Studies on the interaction of chemicals with cellular efflux transporter proteins Danio rerio Abcb4 and Homo sapiens ABCB1

ABCB1, a member of the ATP binding cassette (ABC) transporter family, hydrolyses ATP as energy source for the translocation of substrate chemicals across the cell membrane. ABCB1-like transporters are found in all studied species. Typically, these transporters are abundant in tissues that separate compartments of the body such as the blood-brain barrier. Among the ABC transporters the ABCB1-like transporter proteins are of particular interest because they accept a broad variety of substrates and are therefore able to confer multidrug resistance (MDR) and multixenobiotic resistance (MXR) in wildlife, respectively. Inhibitors of the ABCB1-like transporter function can cause chemosensitisation, i.e. accumulation and increased sensitivity of organisms towards potentially harmful (natural/man-made) ABCB1-like substrate chemicals. In zebrafish (Danio rerio) Abcb4 was identified as functionally homologous to ABCB1. The aim of this study was to further characterise Danio rerio Abcb4 and to provide a database to approach the question to what extent ABCB1-like transporter related functions/effects are of ecotoxicological relevance. Main objectives are whether and how known ABCB1 ATPase stimulators and inhibitors interact with Abcb4 ATPase activity; to what extent ABCB1 ATPase assay data are transferable to Abcb4 ATPase assay data; and whether and how environmental chemicals interact with Danio rerio Abcb4 ATPase activity. In this study we established a test system – the ATPase assay with recombinant Danio rerio Abcb4 – to study the interaction of chemicals with the ATPase activity of the transporter protein. To relate obtained data to data for the well-known Homo sapiens ABCB1 and because available data for Homo sapiens ABCB1 were not in all cases suitable for a comparison, the ATPase assay with recombinant ABCB1 was adapted accordingly. Chemicals were tested up to concentrations in the range of their water solubilities to modulate basal and stimulator co-treated Abcb4 and/or ABCB1 ATPase activities. ATPase stimulators are often transported substrates. However, lipophilic compounds stimulating the transporter ATPase activity are not or little transported by transporter action. Therefore, experiments revealing whether compounds are translocated by transporters chemical interference with the transporter protein will not be indicated. Chemicals inhibiting the stimulator (here verapamil) co-treated ATPase activity compete with the verapamil to stimulate ATPase activity or are non-competitive inhibitors. When tested individually, these chemicals can be stimulators or inhibitors of basal ATPase activity, or do not interact with basal ATPase activity. ATPase inhibitors mitigate ATPase activity and ABCB1-like transporter mediated translocation of substrate chemicals. Obtained ATPase assay data were analysed with regard to concentrations at half-maximal effects (EC50s) and effect strengths (percent modulation). ATPase assays with recombinant Abcb4 (at 27 °C) are comparable to ABCB1 ATPase assay data obtained at 37 °C. Danio rerio Abcb4 seems less temperature-sensitive than ABCB1. Calculated activation energies for Abcb4 ATPase activities (40.75 kJ/mol for basal ATPase activity) were up to half as high as those for ABCB1 ATPase activities (81.61 kJ/mol for basal ATPase activity). Larger activation energies were previously proposed to be indicative for larger conformational rearrangements and hence possibly smaller rearrangements take place in Abcb4 compared to ABCB1. Known standard modulators of Homo sapiens ABCB1 ATPase activity interacted specifically with Danio rerio Abcb4 ATPase actitiy. The EC50s of the tested chemicals – 16 of 17 tested chemiacals interacted with the ABCB1 and the Abcb4 ATPase activity – ranged from 0.09 to 296 µM for ABCB1 and from 0.14 to 171 µM for Abcb4. Qualitative ATPase assay data for ABCB1, as interaction or not, seems transferable to Danio rerio Abcb4. Furthermore, when aligning amino acid sequences of mammalian ABCB1 transporter proteins and Danio rerio Abcb4 and comparing ABCB1 residues known to bind to (lipophilic) chemicals no obvious hints were found that chemical binding to Abcb4 is certainly different from ABCB1. Twenty-five of 33 studied environmental chemicals modulated the Abcb4 ATPase activity as stimulators and/or inhibitors. Stimulation of basal Abcb4 ATPase activity was lower for environmental chemicals than for known standard modulators. EC50s of environmental chemicals ranged from below 10 to 357 µM. Effects by environmental chemicals on Abcb4 ATPase activity with EC50s close to their water solubilities may be rather unspecific. The results of this work underline that Abcb4 function is of ecotoxicological importance as on the one hand several environmental chemicals were identified to inhibit Abcb4 ATPase activity – likely acting as chemosensitisers, while on the other hand chemicals stimulating basal ATPase activity suggest that these chemicals are possibly transported. A number of environmental chemicals also inhibited the basal Abcb4 ATPase activity. Especially non-transported inhibitors of the basal Abcb4 ATPase activity would be of ecotoxicological relevance as organisms (here Danio rerio) exposed to these chemicals would not be protected by Abcb4 mediated multixenobiotic resistance and were moreover threatened by chemosensitisation. Future studies should systematically elucidate under which circumstances chemicals are apparently net transported by ABCB1-like transporters and relate these findings to concentrations of environmental chemicals and ABCB1-like transporter protein abundance in wildlife

Abcb4 acts as multixenobiotic transporter and active barrier against chemical uptake in zebrafish (Danio rerio) embryos

BACKGROUND: In mammals, ABCB1 constitutes a cellular “first line of defense” against a wide array of chemicals and drugs conferring cellular multidrug or multixenobiotic resistance (MDR/MXR). We tested the hypothesis that an ABCB1 ortholog serves as protection for the sensitive developmental processes in zebrafish embryos against adverse compounds dissolved in the water. RESULTS: Indication for ABCB1-type efflux counteracting the accumulation of chemicals in zebrafish embryos comes from experiments with fluorescent and toxic transporter substrates and inhibitors. With inhibitors present, levels of fluorescent dyes in embryo tissue and sensitivity of embryos to toxic substrates were generally elevated. We verified two predicted sequences from zebrafish, previously annotated as abcb1, by cloning; our synteny analyses, however, identified them as abcb4 and abcb5, respectively. The abcb1 gene is absent in the zebrafish genome and we explored whether instead Abcb4 and/or Abcb5 show toxicant defense properties. Quantitative real-time polymerase chain reaction (qPCR) analyses showed the presence of transcripts of both genes throughout the first 48 hours of zebrafish development. Similar to transporter inhibitors, morpholino knock-down of Abcb4 increased accumulation of fluorescent substrates in embryo tissue and sensitivity of embryos toward toxic compounds. In contrast, morpholino knock-down of Abcb5 did not exert this effect. ATPase assays with recombinant protein obtained with the baculovirus expression system confirmed that dye and toxic compounds act as substrates of zebrafish Abcb4 and inhibitors block its function. The compounds tested comprised model substrates of human ABCB1, namely the fluorescent dyes rhodamine B and calcein-am and the toxic compounds vinblastine, vincristine and doxorubicin; cyclosporin A, PSC833, MK571 and verapamil were applied as inhibitors. Additionally, tests were performed with ecotoxicologically relevant compounds: phenanthrene (a polycyclic aromatic hydrocarbon) and galaxolide and tonalide (two polycyclic musks). CONCLUSIONS: We show that zebrafish Abcb4 is a cellular toxicant transporter and provides protection of embryos against toxic chemicals dissolved in the water. Zebrafish Abcb4 thus is functionally similar to mammalian ABCB1, but differs from mammalian ABCB4, which is not involved in cellular resistance to chemicals but specifically transports phospholipids in the liver. Our data have important implications: Abcb4 could affect bioavailability - and thus toxicologic and pharmacologic potency - of chemicals to zebrafish embryos and inhibition of Abcb4 therefore causes chemosensitization, that is, enhanced sensitivity of embryos to toxicants. These aspects should be considered in (eco)toxicologic and pharmacologic chemical screens with the zebrafish embryo, a major vertebrate model

Studies on the interaction of chemicals with cellular efflux transporter proteins Danio rerio Abcb4 and Homo sapiens ABCB1

ABCB1, a member of the ATP binding cassette (ABC) transporter family, hydrolyses ATP as energy source for the translocation of substrate chemicals across the cell membrane. ABCB1-like transporters are found in all studied species. Typically, these transporters are abundant in tissues that separate compartments of the body such as the blood-brain barrier. Among the ABC transporters the ABCB1-like transporter proteins are of particular interest because they accept a broad variety of substrates and are therefore able to confer multidrug resistance (MDR) and multixenobiotic resistance (MXR) in wildlife, respectively. Inhibitors of the ABCB1-like transporter function can cause chemosensitisation, i.e. accumulation and increased sensitivity of organisms towards potentially harmful (natural/man-made) ABCB1-like substrate chemicals. In zebrafish (Danio rerio) Abcb4 was identified as functionally homologous to ABCB1. The aim of this study was to further characterise Danio rerio Abcb4 and to provide a database to approach the question to what extent ABCB1-like transporter related functions/effects are of ecotoxicological relevance. Main objectives are whether and how known ABCB1 ATPase stimulators and inhibitors interact with Abcb4 ATPase activity; to what extent ABCB1 ATPase assay data are transferable to Abcb4 ATPase assay data; and whether and how environmental chemicals interact with Danio rerio Abcb4 ATPase activity. In this study we established a test system – the ATPase assay with recombinant Danio rerio Abcb4 – to study the interaction of chemicals with the ATPase activity of the transporter protein. To relate obtained data to data for the well-known Homo sapiens ABCB1 and because available data for Homo sapiens ABCB1 were not in all cases suitable for a comparison, the ATPase assay with recombinant ABCB1 was adapted accordingly. Chemicals were tested up to concentrations in the range of their water solubilities to modulate basal and stimulator co-treated Abcb4 and/or ABCB1 ATPase activities. ATPase stimulators are often transported substrates. However, lipophilic compounds stimulating the transporter ATPase activity are not or little transported by transporter action. Therefore, experiments revealing whether compounds are translocated by transporters chemical interference with the transporter protein will not be indicated. Chemicals inhibiting the stimulator (here verapamil) co-treated ATPase activity compete with the verapamil to stimulate ATPase activity or are non-competitive inhibitors. When tested individually, these chemicals can be stimulators or inhibitors of basal ATPase activity, or do not interact with basal ATPase activity. ATPase inhibitors mitigate ATPase activity and ABCB1-like transporter mediated translocation of substrate chemicals. Obtained ATPase assay data were analysed with regard to concentrations at half-maximal effects (EC50s) and effect strengths (percent modulation). ATPase assays with recombinant Abcb4 (at 27 °C) are comparable to ABCB1 ATPase assay data obtained at 37 °C. Danio rerio Abcb4 seems less temperature-sensitive than ABCB1. Calculated activation energies for Abcb4 ATPase activities (40.75 kJ/mol for basal ATPase activity) were up to half as high as those for ABCB1 ATPase activities (81.61 kJ/mol for basal ATPase activity). Larger activation energies were previously proposed to be indicative for larger conformational rearrangements and hence possibly smaller rearrangements take place in Abcb4 compared to ABCB1. Known standard modulators of Homo sapiens ABCB1 ATPase activity interacted specifically with Danio rerio Abcb4 ATPase actitiy. The EC50s of the tested chemicals – 16 of 17 tested chemiacals interacted with the ABCB1 and the Abcb4 ATPase activity – ranged from 0.09 to 296 µM for ABCB1 and from 0.14 to 171 µM for Abcb4. Qualitative ATPase assay data for ABCB1, as interaction or not, seems transferable to Danio rerio Abcb4. Furthermore, when aligning amino acid sequences of mammalian ABCB1 transporter proteins and Danio rerio Abcb4 and comparing ABCB1 residues known to bind to (lipophilic) chemicals no obvious hints were found that chemical binding to Abcb4 is certainly different from ABCB1. Twenty-five of 33 studied environmental chemicals modulated the Abcb4 ATPase activity as stimulators and/or inhibitors. Stimulation of basal Abcb4 ATPase activity was lower for environmental chemicals than for known standard modulators. EC50s of environmental chemicals ranged from below 10 to 357 µM. Effects by environmental chemicals on Abcb4 ATPase activity with EC50s close to their water solubilities may be rather unspecific. The results of this work underline that Abcb4 function is of ecotoxicological importance as on the one hand several environmental chemicals were identified to inhibit Abcb4 ATPase activity – likely acting as chemosensitisers, while on the other hand chemicals stimulating basal ATPase activity suggest that these chemicals are possibly transported. A number of environmental chemicals also inhibited the basal Abcb4 ATPase activity. Especially non-transported inhibitors of the basal Abcb4 ATPase activity would be of ecotoxicological relevance as organisms (here Danio rerio) exposed to these chemicals would not be protected by Abcb4 mediated multixenobiotic resistance and were moreover threatened by chemosensitisation. Future studies should systematically elucidate under which circumstances chemicals are apparently net transported by ABCB1-like transporters and relate these findings to concentrations of environmental chemicals and ABCB1-like transporter protein abundance in wildlife

Studies on the interaction of chemicals with cellular efflux transporter proteins Danio rerio Abcb4 and Homo sapiens ABCB1

ABCB1, a member of the ATP binding cassette (ABC) transporter family, hydrolyses ATP as energy source for the translocation of substrate chemicals across the cell membrane. ABCB1-like transporters are found in all studied species. Typically, these transporters are abundant in tissues that separate compartments of the body such as the blood-brain barrier. Among the ABC transporters the ABCB1-like transporter proteins are of particular interest because they accept a broad variety of substrates and are therefore able to confer multidrug resistance (MDR) and multixenobiotic resistance (MXR) in wildlife, respectively. Inhibitors of the ABCB1-like transporter function can cause chemosensitisation, i.e. accumulation and increased sensitivity of organisms towards potentially harmful (natural/man-made) ABCB1-like substrate chemicals. In zebrafish (Danio rerio) Abcb4 was identified as functionally homologous to ABCB1. The aim of this study was to further characterise Danio rerio Abcb4 and to provide a database to approach the question to what extent ABCB1-like transporter related functions/effects are of ecotoxicological relevance. Main objectives are whether and how known ABCB1 ATPase stimulators and inhibitors interact with Abcb4 ATPase activity; to what extent ABCB1 ATPase assay data are transferable to Abcb4 ATPase assay data; and whether and how environmental chemicals interact with Danio rerio Abcb4 ATPase activity. In this study we established a test system – the ATPase assay with recombinant Danio rerio Abcb4 – to study the interaction of chemicals with the ATPase activity of the transporter protein. To relate obtained data to data for the well-known Homo sapiens ABCB1 and because available data for Homo sapiens ABCB1 were not in all cases suitable for a comparison, the ATPase assay with recombinant ABCB1 was adapted accordingly. Chemicals were tested up to concentrations in the range of their water solubilities to modulate basal and stimulator co-treated Abcb4 and/or ABCB1 ATPase activities. ATPase stimulators are often transported substrates. However, lipophilic compounds stimulating the transporter ATPase activity are not or little transported by transporter action. Therefore, experiments revealing whether compounds are translocated by transporters chemical interference with the transporter protein will not be indicated. Chemicals inhibiting the stimulator (here verapamil) co-treated ATPase activity compete with the verapamil to stimulate ATPase activity or are non-competitive inhibitors. When tested individually, these chemicals can be stimulators or inhibitors of basal ATPase activity, or do not interact with basal ATPase activity. ATPase inhibitors mitigate ATPase activity and ABCB1-like transporter mediated translocation of substrate chemicals. Obtained ATPase assay data were analysed with regard to concentrations at half-maximal effects (EC50s) and effect strengths (percent modulation). ATPase assays with recombinant Abcb4 (at 27 °C) are comparable to ABCB1 ATPase assay data obtained at 37 °C. Danio rerio Abcb4 seems less temperature-sensitive than ABCB1. Calculated activation energies for Abcb4 ATPase activities (40.75 kJ/mol for basal ATPase activity) were up to half as high as those for ABCB1 ATPase activities (81.61 kJ/mol for basal ATPase activity). Larger activation energies were previously proposed to be indicative for larger conformational rearrangements and hence possibly smaller rearrangements take place in Abcb4 compared to ABCB1. Known standard modulators of Homo sapiens ABCB1 ATPase activity interacted specifically with Danio rerio Abcb4 ATPase actitiy. The EC50s of the tested chemicals – 16 of 17 tested chemiacals interacted with the ABCB1 and the Abcb4 ATPase activity – ranged from 0.09 to 296 µM for ABCB1 and from 0.14 to 171 µM for Abcb4. Qualitative ATPase assay data for ABCB1, as interaction or not, seems transferable to Danio rerio Abcb4. Furthermore, when aligning amino acid sequences of mammalian ABCB1 transporter proteins and Danio rerio Abcb4 and comparing ABCB1 residues known to bind to (lipophilic) chemicals no obvious hints were found that chemical binding to Abcb4 is certainly different from ABCB1. Twenty-five of 33 studied environmental chemicals modulated the Abcb4 ATPase activity as stimulators and/or inhibitors. Stimulation of basal Abcb4 ATPase activity was lower for environmental chemicals than for known standard modulators. EC50s of environmental chemicals ranged from below 10 to 357 µM. Effects by environmental chemicals on Abcb4 ATPase activity with EC50s close to their water solubilities may be rather unspecific. The results of this work underline that Abcb4 function is of ecotoxicological importance as on the one hand several environmental chemicals were identified to inhibit Abcb4 ATPase activity – likely acting as chemosensitisers, while on the other hand chemicals stimulating basal ATPase activity suggest that these chemicals are possibly transported. A number of environmental chemicals also inhibited the basal Abcb4 ATPase activity. Especially non-transported inhibitors of the basal Abcb4 ATPase activity would be of ecotoxicological relevance as organisms (here Danio rerio) exposed to these chemicals would not be protected by Abcb4 mediated multixenobiotic resistance and were moreover threatened by chemosensitisation. Future studies should systematically elucidate under which circumstances chemicals are apparently net transported by ABCB1-like transporters and relate these findings to concentrations of environmental chemicals and ABCB1-like transporter protein abundance in wildlife

Chemical effects on dye efflux activity in live zebrafish embryos and on zebrafish Abcb4 ATPase activity

ATP‐binding cassette (ABC) transporter proteins include efflux pumps that confer multixenobiotic resistance to zebrafish embryos, a valuable toxico/pharmacological model. Here, we established an automated microscopy‐based rhodamine B dye accumulation assay in which enhanced dye accumulation in live zebrafish embryos indicates inhibition of multixenobiotic efflux transporter activity. Twenty structurally divergent known substrates and/or inhibitors of human ABC transporters and environmentally relevant compounds were examined using this assay and the ATPase activity of recombinant zebrafish Abcb4 as readouts. These two assays confirmed that Abcb4 functions as an efflux transporter in zebrafish, whereas they gave discordant results for some of the tested substances. The dye accumulation assay in zebrafish embryos could be useful to screen environmental pollutants and other chemicals for efflux transporter interaction in a medium‐throughput fashion.Fil: Bieczynski, Flavia. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Patagonia Confluencia; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Patagonia Confluencia. Centro de Investigaciones en Toxicología Ambiental y Agrobiotecnología del Comahue. Instituto de Biotecnología Agropecuaria del Comahue | Universidad Nacional del Comahue. Facultad de Ciencias Agrarias. Centro de Investigaciones en Toxicología Ambiental y Agrobiotecnología del Comahue. Instituto de Biotecnología Agropecuaria del Comahue; ArgentinaFil: Burkhardt Medicke, Kathleen. Universitat Leipzig; Alemania. Helmholtz Centre for Environmental Research; AlemaniaFil: Luquet, Carlos Marcelo. Consejo Nacional de Investigaciones Cientificas y Tecnicas. Centro Cientifico Tecnologico Conicet - Patagonia Norte. Instituto de Investigaciones En Biodiversidad y Medioambiente. Subsede Junín de Los Andes-inibioma-centro de Ecología Aplicada del Neuquén (cean) | Universidad Nacional del Comahue. Centro Regional Universitario Bariloche. Instituto de Investigaciones En Biodiversidad y Medioambiente. Subsede Junín de Los Andes-inibioma-centro de Ecología Aplicada del Neuquén (cean).; ArgentinaFil: Scholz, Stefan. Universitat Leipzig; Alemania. Helmholtz Centre for Environmental Research; AlemaniaFil: Luckenbach, Till. Universitat Leipzig; Alemania. Helmholtz Centre for Environmental Research; Alemani