The generation and validation of a dual cardiac HAND1-Tomato NKX2-5-GFP human embryonic stem cell line UMANe002-A-3.

The transcription factor HAND1 is a critical regulator of cardiac development which is expressed in sub-populations of cardiac progenitors and cardiomyocytes. The transcription factor NKX2-5, in contrast, is expressed more widely in cardiac cells. Here we report the generation of a dual reporter hESC line where the expression of these genes can be simultaneously measured, enabling lineage analysis as well as studies of HAND1 and NKX2-5 gene regulation and protein function. This tool will have wide utility particularly for research on developmental biology and disease modelling.

The generation and validation of two NKX2-5 fluorescent reporter human embryonic stem cell lines: UMANe002-A-1 and UMANe002-A-2.

The transcription factor NKX2-5 is a highly conserved master regulator of heart development which is widely expressed in cardiac progenitors and cardiomyocytes. Fluorescent reporters of NKX2-5 that minimally perturb normal protein expression can enable the identification, quantification and isolation of NKX2-5-expressing cells in a normal physiological state. Here we report the generation of two new hESC lines with eGFP inserted upstream (5') or downstream (3') of NKX2-5, linked by a cleavable T2A peptide. These complementary reporters produce a robust fluorescent signal in cardiac cells and have wide utility particularly for research on developmental biology and disease modelling.

An in vitro rat model of colonic motility to determine the effect of ß-casomorphin-5 on propagating contractions.

Beta-casomorphin-5 (ßCM-5) is a milk-derived bioactive peptide that slows gastro-intestinal transit (GIT) in vivo and blocks the peristaltic reflex in the guinea pig colon in vitro. We wanted to establish an in vitro model system in which effects of dairy-derived substances containing opioid peptides on intestinal motility can be assessed and used to predict in vivo outcomes. Because ßCM-5 is an opioid agonist that acts on enteric neurons, we used this substance to compare two different isolated colonic tissue preparations to determine which would more closely mimic the in vivo response previously reported in the literature. We compared and characterized the effects of ßCM-5 on spontaneous contractions in isolated segments of distal colon (1 cm length) compared with propagating contractions along the isolated intact large intestine (22 cm length). In short segments of distal colon, ßCM-5 increased the tension and frequency of spontaneous contractions in a concentration-dependent manner. At 20 µM ßCM-5 tension increased by 71 ± 17% and the frequency doubled (n = 9), effects inhibited by naloxone (n = 7) and therefore mediated by opioid receptors. In contrast 20 µM ßCM-5 disrupted propagating contractions in the large intestine preparation. At 20 µM ßCM-5 reduced the proportion of contractions initiated in the proximal colon reaching the rectum by 83 ± 11% (n = 5) and this effect was also inhibited by naloxone, consistent with altered GIT reported in vivo. Our results demonstrate that the isolated whole large intestine provides an ideal preparation that mimics the reduced propagation of GIT in vivo in response to an opioid agonist, whereas short colon segments did not. The findings of the current study reveal that preserving large segments of intact large intestine, and hence intact enteric neural circuitry provides an ideal in vitro model to investigate the effect of opioid receptor modulators on intestinal transit.