Epigenetically regulated digital signaling defines epithelial innate immunity at the tissue level

Clark, Helen R.; McKenney, Connor; Livingston, Nathan M.; Gershman, Ariel; Sajjan, Seema; Chan, Isaac S.; Ewald, Andrew J.; Timp, Winston; Wu, Bin; Singh, Abhyudai; Regot, Sergi

doi:10.1038/s41467-021-22070-x

Cited by 21 publications

(35 citation statements)

References 63 publications

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“…In addition to stochastic expression, epigenetic promoter regulation can create multigenerational cell states. For example, epigenetic regulation at one of the TLR promoters showed the predisposition of a subpopulation of human epithelial cells to respond to pathogen-associated molecular patterns (PAMPs) [92]. Lineage tracing coupled with modeling revealed that multiple gene modules, including those important for IFN-I signaling, were expressed only in small fractions of the total cell population, implying that the corresponding epigenetic signatures might predict which cells would become responders, and which ones would not [92].…”

Section: Trends In Immunologymentioning

confidence: 99%

“…For example, epigenetic regulation at one of the TLR promoters showed the predisposition of a subpopulation of human epithelial cells to respond to pathogen-associated molecular patterns (PAMPs) [92]. Lineage tracing coupled with modeling revealed that multiple gene modules, including those important for IFN-I signaling, were expressed only in small fractions of the total cell population, implying that the corresponding epigenetic signatures might predict which cells would become responders, and which ones would not [92]. Of note, the expression of these gene modules was transiently heritable, while studies in vitro showed that, in most cases, these modules were transcriptionally silenced after several generations, suggesting a complicated underlying mechanism of determining cell fate [92].…”

Section: Trends In Immunologymentioning

confidence: 99%

“…Lineage tracing coupled with modeling revealed that multiple gene modules, including those important for IFN-I signaling, were expressed only in small fractions of the total cell population, implying that the corresponding epigenetic signatures might predict which cells would become responders, and which ones would not [92]. Of note, the expression of these gene modules was transiently heritable, while studies in vitro showed that, in most cases, these modules were transcriptionally silenced after several generations, suggesting a complicated underlying mechanism of determining cell fate [92]. Along these lines, in mouse embryonic stem cells and human melanoma cells, for example, several new modeling approaches are using cell fates at the end of a cellular lineage tree to determine whether single-cell responses are purely random or a deterministic function of an underlying heritable state [57,[93][94][95].…”

Section: Trends In Immunologymentioning

confidence: 99%

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Decoding the dynamics of multilayered stochastic antiviral IFN-I responses

Eyndhoven

Singh

Tel

2021

Trends in Immunology

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responses were first recognized for their role in antiviral immunity, but it is now widely appreciated that IFN-Is have many immunomodulatory functions, influencing antitumor responses, autoimmune manifestations, and antimicrobial defenses. Given these pivotal roles, it may be surprising that multilayered stochastic events create highly heterogeneous, but tightly regulated, all-or-nothing cellular decisions. Recently, mathematical models have provided crucial insights into the stochastic nature of antiviral IFN-I responses, which we critically evaluate in this review. In this context, we emphasize the need for innovative single-cell technologies combined with mathematical models to further reveal, understand, and predict the complexity of the IFN-I system in physiological and pathological conditions that may be relevant to a plethora of diseases. From population averages to single-cell resolutionProviding a robust first line of host defense, type I interferon (IFN-I; see Glossary) responses were first recognized for their role in antiviral immunity by Isaacs and Lindemann [1]. In addition, IFN-Is are known to have numerous immunomodulatory functions that go beyond the scope of antiviral immunity, with potent roles in antitumor responses, autoimmune diseases, and microbial infections [2][3][4]. The expression and regulation of IFN-I has been extensively studied in mammals, and important molecular regulators have been characterized (Box 1;). Population-averaged measurements have generated not only a wealth of knowledge on IFN-I responses and regulation, but also contradictory results that remain hard to interpret or understand [7]. Over the past few years, an overwhelming wave of single-cell data has changed the dogma on how systemic immune responses are generated, challenging the traditional assumption that all cells of a given lineage display nearly identical behaviors upon stimulation. HighlightsThe rise of single-cell technologies has highlighted a massive degree of cellular heterogeneity during mammalian interferon (IFN)-I responses.

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Section: Trends In Immunologymentioning

confidence: 99%

Section: Trends In Immunologymentioning

confidence: 99%

Section: Trends In Immunologymentioning

confidence: 99%

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Decoding the dynamics of multilayered stochastic antiviral IFN-I responses

Eyndhoven

Singh

Tel

2021

Trends in Immunology

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“…Beyond this regulation of intrinsic transcriptional noise, ERVs are also known to exhibit high epigenetic variability, 152,153 which may contribute to a higher order patterns of variability, such as the bimodal responsiveness of single cells to interferon signaling or differences across individuals. Like the lower order intrinsic noise that smooths signal responses through temporal variability, variability in interferon responsiveness is also thought to be functional, allowing for a flexible and tunable immune response 154 . The balance of the immune response between restraint and proper activity is crucial to organismal health and difficult to achieve through a global all‐or‐nothing signal.…”

Section: Why Are Viruses Repeatedly Co‐opted For Immunity?mentioning

confidence: 99%

Emerging roles for endogenous retroviruses in immune epigenetic regulation*

Buttler

Chuong

2021

Immunological Reviews

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In recent years, there has been significant progress toward understanding the transcriptional networks underlying mammalian immune responses, fueled by advances in regulatory genomic technologies. Epigenomic studies profiling immune cells have generated detailed genome‐wide maps of regulatory elements that will be key to deciphering the regulatory networks underlying cellular immune responses and autoimmune disorders. Unbiased analyses of these genomic maps have uncovered endogenous retroviruses as an unexpected ally in the regulation of human immune systems. Despite their parasitic origins, studies are finding an increasing number of examples of retroviral sequences having been co‐opted for beneficial immune function and regulation by the host cell. Here, we review how endogenous retroviruses have given rise to numerous regulatory elements that shape the epigenetic landscape of host immune responses. We will discuss the implications of these elements on the function, dysfunction, and evolution of innate immunity.

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“…Recent developments in experimental technology, such as single-cell RNA-seq (scRNA-seq) have made it feasible to study the transcriptomic profiles of individual cells, yielding new insights about cellular heterogeneity at the single-cell level [15]. Heterogeneity in cell populations is known to play a role in many biological contexts, including drug response in cancer [16]- [18], latency in HIV cells [19], [20], immune response in epithelial tissue [21], determination of cell fate in genetically identical populations [22]- [31], and "bet-hedging" responses to environmental stresses in bacteria [32], [33]. For more information, an excellent review of the study of cellular heterogeneity can be found in the Altschuler and Wu (2010) paper "Cellular Heterogeneity: When Do Differences Make a Difference?"…”

Section: Introductionmentioning

confidence: 99%

Moment-Based Estimation of State-Switching Rates in Cell Populations

Saint-Antoine

Singh

2022

Preprint

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In isogenic cell populations, cells can switch back and forth between different gene expression states. These expression states can be biologically relevant. For example, a certain expression state may cause a tumor cell to be resistant to treatment, while another state may leave it vulnerable to treatment. However, estimating the rates of state-switching can be difficult, because experimentally measuring a cell's transcriptome often involves destroying the cell, so it can only be measured once. In this paper, we propose a computational method to estimate the rate of switching between expression states, given data from a Luria-Delbrück style fluctuation test that is experimentally simple and feasible. We then benchmark this method using simulated data to test its efficacy, with varying assumptions made about cell cycle timing distribution in the simulations.

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Epigenetically regulated digital signaling defines epithelial innate immunity at the tissue level

Cited by 21 publications

References 63 publications

Decoding the dynamics of multilayered stochastic antiviral IFN-I responses

Decoding the dynamics of multilayered stochastic antiviral IFN-I responses

Emerging roles for endogenous retroviruses in immune epigenetic regulation*

Moment-Based Estimation of State-Switching Rates in Cell Populations

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