Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0018799 (heart disease)
 34,133 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Heart tissue destruction in chronic Chagas disease cardiopathy (CCC) may be caused by autoimmune recognition of heart tissue by a mononuclear cell infiltrate decades after Trypanosoma cruzi infection. Indirect evidence suggests that there is antigenic crossreactivity between T. cruzi and heart tissue. As there is evidence for immune recognition of cardiac myosin in CCC, we searched for a putative myosin-crossreactive T. cruzi antigen. T. cruzi lysate immunoblots were probed with anti-cardiac myosin heavy chain IgG antibodies (AMA) affinity-purified from CCC or asymptomatic Chagas disease patient-seropositive sera. A 140/116-kDa doublet was predominantly recognized by AMA from CCC sera. Further, recombinant T. cruzi protein B13--whose native protein is also a 140- and 116-kDa double band--was identified by crossreactive AMA. Among 28 sera tested in a dot-blot assay, AMA from 100% of CCC sera but only 14% of the asymptomatic Chagas disease sera recognized B13 protein (P = 2.3 x 10(-6)). Sequence homology to B13 protein was found at positions 8-13 and 1442-1447 of human cardiac myosin heavy chain. Competitive ELISA assays that used the correspondent myosin synthetic peptides to inhibit serum antibody binding to B13 protein identified the heart-specific AAALDK (1442-1447) sequence of human cardiac myosin heavy chain and the homologous AAAGDK B13 sequence as the respective crossreactive epitopes. The recognition of a heart-specific T. cruzi crossreactive epitope, in strong association with the presence of chronic heart lesions, suggests the involvement of crossreactivity between cardiac myosin and B13 in the pathogenesis of CCC.
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PMID:Autoimmunity in Chagas disease cardiopathy: biological relevance of a cardiac myosin-specific epitope crossreactive to an immunodominant Trypanosoma cruzi antigen. 753 37

Idiopathic dilated cardiomyopathy (IDC) is a heart disease of unknown aetiology characterised by impaired ventricular function usually associated with dilatation of the cardiac chambers. In order to test the hypothesis of an immunological cause for the disease at the genetic level, we performed linkage analysis between the putative disease locus and some of the potential candidate genes involved in the immune response or coding for the targets for autoantibodies in a large multigeneration family (63 members) from southern Italy with autosomal dominant transmission of the disease. Twenty-nine polymorphic markers on 18 different chromosomal locations were investigated, including markers linked to the genes coding for the HLA antigens, the immunoglobulin heavy and light chains, the receptors for the immunoglobulin Fc fragments, the subunits of the T cell receptor and the associated CD3, CD4, CD8, and CD45 antigens, interleukins 1, 3, 4, 5, 6, 9, and 11, the interleukin 1 and 2 receptors, and the genes coding for the beta 1 adrenoreceptor, the adenine nucleotide translocator-1, and the cardiac alpha and beta myosin heavy chains. No evidence for genetic linkage to IDC was found at any of these candidate loci. These results indicate that the still unidentified IDC gene maps outside several loci involved in the regulation of immune reactivity.
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PMID:Absence of linkage between idiopathic dilated cardiomyopathy and candidate genes involved in the immune function in a large Italian pedigree. 783 53

GH exerts direct effects on myocardial growth and function. Evidence from laboratory models shows that GH (or IGF-I) induces mRNA expression for specific contractile proteins and myocyte hypertrophy. Furthermore, GH increases the force of contraction and determines myosin phenoconversion toward the low ATPase activity V3 isoform. These data provide plausible explanations for the cardiac abnormalities observed in clinical settings of excessive or defective GH production. In acromegaly, the functional consequences of GH excess initially prevail (hyperkinetic syndrome), followed by alterations of cardiac function when myocardial hypertrophy develops. This involves both ventricles and is purposeless because it occurs without increased wall stress. Hypertrophy also entails proliferation of the myocardial fibrous tissue that leads to interstitial remodeling. The functional consequence is an impaired ventricular relaxation that causes a diastolic dysfunction, followed by impairment of systolic function. In untreated disease, cardiac performance slowly but inexorably deteriorates and heart failure eventually develops. Several lines of evidence support the specificity of heart disease in acromegaly. Particularly demonstrative are the recent studies in which GH production was suppressed by octreotide, with a consequent significant regression of hypertrophy and improvement of cardiac dysfunction. It is not yet established whether full recovery of normal cardiac morphology and function is possible after correction of GH excess. The point is not a minor one since the possibility to revert, albeit partially, myocardial fibrosis is of great relevance to the control of cardiac hypertrophy in general. GHD leads to a reduced mass of both ventricles and to impaired cardiac performance with low heart rate (hypokinetic syndrome). These alterations are particularly evident during physical exercise and might provide an important contribution to the reduced exercise capacity of GHD patients, in addition to the reduced muscle mass and strength. The data also support a role of GH in the maintenance of a normal cardiac structure and performance. The hypokinetic syndrome is well documented in young patients in whom GHD began very early in their childhood. In contrast, the data in adult-onset GHD are less consistent. This suggests that the consequences of GHD are more relevant if the disorder starts during early heart development. As observed with other abnormalities associated with GHD, cardiac dysfunction is also susceptible to marked improvement by hrGH. This observation lends further support to the proposal to treat these patients with replacement therapy.
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PMID:Growth hormone and the heart. 784 68

Injury to cardiac myocytes often leads to the production of anti-myosin antibodies. While these antibodies are a marker of myocardial injury, their contribution to pathogenesis in diseases such as autoimmune myocarditis or rheumatic fever is much less clear. We demonstrate in this report that monoclonal anti-myosin antibodies can mediate myocarditis in a susceptible mouse strain. Additionally, we show disease susceptibility depends on the presence of myosin or a myosin-like molecule in cardiac extracellular matrix. This study demonstrates that susceptibility to autoimmune heart disease depends not only on the activation of self-reactive lymphocytes but also on genetically determined target organ sensitivity to autoantibodies.
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PMID:Antibody-mediated autoimmune myocarditis depends on genetically determined target organ sensitivity. 786 33

Rheumatic fever (RF) follows a throat infection with different M-serotypes of beta-hemolytic group A streptococci (GAS) and can affect different tissues, predominantly the heart. It is thought to be an autoimmune illness. Although histological examination of affected heart shows an infiltrate consisting mainly of T cells, antigens or epitopes that could be putative targets of autoimmune T cells have not been identified. We have examined the T cell response to the conserved C-terminal region of the M protein--a streptococcal surface coiled-coil protein which is the target of opsonic antibodies and antibodies which cross-react with human heart tissue. Australian Aborigine, Caucasian and Thai patients, controls and mice were studied to define regions of the protein immunogenic for T cells, and T cell lines and clones were tested for cross-reactivity to myosin as well as an extract of RF-diseased mitral heart valve. Murine (B10, B10.D2, B10.BR) M peptide-specific T cells were often cross-reactive for other M peptides but did not cross-react with human heart antigens. Patients with RF or other heart diseases, or control subjects exposed more commonly to GAS were more likely to have T cell responses to the M protein, with many regions of the C-terminus being recognized. T cell lines and a clone specific for different M peptides were generated from five donors. Cross-reactivity could be shown between different M peptides, but unlike murine M peptide-specific T cells three of the human T cell lines reacted strongly to peptides representing homologous regions of cardiac and skeletal muscle myosins, and two of these lines also responded to porcine myosin and an extract of human rheumatic mitral valve. However, these last two lines were derived from a normal donor without history of RF or other heart disease. Our data demonstrate that regions of the M protein, including regions that are being considered as subunit vaccines, have the potential to stimulate pre-existing heart cross-reactive T cells, but that the ability of such T cells to cross-react (as measured in vitro) is not in itself sufficient to lead to disease.
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PMID:Identification of T cell autoepitopes that cross-react with the C-terminal segment of the M protein of group A streptococci. 798 Nov 50

A monoclonal enzyme immunoassay for measuring human ventricular myosin light chain isotype 1 (HVMLC1) in serum has been developed. To evaluate the method in patients with suspected myocardial injury, we studied 51 patients (16 acute myocardial infarction (AMI), 19 unstable angina pectoris (UAP), 9 stable angina pectoris, 3 nonischemic heart disease, 4 hip surgery patients), and 190 controls (blood donors). Serial blood-samples were drawn from patients; a single blood-sample from controls. The diagnostic value of the HVMLC1 assay was compared with total creatine kinase (CK), CKMB activity, CKMB mass concentration, lactate dehydrogenase isoenzyme 1 (LD1), troponin T (TnT) and mitochondrial-aspartate aminotransferase (m-ASAT). The detection limit of HVMLC1 was 0.4 microgram/l (linear range 0-20 micrograms/l). Sera from 190 reference persons did not contain detectable levels of HVMLC1 (< 0.4 microgram/l; 99% percentile). The coefficients of variation were 13% (1.0 microgram/l) and 3.1% (17.7 micrograms/l). Cross-reactivity with myosin from skeletal muscle was seen. Times to peak value were: CK 19.3 +/- 2.0, LD1 43.4 +/- 3.2, HVMLC1 72.9 +/- 7.0, and m-ASAT 67.3 +/- 5.6 h. Time-curves of HVMLC1 and m-ASAT were similar, whereas time-curves for HVMLC1 and TnT were quite different in most cases. Peak value of HVMLC1 was five times higher than CK peak value and eight times that of LD1. HVMLC1 appeared in the blood within hours after the onset of chest pain and in the majority remained for more than a week after AMI. Among patients with UAP 16% (3/19) had elevated HVMLC1 in serum, whereas elevated TnT was seen in 26% (5/19) and elevated CKMB mass in 26% (5/19). We conclude that the new HVMLC1 assay offers a sensitive diagnosis of myocardial injury. It is characterized by a wide diagnostic time window. The similarity of the HVMLC1 and m-ASAT curves indicates that it may be used to estimate the extent of myocardial necrosis.
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PMID:Human ventricular myosin light chain isotype 1 as a marker of myocardial injury. 817 43

The relative amounts of cardiac myosin heavy-chain isoforms (MyHC) in right atrial tissue (RA) of 16 neonates and children suffering from congenital heart disease have been investigated. Quantification of MyHC was based on one-dimensional gel electrophoresis and on histometrical evaluation of cyro-sections stained with monoclonal antibodies against alpha- and beta-MyHC. The mean right atrial pressures ranged from 2 to 14 Hg. The RA load was normal in eight patients (5.1 +/- 1.3 mm Hg) and overloaded in eight cases (10 +/- 2.5 mm Hg). The arterial oxygen saturation was normal in 12 and ranged between 85% and 89% in four cases. In all patients a large proportion of atrial myocytes coexpressed alpha- and beta-MyHC. However, in the cases with pressure overloaded RA the amount of beta-MyHC was found to be 1.6 times higher than in the cases with normal pressure. This indicates an adaptational response to overload, as was previously described for the adult human heart. In light of this finding, it seems important to conserve as much as possible of the trained right atrial wall during a Fontan type of operation.
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PMID:Coexpression of alpha and beta myosin heavy-chain isoforms in atria of neonates and infants with congenital heart disease. 824 Feb 29

An inflammatory cardiomyopathy may develop in humans and experimental animals with chronic Trypanosoma cruzi infection (Chagas' disease). Among the possible mechanisms involved in the pathogenesis of Chagas' cardiomyopathy, induction of heart-specific autoimmune responses has recently received substantial experimental support. The goal of the current study was to determine whether cardiac Ag-specific antibodies are produced in T. cruzi-infected mice with heart disease and, if so, to determine their Ag specificities. Upon infection with the Brazil strain of T. cruzi, C57BL/6 mice develop a cardiomyopathy that is histologically similar to that observed in chronically infected humans. Antisera from these mice were found to react with three cardiac Ag, having relative molecular masses of 200, 150, and 53 kDa. p200 and p150 are specifically found in heart muscle, although p53 is found in skeletal muscle as well. C57BL/6 mice infected with the Guayas strain of T. cruzi, which do not develop cardiomyopathy, did not produce antibodies to p200, p150, or p53, indicating that these antibodies may be specific markers of cardiomyopathy. Finally, p200 and p53 were identified as the contractile protein myosin and the intermediate filament protein desmin, respectively. This last finding is of special interest, because antibodies specific for myosin or desmin have been detected in humans and experimental animals with other natural and experimental cardiomyopathies. This suggests that infection with particular strains of T. cruzi may lead to the development of a cardiac Ag-specific autoimmune disease, possibly involving one or more of the Ag identified in this study.
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PMID:Cardiac antigen-specific autoantibody production is associated with cardiomyopathy in Trypanosoma cruzi-infected mice. 830 Nov 48

Autoimmune myocarditis induced by immunization with cardiac myosin can be seen as a virus-free system to analyze the immunopathological mechanisms of certain forms of postinfectious heart disease. Immunodepletion studies have shown that in A.SW mice myosin-induced myocarditis is mediated by both CD4+ and CD8+ cells. The CD4+ subset is at least required for the induction of the autoimmune response, whereas the CD8+ subset seems to play a key role in mediating the myocardial injury. In addition, we found a bias concerning the TCR repertoire, because T cells within the inflammatory heart infiltrate almost exclusively use V beta 8 elements. Furthermore, recent serologic and immunohistologic studies indirectly suggest that the cardiac myocyte is not the target for the anti-myosin response. Rather, the primary target might consist in dendritic cells presenting myosin epitopes even under normal conditions.
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PMID:T cells in cardiac myosin-induced myocarditis. 835 56

Several well-defined coxsackievirus B3 (CVB3)-murine models of inflammatory heart disease are providing information about mechanisms which contribute to myocyte necrosis. Severity of disease induced and mechanisms responsible depend upon unresolved molecular activities of the viral genome, nonspecific defenses of the mouse at time of infection and immune responses of the mouse at the time of infection. Most important are the capabilities and directed responses of each mouse to infection which are determined by age and genetic background of the host. In addition to virus-induced contributions to tissue pathology during primary infection, persistence of viral genomes for week to months in some strains of mice forecast whether the acute disease will resolve or continue as chronic disease with sustained inflammatory reactions in the myocardium. Persistent infections can contribute to nascent cardiopathologic alterations by chronic induction of inflammatory events through expression of viral genes and altered expression of host genes during nonlytic infections. Products of these expressions include viral proteins and nonhomeostatic levels of cytokines and arachidonic acid cascade intermediates and final metabolites. Molecular mimicry via shared epitopes between virion capsid proteins and normal cell molecules/structures located on or within heart tissue cells may be the mechanism by which immune systems in certain strains of mice are persistently stimulated. The products of these immune responses, i.e. antibodies and cytotoxic T lymphocytes, may provide initial protection via termination of infection and virus clearance during acute disease but subsequently these autoreactive processes could contribute to chronic disease. The immune effector products (antibodies and T lymphocytes) have potential pro-inflammatory reactivities, capacity for exacerbating ongoing CVB3-induced disease and/or can induce disease in normal animals. In further support of the hypothesis that autoimmune reactions contribute to sustained inflammation of the heart, non-viral models of myocarditis have been developed. Cell constituents such as myosin and adenosine nucleotide translocator protein can induce cardiopathologic alterations in normal mice of strains known to develop CVB3-induced chronic disease. Thus host genetic background determines whether a mouse survives the initial infection, resolves the acute disease or inadvertently contributes to sustained inflammatory heart disease. Finally, shared epitopes among the enteroviruses may play a role in repeated episodes of disease during sequential infections by different serotypes.
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PMID:What lessons can be learned from animal model studies in viral heart disease? 839 Jul 19


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