Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.6.3.44 (P-glycoprotein)
 13,344 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The MDR1 gene, a multidrug resistance gene, codes for P-glycoprotein which pumps hydrophobic drugs out of the cells. Since cyclosporins also bind to P-glycoprotein and might be pumped by this transmembrane protein, we determined the expression of the MDR1 gene in the lymphocytes of 32 patients with renal transplants. MDR1 RNA expression of lymphocytes was measured by slot blot analysis and compared to the expression of drug-sensitive KB-3-1 cells and multidrug-resistant KB-8-5 cells. MDR1 RNA expression was detected in the lymphocytes of 9 (28%) patients, whereas no expression was seen in the remaining 23 patients. No association between MDR1 RNA expression and transplant function or hematological parameters was observed. However, none of the 6 patients who had transplants for more than 40 months expressed the MDR1 gene in their lymphocytes. In conclusion, expression of the MDR1 gene does occur in lymphocytes of patients with renal transplants and might reduce the immunosuppressive efficacy of cyclosporins through enhanced efflux of cyclosporins.
Nephron 1995
PMID:MDR1 gene expression in lymphocytes of patients with renal transplants. 753 32

P-glycoprotein (Pgp), the product of the multidrug resistance (MDR) gene overexpressed in cancer cells, is present also in normal tissues. In the kidney, MDR1 Pgp has been found in the proximal tubule and in cultured mesangial cells. In situ hybridization and immunohistochemistry were used to determine the complete nephronal localization of MDR mRNA and its product, Pgp, in the human kidney. MDR mRNA expression was studied with the use of nonradioactive in situ MDR RNA probes. MDR1 Pgp was immunolocalized using the specific monoclonal antibody MRK16. The presence of MDR mRNA was confirmed in proximal tubules and mesangium, and demonstrated as well in thick limb of Henle's loops and in collecting ducts. MDR1 Pgp colocalized in the same nephronal segments. This suggests that, in addition to secreting xenobiotics, Pgp may play a role in the transport of endogenous substrates or in the regulation of Cl- channels.
Nephron 1997
PMID:Expression of MDR1 (multidrug resistance) gene and its protein in normal human kidney. 937 21

Cadmium (Cd(2+)) is a non-essential heavy metal, which is taken up from the environment into the body through pulmonary and enteral pathways. The S1 segment of the kidney proximal tubule (PT) is a major target of chronic Cd(2+) toxicity. Renal dysfunction develops in up to 7% of the general population and in its most severe form displays major features of Fanconi syndrome, such as a defective protein, amino acid, glucose, bicarbonate and phosphate reabsorption. The major pathway for Cd(2+) uptake by PT cells (PTCs) in vivo is apical endocytosis of Cd(2+) complexed to the high-affinity metal-binding protein metallothionein (MT), which may be receptor-mediated. MT is subsequently degraded in endo-lysosomes, and Cd(2+) is liberated for translocation into the cytosolic compartment, possibly using transporters for Fe(2+), Zn(2+) or Cu(2+), such as the divalent metal transporter DMT1. Free Cd(2+) ions in the extracellular space are translocated across apical and/or basolateral PTC membranes into the cytosol via transporters, whose identity remains unknown. Cytosolic Cd(2+) generates reactive oxygen species (ROS), which deplete endogenous radical scavengers. ROS also damage a variety of transport proteins, including the Na(+)/K(+)-ATPase, which are subsequently degraded by the proteasome and endo-lysosomal proteases. Cd(2+) causes mitochondrial swelling and release of cytochrome C. If these ROS-mediated stress events are not balanced by repair processes, affected cells undergo apoptosis. But Cd(2+) also induces the upregulation of cytoprotective stress and metal-scavenging proteins, such as MT. In addition, Cd(2+) upregulates the detoxifying pump multidrug resistance P-glycoprotein, which appears to protect PTCs against Cd(2+)-induced apoptosis. Thus, Cd(2+) interferes with various cellular events ranging from mechanisms of induction of programmed cell death to activation of cell survival genes. A better understanding of the cellular mechanisms involved in Cd(2+) nephrotoxicity should provide insights into other heavy metal (e.g. Pb(2+), Hg(2+)) nephropathies and various forms of acquired Fanconi syndrome.
Nephron Physiol 2003
PMID:Nephrotoxicity and the proximal tubule. Insights from cadmium. 1275 69

The kidney plays an important role in the elimination of numerous hydrophilic xenobiotics, including drugs, toxins, and endogenous compounds. It has developed high-capacity transport systems to prevent urinary loss of filtered nutrients, as well as electrolytes, and simultaneously to facilitate tubular secretion of a wide range of organic ions. Transport systems for organic anions and cations are primarily involved in the secretion of drugs in renal tubules. The identification and characterization of organic anion and cation transporters have been progressing at the molecular level. To date, many members of the organic anion transporter, organic cation transporter, and organic anion-transporting polypeptide families have been found to mediate the transport of diverse organic ions. It has also been suggested that ATP-dependent primary active transporters such as MDR1/P-glycoprotein and the multidrug resistance-associated protein family function as efflux pumps of renal tubular cells for more hydrophobic molecules and anionic conjugates. Tubular reabsorption of peptide-like drugs such as beta-lactam antibiotics across the brush-border membranes appears to be mediated by two distinct H+/peptide cotransporters: PEPT1 and PEPT2. Renal disposition of drugs occurs through interaction with these diverse secretory and absorptive transporters in renal tubules. Studies of the functional characteristics, such as substrate specificity and transport mechanisms, and of the localization of drug transporters could provide information regarding the cellular network involved in renal handling of drugs. Detailed information concerning molecular and cellular aspects of drug transporters expressed in the kidney has facilitated studies of the mechanisms underlying renal disposition as well as transporter-mediated drug interactions.
Nephron Physiol 2006
PMID:Renal tubular drug transporters. 1655 67