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Query: UMLS:C0019158 (
hepatitis
)
30,205
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In order to better understand the first steps leading to drug-induced immunoallergic
hepatitis
, we studied the target of anti-LKM2 autoantibodies appearing in tienilic acid-induced
hepatitis
, and the target of tienilic acid-reactive metabolites. It was identified as cytochrome P450 2C9, (P450 2C9): indeed, anti-LKM2 specifically recognized P450 2C9, but none of the other P450s tested (including other 2C subfamily members, 2C8 and 2C18).
Tienilic acid
-reactive metabolite(s) specifically bound to P450 2C9, and experiments with yeast expressing active isolated P450s showed that P450 2C9 was responsible for tienilic acid-reactive metabolite(s) production. Results of qualitative and quantitative covalent binding of tienilic acid metabolite(s) to human liver microsomes were then compared to those obtained with two drugs leading to direct toxic
hepatitis
, namely, acetaminophen and chloroform. Kinetic constants (Km and Vmax) were measured, and the covalent binding profile of the metabolites to human liver microsomal proteins was studied.
Tienilic acid
had both the lowest Km and the highest covalent binding rate at pharmacological doses. For acetaminophen and chloroform, several microsomal proteins were covalently bound, while covalent binding was highly specific for tienilic acid and dihydralazine, another drug leading to immunoallergic
hepatitis
. Although low numbers of drugs were tested, these results led us to think that there may exist a relationship between the specificity of covalent binding and the type of hepatotoxicity.
...
PMID:Specificity of in vitro covalent binding of tienilic acid metabolites to human liver microsomes in relationship to the type of hepatotoxicity: comparison with two directly hepatotoxic drugs. 807 77
Tienilic acid
-induced
hepatitis
is characterized by the presence of anti-liver and -kidney microsomal (anti-LKM2) autoantibodies in patient sera. Cytochrome P4502C9(CYP2C9), involved in the metabolism of tienilic acid, was shown to be a target for tienilic acid-reactive metabolites and for autoantibodies. To further investigate the relationship between drug metabolism and the pathogenesis of this drug-induced autoimmune disease, the specificity of anti-LKM2 autoantibodies toward CYP2C9 was first determined, and the antigenic sites on CYP2C9 were localized. By constructing several deletion mutants derived from CYP2C9 cDNA and by probing the corresponding proteins with different anti-LKM2 sera, we defined three regions (amino acids 314-322, 345-356, and 439-455); they interacted to form a major conformational autoantibody binding site. This binding site was immunoreactive with 100% of sera and allowed removal of the entire reactivity of the sera tested by immunoblotting. Epitope mapping studies have been performed for CYP2D6, CYP17, CYP21A2, and, recently, CYP3A. Those data were compared with the results obtained in the current study with CYP2C9 in an attempt to elucidate one of the mechanisms by which CYP becomes immunogenic.
...
PMID:Tienilic acid-induced autoimmune hepatitis: anti-liver and-kidney microsomal type 2 autoantibodies recognize a three-site conformational epitope on cytochrome P4502C9. 870 Jan 40
Patients with tienilic acid
hepatitis
exhibit autoantibodies that recognize unalkylated cytochrome P450 2C9 in humans but recognize 2C11 in rats. Our aim was to determine whether the immune reaction is also directed against neoantigens. Rats were treated with tienilic acid and hepatocytes were isolated. Immunoprecipitation, immunoblotting, and flow cytometry experiments were performed with an anti-tienilic acid or an anti-cytochrome P450 2C11 antibody. Cytochrome P450 2C11 was the main microsomal or plasma membrane protein that was alkylated by tienilic acid. Inhibitors of vesicular transport decreased flow cytometric recognition of both unalkylated and tienilic acid-alkylated cytochrome P450 2C11 on the plasma membrane of cultured hepatocytes.
Tienilic acid
hepatitis
sera that were preadsorbed on microsomes from untreated rats (to remove autoantibodies), poorly recognized untreated hepatocytes in flow cytometry experiments, but better recognized tienilic acid-treated hepatocytes. This recognition was decreased by adsorption with tienilic acid or by preexposure to the anti-tienilic acid or the anti-cytochrome P450 2C11 antibody. We conclude that cytochrome P450 2C11 is alkylated by tienilic acid and follows a vesicular route to the plasma membrane.
Tienilic acid
hepatitis
sera contain antibodies against this tienilic acid adduct, in addition to the previously described anticytochrome P450 autoantibodies.
...
PMID:Antigenic targets in tienilic acid hepatitis. Both cytochrome P450 2C11 and 2C11-tienilic acid adducts are transported to the plasma membrane of rat hepatocytes and recognized by human sera. 882 14
Tienilic acid
(TA) is responsible for an immune-mediated drug-induced hepatitis in humans, while its isomer (TAI) triggers a direct
hepatitis
in rats. In this study, we describe an immunological approach developed for studying the specificity of the covalent binding of these two compounds. For this purpose, two different coupling strategies were used to obtain TA-carrier protein conjugates. In the first strategy, the drug was linked through its carboxylic acid function to amine residues of carrier proteins (BSA-N-TA and casein-N-TA), while in the second strategy, the thiophene ring of TA was attached to proteins through a short 3-thiopropanoyl linker, the corresponding conjugates (BSA-S-5-TA and betaLG-S-5-TA) thus preferentially presenting the 2, 3-dichlorophenoxyacetic moiety of the drug for antibody recognition. The BSA-S-5-TA conjugate proved to be 30 times more immunogenic than BSA-N-TA. Anti-TA-protein adduct antibodies were obtained after immunization of rabbits with BSA-S-5-TA (1/35000 titer against betaLG-S-5-TA in ELISA). These antibodies strongly recognized the 2, 3-dichlorophenoxyacetic moiety of TA but poorly the part of the drug engaged in the covalent binding with the proteins. This powerful tool was used in immunoblots to compare TA or TAI adduct formation in human liver microsomes as well as on microsomes from yeast expressing human liver cytochrome P450 2C9. TA displayed a highly specific covalent binding focused on P450 2C9 which is the main cytochrome P450 responsible for its hepatic activation in humans. On the contrary, TAI showed a nonspecific alkylation pattern, targeting many proteins upon metabolic activation. Nevertheless, this nonspecific covalent binding could be completely shifted to a thiol trapping agent like GSH. The difference in alkylation patterns for these two compounds is discussed with regard to their distinct toxicities. A relationship between the specific covalent binding of P450 2C9 by TA and the appearance of the highly specific anti-LKM2 autoantibodies (known to specifically recognize P450 2C9) in patients affected with TA-induced
hepatitis
is strongly suggested.
...
PMID:Opposite behaviors of reactive metabolites of tienilic acid and its isomer toward liver proteins: use of specific anti-tienilic acid-protein adduct antibodies and the possible relationship with different hepatotoxic effects of the two compounds. 1007 92
Cytochrome P450 (P450) enzymes oxidize xenobiotics into chemically reactive metabolites or intermediates as well as into stable metabolites. If the reactivity of the product is very high, it binds to a catalytic site or sites of the enzyme itself and inactivates it. This phenomenon is referred to as mechanism-based inactivation. Many clinically important drugs are mechanism-based inactivators that include macrolide antibiotics, calcium channel blockers, and selective serotonin uptake inhibitors, but are not always structurally and pharmacologically related. The inactivation of P450s during drug therapy results in serious drug interactions, since irreversibility of the binding allows enzyme inhibition to be prolonged after elimination of the causal drug. The inhibition of the metabolism of drugs with narrow therapeutic indexes, such as terfenadine and astemizole, leads to toxicities. On the other hand, the fate of P450s after the inactivation and the toxicological consequences remains to be elucidated, while it has been suggested that P450s modified and degraded are involved in some forms of tissue toxicity. Porphyrinogenic drugs, such as griseofulvin, cause mechanism-based heme inactivation, leading to formation of ferrochelatase-inhibitory N-alkylated protoporphyrins and resulting in porphyria. Involvement of P450-derived free heme in halothane-induced hepatotoxicity and catalytic iron in cisplatin-induced nephrotoxicity has also been suggested. Autoantibodies against P450s have been found in
hepatitis
following administration of tienilic acid and dihydralazine.
Tienilic acid
is activated by and covalently bound to CYP2C9, and the neoantigens thus formed activate immune systems, resulting in the formation of an autoantibodydirected against CYP2C9, named anti-liver/kidney microsomal autoantibody type 2, whereas the pathological role of the autoantibodies in drug-induced hepatitis remains largely unknown.
...
PMID:Toxicological significance of mechanism-based inactivation of cytochrome p450 enzymes by drugs. 1761 53
Thiophene is a five-membered, sulfur-containing heteroaromatic ring commonly used as a building block in drugs. It is considered to be a structural alert, as its metabolism can lead to the formation of reactive metabolites. Thiophene S-oxides and thiophene epoxides are highly reactive electrophilic thiophene metabolites whose formation is cytochrome P450-dependent. These reactive thiophene-based metabolites are quite often responsible for drug-induced hepatotoxicity.
Tienilic acid
is an example of a thiophene-based drug that was withdrawn from the market after only a few months of use, due to severe cases of immune
hepatitis
. However, inclusion of the thiophene moiety in drugs does not necessarily result in toxic effects. The presence of other, less toxic metabolic pathways, as well as an effective detoxification system in our body, protects us from the bioactivation potential of the thiophene ring. Thus, the presence of a structural alert itself is insufficient to predict a compound's toxicity. The question therefore arises as to which factors significantly influence the toxicity of thiophene-containing drugs. There is no easy way to answer this question. However, the findings presented here indicate that, for a number of reasons, daily dose and alternative metabolic pathways are important factors when predicting toxicity and will therefore be discussed together with examples.
...
PMID:Bioactivation potential of thiophene-containing drugs. 2501 78
