult-derived engineered muscle fails to properly self-repair after injury, even when treated with pro-regenerative cytokines. We then show that rat bone-marrow-derived macrophages or human blood-derived macrophages resident within the in vitro engineered tissues stimulate muscle satellite cell-mediated myogenesis while significantly limiting myofibre apoptosis and degeneration. Moreover, bone-marrow-derived macrophages within engineered tissues implanted in a mouse dorsal window-chamber model augmented blood vessel ingrowth, cell survival, muscle regeneration and contractile function.

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iPSC-Derived Endothelial Cells Affect Vascular Function in a Tissue-Engineered Blood Vessel Model of Hutchinson-Gilford Progeria Syndrome

Atchison

Abutaleb

Snyder-Mounts

et al. 2020

Stem Cell Reports

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Hutchinson-Gilford progeria syndrome (HGPS) is a rare disorder caused by a point mutation in the Lamin A gene that produces the protein progerin. Progerin toxicity leads to accelerated aging and death from cardiovascular disease. To elucidate the effects of progerin on endothelial cells, we prepared tissue-engineered blood vessels (viTEBVs) using induced pluripotent stem cell-derived smooth muscle cells (viSMCs) and endothelial cells (viECs) from HGPS patients. HGPS viECs aligned with flow but exhibited reduced flow-responsive gene expression and altered NOS3 levels. Relative to viTEBVs with healthy cells, HGPS viTEBVs showed reduced function and exhibited markers of cardiovascular disease associated with endothelium. HGPS viTEBVs exhibited a reduction in both vasoconstriction and vasodilation. Preparing vi-TEBVs with HGPS viECs and healthy viSMCs only reduced vasodilation. Furthermore, HGPS viECs produced VCAM1 and E-selectin protein in TEBVs with healthy or HGPS viSMCs. In summary, the viTEBV model has identified a role of the endothelium in HGPS.

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Engineered skeletal muscles for disease modeling and drug discovery

et al. 2019

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Development and Application of Endothelial Cells Derived From Pluripotent Stem Cells in Microphysiological Systems Models

Kennedy

Brown

Abutaleb

et al. 2021

Front. Cardiovasc. Med.

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The vascular endothelium is present in all organs and blood vessels, facilitates the exchange of nutrients and waste throughout different organ systems in the body, and sets the tone for healthy vessel function. Mechanosensitive in nature, the endothelium responds to the magnitude and temporal waveform of shear stress in the vessels. Endothelial dysfunction can lead to atherosclerosis and other diseases. Modeling endothelial function and dysfunction in organ systems in vitro, such as the blood–brain barrier and tissue-engineered blood vessels, requires sourcing endothelial cells (ECs) for these biomedical engineering applications. It can be difficult to source primary, easily renewable ECs that possess the function or dysfunction in question. In contrast, human pluripotent stem cells (hPSCs) can be sourced from donors of interest and renewed almost indefinitely. In this review, we highlight how knowledge of vascular EC development in vivo is used to differentiate induced pluripotent stem cells (iPSC) into ECs. We then describe how iPSC-derived ECs are being used currently in in vitro models of organ function and disease and in vivo applications.

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Engineering Escherichia coli for enhanced sensitivity to the autoinducer‐2 quorum sensing signal

Stephens

Zargar

Emamian

et al. 2019

Biotechnology Progress

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The autoinducer‐2 (AI‐2) quorum sensing system is involved in a range of population‐based bacterial behaviors and has been engineered for cell–cell communication in synthetic biology systems. Investigation into the cellular mechanisms of AI‐2 processing has determined that overexpression of uptake genes increases AI‐2 uptake rate, and genomic deletions of degradation genes lowers the AI‐2 level required for activation of reporter genes. Here, we combine these two strategies to engineer an Escherichia coli strain with enhanced ability to detect and respond to AI‐2. In an E. coli strain that does not produce AI‐2, we monitored AI‐2 uptake and reporter protein expression in a strain that overproduced the AI‐2 uptake or phosphorylation units LsrACDB or LsrK, a strain with the deletion of AI‐2 degradation units LsrF and LsrG, and an “enhanced” strain with both overproduction of AI‐2 uptake and deletion of AI‐2 degradation elements. By adding up to 40 μM AI‐2 to growing cell cultures, we determine that this “enhanced” AI‐2 sensitive strain both uptakes AI‐2 more rapidly and responds with increased reporter protein expression than the others. This work expands the toolbox for manipulating AI‐2 quorum sensing processes both in native environments and for synthetic biology applications.

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Nadia Abutaleb

Incorporation of macrophages into engineered skeletal muscle enables enhanced muscle regeneration

iPSC-Derived Endothelial Cells Affect Vascular Function in a Tissue-Engineered Blood Vessel Model of Hutchinson-Gilford Progeria Syndrome

Engineered skeletal muscles for disease modeling and drug discovery

Development and Application of Endothelial Cells Derived From Pluripotent Stem Cells in Microphysiological Systems Models

Engineering Escherichia coli for enhanced sensitivity to the autoinducer‐2 quorum sensing signal

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