Systems Biology Approaches in Pharmacology and Toxicology

DALE E. JOHNSON

1.1 Introduction

The science and practical field of toxicology has been changing dramatically over the last 15–20 years, transitioning into a more systems biology and network-based approach. Several factors have been involved, including the developing genomics era where the understanding of genetic changes has enhanced the ability to understand diseases and chemically-induced toxicities at the molecular level. The genomics era has also ushered in "omics" technologies and approaches such as transcriptomics, metabolomics, proteomics, and epigenomics, which have changed the way we view mechanisms of toxicity and the perturbation of biological systems that lead to adverse outcomes. These advances have been coupled with the public availability of large datasets of information and new modeling approaches that have enhanced the ability to understand toxicological events and effects at multiple biological levels. Since our scientific approaches, inquiries, and visions aimed at understanding toxicological events and outcomes have been broadened tremendously, this reinforces our need for new and better ways to assess toxicity and risk. The large numbers of uncharacterized chemicals already present in the environment and new chemicals that continue to enter it has required hazard and risk assessments to be made with very few data. These factors have had a major influence on the need to accelerate new approaches and move away from an overdependence on in vivo animal testing and make better use of computational, molecular, and in vitro tools. The identification of the majority of toxic events in in vivo animal toxicology studies rely on high-dose exposure to the animals and default linear extrapolation procedures, with the incorporation of newer technologies absent in the vast majority of animal studies. This has been considered a shortcoming in risk assessment and several weaknesses in this process include the comparative shape of the dose–response relationship after relevant levels of human exposure, whether biological and/or toxicological thresholds do in fact exist and for what toxicological endpoints, and potential population variability in response.

1.2 Systems Toxicology

Accordingly, research in toxicology has moved into a new systems-oriented phase called systems toxicology, which involves the study of complex molecular response networks initiated by exposure (both intentional and unintentional) to chemical substances. At the heart of systems toxicology approaches are the development and usage of quantitative mechanistic models that create a predictive toxicology aspect relevant to all toxicology fields, including drug research and development and environmental research. The overall approach involves the integration of classical toxicology with the quantitative analysis of large networks of chemically-induced molecular and functional changes, which occur across multiple levels of biological organization. Examples of key influential events in this transition since the year 2000 include the release of human genome sequencing data including specific signal transduction domains, the development and issuance of the report Toxicity Testing in the Twenty-first Century by the National Research Council (NRC),which has influenced all sectors of the toxicology field, and the development and publication of the adverse outcome pathway (AOP) approach, which has highlighted the realities that exist as the science moves away from an overdependence on in vivo testing and makes greater use of computational, molecular, and focused in vitro tools. Additional drivers of change include the European Union (EU) report from the Scientific Committee on Health and Environmental Risks, the EU's Registration, Evaluation, Authorisation and Restriction of Chemical Substances (REACH) program, and the International Programme on Chemical Safety (IPCS). The paradigm shift can also be seen in the drug research and development sector, but rather than focusing on drugs during late stages of development or on marketed drugs, the systems-related efforts are positioned at the front end of research, both on safer chemical design and extensive target research. While the drug industry is required to conduct animal toxicology studies by regulatory agencies and international guidelines, the major effort underway is to determine chemical liabilities early in the drug discovery pipeline, both to reduce the time and cost of failures later in the process, but also to avoid costly failures once a drug reaches the market. Currently, there is an International Consortium for Innovation and Quality in Pharmaceutical Development (IQ), where several pharmaceutical and biotechnology companies have created a Nonclinical to Clinical Translational Database (WG1) to allow analysis of the reliability and potential limitations of nonclinical data in predicting clinical outcomes, including the evaluation of conventional biomarkers of toxicity. Current screening approaches applied to the front end of drug research are described below.

1.3 Chemical Toxicities

1.3.1 Single-Target Toxicity Concepts

The science and practice of toxicology over the past several decades have consistently used classic toxicological approaches, such as in vivo and in vitro toxicology studies, combined with predictive toxicological methodologies. The desired endpoints of the in vivo animal research efforts have been the determination of a toxic dose where a chemical could be shown to induce pathologic effects after a specified duration of treatment or exposure. Where appropriate, these studies have included the estimate of the lowest observed adverse effect level, the no observed adverse effect level, and the maximally tolerated dose (MTD). These adverse effect level estimates are traditionally used in drug research and development to predict the first dose in humans and to predict margins of safety estimates based on delivered dose and/or internal exposure from pharmacokinetic/pharmacodynamic (PK/PD) modeling with extrapolations into clinical trial subjects. By regulatory requirements, all potential drugs undergoing research and development will undergo both in vitro and in vivo studies, and, if the compound reaches the clinical trial stage successfully, data from human exposure to judge the adequacy of nonclinical data in predicting clinical outcomes. Uncertainties in these estimates include the definition of adverse, which is specific for each organ system in each study and typically determined by the study pathologist; the accuracy of cross- species extrapolations (particularly rodent-to-human); and the true definition of risk–benefit for each individual drug. However, the generation of classical toxicology data does not assure the accurate prediction of potential human toxicity. Sundqvist and colleagues have reported on a human dose prediction process, supplemented by case studies, to integrate uncertainties into simplified plots for quantification. Drug safety is recognized as one of the primary causes of attrition during the clinical phases of development; however, in numerous instances the actual determination of serious adverse effects only occurs after the drug reaches the market. In the United States, ~2 million patients are affected with drug-mediated adverse effects per year, of which ~5% are fatal. This places drug toxicity as one of the top five causes of death in the United States, and the costs to the health care system worldwide are estimated at US$40–50 billion per year. In drug development there are always risk–benefit considerations, which will weigh any potential toxicity against the benefit expected to be gained by a patient taking the drug. An example of the uncertainty of these estimates can be seen in the methods used for carcinogenicity testing and evaluation for drug approval. The design of these studies rely on high-dose exposure to animals and default linear extrapolation procedures, while little consideration is given to many of the new advances in the toxicological sciences. Carcinogenicity studies are typically 2-year studies in rodents conducted with three dosage groups (low, mid, and high dose) and one or two concurrent control groups. Dose levels are established from previous studies, such as 13-week toxicity studies, where a MTD has been estimated. Each group in the carcinogenicity study has 60–70 animals of each sex, and the analysis of whether there is a potential carcinogenicity concern is based on an analysis of each tumor in each tissue or organ system individually by gender; certain tumors are combined via standardized procedures for statistical analysis. The analysis uses the historical database from the laboratory where the studies are conducted to determine whether each tumor is considered common or rare, using the background incidence of 1% as the standard. Common tumors are those with a background incidence of 1% or over and rare tumors are those with a background incidence below 1%. In the statistical analysis, p-values for rare and common tumors are evaluated for pair-wise significance at 0.05 (for rare) and 0.01 (for common). The rare vs. common tumor classification is an arbitrary tumor threshold and adjustments to the specific classifications by individual tumor, which can occur from laboratory to laboratory and via analyses of different control groups, can have consequences in the overall tumor evaluation outcome. Applying a "weight of evidence" approach into the evaluation procedures, particularly during regulatory review, attempts to alleviate some of the uncertainties; however, after more than 50 years of on-going experience, these studies still fail to bring the 21st century mindset to carcinogenicity testing. The classic toxicological process for drug development assumes that a chemical interacts with a higher affinity to a single macromolecule (the toxicological target), and therefore a single biological pathway may be perturbed at the initial target modulation. This would be followed by downstream activation of secondary and possibly tertiary pathways that result in the tissue or organ effect as indicated by key biomarkers. In this concept, the magnitude of toxicological effects are related to the concentration of altered molecular targets (at the site of interest), which in turn is related to the concentration of the active form of the chemical (parent compound or metabolite) at the site where the molecular targets are located. Also included in this concept is the unique susceptibility of the organism exposed to the compound.

1.3.2 Toxicological Profiling for Potential Adverse Reactions

Predictive toxicology efforts in drug research and development involve the use of multiple sources of legacy data including data generated by chemical and pharmaceutical companies and data submitted to regulatory agencies. These efforts have led to the "data warehouse" model which includes data generated through high throughput and targeted screening, and in vitro and in vivo toxicology studies on thousands of compounds and structural analogues. In a majority of cases these data also include findings from clinical trials where an experimental drug was tested on humans.

The information is applied in a "backward" fashion to predict potential findings where data do not yet exist or where decisions are being made on new potential drug candidates. Bowes and colleagues have described a pharmacological profiling effort by four large pharmaceutical companies: AstraZeneca, GlaxoSmithKline, Novartis, and Pfizer. The companies suggest that ~75% of adverse drug reactions can be predicted by studying pharmacological profiles of candidate drugs. The pharmacological screening identifies primary effects related to the intended action of the candidate drug, whereas identification of secondary effects due to interactions with targets other than the primary (intended) target could be related to off-target adverse events. The groups have identified 44 screening targets including 24 G-protein coupled receptors, eight ion channels, six intracellular enzymes, three neurotransmitter transporters, two nuclear receptors, and one kinase. These types of screening data are used in the data warehouse model, typically configured in a proprietary fashion within each company. Other collaborative efforts have been developed and data from these sources would also be incorporated.

Blomme and Will have reviewed the current and past efforts by the pharmaceutical industry to optimize safety into molecules at the earliest stage of drug research. They conclude that new and emerging technologies in the past two decades have had limited impact on nonclinical attrition rates associated with safety issues. In addition, they point out that front-loading series of toxicology assays to "kill early, kill often" have been challenged due to high false-positive rates and an overall low positive predictive value. The primary issue cited is the lack of information on an efficacious exposures (PK/PD) and the fact that the assays are more likely to represent hazard identification and not risk assessment. Therefore, it is suggested that these data be used as alerts rather than discontinuance criteria. In a more systems toxicology approach, a large effort is now being directed towards understanding the extent of pharmacological modulation of both precedented and unprecedented targets in relation to potential safety liabilities and developing technologies to determine achievable therapeutic windows. Blomme and Willdiscuss efforts at AbbVie and Pfizer where target safety assessments are explored. The assessments include the biology of the target, tissue expression maps, messenger RNA and proteins, human genetic data, phenotypes from genetically engineered animal models, historical data from on-going and past clinical trials targeting similar targets and associated pathways, extensive datamining via biomedical databases, and in silico simulation of the various consequences of target modulation. The majority of systems research in drug safety use specific toxicities as the starting point. Ivanov and colleagues discuss the use of specific methods to counteract ventricular tachyarrhythmia (VT). While the in vitro HERG potassium channel assay is used universally as a predictor of VT, this is only one mechanism of action and other targets must also be identified and explored. These researchers have used the following approach: (1) creation of VT positive and negative compound libraries; (2) in silico prediction of extensive drug–target interaction profiles of chemical libraries identifying potential VT-related targets; (3) gene ontology and pathway enrichment on these potential VT targets to elucidate potential biological processes; (4) creation of a cardiomyocyte regulatory network based on general and heart-specific signaling and regulatory pathways; and (5) simulation of the changes in the regulatory network caused by the inhibition at each node in order to define potential VT-related targets. These are the type of studies that lead to more refined in vitro and in silico assessments of potential drug adverse effects at the early stage of drug research.

Verbist and colleagues have outlined another type of systems toxicology proposal at Janssen involving QSTAR (quantitative structure-transcription-assay relationships) by integrating high- throughput gene expression profiling data; chemical information, particularly detailed analogue analysis; and bioassay data. Using several compounds from a single chemical scaffold targeting PDE10A, a target of pharmacological interest at Janssen, changes in tubulin gene expression were identified in a subset of compounds. Therefore a screening process was developed involving multiple cell lines, gene expression profiling, in vitro micronucleus assays, and high- content imaging to show microtubule aggregates as compared to other phenotypes. Besides the chemical series of interest, known positive and negative compounds were included in the process. This study presents a valuable proof-of-concept of how to link and potentially improve the risk assessment in early drug discovery using several technologies in a drug research systems toxicology approach.