SUMMARY:Smoking is associated with aberrant cutaneous tissue remodeling, such as precocious skin aging and impaired wound healing. The mechanism is not fully understood. Dermal fibroblasts (DF) are the primary cellular component of the dermis and may provide a target for pathobiologic effects of tobacco products. The purpose of this study was to characterize a mechanism of nicotine (Nic) effects on the growth and tissue remodeling function of DF. We hypothesized that the effects of Nic on DF result from its binding to specific nicotinic acetylcholine receptors (nAChRs) expressed by these cells and that downstream signaling from the receptors alters normal cell functioning, leading to changes in skin homeostasis. Using RT-PCR and Western blotting, we found that a 24-hour exposure of human DF to 10 M Nic causes a 1.9-to 28-fold increase of the mRNA and protein levels of the cell cycle regulators p21, cyclin D1, Ki-67, and PCNA and a 1.7-to 2-fold increase of the apoptosis regulators Bcl-2 and caspase 3. Nic exposure also up-regulated expression of the dermal matrix proteins collagen type I␣1 and elastin as well as matrix metalloproteinase-1. Mecamylamine (Mec), the specific antagonist of nAChRs, abolished Nic-induced alterations, indicating that they resulted from a pharmacologic stimulation of nAChRs expressed by DF. To establish the relevance of these findings to a specific nicotinergic pathway, we studied human DF transfected with anti-␣3 antisense oligonucleotides and murine DF from ␣3 nAChR knockout mice. In both cases, lack of ␣3 was associated with alterations in fibroblast growth and function that were opposite to those observed in DF treated with Nic, suggesting that the nicotinic effects on DF were mostly mediated by ␣3 nAChR. In addition to ␣3, the nAChR subunits detected in human DF were ␣5, ␣7, 2, and 4. The exposure of DF to Nic altered the relative amounts of each of these subunits, leading to reciprocal changes in [ 3 H]epibatidine-binding kinetics. Thus, some of the pathobiologic effects of tobacco products on extracellular matrix turnover in the skin may stem from Nic-induced alterations in the physiologic control of the unfolding of the genetically determined program of growth and the tissue remodeling function of DF as well as alterations in the structure and function of fibroblast nAChRs. (Lab Invest 2003, 83:207-225).
Abnormalities of nephrin expression appear to be associated with acquired as well as congenital causes of human nephrotic syndrome.
Clinical applications of gene therapy require advances in gene delivery systems. Although numerous clinical trials are already underway, the ultimate success of gene therapies will depend on gene transfer vectors that facilitate the expression of a specific gene at therapeutic levels in the desired cell populations without eliciting cytotoxicity. In clinical applications for which transient expression is desirable, mRNA delivery is of particular interest. We have shown cationic lipid-mediated mRNA delivery to be feasible, efficient, and reproducible in vitro. mRNA delivery to the cerebrospinal fluid (CSF) in vivo would provide a means of vector distribution throughout the central nervous system (CNS). This study examined the functional integrity and protection from degradation of mRNA/cationic complexes (lipoplexes) in human cerebrospinal fluid (hCSF) in vitro and expression of these lipoplexes in vivo. Results obtained from gel electrophoresis indicate that cationic lipids protect mRNA transcripts from RNases in hCSF for at least 4 hr. This is in contrast to the total disappearance of nonlipid-complexed mRNA in less than 5 min. We confirmed the importance of RNase activity by incubating mRNA transcripts encoding luciferase or green fluorescent protein (GFP) in hCSF to which RNase inhibitors had been added. After incubation, these solutions were used to transfect Chinese hamster ovary (CHO) cells in vitro. Next, assays for both GFP and luciferase were used to demonstrate functional integrity and translation of the mRNA transcripts. Finally, we delivered in vitro transcribed mRNA vectors encoding for Hsp70 and luciferase to the lateral ventricle of the rat in a series of preliminary in vivo experiments. Initial immunohistochemistry analysis demonstrates that the distribution, uptake, and expression of reporter sequences using lipid-mediated mRNA vector delivery is extensive, as we earlier reported using similar methods with DNA vectors but that the expression may be less intense. Expression was noted in coronal sections throughout the rat brain, confirming the potential for lipid-mediated mRNA delivery to the CNS. These findings confirm that complexing mRNA with cationic lipid before exposure to CSF confers protection against RNase activity, facilitating distribution, cellular uptake, and expression of mRNA delivered into the CNS.
The use of reverse transcription (RT) PCR for relative quantitation of gene transcripts relies on the reproducibility of the individual RT, PCR and product measurement steps. Semi-competitive RT-PCR (RT-cPCR) uses an internal competitor template in the PCR step to improve quantitation. We have surveyed the reproducibility of RT, PCR, RT-cPCR and measurement, amplifying the glyceraldehyde-3-phosphate dehydrogenase "housekeeping" gene from isolated renal glomeruli. We used an enzyme-linked immunosorbent assay (ELISA) to quantify PCR products. We also report our PCR-based method for constructing a competitor DNA identifiable independently of the native product. Our results show that the entire RT-PCR and ELISA process had a standard deviation (SD) of less than 10% (n = 10). This compared to an SD of less than 13% (n = 10) in PCR and ELISA. The SD for ELISA alone was less than 11% (n = 10). RT-cPCR quantitation gave an SD of approximately 15% (n = 10). These results support the use of standard RT-PCR for the relative quantitation of mRNA. RT-cPCR is also suited to relative quantitation, but it is also independent of the amplification saturation curve and permits the identification of differences in cellularity between samples.
We have previously reported the presence in human gingival keratinocytes (GKC) of choline acetyltransferase, the acetylcholine (ACh) synthesizing enzyme, acetylcholinesterase, the ACh degrading enzyme, and alpha 3, alpha 5, alpha 7, beta 2 as well as alpha 9 nicotinic ACh receptor subunits. To expand the knowledge about the role of ACh in oral biology, we investigated the presence of the muscarinic ACh receptor (mAChR) subtypes in GKC. RT-PCR demonstrated the presence of m2, m3, m4, and m5 mRNA transcripts. Synthesis of the respective proteins was verified by immunoblotting with the subtype-specific antibodies that revealed receptor bands at the expected molecular weights. The antibodies mapped mAChR subtypes in the epithelium of human attached gingiva and also visualized them on the cell membrane of cultured GKC. The whole cell radioligand binding assay revealed that GKC have specific binding sites for the muscarinic ligand [3H]quinuclidinyl benzilate, Bmax = 222.9 fmol/106 cells with a Kd of 62.95 pM. The downstream coupling of the mAChRs to regulation of cell cycle progression in GKC was studied using quantitative RT-PCR and immunoblotting assays. Incubation of GKC for 24 h with 10 micro m muscarine increased relative amounts of Ki-67, PCNA and p53 mRNAs and PCNA, cyclin D1, p21 and p53 proteins. These effects were abolished in the presence of 50 micro m atropine. The finding in GKC of mAChRs coupled to regulation of the cell cycle progression demonstrate further the structure/function of the non-neuronal cholinergic system operating in human oral epithelium. The results obtained in this study help clarify the role for keratinocyte ACh axis in the physiologic control of oral gingival homeostasis.
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