Production of zebrafish cardiospheres and cardiac progenitor cells in vitro and three-dimensional culture of adult zebrafish cardiac tissue in scaffolds.

The hearts of adult zebrafish (Danio rerio) are capable of complete regeneration in vivo even after major injury, making this species of particular interest for understanding the growth and differentiation processes required for cardiac tissue engineering. To date, little research has been carried out on in vitro culture of adult zebrafish cardiac cells. In this work, progenitor-rich cardiospheres suitable for cardiomyocyte differentiation and myocardial regeneration were produced from adult zebrafish hearts. The cardiospheres contained a mixed population of c-kit+ and Mef2c+ cells; proliferative peripheral cells of possible mesenchymal lineage were also observed. Cellular outgrowth from cardiac explants and cardiospheres was enhanced significantly using conditioned medium harvested from cultures of a rainbow trout cell line, suggesting that fish-specific trophic factors are required for zebrafish cardiac cell expansion. Three-dimensional culture of zebrafish heart cells in fibrous polyglycolic acid (PGA) scaffolds was carried out under dynamic fluid flow conditions. High levels of cell viability and cardiomyocyte differentiation were maintained within the scaffolds. Expression of cardiac troponin T, a marker of differentiated cardiomyocytes, increased during the first 7 days of scaffold culture; after 15 days, premature disintegration of the biodegradable scaffolds led to cell detachment and a decline in differentiation status. This work expands our technical capabilities for three-dimensional zebrafish cardiac cell culture with potential applications in tissue engineering, drug and toxicology screening, and ontogeny research. Biotechnol. Bioeng. 2017;114: 2142-2148. © 2017 Wiley Periodicals, Inc.

Lmx1a allows context-specific isolation of progenitors of GABAergic or dopaminergic neurons during neural differentiation of embryonic stem cells.

LIM homeobox transcription factor 1 alpha (Lmx1a) is required for the development of midbrain dopaminergic neurons, roof plate formation, and cortical hem development. We generated a reporter embryonic stem cell (ESC) line for Lmx1a and used it to track differentiation and extract neural progenitors from differentiating mouse ESCs. Lmx1a(+) cells gave rise to functional cortical upper layer GABAergic neurons or dopaminergic neurons depending on the culture conditions used for differentiation. Under chemically defined neurobasal conditions, ESC differentiation resulted in widespread and transient expression of Lmx1a, without the addition of exogenous factors such as sonic hedgehog (Shh), Wnts, and/or bone morphogenic proteins (BMPs). Under neutral conditions, Lmx1a(+) cells express genes known to be downstream of Lmx1a and cortical hem markers Wnt3a and p73. The majority of these cells did not express the ventral midbrain dopaminergic marker Foxa2 or dorsal roof plate marker BMP-2. Lmx1a(+) -Foxa2(-) cells were primed to become SatB2(+) GABAergic neurons and appeared to be resistant to dopaminergic patterning cues. PA6 coculture produced a substantial population of Lmx1a(+) progenitors that also expressed Foxa2 and on further differentiation gave rise to dopaminergic neurons at high frequency. We conclude that Lmx1a is a useful marker for the extraction of progenitors of GABAergic or dopaminergic neurons. We caution against the assumption that it indicates dopaminergic commitment during in vitro differentiation of ESCs. Indeed, in monolayer culture under neurobasal conditions, with or without the addition of Shh and fibroblast growth factor 8 (FGF8), Lmx1a(+) cells were predominantly progenitors of forebrain GABAergic neurons. We obtained dopaminergic cells in large numbers only by coculture with PA6 cells.

Interactivity of biochemical and physical stimuli during epigenetic conditioning and cardiomyocytic differentiation of stem and progenitor cells derived from adult hearts.

Mixed populations of cardiosphere-derived stem and progenitor cells containing proliferative and cardiomyogenically committed cells were obtained from adult rat hearts. The cells were cultured in either static 2D monolayers or dynamic 3D scaffold systems with fluid flow. Cardiomyocyte lineage commitment in terms of GATA4 and Nkx2.5 expression was significantly enhanced in the dynamic 3D cultures compared with static 2D conditions. Treatment of the cells with 5-azacytidine (5-aza) produced different responses in the two culture systems, as activity of this chemical epigenetic conditioning agent depended on the cell attachment and hydrodynamic conditions provided during culture. Cell growth was unaffected by 5-aza in the static 2D cultures but was significantly reduced under dynamic 3D conditions relative to untreated controls. Myogenic differentiation measured as Mef2c expression was markedly upregulated by 5-aza in the dynamic 3D cultures but downregulated in the static 2D cultures. The ability of the physical environment to modulate the cellular cardiomyogenic response to 5-aza underscores the interactivity of biochemical and physical stimuli applied for cell differentiation. Accordingly, observations about the efficacy of 5-aza as a cardiomyocyte induction agent may not be applicable across different culture systems. Overall, use of dynamic 3D rather than static 2D culture was more beneficial for cardio-specific myogenesis than 5-aza treatment, which generated a more ambiguous differentiation response.

Nanotopography as a trigger for the microscale, autogenous and passive lysis of erythrocytes.

Microscale devices are increasingly being developed for diagnostic analysis although conventional lysis as an initial step presents limitations due to its scale or complexity. Here, we detail the physical response of erythrocytes to the surface nanoarchitecture of black Si (bSi) and foreshadow their potential in microanalysis. The physical interaction brought about by the spatial convergence of the two topologies: (a) the nanopillar array present on the bSi and (b) the erythrocyte cytoskeleton present on the red blood cells (RBCs), provides spontaneous stress-induced cell deformation, rupture and passive lysis within an elapsed time of ∼3 min from immobilisation to rupture and without external chemical or mechanical intervention. The mechano-responsive bSi surface provides highly active yet autogenous RBC lysis and a prospect as a front-end platform technology in evolving micro-fluidic platforms for cellular analyses.

Extended periods of neural induction and propagation of embryonic stem cell-derived neural progenitors with EGF and FGF2 enhances Lmx1a expression and neurogenic potential.

Neural stem (NS) cells are multipotent cells defined by their capacity to proliferate and differentiate into all neuronal and glial phenotypes. NS cells can be obtained from specific regions of the adult brain, or generated from embryonic stem cells (ESCs). NS cells differentiate into neural progenitor (NP) cells and subsequently neural precursors, as transient steps towards terminal differentiation into specific mature neuronal or glial phenotypes. When cultured in EGF and FGF2, ESC-derived NS cells have been reported to be stable and multipotent. Conditions that enable differentiation of NS cells through the committed progenitor and precursor stages to specific neuronal subtypes have not been fully established. In this study we investigated, using Lmx1a reporter ESCs, whether the length of neural induction (NI) dictated the phenotypic potential of cultures of ESC-derived NS cells or NP cells. Following 4, 7 or 10 day periods of NI, ESCs in monolayer culture were harvested and cultured as neurospheres, prior to replating as monolayer cultures for several passages in EGF and FGF2. The NS/NP cultures were then directed towards mature neuronal fates over 16-17 days. 4 and 7-day NS cell cultures could not be differentiated towards dopaminergic, serotonergic or cholinergic fates as determined by the absence of tyrosine hydroxylase, 5-HT or choline acetyltransferase (ChAT) immunolabelling. In contrast NS/NP cultures derived after 10 days of NI were able to generate tyrosine hydroxylase and 5-HT positive neurons (24±6 and 13±1% of the ßIII-tubulin positive population, respectively, n=3). Our data suggest that extended periods of neural induction enhanced the potential of mouse ESC-derived NS/NP cells to generate specific subtypes of neurons. NS/NP cells derived after shorter periods of NI appeared to be lineage-restricted in relation to the neuronal subtypes observed after removal of EGF.