Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:Q9UIJ5 (Rec)
 58,342 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Histochemical reactions which demonstrate cholinesterase reactions in tissues were used for slides of serial frozen sections of hearts of pigs, dogs, and rats to determine whether there are special types of modified muscle cells in continuous pathways from the SA (sinoatrial) to the AV (atrioventricular) node. There were positive reactions for acetylcholinesterase with less reaction for butyryl cholinesterase in ganglion cells and nerve fibers. No continuous pathways of cholinesterase-reacting cardiac muscle fibers from the SA to the AV node were identified although the muscle fibers were in intimate relation with the nerve fibers. No cells of Purkinje type were demonstrated in the atria.
Anat Rec 1981 Sep
PMID:A restudy of cardiac conduction pathways by techniques for visualization of cholinesterase reaction. 703 Jan 46

The ultrastructural quantitative composition of left ventricular cardiac myocytes from isolated Langendorff-perfused hearts was studied in three different mammals (rabbit, guinea pig, and rat). Volume densities of mitochondria, myofibrils, and unspecified cytoplasm were determined using morphometry and were compared to functional parameters including left ventricular developed pressure (LVDP), contractility (dP/dt), heart rate, TTI (tension-time index, an index of oxygen consumption), and relative heart mass (H/B) obtained from these hearts. Each of the mammals was found to possess a very specific and characteristic quantitative composition of cardiac myocyte. Cardiac myocytes contained 26.8% mitochondria and 56.3% myofibrils in rabbits, 25.8% mitochondria and 60.9% myofibrils in guinea pigs, and 27.7% mitochondria and 58.1% myofibrils in rats. The LVDP, contractility, heart rate, and TTI were quite different among species. However, there were close correlations between the mitochondrial volume density and the LVDP (p < 0.05), and between the mitochondrial volume density and the TTI (p < 0.05), in any group of the animals. It is concluded that the mitochondrial volume density is a good indirect indicator of function of cardiac muscle related to oxidative capacity.
Anat Rec 1994 Feb
PMID:Quantitative study on the relation between structural and functional properties of the hearts from three different mammals. 815 6

Following an outbreak of wobbly possum disease in a colony of brush tail possums (Trichosurus vulpecula), the disease was established experimentally in captive possums by inoculating the animals intraperitoneally with tissue homogenates. Crude tissue homogenates of liver remained infectious after freezing at -75 degrees C or filtration through a 0.22 micron filter. The disease was characterised by docility, incoordination, loss of balance and wasting. Fifteen of 16 infected animals had to be euthanased owing to the severity of clinical signs. Cachexia was the only change observed postmortem. Histology revealed widespread perivascular infiltrations with plasma cells and lymphocytes which were severe in the liver and kidney and moderate to mild in a variety of other tissues, including skeletal and cardiac muscle. Changes in the brain consisted of a mild to moderate mononuclear perivascular cuffing. Most of the animals had small to large numbers of circulating nucleated red blood cells and eosinopenia when they were euthanased. There was a consistent decrease in serum albumin concentration and an increase in serum globulins, which resulted in a decreased albumin:globulin ratio. Virus-like particles were observed in preparations of liver from two animals; they appeared to be spherical or icosahedral and were 45 nm in diameter.
Vet Rec 1997 Aug 30
PMID:Pathological studies of wobbly possum disease in New Zealand brushtail possums (Trichosurus vulpecula). 930 Oct 11

In search of unique components of the seminiferous tubule extracellular matrix, monoclonal antibodies were raised against an isolated seminiferous tubule extracellular matrix, and the monoclonal antibody 12G11 was cloned. By immunofluorescence microscopy in eight kinds of rat tissues (testis, lung, liver, small intestine, cardiac muscle, skeletal muscle, kidney, and brain), 12G11 antigen existed only in the testis. Immunoelectron microscopy revealed that the antigen is localized in the basement membrane of the seminiferous tubule and in the basement membranes of myoid cells. For a biochemical analysis, eight kinds of rat extracellular matrices were isolated and solubilized with 8 M urea and 2% beta-mercaptoethanol. Immunoblot analysis of these samples in 0.8% agarose gel also showed that the antigen was specific for the testis, and in a two high-molecular weight aggregates. These aggregates seemed to contain type IV collagen and laminin chains. The antigen of 12G11 antibody was shown to be 27 kDa by 10% SDS-PAGE followed by immunoblotting. From these data, the existence of a testis specific 27 kDa basement membrane protein, which associate with type IV collagen and laminin, was suggested.
Anat Rec 2000 12 01
PMID:27 kDa extracellular matrix protein revealed by a monoclonal antibody raised against rat testis. 1107 6

Achieving the lofty goal of developing a tissue engineered heart will likely rely on progress in engineering the various components: blood vessels, heart valves, and cardiac muscle. Advances in tissue engineered vascular grafts have shown the most progress to date. Research in tissue-engineered vascular grafts has focused on improving scaffold design, including mechanical properties and bioactivity; genetically engineering cells to improve graft performance; and optimizing tissue formation through in vitro mechanical conditioning. Some of these same approaches have been used in developing tissue engineering heart valves and cardiac muscle as well. Continued advances in scaffold technology and a greater understanding of vascular cell biology along with collaboration among engineers, scientists, and physicians will lead to further progress in the field of cardiovascular tissue engineering and ultimately the development of a tissue-engineered heart.
Anat Rec 2001 08 01
PMID:Tissue engineering in the cardiovascular system: progress toward a tissue engineered heart. 1150 Aug 13

The tubular heart differentiates from the bilateral cardiac fields in the splanchnic mesoderm. The expression of smooth muscle proteins has been shown to accompany the early phases of cardiac muscle formation. In this study we show that during elongation of the arterial pole of the mouse linear heart tube, alpha-smooth muscle actin (alpha-Sma) expression extends in the area that has been shown to become recruited into the myocardial lineage, but does not yet express myocardial markers. These data suggest that alpha-Sma identifies mesodermal cells that during subsequent development will be recruited into the myocardial lineage. Myocardium formation is not only observed at the arterial pole, but also at the venous pole and in the intracardiac mesenchyme. This results in the formation of the caval and pulmonary myocardium, the smooth-walled atrial myocardium, the myocardial atrioventricular septum, and the myocardial outlet septum. To determine whether recruitment into the myocardial lineage also takes place in these regions, the spatiotemporal pattern of expression of alpha-Sma and of the myocardial markers sarcoplasmatic reticulum calcium ATPase (Serca2a), alpha-myosin heavy chain (Mhc), and beta-Mhc were examined. We show that prior to the expression of myocardial markers, alpha-Sma is expressed in these regions, which suggests that these mesodermal cells become recruited into the cardiac lineage after formation of the linear heart tube.
Anat Rec A Discov Mol Cell Evol Biol 2003 Apr
PMID:Recruitment of intra- and extracardiac cells into the myocardial lineage during mouse development. 1262 73

Capillary basement membrane (CBM) thickening is an ultrastructural hallmark in diabetic patients and in animal models of diabetes. However, the wide variety of tissues sampled and diverse methods employed have made the interpretation of thickness data difficult. We showed previously that acellular glomerular BMs in OVE26 transgenic diabetic mice were thickened beyond normal age-related thickening, and in the current study we hypothesized that other microvascular BMs likewise would show increased widths relative to age-matched controls. Accordingly, a series of tissues, including skeletal and cardiac muscle, ocular retina and choriod, peripheral nerve, lung, pancreas, and renal glomerulus was collected from 300-350-day-old normal and transgenic mice. Transmission electron micrographs of cross sections through capillary walls were prepared, and CBM thickness (CBMT) was determined by the "orthogonal intercept" method. Morphometric analyses showed highly variable transgene-related BMT increases in the sampled tissues, with glomerular BM showing by far the greatest increase (+87%). Significant thickness increases were also seen in the retina, pulmonary alveolus, and thoracoabdominal diaphragm. BMT increases were not universal; however, most were modestly widened, and those that were thickest in controls generally showed the greatest increase. Although the pathogenesis of diabetes-related increases in CBM is poorly understood, data in the current study showed that in OVE26 transgenic mice increased BMT was a frequent concomitant of hyperglycemia. Accordingly, it seems likely that hyperglycemia-induced microvascular damage may be a contributing factor in diabetic BM disease, and that microvessel cellular and extracellular heterogeneity may limit the extent of CBM thickening in diverse tissues.
Anat Rec A Discov Mol Cell Evol Biol 2003 Apr
PMID:Ultrastructural morphometry of capillary basement membrane thickness in normal and transgenic diabetic mice. 1262 76

Adult cardiac muscle is unable to repair itself following severe disease or injury. Because of this fundamental property of the myocardium, it was long believed that the adult myocardium is a postmitotic tissue. Yet, recent studies have indicated that new cardiac myocytes are generated throughout the life span of an adult and that extracardiac cells can contribute to the renewal of individual cells within the myocardium. In addition, investigations of the phenotypic capacity of adult stem cells have suggested that their potential is not solely restricted to the differentiated cell phenotypes of the source tissue. These observations have great implications for cardiac biology, as stem cells obtained from the bone marrow and other readily accessible adult tissues may serve as a source of replacement cardiac myocytes. In this review, we describe the evidence for these new findings and discuss their implications in context of the continuing controversy over stem cell plasticity.
Anat Rec A Discov Mol Cell Evol Biol 2004 Jan
PMID:Adult stem cells and their cardiac potential. 1469 37

In early-stage heart, the cardiac impulse does not propagate through the specialized conduction system but spreads from myocyte to myocyte. We hypothesized that the gap junction protein connexin45 (Cx45) regulates early-stage contractions, because it is the only gap junction protein described in early hearts. Cx45-deficient (Cx45(-/-)) mice die of heart failure, concomitantly displaying other complex defects in the cardiovascular system. In order to determine the specific cardiac muscular function of Cx45, we created Cx45(-/-) embryonic stem (ES) cells to be differentiated into cardiac muscle in vitro. Unlike the coordinated contractions of wild-type cells, differentiated Cx45(-/-) cardiac myocytes showed high and irregular pulsation rates. Alterations of the electrophysiological properties of the Cx45(-/-) cardiac myocytes were indicated both by extracellular recording on planar multielectrode array probes and by intracellular Ca(2+) recording of the fluorescent Ca(2+) indicator fura-2. The in vitro system minimizes an influence of hemodynamic factors that complicate the phenotypes of Cx45(-/-) mice. Our results indicate that Cx45 is an essential connexin for coordinated conduction through early cardiac myocytes. The Supplementary Material referred to in this article can be found at the Anatomical Record website (http://www.interscience.wiley.com/jpages/0003-276X/suppmat).
Anat Rec A Discov Mol Cell Evol Biol 2004 Oct
PMID:Conduction abnormality in gap junction protein connexin45-deficient embryonic stem cell-derived cardiac myocytes. 1537 87

A defining characteristic of embryonic cells is their ability to divide rapidly, even in tissues such as cardiac muscle, which cannot divide once fully differentiated. This suggests that regulators of cell division differ in embryonic and differentiated cells. LEK1 is a member of an emerging family of proteins with diverse functions but shared structural domains, including numerous leucine zippers, a nuclear localization site, and a functional Rb-binding domain. LEK1 is expressed ubiquitously in the developing mouse embryo from the earliest stages of differentiation through birth. It is absent in adult tissues, even those that maintain active cell division. We hypothesize that LEK1 is a regulator of mitosis restricted to the developing embryo and early neonate. Here, using BrdU incorporation, we show that LEK1 protein downregulation in cardiac myocytes correlates directly with cessation of DNA synthesis between neonatal days 6 and 10. In contrast, in an immortalized cardiac cell line (HL1 cells), both BrdU incorporation and LEK1 protein expression persist, and actively dividing cells express LEK1. However, BrdU incorporation can be decreased in these cells by treatment with a morpholino targeting LEK1 mRNA. These data suggest a role for LEK1 in regulating the normal embryonic cardiomyocyte cell cycle and in promoting continued mitosis in transformed, abnormally dividing cardiomyocytes.
Anat Rec A Discov Mol Cell Evol Biol 2005 Sep
PMID:LEK1 protein expression in normal and dysregulated cardiomyocyte mitosis. 1604 83


<< Previous 1 2 3 Next >>