Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
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Query: UMLS:C0004153 (
atherosclerosis
)
77,401
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
During the last decade, a multitude of experimental arguments have led to the concept that EDRF is nitric oxide (NO), a messenger not only involved in the control of vasomotor tone but also in vascular homeostasis, neuronal and immunological functions. Regardless of its origin, endogenous NO is produced through the conversion of L-arginine to L-citrulline by NO-synthase (NOS) from which several isoforms have recently been isolated, purified and cloned. NOS-type I (isolated from brain) and type III (isolated from endothelial cells) are termed "constitutive-NOS" and produce picomolar levels of NO from which only a small fraction elicits physiological responses. These isoforms are regulated by Ca(2+)-calmodulin with NADPH,
FAD
/FMN and tetrahydrobiopterin as co-factors and reveal a high degree of homology with the amino-acid sequence of cytochrome P450 reductase within the C-terminal domain. Functionally, neuronal-NOS type I is important in neurotransmission (modulation of NMDA receptor), the central control of vascular homeostasis and possibly learning and memory. In the peripheral nervous system, NOS appears to be linked to nonadrenergic noncholinergic (NANC) neuronal pathways. Endothelial-NOS type III is essential for the control of vascular tone in response to the release of endogenous mediators, although shear stress is the major trigger of endothelial-NOS activity under physiological conditions. NOS-type III also contributes to the prevention of abnormal platelet aggregation. NOS-types II and IV (isolated from macrophages) are Ca(2+)-calmodulin independent and are termed "inducible-NOS" since their activation is only promoted under pathophysiological situations where macrophages exert cytotoxic effects in response to cytokines. In contrast with NOS-types I and III, activation of NOS-type II in these cells induces the formation of nanomolar levels of NO which act as a defense mechanism of the immune system. Dysfunctions of the L-arginine-NO pathway have been characterized in multiple diseases (
atherosclerosis
, hypertension, diabetes, sepsis, cerebral ischemia, etc) and the design of more selective activators/inhibitors of NOS isoforms is a new challenge for the understanding of their pathophysiology and treatment.
...
PMID:Nitric oxide: an ubiquitous messenger. 829 80
Several reports have appeared in the literature proving that hypothyroidism is associated with increased risk for cardiovascular disease, especially coronary heart disease. This increased risk for premature
atherosclerosis
is supported by autopsy and epidemiological studies in patients with thyroid hormone deficiency. Hypothyroid patients have increased diastolic blood pressure (as a result of increased systemic vascular resistance), altered lipid profile (elevated levels of total cholesterol, LDL-cholesterol and apolipoprotein B). More recently homocysteine, C-reactive protein, increased arterial stiffness, endothelial dysfunction and altered coagulation parameters have been recognized as a "new" risk factors for
atherosclerosis
in patients with thyroid hormone deficiency. The plasma total homocysteine concentration, an independent risk factor for
atherosclerosis
, is moderately elevated in overtly hypothyroid patients and it decreases with thyroid replacement therapy. Several experimental study have shown that hypothyroidism affects folate metabolism and the enzymes involved in the remetylation pathway of homocysteine (particularly 5,10-methylenotetrahydrofolate reductase - MTHFR). In hypothyroid condition the hepatic activity of flavoenzyme - MTHFR, is decreased. Thyroid hormone may affect the availability of FMN and
FAD
- necessary for stabilizing MTHFR. An impairment of enzyme involved in transsulfuration pathway is suggested. The increased serum creatinine level in hypothyroidism probably reflects a reduced glomerular filtration rate, which is linked to impaired renal homocysteine clearance and hyperhomocysteinemia.
...
PMID:[The influence of thyroid hormones on homocysteine and atherosclerotic vascular disease]. 1633 88
Human flavin-containing monooxygenase isoform 3 (hFMO3) is an important hepatic drug-metabolizing enzyme, catalyzing the monooxygenation of nucleophilic heteroatom-containing xenobiotics. Based on the structure of bacterial FMO, it is proposed that a conserved asparagine is involved in both NADP(H) and substrate binding. In order to explore the role of this amino acid in hFMO3, two mutants were constructed. In the case of N61Q, increasing the steric hindrance above the flavin N5-C4a causes poor NADP(H) binding, destabilizing the catalytic
FAD
intermediate, whereas the introduction of a negatively charged residue, N61D, interferes mainly with catalytic intermediate formation and its stability. To better understand the substrate-enzyme interaction, in vitro as well as in silico experiments were carried out with methimazole as substrate. Methimazole is a high-affinity substrate of hFMO3 and can competitively suppress the metabolism of other compounds. Our results demonstrate that methimazole Pi-stacks above the isoalloxazine ring of
FAD
in hFMO3, in a similar way to indole binding to the bacterial FMO. However, for hFMO3 indole is found to act as a non-substrate competitive inhibitor. Finally, understanding the binding mode of methimazole and indole could be advantageous for development of hFMO3 inhibitors, currently investigated as a possible treatment strategy for
atherosclerosis
.
...
PMID:Binding of methimazole and NADP(H) to human FMO3: In vitro and in silico studies. 2995 3
