In vitro epigenetic reprogramming of human cardiac mesenchymal stromal cells into functionally competent cardiovascular precursors

Adult human cardiac mesenchymal-like stromal cells (CStC) represent a relatively accessible cell type useful for therapy. In this light, their conversion into cardiovascular precursors represents a potential successful strategy for cardiac repair. The aim of the present work was to reprogram CStC into functionally competent cardiovascular precursors using epigenetically active small molecules. CStC were exposed to low serum (5% FBS) in the presence of 5 \ub5M all-trans Retinoic Acid (ATRA), 5 \ub5M Phenyl Butyrate (PB), and 200 \ub5M diethylenetriamine/nitric oxide (DETA/NO), to create a novel epigenetically active cocktail (EpiC). Upon treatment the expression of markers typical of cardiac resident stem cells such as c-Kit and MDR-1 were up-regulated, together with the expression of a number of cardiovascular-associated genes including KDR, GATA6, Nkx2.5, GATA4, HCN4, NaV1.5, and \u3b1-MHC. In addition, profiling analysis revealed that a significant number of microRNA involved in cardiomyocyte biology and cell differentiation/proliferation, including miR 133a, 210 and 34a, were up-regulated. Remarkably, almost 45% of EpiC-treated cells exhibited a TTX-sensitive sodium current and, to a lower extent in a few cells, also the pacemaker I(f) current. Mechanistically, the exposure to EpiC treatment introduced global histone modifications, characterized by increased levels of H3K4Me3 and H4K16Ac, as well as reduced H4K20Me3 and H3s10P, a pattern compatible with reduced proliferation and chromatin relaxation. Consistently, ChIP experiments performed with H3K4me3 or H3s10P histone modifications revealed the presence of a specific EpiC-dependent pattern in c-Kit, MDR-1, and Nkx2.5 promoter regions, possibly contributing to their modified expression. Taken together, these data indicate that CStC may be epigenetically reprogrammed to acquire molecular and biological properties associated with competent cardiovascular precursors

Pseudo-Placentational Endometrial Hyperplasia in the Bitch: Case Series

Canine pseudo-placentational endometrial hyperplasia differs from the classical form of cystic endometrial hyperplasia for the well-organized tissue architecture resembling the canine placenta. After the discovery, it has been inconstantly reported. The present work reports the clinicopathological details of six spontaneous cases retrieved retrospectively from a large database. The lesion was found in young non-pregnant female dogs (median 2.0 years) at the end of dioestrus. It could be imaged by ultrasound and was always grossly detectable as single or multiple uterine enlargements of 2–3 cm in diameter with a villous whitish tissue growing on the mucosa and occluding the lumen. Histology confirmed the tissue architecture of the canine placenta with a basal glandular layer, a connective band, a spongy layer and a tortuous and compact labyrinth, often poorly recognizable. The pseudo-placentational hyperplasia is a non-inflammatory proliferative lesion although numerous mast cells inhabit the connective band, and a superimposed inflammatory infiltrate was seen in a case. Canine pseudo-placentational endometrial hyperplasia has very peculiar features, and it is a model for canine placentation and may help to better understand the cystic endometrial hyperplasia/pyometra complex

Pseudo-Placentational Endometrial Hyperplasia in the Bitch: Case Series

Canine pseudo-placentational endometrial hyperplasia differs from the classical form of cystic endometrial hyperplasia for the well-organized tissue architecture resembling the canine placenta. After the discovery, it has been inconstantly reported. The present work reports the clinicopathological details of six spontaneous cases retrieved retrospectively from a large database. The lesion was found in young non-pregnant female dogs (median 2.0 years) at the end of dioestrus. It could be imaged by ultrasound and was always grossly detectable as single or multiple uterine enlargements of 2–3 cm in diameter with a villous whitish tissue growing on the mucosa and occluding the lumen. Histology confirmed the tissue architecture of the canine placenta with a basal glandular layer, a connective band, a spongy layer and a tortuous and compact labyrinth, often poorly recognizable. The pseudo-placentational hyperplasia is a non-inflammatory proliferative lesion although numerous mast cells inhabit the connective band, and a superimposed inflammatory infiltrate was seen in a case. Canine pseudo-placentational endometrial hyperplasia has very peculiar features, and it is a model for canine placentation and may help to better understand the cystic endometrial hyperplasia/pyometra complex

Mesoangioblasts from ventricular vessels can differentiate in vitro into cardiac myocytes with sinoatrial-like properties

Cardiac mesoangioblasts (MABs) are a class of vessel-associated clonogenic, self-renewing progenitor cells, recently identified in the post-natal murine heart and committed to cardiac differentiation. Cardiomyocytes generated during cardiogenesis from progenitor cells acquire several distinct phenotypes, corresponding to different functional properties in diverse structures of the adult heart. Given the special functional relevance to rhythm generation and rate control of sinoatrial cells, and in view of their prospective use in therapeutical applications, we sought to determine if, and to what extent, cardiac mesoangioblasts could also differentiate into myocytes with properties typical of mature pacemaker myocytes. We report here that a subpopulation of cardiac mesoangioblasts, induced to differentiate in vitro into cardiomyocytes, do acquire a phenotype with specific mature pacemaker myocytes properties. These include expression of the HCN4 isoform of pacemaker ("funny", f-) channels and connexin 45 (Cx45), as well as reduced expression of inwardly-rectifying potassium channels. Furthermore, MAB-derived myocytes form agglomerates of pacing cells displaying stable rhythmic activity, and as in native cardiac pacemaker cells, f-channel modulation by autonomic transmitters contributes to control of spontaneous rate in differentiated mesoangioblasts. These data represent the first evidence for in vitro generation of pacemaker-like myocytes from proliferating non-embryonic stem/progenitor cells

EpiC-treated CStCs express functionally competent ion channels.

<p>In panel (A) a family sodium current recorded from a representative EpiC-treated TTX (10 µM) low -sensitive CStC, following the application of a standard depolarizing protocol (see inset), is shown. (B) Mean current-voltage relation of normalized TTX-sensitive currents showing a threshold of activation around −40 mV and a peak around 0 mV. (C) SCN5A and SCN2A genes were up-regulated (n = 3, *P≤0.05) by real-time PCR analysis. (D) Western Blot evidences increase of the type V (NaV1.5) and type II (NaV1.2) voltage-gated sodium channel protein level in CStC cells exposed to EpiC (n = 5, *P≤0.05). FL = full length protein. (E) In few cells, membrane hyperpolarization in the range −35 to −125 mV (see inset) revealed an inward current with the kinetic features of the native pacemaker I_f current. (F) Plot of the mean activation curve obtained from the analysis of the I_f currents recorded in a subset of EpiC-treated CStC.</p

Differentially expressed microRNAs.

<p>microRNA normalized relative expression levels in GM and EpiC-treated cells are expressed as mean ± SD. FC = fold change. FDR = false discovery rate.</p