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A/Prof Andrew Crowe

Diagnostic and Therapeutic Sciences

In Vitro Drug Efflux Group

A/Prof. Andrew Crowe’s research journey began with his PhD in iron metabolism in the brain, where he investigated the effectiveness of iron chelators. This early work led to an opportunity in Switzerland, initially focused on developing new iron chelators. As his role evolved into compound formulation and selection, supporting broader drug development efforts, he developed a deeper appreciation of how efflux proteins influence drug bioavailability.
 
Through this experience, A/Prof. Crowe became particularly interested in the body’s ability to develop resistance to treatment, through mechanisms that amplify these pathways, much like bacterial resistance. Understanding and overcoming this form of inherent drug resistance has since become a central focus of his work.
 
He has long been fascinated by the role of biometals, especially iron and copper, in human biology. This curiosity continues to drive his research, particularly in exploring how the body can actively limit the effectiveness of treatments and how these challenges might be addressed to improve therapeutic outcomes.


About

A/Prof. Andrew Crowe completed his PhD at the University of Western Australia in the 1990s, where he investigated iron chelation and the influence of neurotoxic metals on iron absorption in the developing brain. He then undertook a postdoctoral fellowship with Novartis in Switzerland, focusing on the development of orally active iron chelators, before contributing to broader drug development efforts examining how human efflux systems affect the oral absorption of new drug compounds.


Since returning to Curtin University in 1999, A/Prof. Crowe has continued to advance in vitro models for studying drug transport, particularly efflux detection using human Caco-2 gastrointestinal cell systems. His work has led to the development of a rapid model that produces functional results in just six days, compared to the traditional three week timeframe. His research also explores the role of biometals in drug efflux, as well as how drug induced changes in efflux systems can influence bioavailability and contribute to potential drug to drug interactions.

  • Member of Australasian Society for Clinical and Experimental Pharmacologists and Toxicologists (ASCEPT)

Research Focus

A/Prof. Andrew Crowe investigates the role of multidrug efflux systems, including P glycoprotein, BCRP, and the MRP family, in the transport of drugs across human cell monolayers. His work examines quantitative differences in efflux and transport among related drug groups, providing insight into how these systems influence drug behaviour.


He also explores how drugs can suppress or enhance efflux protein expression, with the aim of better understanding drug interactions and their impact on bioavailability within the body.

Publications

ABSTRACT

The CLEFF4 sub clone from stock late passage Caco2 cells has a unique property of being able to develop polarised cell monolayers with high P-gp expression and tight junctions much quicker than the original cell line. Instead of being useful for transport studies 21–24 days after initiating culture, the CLEFF4 cell line matures in 5–6 days with tight junctions surpassing that of 3 week old Caco2 cells in that time frame [1]. This has enabled the CLEFF4 cell line to provide measures of apparent permeability for potential drug candidates, so important for pre-clinical drug development, 4 times faster than the original cell line. RNA samples were collected and analysed at days 4 and 7 of culture over a 3 year period and had full RNA transcriptome analysed by the ranaseq.eu open bioinformatics platform. Protein was also collected from day 4 to day 22 of culture. Differential expression data from the FASTQ files have shown significant differences in expression in multiple genes involved with drug efflux, tight junctions, phase 2 metabolism and growth factors, which have been confirmed from protein determination that may hold the key to understanding accelerated human cell maturation. These gene expression results may be significant for other tissues beyond the gastrointestinal tract, and potentially for accelerated cell growth for the new field of laboratory grown tissues for organ replacement. The data also confirms the different genetic expression in CLEFF4 cells compared to Caco2 and the stable nature of the different expression over many years.

Crowe, A. 2024. Transcriptomic and western blot characterisation of the human CLEFF4 clone, a new rapid cell line replacement for the Caco2 model.European Journal of Pharmaceutics and Biopharmaceutics 199
ABSTRACT

The COVID-19 pandemic has had a significant and lasting impact on the world. Four years on, despite the existence of effective vaccines, the continuous emergence of new SARS-CoV-2 variants remains a challenge for long-term immunity. Additionally, there remain few purpose-built antivirals to protect individuals at risk of severe disease in the event of future coronavirus outbreaks. A promising mechanism of action for novel coronavirus antivirals is the inhibition of viral entry. To facilitate entry, the coronavirus spike glycoprotein interacts with angiotensin converting enzyme 2 (ACE2) on respiratory epithelial cells. Blocking this interaction and consequently viral replication may be an effective strategy for treating infection, however further research is needed to better characterize candidate molecules with antiviral activity before progressing to animal studies and clinical trials. In general, antiviral drugs are developed from purely synthetic compounds or synthetic derivatives of natural products such as plant secondary metabolites. While the former is often favored due to the higher specificity afforded by rational drug design, natural products offer several unique advantages that make them worthy of further study including diverse bioactivity and the ability to work synergistically with other drugs. Accordingly, there has recently been a renewed interest in natural product-derived antivirals in the wake of the COVID-19 pandemic. This review provides a summary of recent research into coronavirus entry inhibitors, with a focus on natural compounds derived from plants, honey, and marine sponges.

Szabó, D., A. Crowe, C. Mamotte, and P. Strappe. 2024. Natural products as a source of Coronavirus entry inhibitors.Frontiers in Cellular and Infection Microbiology 14

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