Reversing the direction of drug transport mediated by the human multidrug transporter P-glycoprotein

Andaleeb Sajid; Sabrina Lusvarghi; Megumi Murakami; Eduardo E. Chufan; Biebele Abel; Michael M. Gottesman; Stewart R. Durell; Suresh V. Ambudkar

doi:10.1073/pnas.2016270117

New Research In

Contributed by Michael M. Gottesman, September 30, 2020 (sent for review July 31, 2020; reviewed by Björn Bauer and Cynthia Vianne Stauffacher)

Significance

The multidrug transporter P-glycoprotein protects tissues from xenobiotics and other toxic compounds by pumping them out of cells. This transporter has been implicated in altering the bioavailability of chemotherapeutic drugs and in the development of multidrug resistance in tumor cells. Despite decades of research, the modulation of P-glycoprotein to overcome drug resistance in the clinic has not been successful. Here, by substituting a group of 14 conserved residues in homologous transmembrane helices 6 and 12 with alanine, we generated a mutant that exhibits a change in the direction of transport from export to import for certain drug substrates including the taxol derivative flutax-1. The ability to convert P-glycoprotein into a drug importer provides a strategy to combat cancer drug resistance.

Abstract

P-glycoprotein (P-gp), also known as ABCB1, is a cell membrane transporter that mediates the efflux of chemically dissimilar amphipathic drugs and confers resistance to chemotherapy in most cancers. Homologous transmembrane helices (TMHs) 6 and 12 of human P-gp connect the transmembrane domains with its nucleotide-binding domains, and several residues in these TMHs contribute to the drug-binding pocket. To investigate the role of these helices in the transport function of P-gp, we substituted a group of 14 conserved residues (seven in both TMHs 6 and 12) with alanine and generated a mutant termed 14A. Although the 14A mutant lost the ability to pump most of the substrates tested out of cancer cells, surprisingly, it acquired a new function. It was able to import four substrates, including rhodamine 123 (Rh123) and the taxol derivative flutax-1. Similar to the efflux function of wild-type P-gp, we found that uptake by the 14A mutant is ATP hydrolysis-, substrate concentration-, and time-dependent. Consistent with the uptake function, the mutant P-gp also hypersensitizes HeLa cells to Rh123 by 2- to 2.5-fold. Further mutagenesis identified residues from both TMHs 6 and 12 that synergistically form a switch in the central region of the two helices that governs whether a given substrate is pumped out of or into the cell. Transforming P-gp or an ABC drug exporter from an efflux transporter into a drug uptake pump would constitute a paradigm shift in efforts to overcome cancer drug resistance.

Footnotes

↵¹To whom correspondence may be addressed. Email: ambudkar{at}mail.nih.gov.

Author contributions: A.S., S.L., E.E.C., and S.V.A. designed research; A.S., S.L., M.M., E.E.C., and B.A. performed research; A.S., S.L., M.M., E.E.C., and B.A. analyzed data; S.R.D. carried out in silico studies including molecular dynamics simulations; A.S., S.L., M.M.G., S.R.D., and S.V.A. wrote the paper; and S.V.A. supervised the study.
Reviewers: B.B., University of Kentucky; and C.V.S., Purdue University.
The authors declare no competing interest.
This article contains supporting information online at https://www.pnas.org/lookup/suppl/doi:10.1073/pnas.2016270117/-/DCSupplemental.