Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-29T04:47:36.209Z Has data issue: false hasContentIssue false

Blurring Boundaries: A Proposed Research Agenda for Ethical, Legal, Social, and Historical Studies at the Intersection of Infectious and Genetic Disease

Published online by Cambridge University Press:  22 October 2024

Sheethal Jose
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Juli Bollinger
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Gail Geller
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Jeremy Greene
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Leslie Meltzer Henry
Affiliation:
UNIVERSITY OF MARYLAND, BALTIMORE, MARYLAND, USA
Brian Hutler
Affiliation:
TEMPLE UNIVERSITY, PHILADELPHIA, PENNSYLVANIA, USA
Eric Thomas Juengst
Affiliation:
UNIVERSITY OF NORTH CAROLINA, CHAPEL HILL, NORTH CAROLINA, USA
Jeffrey Kahn
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Anna C. Mastroianni
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Graham Mooney
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Alexandre White
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Rebecca Wilbanks
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Debra J. H. Mathews
Affiliation:
JOHNS HOPKINS UNIVERSITY, BALTIMORE, MARYLAND, USA
Rights & Permissions [Opens in a new window]

Abstract

Contemporary understanding of the mechanisms of disease increasingly points to examples of “genetic diseases” with an infectious component and of “infectious diseases” with a genetic component. Such blurred boundaries generate ethical, legal, and social issues and highlight historical contexts that must be examined when incorporating host genomic information into the prevention, outbreak control, and treatment of infectious diseases.

Type
Independent Articles
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of American Society of Law, Medicine & Ethics

Contemporary understanding of the mechanisms of disease point to a growing number of examples of “genetic diseases” with an infectious component and of “infectious diseases” with a genetic component. This overlap of what had formerly been understood as distinct categories of disease is noteworthy for both the change it signals in the understanding of disease mechanisms and the ethical, legal, and social implications (ELSI) it invokes. We refer to this phenomenon and its implications as “blurring boundaries.” Although such reinterpretation of boundaries ought to influence our understanding of disease causation and gene-environment interactions, it is not clear whether or how much this will be the case. The blurring boundaries between infectious disease and genetic disease has implications for the boundaries that mark the intersections of public health, clinical care, and scientific research. Considerable research is required to better describe and understand the ELSI landscape of these blurred boundaries, ideally before host genomic discoveries are translated into infectious disease practice and policy.

The COVID-19 pandemic and the associated global research projects exploring host genomic modifiers of response to the infection caused by SARS-CoV-2 have brought into sharp relief the need to identify, study, and respond to the ELSI issues and historical contexts — for individuals, groups or the larger society — of using genomic information in the management of infectious diseaseReference Geller1. The Johns Hopkins Center for Bridging Infectious Disease, Genomics, and Society (BRIDGES) — a Center for Excellence in ELSI Research — was established to examine the ethical, legal, social, historical, and policy issues confronting the incorporation of genomics in the prevention, outbreak control, and treatment of a range of infectious diseases. In this paper, references to infectious and genetic diseases are meant to include a range of infectious and genetic conditions, whether or not they rise to the level of a disease classification.

As part of the BRIDGES exploration of these issues, we formed a “Research Collaboratory” to craft research and policy agendas that clarify the implications of the blurring of boundaries and the merging of scientific categories that were previously distinct. One product of that work is a proposed research agenda for ethical, legal, social, and historical studies that identifies the most pressing —and intriguing — unanswered questions raised at and by the blurring boundaries. We hope that others will begin to pick up and address these issues in anticipation not only of further blurring boundaries, but also future pandemics and relevant genetics research.

As part of the BRIDGES exploration of these issues, we formed a “Research Collaboratory” to craft research and policy agendas that clarify the implications of the blurring of boundaries and the merging of scientific categories that were previously distinct. One product of that work is a proposed research agenda for ethical, legal, social, and historical studies that identifies the most pressing —and intriguing — unanswered questions raised at and by the blurring boundaries. We hope that others will begin to pick up and address these issues in anticipation not only of further blurring boundaries, but also future pandemics and relevant genetics research.

Background

BRIDGES began in 2014 with a focus on the ethical, legal, social, and policy significance of communicable disease transmission, and variation in the modes and patterns of transmission among diverse communities and populations, with an eye toward reducing disparities in infectious disease burden. This work included three pilot projects focused on these three discrete but related program areas: (1) Research, (2) Public Health Policy, and (3) Clinical Practice. The pilot projects studied the implications of implementing genomic medicine in the infectious disease context in each of these three areas, using a specific infectious disease as an example. The first project assessed the ELSI impact of research on genetic variation in the transmission of human immunodeficiency virus (HIV) and hepatitis C virus (HCV) in cohorts of at-risk urban populationsReference Boyce2. The second project analyzed the role and impact of advances in “vaccinomics” for informing population-based prevention of infectious diseases such as pandemic influenzaReference Gerber3. Vaccinomics is the application of genomics in improving the development of vaccines and studying host response to vaccinesReference Poland4. The third and final pilot project assessed the application of genomics in the clinical management of acute, high consequence infections such as Ebola and Methicillin-resistant Staphylococcus aureus (MRSA)4.

The BRIDGES Center consists of an interdisciplinary group of co-investigators, consultants, trainees, and members of an Internal Advisory Board. These groups include experts from the fields of history, law, philosophy, applied ethics, genetics, and medicine, in addition to ELSI experts. Sub-teams were formed around particular disciplines or topics, including historical analysis and legal issues; woven throughout all three of the pilot projects was cross-cutting history and legal scholarship. The BRIDGES history team investigated biocontainment in the historical context of infectious disease control and the genetic modification of nonhuman species for public health purposesReference Wilbanks5. The BRIDGES legal team examined whether genetic testing for variants associated with influenza infection should be mandatory for healthcare employees and whether there are legal obstacles to accessing and using genetic information from biobanked research samples for infectious disease researchReference Lewis6.

Taking advantage of the infrastructure and relationships created in these pilot projects, the BRIDGES team (comprised of the authors of this paper) focused the next phase of the project on crafting an ELSI research agenda outlining work that remains to be done. This phase coincided with the COVID-19 pandemic, which has seen unprecedented levels of international collaboration and coordination to identify host genomic factors involved in COVID-19. The global COVID-19 Host Genetics Initiative was launched early on in the pandemic with the aim of bringing “together the human genetics community to generate, share, and analyze data to learn the genetic determinants of COVID-19 susceptibility, severity, and outcomes”7. This pandemic, coupled with advances in genomic sequencing technology, has provided a global laboratory for identifying host genomic factors that might play a role in COVID-19 transmission, infection, and/or severity. The identification of such factors has implications for both clinical management and public health practice. In 2020, Geller et al. published on the ethical implications of using COVID-19 host genomics for clinical and public health practice as the current pandemic “provides an opportunity to move from theory to action in a very real context”8. The article highlighted some of the ethical questions that need to be considered before using host genomic information to inform decision-making in the clinical, public health, and health workforce settings. Similar kinds of information, such as non-genomic risk factors and vaccination statuses, are already being used to make decisions about resource allocation9, insurance coverage10, and travel restrictions11. Before host genomic information is added to this list, it is important to investigate a broad range of ELSI issues, from conceptual or framing issues to more concrete questions related to clinical practice, public health policy, and social policy, as described below.

Methods

The BRIDGES team planned and facilitated a collaborative, interdisciplinary research agenda-setting exercise over the course of two years. This exercise involved two key stages: (1) conceptual and (2) deliberative. The conceptual stage was primarily focused on conducting a series of literature reviews and generating case studies. The deliberative stage of the project focused on forming the Research Collaboratory, facilitating the Collaboratory meetings and the collective, iterative development of the research agenda.

Stage 1: Conceptual

During this first stage, the main aim was to characterize the relationship and boundaries between infectious and genetic diseases, examine the historical context of this distinction, and explore the implications of the changing and overlapping nature of these boundaries for ELSI discourse, scholarship, and translation. The BRIDGES team met on a monthly basis to define the scope of the project, identify key search terms, conduct literature reviews across the historical, philosophical, legal, ethical, and social terrains at this intersection, and generate a set of infectious disease and host genomics case studies to be used in the deliberative stage. The history and philosophy team explored the historical literature to identify examples of blurring boundaries between infectious and genetic diseases and how the nature of those blurring boundaries have changed over time. The bioethics and legal team reviewed the relevant ELSI literature. In addition, the legal team examined the legislative history of GINA, the potential use of genetic information by public health officials, and vaccine injury compensation. These reviews identified examples of blurred boundaries in science and medicine with an ELSI lens and specific cases for informing the deliberative process.

Informed by these discipline-specific literature reviews and analyses, we generated six brief candidate case studies that represent a range of interdisciplinary topics at this blurred boundary. These cases would serve to catalyze and frame the discussions in the deliberative stage. The six selected case studies were based on different infectious diseases with demonstrated or likely host genomic components. The cases include: (1) COVID-19 caused by SARS-CoV-2, (2) acquired immunodeficiency syndrome (AIDS) caused by HIV, (3) hepatitis C, (4) Ebola, (5) Zika, and (6) tuberculosis (TB). These cases were selected to capture a broad range of infectious disease characteristics, host genomic findings, histories, and ethical issues. The cases vary in terms of the mode of transmission, the clinical and public health implications of the host genomic variants, the legal issues raised, and a variety of other historical and contextual factors including stigma associated with the disease, treatment cost, availability of effective treatments, and resource allocation. Each case study included a one-page description with information on the science of the infectious disease and host genomics as well as a context section that highlighted the key cultural, historical, and/or legal contexts associated with the specific infectious disease. These case studies along with the other materials synthesized during this conceptual stage informed the deliberative stage of the research-agenda-setting exercise.

Stage 2: Deliberative

In this next stage, the main aim was to leverage the infrastructure and relationships created in Phase 1 of BRIDGES to bring together colleagues working at the intersection of infectious disease and genomics for a series of planning and working group meetings of a Research Collaboratory. The deliberative stage consisted of three parts: (1) forming the interdisciplinary Collaboratory, (2) facilitating the two Collaboratory Meetings with the goal of drafting the preliminary research agenda, and (3) refining the case studies and the research agenda.

Forming the Collaboratory

An invitation list of key experts across a diverse range of disciplines was formed. Based on prior research, our target disciplines were bioethics, ELSI, genomics, history, infectious disease, law, philosophy, and public health. This list of invited Collaboratory members consisted of experts both internal and external to Johns Hopkins University. The final Research Collaboratory included 15 outside experts and all 16 members of the BRIDGES team.

Collaboratory Meetings & Preliminary Research Agenda

Two Collaboratory Meetings were organized. Due to the COVID-19 pandemic, both 3-hour meetings were hosted virtually via zoom. Collaboratory Meeting 1, titled “Horizon Scanning of ELSI Issues Relevant to the Blurring Boundary Between Infectious and Genetic Diseases,” was held in 2020; while Collaboratory Meeting 2, titled “Development of an ELSI Research Agenda Relevant to the Blurring Boundary Between Infectious and Genetic Diseases,” was held in 2021.

Collaboratory Meeting 1

The main goal of the first meeting was to develop a broad list of ELSI issues relevant to the blurring boundaries and select two case studies (of the six short cases presented and discussed) as a focus for the second meeting. In advance of the first meeting, Collaboratory members were sent the six short cases and a list of discussion prompts to stimulate thinking about the various ethical, legal, social, historical, and policy considerations that may arise in the public health, clinical, and research contexts. These prompts were extracted from a prior BRIDGES publication which had identified various contexts both in COVID-19 and other infectious diseases in which host genomic data could be used12. Collaboratory members were given a brief background on current knowledge regarding the host genomics’ underlying response to infection in the cases referenced above. These short presentations were intended to introduce participants to the scientific concepts relevant for the discussions. Following this introduction, the large group discussed the SARS-CoV-2 case to identify a list of ELSI issues and historical antecedents specific to the potential use of host genomics in employment, public health, clinical care, and other contexts. The other five case studies were divided among three small breakout groups. Each group was tasked with identifying ELSI issues specific to each of their assigned cases. During these discussions, human papillomavirus (HPV) emerged as a possible case study, given its role in the development of non-communicable diseases (i.e., cancers). The HPV/Cancers case highlighted a unique case of the blurring boundary of infectious and genetic diseases. After a series of large group discussions, the Collaboratory selected SARS-CoV-2/COVID-19 and HPV/Cancers as the two final case studies for further development to aid with the generation of the research agenda at the second meeting.

These two cases were used to represent two ends of the spectrum of the blurring boundary between infectious and genetic diseases and come with very different cultural contexts. The SARS-CoV-2/COVID-19 case is an example of a primarily infectious or communicable disease that has host genomic features. The initial case was expanded to highlight structural racism in the US, as the pandemic continues to disproportionately impact historically marginalized populations, and the need to understand that the racial inequities in morbidity and mortality are due to underlying social inequalities rather than innate biological differences between the groups. The HPV/Cancers case was created as an example of a primarily non-communicable disease with an infectious agent as a primary cause. This case highlights the context of sexuality and the disproportionate focus of HPV awareness and vaccination among women and girls, with substantially less engagement with boys and men who can also carry and transmit HPV to sexual partners. These two expanded case studies were shared with Collaboratory members in advance of the second meeting.

Collaboratory Meeting 2

The main goal of the second meeting was to develop an ELSI research agenda based on the two selected case studies. The Collaboratory was split into two small, intentionally interdisciplinary breakout groups that met twice to generate a more comprehensive list of research topics and questions. Collaboratory members were encouraged to identify research questions across the various disciplines represented in the group and potential contexts for the use of host genomic information. The lists of research questions identified in each group were then compiled and de-duplicated to develop the preliminary version of the research agenda. Following this meeting, the preliminary research agenda was shared with the Collaboratory members for further input on each of the questions and to add any questions that may have been missed.

Refining the Case Studies and the Research Agenda

Building on the discussion at the Collaboratory meetings, BRIDGES held a series of internal team discussions to revise, expand, and further analyze the two selected case studies and the research agenda questions. Over the next six months, the team met bi-weekly to examine the gaps in the case studies and research agenda questions. Both the SARS-CoV-2/COVID-19 and HPV/Cancers cases were revised to include more of the global impact of the diseases as well as issues related to vaccinomics. The context sections of both cases were also expanded to include additional historical research. For example, these contexts include how racism and sexism have and continue to shape the response to SARS-CoV-2/COVID-19 and HPV/Cancers, respectively.

After finalizing the case studies (see Supplements 1 and 2 for the final case study documents), the team refined the preliminary research agenda based on the feedback from the Collaboratory members and spent multiple rounds workshopping the framing and organization of the research questions.

Results — Research Agenda

The Research Collaboratory identified 44 research questions that we have categorized under four broad themes, listed below. It’s important to note that the questions could have been categorized in many different ways, such as by specific topic areas (i.e., vaccine, employment, disparities, etc.), types of policies (i.e., social, public health, etc.), or discipline (i.e., history, science, legal, etc.), and in fact may fit rationally in multiple categories given the blurring boundaries. We ultimately landed on conceptual framing and knowledge interpretation and three sets of topical questions (clinical practice, public health policy, and social policy) due to the centrality to this whole project of the blurring boundaries concept, the subsequent conceptual shifts at that boundary identified through our work, and the desire to organize the remaining questions in a way that highlights the value and importance of interdisciplinary work amid such conceptual shifts. Academics, funding organizations, and others will need to address these questions as we move towards the implementation of host genomics in the infectious disease context. These stakeholders can also recategorize the questions in ways that are most useful and informative for them. Below, we highlight a subset of the 44 questions that generated considerable discussion among the Research Collaboratory members and serves to illustrate the intersections, overlaps, and synergies among all the questions. We provide additional information regarding the historical context and the motivation for those specific research agenda questions within each of the four categories. The order of the questions was decided based on narrative flow and not priority.

Theme 1: Conceptual Framing and Knowledge Interpretation

This first category of research agenda questions centers on how to best understand different claims about the blurring boundaries concept, disease causation, and their associated social meanings. The first research agenda question in this category (see Q1 in Table 1) asks: What kinds of social interests have influenced different stakeholders’ views of (blurring boundaries) disease causation in the past, including causes related not only to infectious agents and host genomics, but also social determinants of health (SDH)? This question involves exploring the large and rich historical literature on disease causation to identify why certain factors were highlighted as causative over other factors. Social interests and factors may have influenced different stakeholders in adopting a narrower view of disease causation and focusing on perceived scientific causes rather than a multidimensional view of disease causation. For example, early in the HIV/AIDS epidemic, hemophiliacs, injection drug users, Haitian immigrants, and the gay community were recognized as major risk groupsReference Friedman-Kien13. The members of these groups, known colloquially, and denigrated as, the 4-H club, were stigmatized as the primary agents of disease spread while their belonging to these groups rendered them at-risk of persecution and also unable to donate bloodReference Marc14. Moralistic and derogatory narratives about injection drug users, members of LGBTQ communities, and racial minorities led to highly discriminatory disease surveillance policies that served to advance certain social and political interests and further marginalize these groups. Such framing also contributed to a lack of knowledge of, and the motivation to address, the root causes of HIV as well at its manifestations in other at-risk groups, including women. The case of HPV-related cancers demonstrates related dynamics with regard to women’s sexuality and race. Nineteenth century theories about cervical cancer causation supported the idea that women were more physically vulnerable and defined by their sex organs, assumptions that justified their confinement to the domestic sphereReference Moscucci15. The low rate of cervical cancer observed in Jewish populations has also been used to support the idea that racial categories are biologicalReference Hausen16.

Table 1 Conceptual Framing and Knowledge Interpretation Research Agenda Questions

The racialization of disease evidenced in HIV and HPV histories is not unique to infectious disease. In the genomics context, race is often treated as a proxy for genetic ancestryReference Byeon17. Expert claims about the hereditary basis of race, intelligence, crime, and even unemployment pre-date and continue with the emergence of genetic scienceReference Duster18. For example, the eugenics movement heavily relied on the biologization of race and in turn, helped create and reinforce racial hierarchiesReference Lombardo19. These narratives have contributed to the false belief that race is biological.Reference Roberts20 In the case of host genomics, researchers may discover genetic variants that occur in high frequency in particular ancestry groups. Such discoveries pose a significant risk of being interpreted as demonstrating fixed biological differences between different race/ethnicity groups and reviving/reinforcing the biologization of race21. Thus, in part due to what we have learned about the history of notions of disease causation, these findings need to be communicated with care (see Q7 in Table 1): How should researchers talk about the real (if probabilistic) differences across populations with different ancestries without reifying social constructs, and while appropriately attending to social determinants of health, including the impact of racism, on infectious disease exposure and outcomes? When ancestry-associated host genomic risk factors are identified in infectious disease susceptibility or severity, it is critical to balance these factors with the non-genomic risk factors, such as SDH and racism, that play a role in preexisting health status, infectious disease exposure, and health care access.

One of the ways in which these multiple risk factors can be balanced is by taking into account the predictive value of genetic variants. Predictive value is the likelihood that a person will develop the phenotype if they have the mutation of interest; this is complicated in host genomics of infectious disease, because exposure to the infectious agent is required. And exposure is determined by a range of non-genetic factors, including many social determinants of health. Thus, even in the context of a high predictive value genetic variant, if an individual is able to avoid exposure, the genetic risk is immaterial. This raises the broader issue of what kinds of actions are taken given different levels of predictive value for genetic variants, highlighted by the research agenda question (see Q9 in Table 1): What factors (clinical, scientific, social) determine what counts as a “meaningful” level of predictive value for genetic variants across infectious and non-infectious disease contexts, where “meaningful” relates to clinical, public health, or personal utility and the opportunity costs inherent in the (public) investment required to find such genetic variants? There may not be one level of predictive value that could be applied to all genetic variants or infectious diseases. Since the boundary between the two categories of disease is blurring, other related factors, such as the mode of transmission, the infectiousness of the disease, and the health consequences of the disease need to be considered and they may determine the level of predictive value that makes a mutation’s predictive value meaningful. For example, there may be instances where genetic variants with low predictive value are found for a high consequence infectious disease and/or variants with high predictive value but for a low consequence infectious disease. These scenarios raise questions about when it is appropriate to use host genomics in the infectious disease context, what the consequences are of not having a single threshold for predictive value, what counts as a meaningful level of predictive value, and who should decide these thresholds?

Theme 2: Clinical Practice

This category includes research questions about the use of host genetic testing in clinical practice when a test becomes available that helps predict an individual’s response to an infectious disease or vaccine. There are several normative research questions about law and policy that are also raised in this category, such as whether medical providers should be permitted to or prohibited from reporting parental neglect in the case of not vaccinating a child who is at a greater genetic risk of infectious disease susceptibility (see Q15 in Table 2) or notifying affected individuals of relevant incidental genetic findings in the infectious disease context (see Q19 in Table 2). If genetic variants are found to play a role in increased severity of an infectious disease and are determined to have meaningful predictive values, then a host genetic test may be developed to identify individuals who are at greater risk of severe disease and/or adverse outcomes. For example, in the COVID-19 case (see Supplement 1), several genome-wide association studies have identified and replicated the finding of genetic variants in a gene cluster on chromosome 3 that are associated with COVID-19 hospitalization and/or severity22. These host genomic findings could inform the allocation of scarce resources, such as vaccines or treatments. If vaccines, medications, or treatments are scarce during an infectious disease outbreak, healthcare institutions could decide to allocate doses only to those individuals who are at a higher genetic risk of adverse response to vaccines or outcomes from the infectious disease, in an effort to conserve resources.Reference McMahon23 Such a public health policy would necessarily be implemented by physicians, whose duty is to the patient in front of them, creating a potential conflict. For example, physicians may need to withhold vaccine doses from patients who are not at genetic risk for severe disease and/or from those who may be genetically resistant to the infectious disease. These cases highlight the research agenda question (see Q14 in Table 2): How should the issues raised by the dual roles of physicians as both clinician and public health provider in the context of vaccine decision-making be addressed in policy and practice?

Table 2 Clinical Practice Research Agenda Questions

Another clinical practice question is related to cases where physicians may not have a choice but to inform their patients of incidental host genetic findings related to infectious disease. The area of incidental genetic findings has been fraught with debates on whether or not providers have legal or ethical duties to notify patients of such findingsReference Clayton24. The same question is raised in the infectious disease context (see Q19 in Table 2): Do laboratories, health care providers, and/or others have a heightened duty to notify individuals of incidental genetic findings that have implications for infectious disease transmission, severity, immunity, and/or treatment? Genetic findings in this context can also include pharmacogenomic (PGx) information which may be used in the clinical treatment and public health reporting of infectious disease. What are the implications of pleiotropy (when a particular genetic variant has implications to more than one trait/condition) at this intersection? (see Q16 in Table 2). In addition to questions about a provider’s duty to notify, this may also result in patients knowing about their risk and/or outcomes for both diseases without the choice of knowing about just one of the diseases. Thus, a patient’s right not to know could also be implicated in the cases where there is pleiotropyReference Flatau25.

Theme 3: Public Health Policy

This third category includes research questions about what public health programs should do in relation to the use of host genomic information in screening, surveillance, vaccination, and other public health interventions for infectious disease. If the infectious disease outbreak is also declared as a public health emergency at the state or national level, then there is an additional layer of policy implications for using host genomic information in that context. Similar to the clinical practice question of a physician’s duty to notify individuals of host genetic findings, the same findings may also need to be reported to public health authorities in the case of an infectious disease outbreak. States might wish to require mandatory reporting of host genetic findings, which, subject to legal analysis, could further blur the line between clinical care and public health. Infectious diseases have an impact both at the individual and population level and as such, any host genetic findings related to an infectious disease has implications for both the individual patient and public health. Consequently, when an individual’s genetic test result suggests that they have greater susceptibility to infectious disease or greater likelihood of severe disease, should infectious disease reporting laws require laboratories, health care providers, and/or others to report genetic test results to public health authorities? (see Q20 in Table 3).

Table 3 Public Health Policy Research Agenda Questions

While the above question deals with genetic tests that take place in a traditional clinical setting, there may be public health implications when individuals choose to learn about their own host genomic risk related to infectious disease through direct-to-consumer (DTC) or other similar types of personal genetic testing. Should individuals be permitted to use their personal genetic information from DTC or other types of genetic testing to exempt themselves from public health interventions? Would research into individual risk factors undermine collective approaches to reduce disease burden in the population through public health interventions (e.g., vaccination)? (see Q33 in Table 3). If an individual finds that they are at a much lower genetic risk of severe infectious disease, should they be permitted to use that result to exempt themselves from quarantine or social distancing measures? This question has broader implications for host genomic research as well. Traditional public health interventions rely on the cooperation and collective action of communities, which may be undermined if individual risk and preferences serve as exemptions from public health measures. On the other hand, can or should public health authorities use host genetic risk to target certain public health interventions? As the research agenda question asks, should law prevent or facilitate the use of host genetic information to regulate the movement of specific individuals? (see Q30 in Table 3). For example, genetic passports could be used to implement quarantine or isolation policies based on host genetic information rather than infectious disease exposure or a documented infectious disease diagnosisReference Gyngell and Savulescu26. The answer to this question may be informed by studying how (presumed) genetic and/or infectious disease risk information has been used to limit movement, such as immigration restrictions, in the past (see Q31 in Table 3). Historical analyses could provide important insight into how the use of host genomic information to target interventions among at-risk groups can be balanced with the ideas of collective action and solidarity emphasized in traditional public health measures.

Theme 4: Social Policy

Social policy issues such as discrimination, privacy, and the biologization of race also arise at the blurred boundaries between infectious and genetic diseases.

One of the most important social policy questions regards the harmful impact of using host genomic information on the concept of biologization of race (see Q36 in Table 4). While race is often constructed as hereditary, it is without biological significance and is rooted in racial scientific constructions of difference most often linked to phenotypical characteristics as well as stereotyping. If and when genetic variants in infectious diseases are found to be highly prevalent among individuals with a shared genetic ancestry, safeguards should be in place to resist the stratification of the population based on race and ethnicity.

Table 4 Social Policy Research Agenda Questions

Biomedical research in both genetic disease and infectious disease has a legacy of biologizing social categories of race and ethnicity. For example, racial disparities in epidemic disease have been blamed on perceived differences in the biologies or behaviors of racial and ethnic groups as illustrated by the earlier example of the certain identified groups during the HIV/AIDS epidemicReference Shah27. In the case of COVID-19, to date there has been an insistence that differences in disease outcome must be understood in structural terms, as social rather than biological phenomena. At the same time, there are calls for increasing participation of minoritized populations in both genomic and vaccine research, which are often justified in terms of biological differencesReference Popejoy and Fullerton28.

The genomics community is actively grappling with the use of race, ethnicity, and ancestry as population descriptors in genomics researchReference Lewis29, bringing us to the question(s): What social policies might help future research into genomics of susceptibility not collapse into yet another biologization of racial and ethnic differences, and at the same time avoid exclusionary “color-blindness” in the design of scientific research? And what role can bioethics and public health researchers play in advancing this discussion and preventing the conflation of racism, race, social determinants, ethnicity, and ancestry within the context of public health? (see Q36 in Table 4). It is important for the bioethics and public health research communities to learn about and become involved in these efforts so as to ensure that host genomic findings associated with genetic ancestry do not reinforce the biologization of race.

While understanding the links between disease risk and genetic ancestry may improve health outcomes, it is also important to recognize the threats posed by the implementation of public health policies using that knowledge30, for example, if inappropriate causative weight is attached to correlations between genetic variants and race/ethnicity by both the public and public health officials. This threat is highlighted in the following research question: if there is a genetic variant associated with infectious disease transmissibility (e.g., super-spreader) that positively correlates with a particular racial and/or ethnic group, should public health officials have the legal authority to restrict the movement of members of that group to stem the transmission of disease during a public health emergency? (see Q37 in Table 4). Such questions raise issues of genetic discrimination and whether members of the targeted group can contest the infringement on their liberty on any legal grounds (see Q37 in Table 4). If public health interventions are targeted at specific groups based on genetic ancestry, it is possible that those interventions could be construed as discriminatory, given that genetic ancestry is often used as a proxy for race/ethnicity31. Thus, it is critical for the concept of genetic ancestry to be disentangled from the socially constructed concepts of race and ethnicity before implementing policies that target individuals from a genetic ancestry group who have merely a probabilistically higher genetic risk for, say, infectious disease transmissibility.

Another social policy issue raised by blurring boundaries between disease categories are the tensions created among the areas of research, clinical practice, and public health practice as it becomes difficult for these areas of practice and policy to remain siloed. There are different justifications and policies for activities in the areas of research, clinical care, infection control, and public health operations, all of which could have activities related to genetics and infectious disease. How do we manage these conflicts which are ongoing and likely to increase moving forward? (see Q34 in Table 4). The silos around the different data sources in these areas are also crumbling, especially as it relates to the collection, storage, and use of genetic data, raising additional issues regarding privacy, data sovereignty, and other values, as genetic data flows across contexts.

Conclusion

Boundaries between infectious disease and genetic disease that many had perceived as clear and meaningful are becoming increasingly blurred. Host genomic factors are being sought to help explain infectious disease transmission, infection, and severity, and response to prophylaxis or treatment. The identification of such factors has implications for research, clinical management, public health practice, and policy.

During the COVID-19 pandemic, vaccination status and other risk factors have been used in decision-making regarding treatment access, death benefits, travel, and other aspects. It seems plausible that genetic risk information will be added to the calculus of such decisions in the future. Before this happens, it is critical to address the broad range of ELSI issues that would be raised by such a practice.

Broad expertise will be required to address these issues, including but not restricted to bioethics, genomics, history, infectious disease, law, philosophy, and public health. A similarly broad array of funding agencies should be interested in different aspects of this work.

Our intention is that working through the research agenda articulated here will help researchers, clinicians, policymakers and the public understand how the complexity of blurred boundaries came about, their implications, and how to manage the blurring in ways that do not recapitulate or exacerbate inequities at the intersection of genetic and infectious disease.

Notes

This work was supported by a Center for Excellence in ELSI Research (CEER) grant from the National Human Genome Research Institute (5RM1HG009038-03). All authors were involved in the planning and conduct of the Collaboratory Meetings, provided critical feedback, and helped shape the analysis and manuscript. S.J. and D.M. led the writing of the manuscript. All case studies used and analyzed are included in the supplementary material files. Further enquiries can be directed to the corresponding author, Debra Mathews, at .

References

Geller, G. et al., “Genomics and infectious disease: a call to identify the ethical, legal and social implications for public health and clinical practice,” Genome Medicine 6, no. 11 (2014): 106; G. Geller et al., “Genomics in the era of COVID-19: ethical implications for clinical practice and public health,” Genome Medicine 12, no. 1 (2020): 95; R. Milne, “Societal considerations in host genome testing for COVID-19,” Genetics in Medicine 22 no. 9, 1464–1466.CrossRefGoogle Scholar
Boyce, A. et al., “Personal Genetic Information about HIV: Research Participants’ Views of Ethical, Social, and Behavioral Implications,” Public Health Genomics 22 vols 1–2 (2019): 3645; A. Walker et al., “Direct-acting antivirals and hepatitis C: the ethics of price and rationing by genotype,” Clinical Infectious Diseases 67 no. 6: 983–984; A. Walker et al., “The Ethics of Precision Rationing: Human Genetics and the Need for Debate on Stratifying Access to Medication,” Public Health Genomics 23 no. 3–4 (2020): 149–154.CrossRefGoogle ScholarPubMed
Gerber, J. E. et al., “Ethical and policy implications of vaccinomics in the United States: community members’ perspectives,” Human Vaccines & Immunotherapeutics 17 no. 7 (2021); 21332144; S. M. Bartsch et al., “What If the Influenza Vaccine Did Not Offer Such Variable Protection?” The Journal of Infectious Diseases 222 no. 7 (2020): 1138–1144; A. Walker et al., “Genomics and Infectious Diseases: Expert Perspectives on Public Health Considerations regarding Actionability and Privacy,” Ethics & Human Research 42 no. 3: 30–40.CrossRefGoogle ScholarPubMed
Poland, G. A. et al., “Vaccinomics and a New Paradigm for the Development of Preventive Vaccines Against Viral Infections,” Omics: a Journal of Integrative Biology 15 no. 9 (2011): 625636; G. A. Poland et al., “Vaccinomics, adversomics, and the immune response network theory: Individualized vaccinology in the 21st century,” Seminars in immunology 25 no. 2 (2013): 89–103; A. M. Boyce and B. T. Garibaldi, “Genomics and High-Consequence Infectious Diseases: A Scoping Review of Emerging Science and Potential Ethical Issues,” Health Security 17 no. 1 (2019): 62–68; J. E. Gerber et al., “Genomics in Patient Care and Workforce Decisions in High-Level Isolation Units: A Survey of Healthcare Workers,” Health Security 19 no. 3 (2021): 318–326.CrossRefGoogle Scholar
Wilbanks, R., “Genetic Control in Historical Perspective: The Legacy of India’s Genetic Control of Mosquitoes Unit,” The Hastings Center Report 51 Suppl. 2 (2021): S11S18.CrossRefGoogle ScholarPubMed
Lewis, M. H., “Should Genetic Testing for Variants Associated with Influenza Infection Be Mandatory for Health Care Employees?AMA Journal of Ethics 20 no. 9 (2018): E819825.Google ScholarPubMed
. About COVID-19 host genetics initiative, COVID-19 Host Genetics Initiative, available at <https://www.covid19hg.org/about/> (last visited June 12, 2024); COVID-19 Host Genetics Initiative, “The COVID-19 Host Genetics Initiative, a global initiative to elucidate the role of host genetic factors in susceptibility and severity of the SARS-CoV-2 virus pandemic,” European Journal of Human Genetics 28 no. 6 (2020): 715718.CrossRef+(last+visited+June+12,+2024);+COVID-19+Host+Genetics+Initiative,+“The+COVID-19+Host+Genetics+Initiative,+a+global+initiative+to+elucidate+the+role+of+host+genetic+factors+in+susceptibility+and+severity+of+the+SARS-CoV-2+virus+pandemic,”+European+Journal+of+Human+Genetics+28+no.+6+(2020):+715–718.>Google Scholar
See Geller et al., “Genomics in the Era of COVID-19,” supra note 1.Google Scholar
National Institutes of Health, Prioritization of Anti-SARS-CoV-2 Therapies for the Treatment and Prevention of COVID-19 When There Are Logistical or Supply Constraints (December 20, 2023), NIH COVID-19 Treatment Guidelines, available at <https://www.covid19treatmentguidelines.nih.gov/overview/prioritization-of-therapeutics/> (last visited June 14, 2024). The website is scheduled to be shut down after August 16, 2024.+(last+visited+June+14,+2024).+The+website+is+scheduled+to+be+shut+down+after+August+16,+2024.>Google Scholar
A. Hsu, Companies are telling unvaccinated workers to pay more for health insurance (November 22, 2021), NPR, available at <https://www.npr.org/2021/11/22/1056238770/covid-delta-unvaccinated-higher-health-insurance-premiums> (last visited June 12, 2024); M. Andrews, Families could be denied death benefits if their unvaccinated loved one dies (November 3, 2021), CNN Website, available at <https://www.cnn.com/2021/11/03/health/unvaccinated-death-benefits-khn-partner/index.html> (last visited June 12, 2024).+(last+visited+June+12,+2024);+M.+Andrews,+Families+could+be+denied+death+benefits+if+their+unvaccinated+loved+one+dies+(November+3,+2021),+CNN+Website,+available+at++(last+visited+June+12,+2024).>Google Scholar
National Center for Immunization and Respiratory Diseases Division of Viral Diseases, Requirement for proof of COVID-19 vaccination for air passengers: required for non-U.S. citizen, nonimmigrant passengers arriving from a foreign country to the United States by air (December 2022), Centers for Disease Control and Prevention, available at <https://stacks.cdc.gov/view/cdc/116833> (last visited June 12, 2024).+(last+visited+June+12,+2024).>Google Scholar
See Geller et al., “Genomics in the Era of COVID-19,” supra note 1.Google Scholar
Friedman-Kien, A. E., “Disseminated Kaposi’s sarcoma syndrome in young homosexual men,” Journal of the American Academy of Dermatology 5 no. 4 (1981): 468–71; M. D. Grmek, History of AIDS: Emergence and origin of a modern pandemic, (New Jersey: Princeton University Press, 1990): 1–290; L. K. Altman, New homosexual disorder worries health officials (May 11, 1982), New York Times: C1–6, available at <https://www.nytimes.com/1982/05/11/science/new-homosexual-disorder-worries-health-officials.html> (last visited June 12, 2024); A. E. Pitchenik et al., “Opportunistic infections and Kaposi’s sarcoma among Haitians: evidence of a new acquired immunodeficiency state,” Annals of Internal Medicine 98 no. 3 (1983): 277–84; P. J. Hilts, FDA Set to reverse blood ban (April 24, 1990), New York Times: C11, available at <https://www.nytimes.com/1990/04/24/science/fda-set-to-reverse-blood-ban.html> (last visited June 12, 2024).Google Scholar
Marc, L. G. et al., “HIV among Haitian-born persons in the United States, 1985–2007,” AIDS 24 no. 13 (2010): 2089–97; S. Loue and E. Lamb, “Retraumatized: COVID-19, the specter of HIV/AIDS, and reorienting responsibility,” Logos Universality Mentality Education Novelty: Philosophy & Humanistic Sciences 8, no. 1 (2020): 1–7.CrossRefGoogle ScholarPubMed
Moscucci, O., “Gender and Cancer in Britain, 1860–1910: the emergence of cancer as a public health concern,” American Journal of Public Health 95 no. 8 (2005): 1312–21.CrossRefGoogle ScholarPubMed
Hausen, H. Zur, “Papillomaviruses in the causation of human cancers — a brief historical account,” Virology 384 no. 2 (2009): 260–5; D. Rigoni-Stern, “Fatti statistici relative alle mallatie cancrosi che servirono de base alla poche cose dette dal dott,” Giornale service propr.pathol.terap.ser 2, (1842): 507–517; J.-P. Gaudillière and I. Löwy, “The Hereditary Transmission of Human Pathologies between 1900 and 1940: The Good Reasons Not to Become ‘Mendelian’,” in Müller-Wille and Brandt, eds., Heredity Explored (Cambridge, MA: MIT Press, 2016): at 311–335; J. Menczer, “The low incidence of cervical cancer in Jewish women: has the puzzle finally been solved?” The Israel Medical Association Journal 5 no. 2 (2003): 120–3.CrossRefGoogle ScholarPubMed
Byeon, Y. J. J. et al., “Evolving use of ancestry, ethnicity, and race in genetics research — A survey spanning seven decades,” American Journal of Human Genetics 108 no. 12 (2021): 22152223.CrossRefGoogle ScholarPubMed
Duster, T., Backdoor to Eugenics (United Kingdom: Routledge, 2003): 1260.Google Scholar
Lombardo, P. A., “Miscegenation, eugenics, and racism: Historical footnotes to Loving v. Virginia,” UC Davis Law Review 21 no. 2 (1988): 421; M. Sirleaf, “Racial Valuation of Diseases,” UCLA Law Review 67 (2021): 1820–1857.Google Scholar
Roberts, D., Fatal Invention: How Science, Politics, and Big Business Re-create Race in the Twenty-first Century (New York: New Press, 2011): 1400.Google Scholar
See Sirleaf, supra note 19.Google Scholar
Severe Covid-19 GWAS Group et al., “Genomewide Association Study of Severe Covid-19 with Respiratory Failure,” The New England Journal of Medicine vol. 383 no. 16 (2020): 15221534; E. Pairo-Castineira et al., “Genetic mechanisms of critical illness in Covid-19,” Nature 591 no. 7848 (2021): 92–98; J. F. Shelton et al., “Trans-ancestry analysis reveals genetic and nongenetic associations with COVID-19 susceptibility and severity,” Nature Genetics 53, no. 6 (2021): 801–808.CrossRefGoogle Scholar
A. Joseph, Doctors have an arsenal of Covid-19 treatments, but setbacks and shortages are undercutting options (January 7, 2022), STAT, available at <https://www.statnews.com/2022/01/07/on-paper-we-have-amazing-ways-to-treat-covid-19-but-setbacks-and-shortages-are-undercutting-those-options/> (last visited June 12, 2024); McMahon, D. E. et al., “Global resource shortages during COVID-19: Bad news for low-income countries,” PLOS Neglected Tropical Diseases 14 no. 7 (2020): e0008412; S. Jose et al., “The Ethics of Using COVID-19 Host Genomic Information for Clinical and Public Health Decision-Making: A Survey of US Health Professionals,” Human Genetics and Genomics Advances 5.1 (2024).CrossRefGoogle ScholarPubMed
Clayton, E. W. et al., “Managing incidental genomic findings: legal obligations of clinicians,” Genetics in Medicine 15 no. 8 (2013): 624629.CrossRefGoogle ScholarPubMed
Flatau, L. et al., “Genomic information and a person’s right not to know: A closer look at variations in hypothetical informational preferences in a German sample,” PloS One 13 no. 6 (2018): e0198249.CrossRefGoogle Scholar
Gyngell, C. and Savulescu, J., “Ethics of genomic passports: should the genetically resistant be exempted from lockdowns and quarantines?Journal of Medical Ethics 48 no. 10 (2021): 689694.CrossRefGoogle ScholarPubMed
See L. G. Marc et al., supra note 14; Shah, N., Contagious Divides: Epidemics and Race in San Francisco’s Chinatown, vol. 7 (Berkeley, California: University of California Press, 2001): 1400; M. Sirleaf, COVID-19 Symposium: COVID-19 and the Racialization of Diseases (Part I) (July 4, 2020), OpinioJuris, available at <http://opiniojuris.org/2020/04/07/covid-19-symposium-covid-19-and-the-racialization-of-diseases-part-i/> (last visited June 12, 2024).; M. Sirleaf, COVID-19 Symposium: COVID-19 and the Racialization of Diseases (Part II) (April 7 2020), OpinioJuris Website, available at <http://opiniojuris.org/2020/04/07/covid-19-symposium-covid-19-and-the-racialization-of-diseases-part-ii/> (last visited June 12, 2024).Google Scholar
Popejoy, A. B. and Fullerton, S. M., “Genomics is failing on diversity,” Nature 538 no. 7624 (2016): 161164; M. A. McQuillan et al., “The importance of including ethnically diverse populations in studies of quantitative trait evolution,” Current Opinion in Genetics & Development 62 (2020): 30–35.CrossRefGoogle ScholarPubMed
R. P. Ortega, Human geneticists curb use of the term ‘race’ in their papers (December 2, 2021), Science, available at <https://www.science.org/content/article/human-geneticists-curb-use-term-race-their-papers> (last visited June 12, 2024); Lewis, A. C. F. et al., “Getting genetic ancestry right for science and society,” Science 376 vol 6590 (2022): 250252; National Academies of Sciences Engineering and Medicine, Using Population Descriptors in Genetics and Genomics Research: A New Framework for an Evolving Field (Washington, DC: The National Academies Press, 2023): 1–240; D. Fullwiley, “Race, genes, power,” The British Journal of Sociology 66 no. 1 (2015): 36–45.CrossRefGoogle ScholarPubMed
Id Fullwiley.Google Scholar
See Y. J. J. Byeon, supra note 17.Google Scholar
Figure 0

Table 1 Conceptual Framing and Knowledge Interpretation Research Agenda Questions

Figure 1

Table 2 Clinical Practice Research Agenda Questions

Figure 2

Table 3 Public Health Policy Research Agenda Questions

Figure 3

Table 4 Social Policy Research Agenda Questions

Supplementary material: PDF

Jose et al supplementary material

Jose et al supplementary material

Download Jose et al supplementary material(PDF)
PDF 378.7 KB