Possibly a short period of differentiation, analysis of marker connected with terminal differentiation only, and low transduction efficacy of HO-1 construct (112) could hinder the detection of potential influence. in cell differentiation, and possible HO-1-dependent signal transduction pathways. Among the potential mediators, we focused RAD1901 HCl salt on microRNA (miRNA). These Spry2 small, noncoding RNAs are critical for cell differentiation. Recently we have found that HO-1 not RAD1901 HCl salt only influences expression of specific miRNAs but also regulates miRNA processing enzymes. It seems that interplay between HO-1 and miRNAs may be important in regulating fates of stem and progenitor cells and needs further intensive studies. 20, 1827C1850. Introduction Stem and progenitor cells Stem cells (SCs) are defined by two major features. First, they can differentiate into diverse specialized cell types. Second, they are capable of self-renewalafter asymmetric division each SC can generate one daughter cell with a stemness characteristic, and one daughter cell that differentiates. In this manner SCs can maintain their own population. They can also undergo a symmetric division to self-renew and expand (193). SCs can be classified according to their differentiation potency to (i) totipotent, (ii) pluripotent, (iii) multipotent, and (iv) unipotent (monopotent). Totipotent SCs can give rise to all embryonic as well as extraembryonic tissues (trophoblast and placenta). This feature is evident only for zygote (which itself is not an SC, as does not self-renew), and cells within the first couple of divisions after fertilization (193). Pluripotent embryonic stem cells (ESCs) appear at later stage of embryogenesis and their cultures are established from epiblast tissue of the inner cell mass of a blastocyst. They can develop into all cell types in embryo, regardless of the germ layer, and can form all cells of the organisms, except of the placenta. Among markers characteristic for pluripotent SCs are Oct4, Nanog, SSEA-1 (in mouse), or SSEA-4 (in human). In 2006 a breakthrough research demonstrated that pluripotent cells can be obtained from terminally differentiated somatic cells by an enforced expression RAD1901 HCl salt of Oct4 and Sox2, accompanied by Klf4 and Myc or Nanog and Lin28. Reprogramming of human somatic cells was demonstrated a year later. Cells created this way are termed the induced pluripotent stem cells (iPS cells) and resemble ESCs, as they are able to differentiate in all somatic tissues as well as contribute to germline (18, 164, 193). Multipotent SCs can differentiate into tissues of a single germ layer. Mesenchymal stem cells (MSCs) are regarded as multipotent, since they can differentiate into osteoblasts, chondrocytes, and adipocytes. Additionally, MSCs were postulated to give rise to functional endothelial cells or cardiomyocytes; however, this concept has not been conclusively proved so far (21, 22, 193). Despite suggestions that MSCs can be found in different adult tissues (gene) is regulated mainly at the transcriptional level (133, 178) (Fig. 2). However, as it was recently shown, expression of HO-1 is also regulated directly and RAD1901 HCl salt indirectly by miRNAs (Fig. 2). Thus, miR-377 and miR-217 decrease HO-1 level in endothelial cells by interaction with 3UTR of mRNA (17). Additionally, miR-122 was shown to reduce HO-1 expression (172), whereas our recent work highlights a negative regulation of HO-1 by miR-200c in renal proximal tubular epithelial cells (195) and by miR-378 in lung cancer cells (189). The other important mediator is also miR-155 that targets Bach1 mRNA and thereby increases expression of HO-1 in endothelial cells and macrophages by enhancing Nrf2 activity (109, 171), as well as miR-196 and let-7, which have similar effects in hepatocytes (74, 75). miR-132 by silencing Nrf2 mRNA can decrease HO-1 expression (195). It is important to note that regulation of HO-1 by miRNAs can be cell-type specific, as, for example, neither miR-217 nor miR-377 is expressed in kidney proximal tubular epithelial cells (195). Open in a.