# Terpenoids: Emerging Natural Modulators for Reversing ABC Transporter-Mediated Multidrug Resistance in Cancer Chemotherapy

**Authors:** Lanfei Ma, Dina Mahemuti, Yuanhong Lan, Jianxiong Xu, Wenfang Li, Zhengding Su, Jinyao Li, Aytursun Abuduwaili, Ayitila Maimaitijiang

PMC · DOI: 10.3390/ph19010146 · Pharmaceuticals · 2026-01-14

## TL;DR

This paper explores how terpenoids, natural compounds, can reverse drug resistance in cancer by targeting ABC transporters and offers insights into their advantages and future research directions.

## Contribution

The paper systematically summarizes terpenoids' inhibitory effects on ABC transporters and proposes new strategies to enhance their clinical translation.

## Key findings

- Terpenoids show low toxicity and high specificity in inhibiting ABC transporters compared to traditional reversal agents.
- Compounds like BBA and sooneuphanone D demonstrate potent MDR reversal activity and druggable modifiability.
- The paper identifies bottlenecks such as low bioavailability and proposes solutions like nano-delivery and structural optimization.

## Abstract

Multidrug resistance (MDR) is a central cause of chemotherapy failure and tumor recurrence and metastasis, and its mechanism involves enhanced drug efflux, target mutation, upregulation of DNA repair and remodeling of the tumor microenvironment. ABC transporter protein (P-gp, MRP, and BCRP)-mediated efflux of drugs is the most intensively researched aspect of the study, but the first three generations of small-molecule reversal agents were stopped in the clinic because of toxicity or pharmacokinetic defects. Natural products are considered as the fourth generation of MDR reversal agents due to their structural diversity, multi-targeting and low toxicity. In this paper, we systematically summarize the inhibitory activities of monoterpenes, sesquiterpenes, diterpenes and triterpenes against ABC transporter proteins in in vitro and in vivo models and focus on the new mechanism of reversing drug resistance by blocking efflux pumps, modulating signaling pathways such as PI3K-AKT, Nrf2, NF-κB and remodeling the tumor microenvironment. For example, Terpenoids possess irreplaceable core advantages over traditional multidrug resistance (MDR) reversers: Compared with the first three generations of synthetic reversers, natural/semisynthetic terpenoids integrate low toxicity (mostly derived from edible medicinal plants, half-maximal inhibitory concentration IC50 > 50 μM), high target specificity (e.g., oleanolic acid specifically inhibits the ATP-binding cassette (ABC) transporter subtype ABCC1 without cross-reactivity with ABCB1), and multi-mechanistic synergistic effects (e.g., β-caryophyllene simultaneously mediates the dual effects of “ABCB1 efflux inhibition + apoptotic pathway activation”). These unique characteristics enable terpenoids to effectively circumvent key limitations of traditional synthetic reversers, such as high toxicity and severe drug–drug interactions. Among them, lupane-type derivative BBA and euphane-type sooneuphanone D (triterpenoids), as well as dihydro-β-agarofuran-type compounds and sesquiterpene lactone Conferone (sesquiterpenoids), have emerged as the core lead compounds with the greatest translational potential in current MDR reverser research, attributed to their potent in vitro and in vivo MDR reversal activity, low toxicity, and excellent druggable modifiability. At the same time, we point out bottlenecks, such as low bioavailability, insufficient in vivo evidence, and unclear structure–activity relationship and put forward a proposal to address these bottlenecks. At the same time, the bottlenecks of low bioavailability, insufficient vivo evidence and unclear structure–activity relationship have been pointed out, and future research directions such as nano-delivery, structural optimization and combination strategies have been proposed to provide theoretical foundations and potential practical pathways for the clinical translation research of terpenoid compounds, whose clinical application still requires further in vivo validation and translational research support.

## Linked entities

- **Proteins:** PGP (phosphoglycolate phosphatase), ABCC1 (ATP binding cassette subfamily C member 1 (ABCC1 blood group)), ABCG2 (ATP binding cassette subfamily G member 2 (JR blood group)), ABCC1 (ATP binding cassette subfamily C member 1 (ABCC1 blood group)), ABCB1 (ATP binding cassette subfamily B member 1), GABPA (GA binding protein transcription factor subunit alpha), NFKB1 (nuclear factor kappa B subunit 1)
- **Chemicals:** β-caryophyllene (PubChem CID 5281515), Conferone (PubChem CID 3108117)
- **Diseases:** cancer (MONDO:0004992)

## Full-text entities

- **Genes:** ABCG2 (ATP binding cassette subfamily G member 2 (JR blood group)) [NCBI Gene 9429] {aka ABC15, ABCP, BCRP, BMDP, CD338, CDw338}, AKT1 (AKT serine/threonine kinase 1) [NCBI Gene 207] {aka AKT, PKB, PKB-ALPHA, PRKBA, RAC, RAC-ALPHA}, ABCC1 (ATP binding cassette subfamily C member 1 (ABCC1 blood group)) [NCBI Gene 4363] {aka ABC29, ABCC, DFNA77, GS-X, MRP, MRP1}, NFE2L2 (NFE2 like bZIP transcription factor 2) [NCBI Gene 4780] {aka IMDDHH, NRF2, Nrf-2}, PIK3CB (phosphatidylinositol-4,5-bisphosphate 3-kinase catalytic subunit beta) [NCBI Gene 5291] {aka P110BETA, PI3K, PI3KBETA, PIK3C1}, PGP (phosphoglycolate phosphatase) [NCBI Gene 283871] {aka AUM, G3PP, PGPase}, NFKB1 (nuclear factor kappa B subunit 1) [NCBI Gene 4790] {aka CVID12, EBP-1, KBF1, NF-kB, NF-kB1, NF-kappa-B1}, ABCB1 (ATP binding cassette subfamily B member 1) [NCBI Gene 5243] {aka ABC20, CD243, CLCS, ENPAT, GP170, MDR1}
- **Diseases:** toxicity (MESH:D064420), Cancer (MESH:D009369), metastasis (MESH:D009362)
- **Chemicals:** diterpenes (MESH:D004224), beta-caryophyllene (MESH:C024714), oleanolic acid (MESH:D009828), Conferone (MESH:C513235), sesquiterpenes (MESH:D012717), triterpenes (MESH:D014315), monoterpenes (MESH:D039821), BBA (MESH:C034290), euphane (-), Terpenoids (MESH:D013729), lupane (MESH:C480546), dihydro-beta-agarofuran (MESH:C079978)

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12845493/full.md

## References

150 references — full list in the complete paper: https://tomesphere.com/paper/PMC12845493/full.md

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Source: https://tomesphere.com/paper/PMC12845493