Translating Pharmacomicrobiomics: Three Actionable Challenges/Prospects in 2020

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Translating Pharmacomicrobiomics: Three Actionable Challenges/Prospects in 2020

The year 2020 marks a decade since the term pharmacomicrobiomics was coined (Rizkallah et al., 2010) to crystallize a century-old concept of mutual interactions between humans, drugs, and the microbial world. The human microbiome, with its immense metabolic potential that exceeds and expands the human metabolic capacities, has the ability to modulate pharmacotherapy by affecting both pharmacokinetics and pharmacodynamics of drug molecules:


"The simple definition of pharmacomicrobiomics is the (systematic) study of drug-microbiome interactions. More specifically, it is the study of how intra- and inter-individual microbiome variations affect drug action, disposition, efficacy, and toxicity. The emphasis here is on the effect of microbiome (i.e., microbial community) variations on pharmacokinetics and pharmacodynamics of drug therapy, rather than interactions between drugs and individual microbes. (Aziz, 2018)"

Although drug–microbiome interactions have been described for decades, before the Human Microbiome Project (HMP), all such reported interactions were scattered and uncoordinated, as they originated from sporadic studies spread over the years; thus, integrating them was challenging. As the human microbiome research gained momentum and began to define core microbiomes and microbiome variants (enterotypes, vagitypes, and metabotypes), the previously scattered reports seemed to have finally found a research niche that could lead to an exciting systematic field of scholarly inquiry.

What sounded perhaps like science fiction, or a futuristic "glimpse," when the word/concept of pharmacomicrobiomics was coined in 2010 (Rizkallah et al., 2010), is now becoming a concrete reality.

In 2010, we predicted three possible implications of pharmacomicrobiomics for the 2010–2019 decade. Our predictions included the use of personalized probiotics and phage cocktails, both of which are finding applications today to alleviate the adverse effects of chemotherapy or treat recalcitrant infections. We have also proposed resistome scanning or mapping of different human tissues, which may not be an implemented clinical strategy yet, but is being heavily researched and could be coming soon to the clinical practice (Rizkallah et al., 2010).

An imminently pressing idea that has yet to see the light is pharmacomicrobiomic testing. A million dollar question is: Has not the time come for routine microbiome testing and establishing pharmacomicrobiomic guidelines, at least for some drugs, in 2020?

Looking forward to 2020, we highlight three actionable challenges in the field of pharmacomicrobiomics that can transform to prospects for discovery and clinical science innovation.

Actionable Challenge 1

Systematic high-throughput microbiome screening studies

With the remarkable advances in sequencing technology, computational biology, and robotics, high-throughput screens became more available to medium-sized research laboratories, allowing academic and start-up research groups to enter the race of systematic screens for lead molecules, antimicrobials, and vaccine candidates.

Another axis that witnessed tremendous advance is that of culturing the microbiota or culturomics (Lagier et al., 2016). Whereas microbiome research started with the notion that the vast majority of microbial life remains uncultured, the past decade witnessed at least a doubling of the number of microbial taxa that can be cultured (Lagier et al., 2016).

The exciting intersection of the aforementioned two technologies (high-throughput sequencing/screening and microbial culturomics) has now made pharmacomicrobiomic and toxicomicrobiomic screening a reality.

An outstanding prototypic study in this premise screened 76 gut microbial taxa against 271 orally administered drugs (Zimmermann et al., 2019), ushering in a new phase of pharmacomicrobiomics that will likely be characterized by routine screens at different phases of drug development (lead discovery and preclinical phases, safety studies, and postmarketing surveys).

Actionable Challenge 2

Phage-enabled precision microbiome engineering/editing

Although bacteriophages and phage cocktails are already being used at different levels in biocontrol or antimicrobial therapy, precise removal of specific members of the microbiota by bacteriophage is still in its early phases.

In the coming decade, we expect to see bacteriophages used to precisely remove colorectal cancer-causing microbes, to eliminate specific microbes that aggravate adverse effects of chemotherapeutic agents, or as a supportive therapy with some drugs with narrow therapeutic index (e.g., digoxin) to remove bacteria that render it inefficient (e.g., Cgr-encoding Eggerthella lenta; Haiser et al., 2013).

Just a few months ago, an elegant study reported the successful use of a bacteriophage to decrease mortality by alcoholic fatty liver through selective removal of Enterococcus faecalis, which produces cytolysins that lead to deterioration of patients with alcoholic hepatitis (Duan et al., 2019). We see this as a prescient study for the next decade in use of phages for microbiome editing/rewiring.

We predict massive expansion of this microbiome editing field, not only on the community composition level (modulating the microbiota), but also by modulating the microbiome through editing the core and accessory genomes of specific members of the microbiota. This subgenomic-level editing can be transiently achieved through RNA interference (some sort of microbiata gene therapy) or through the use of CRISPR-CAS systems for higher resolution editing of the microbiota (e.g., by removing specific genetic loci, genomic islands, or inserting desired genes).

Actionable Challenge 3

Pharmacomicrobiomics in the clinic

We view clinical pharmacomicrobiomics as an imminent overdue measure, especially for some drugs whose pharmacomicrobiomic interactions are well defined [e.g., digoxin (Haiser et al., 2013), irinotecan (Lin et al., 2014), tenofovir (Klatt et al., 2017), and acetaminophen (Clayton et al., 2009)]. Moreover, we foresee an expansion of pharmacomicrobiomic and pharmacogenomic testing, as well as clinical guidelines that will cover major classes of drugs; and we believe that this expansion will mark a pivotal turning point in the history of precision medicine.

Conclusion

We anticipate that the next decade, which coincides with phase 2 of the HMP (the phase that aims at moving from identification to integration to intervention), will witness both interventional measures (e.g., microbiome editing) and clinical implementation (microbiome testing) that will be guided by a booming number of pharmacomicrobiomic screens, which we also think will soon be a routine step in drug discovery and pharmacovigilance protocols.

Our three suggested challenges will help translate the nascent area of pharmacomicrobiomics from bench to bedside, from bench to clinical laboratories, and from bench to pharmaceutical innovation. Translating pharmacomicrobiomics to routine health care applications is one of the current and actionable million dollar questions within the systems sciences innovation ecosystem.

For references and to view this article in its entirety.

OMICS: A Journal of Integrative Biology, published by Mary Ann Liebert, Inc., the only peer-reviewed forum covering all trans-disciplinary OMICS-related areas such as integrative (systems) biology and medicine, including but not limited to those specialties listed below. The above article was first published in OMICS: A Journal of Integrative Biology. The views expressed here are those of the authors and are not necessarily those of OMICS: A Journal of Integrative Biology, Mary Ann Liebert, Inc., publishers, or their affiliates. No endorsement of any entity or technology is implied.

Ubigene Biosciences is co-founded by biological academics and elites from China, the United States, and France. We are located in Guangzhou Science City, which serves as a global center for high technology and innovation. Ubigene Biosciences has 1000㎡ office areas and laboratories, involving genome editing, cell biology technology, and zebrafish research. We provide products and services for plasmids, viruses, cells, and zebrafish. We aim to provide customers with better gene-editing tools for cell or animal research.

We developed CRISPR-U™ and CRISPR-B™ (based on CRISPR/Cas9 technology) which is more efficient than general CRISPR/Cas9 in double-strand breaking, CRISPR-U™ and CRISPR-B™ can greatly improve the efficiency of homologous recombination, easily achieve knockout (KO), point mutation (PM) and knockin (KI) in vitro and in vivo. 

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——Focusing on the Application of CRISPR-U™ and CRISPR-B™ Gene Editing Technology
1. Provides various types of gene-editing vectors for different species.2. Provides different virus packaging services, including lentiviruses, adenoviruses and adeno-associated viruses.3. Provides high-quality services for gene knockout, point mutation and knockin cell lines. 

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1. Provides over 400 types of primary cells.2. Provides culture strategies and related products for different cell types.3. Provides cell biology-related services such as cell isolation, extraction and validation.