Rituximab serum concentrations during immuno-chemotherapy of follicular lymphoma correlate with patient gender, bone marrow infiltration and clinical response.

BACKGROUND: Treatment of follicular lymphoma with rituximab is currently recommended at a dose of 375 mg/m(2). We aimed to provide a rationale for optimal dosing and scheduling of this anti-CD20 antibody based on pharmacokinetics. DESIGN AND METHODS: Clinical efficacy of immunochemotherapy with rituximab, fludarabine and mitoxantrone followed by 2-monthly rituximab maintenance was evaluated in 29 patients with previously untreated follicular lymphoma in a prospective phase II trial (AGMT-NHL9). Pharmacokinetic analysis was assessed in 17 patients. RESULTS: Induction treatment resulted in high clinical response rates (complete remission 66%; ORR 100%). Significantly higher complete remission rates were observed in female patients (86 vs. 47%; Odds Ratio 6.8, 95% CI: 1.12; 41.82; P=0.05). Rituximab pharmacokinetic analysis showed a high variability ranging over almost 1 order of magnitude at maintenance cycle 1 (area under the curve 1,540-12,025 g/L*days). Median area under the curve was lower in men (81%) and in patients with initial bone marrow infiltration (76%). Higher rituximab serum concentrations before next therapy (C(trough)) were associated with female sex (P=0.04) as well as with absence of initial bone marrow infiltration (P=0.001). C(trough) correlated with remission quality (complete vs. partial remission; P=0.005) and progression-free survival (P=0.03). A decline in rituximab C(trough) below 25,000 ng/mL was observed 9.5 to 62 months before clinical relapse (P=0.008). CONCLUSIONS: The results of this pilot trial suggest that more differentiated dosing schedules based on gender and bone marrow infiltration should be explored for rituximab therapy for lymphoma. This study was registered in ClinicalTrials.gov (Identifier: NCT01560117).

Effects of tibolone on sulfatase pathway of estrogens metabolism and on growth of MCF-7 human breast tumors implanted in ovariectomized nude mice.

BACKGROUND: The benefits of estrogen plus progestin in healthy post-menopausal women remain uncertain. Tibolone, with its in vitro documented inhibitory effects on estrogens metabolism and its selective action on breast, may be an alternative that could favorably influence the health benefit of hormone replacement therapy. METHODS: We studied the effect of tibolone on the tumor growth of MCF-7 cells implanted in 40 ovariectomized nude mice, receiving subcutaneous pellets of 17beta-estradiol, estrone, estrone-sulfate or vehicle, and daily gavages of tibolone or placebo. RESULTS: Tibolone, although used at high dose, did not stimulate nor inhibit the estrogen-induced tumors, nor the tumors in estrogen-deprived mice. Measurements of plasma levels of estrogens indicated that tibolone potently stimulated sulfotransferase activity, but intra-tumor levels of estrogens were not significantly modified by tibolone. CONCLUSIONS: This in vivo study performed with high dose of orally administered tibolone that allowed its hepatic conversion into active metabolites has shown no significant effect on breast tumors growth. Tibolone increased the circulating sulfated estrogens by its activity on the hepatic sulfation but not the intra-tumor levels of estrogens (free or sulfated). However, further studies of dose-response curve and molecular markers are needed to exclude definitely a stimulatory effect of tibolone on tumor growth.

A three-dimensional model for the substrate binding domain of the multidrug ATP binding cassette transporter LmrA.

Multidrug resistance presents a major obstacle to the treatment of infectious diseases and cancer. LmrA, a bacterial ATP-dependent multidrug transporter, mediates efflux of hydrophobic cationic substrates, including antibiotics. The substrate-binding domain of LmrA was identified by using photo-affinity ligands, proteolytic degradation of LmrA, and identification of ligand-modified peptide fragments with matrix-assisted laser desorption ionization/time of flight mass spectrometry. In the nonenergized state, labeling occurred in the alpha-helical transmembrane segments (TM) 3, 5 and 6 of the membrane-spanning domain. Upon nucleotide binding, the accessibility of TM5 for substrates increased, whereas that of TM6 decreased. Inverse changes were observed upon ATP-hydrolysis. An atomic-detail model of dimeric LmrA was generated based on the template structure of the homologous transporter MsbA from Vibrio cholerae, allowing a three-dimensional visualization of the substrate-binding domain. Labeling of TM3 of one monomer occurred in a predicted area of contact with TM5 or TM6 of the opposite monomer, indicating substrate-binding at the monomer/monomer interface. Inverse changes in the reactivity of TM segments 5 and 6 suggest that substrate binding and release involves a repositioning of these helices during the catalytic cycle.

The lactococcal secondary multidrug transporter LmrP confers resistance to lincosamides, macrolides, streptogramins and tetracyclines.

The active efflux of toxic compounds by (multi)drug transporters is one of the mechanisms that bacteria have developed to resist cytotoxic drugs. The authors describe the role of the lactococcal secondary multidrug transporter LmrP in the resistance to a broad range of clinically important antibiotics. Cells expressing LmrP display an increased resistance to the lincosamide, streptogramin, tetracycline and 14- and 15-membered macrolide antibiotics. The streptogramin antibiotic quinupristin, present in the fourth-generation antibiotic RP 59500, can inhibit LmrP-mediated Hoechst 33342 transport, but is not transported by LmrP, indicating that quinupristin acts as a modulator of LmrP activity. LmrP-expressing Lactococcus lactis cells in which a proton-motive force is generated accumulate significantly less tetracycline than control cells without LmrP expression. In contrast, LmrP-expressing and control cells accumulate equal amounts of tetracycline in the absence of metabolic energy. These findings demonstrate that the increased antibiotic resistance in LmrP-expressing cells is a result of the active extrusion of antibiotics from the cell.

An ABC-type multidrug transporter of Lactococcus lactis possesses an exceptionally broad substrate specificity.

LmrA is a 590-amino acid membrane protein which confers multidrug resistance on Lactococcus lactis cells by extruding amphiphilic compounds from the inner leaflet of the cytoplasmic membrane at the expense of ATP hydrolysis. Its structural and functional characteristics place it in the P-glycoprotein cluster of the ATP-binding cassette transporter superfamily, making it the first prokaryotic multidrug transporter of this cluster. The number of compounds recognized and transported by LmrA is remarkably vast and includes many lipophilic cations as well as a record of eight classes of clinically relevant broad-spectrum antibiotics. Homologs of LmrA have been found in pathogenic bacteria, suggesting that these putative efflux pumps may play a crucial role in antibiotic resistance of human pathogens. Recent evidence indicates that LmrA is functional as a homodimer, consistent with the overall structure of P-glycoprotein, and mediates drug transport by an alternating two-site transport mechanism. Copyright 2000 Harcourt Publishers Ltd.