The zebrafish xenograft platform-a novel tool for modeling KSHV-associated diseases

Eric S. Pringle; Jaime Wertman; Nicole Melong; Andrew J. Coombs; Andrew L. Young; David O'Leary; Chansey Veinotte; Carolyn Ann Robinson; Michael N. Ha; Graham Dellaire; Todd E. Druley; Craig McCormick; Jason N. Berman

doi:10.3390/v12010012

The zebrafish xenograft platform-a novel tool for modeling KSHV-associated diseases

Eric S. Pringle, Jaime Wertman, Nicole Melong, Andrew J. Coombs, Andrew L. Young, David O'Leary, Chansey Veinotte, Carolyn Ann Robinson, Michael N. Ha, Graham Dellaire, Todd E. Druley, Craig McCormick, Jason N. Berman

Medicine

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

12 Citas (Scopus)

Resumen

Kaposi's sarcoma associated-herpesvirus (KSHV, also known as human herpesvirus-8) is a gammaherpesvirus that establishes life-long infection in human B lymphocytes. KSHV infection is typically asymptomatic, but immunosuppression can predispose KSHV-infected individuals to primary effusion lymphoma (PEL); a malignancy driven by aberrant proliferation of latently infected B lymphocytes, and supported by pro-inflammatory cytokines and angiogenic factors produced by cells that succumb to lytic viral replication. Here, we report the development of the first in vivo model for a virally induced lymphoma in zebrafish, whereby KSHV-infected PEL tumor cells engraft and proliferate in the yolk sac of zebrafish larvae. Using a PEL cell line engineered to produce the viral lytic switch protein RTA in the presence of doxycycline, we demonstrate drug-inducible reactivation from KSHV latency in vivo, which enabled real-time observation and evaluation of latent and lytic phases of KSHV infection. In addition, we developed a sensitive droplet digital PCR method to monitor latent and lytic viral gene expression and host cell gene expression in xenografts. The zebrafish yolk sac is not well vascularized, and by using fluorogenic assays, we confirmed that this site provides a hypoxic environment that may mimic the microenvironment of some human tumors. We found that PEL cell proliferation in xenografts was dependent on the host hypoxia-dependent translation initiation factor, eukaryotic initiation factor 4E2 (eIF4E2). This demonstrates that the zebrafish yolk sac is a functionally hypoxic environment, and xenografted cells must switch to dedicated hypoxic gene expression machinery to survive and proliferate. The establishment of the PEL xenograft model enables future studies that exploit the innate advantages of the zebrafish as a model for genetic and pharmacologic screens.

Idioma original	English
Número de artículo	12
Publicación	Viruses
Volumen	12
N.º	1
DOI	https://doi.org/10.3390/v12010012
Estado	Published - dic. 20 2019

Nota bibliográfica

Funding Information:
E.S.P. was supported by a trainee award from the Beatrice Hunter Cancer Research Institute, with funds provided by the Canadian Imperial Bank of Commerce as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR. J.W. was supported by an IWK Health Center Graduate Scholarship. This work was supported by the Nova Scotia Health Research Foundation Development/Innovative Grant MED-Capacity-2012-8464, the Canadian Breast Cancer Foundation (CBCF)-Atlantic Chapter-Research Grant 14787, and the Canadian Institutes for Health Research Operating Grant MOP-84554. We thank Gretchen Wagner, David Malloy, and the Dalhousie Zebrafish CORE facility for animal husbandry and members of the Berman and McCormick laboratories for helpful discussions. We thank Sandy Edgar (Dalhousie) for helpful discussions about droplet digital PCR. Reagents were generously provided by Don Ganem (UCSF; Chan-Zuckerberg Biohub), David Lukac (Rutgers), Jae Jung (USC), and Didier Trono (EPFL).

Funding Information:
Funding: E.S.P. was supported by a trainee award from the Beatrice Hunter Cancer Research Institute, with funds provided by the Canadian Imperial Bank of Commerce as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR. J.W. was supported by an IWK Health Center Graduate Scholarship. This work was supported by the Nova Scotia Health Research Foundation Development/Innovative Grant MED-Capacity-2012-8464, the Canadian Breast Cancer Foundation (CBCF)—Atlantic Chapter—Research Grant 14787, and the Canadian Institutes for Health Research Operating Grant MOP-84554.

Publisher Copyright:
© 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

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Infectious Diseases
Virology

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title = "The zebrafish xenograft platform-a novel tool for modeling KSHV-associated diseases",

abstract = "Kaposi's sarcoma associated-herpesvirus (KSHV, also known as human herpesvirus-8) is a gammaherpesvirus that establishes life-long infection in human B lymphocytes. KSHV infection is typically asymptomatic, but immunosuppression can predispose KSHV-infected individuals to primary effusion lymphoma (PEL); a malignancy driven by aberrant proliferation of latently infected B lymphocytes, and supported by pro-inflammatory cytokines and angiogenic factors produced by cells that succumb to lytic viral replication. Here, we report the development of the first in vivo model for a virally induced lymphoma in zebrafish, whereby KSHV-infected PEL tumor cells engraft and proliferate in the yolk sac of zebrafish larvae. Using a PEL cell line engineered to produce the viral lytic switch protein RTA in the presence of doxycycline, we demonstrate drug-inducible reactivation from KSHV latency in vivo, which enabled real-time observation and evaluation of latent and lytic phases of KSHV infection. In addition, we developed a sensitive droplet digital PCR method to monitor latent and lytic viral gene expression and host cell gene expression in xenografts. The zebrafish yolk sac is not well vascularized, and by using fluorogenic assays, we confirmed that this site provides a hypoxic environment that may mimic the microenvironment of some human tumors. We found that PEL cell proliferation in xenografts was dependent on the host hypoxia-dependent translation initiation factor, eukaryotic initiation factor 4E2 (eIF4E2). This demonstrates that the zebrafish yolk sac is a functionally hypoxic environment, and xenografted cells must switch to dedicated hypoxic gene expression machinery to survive and proliferate. The establishment of the PEL xenograft model enables future studies that exploit the innate advantages of the zebrafish as a model for genetic and pharmacologic screens.",

author = "Pringle, {Eric S.} and Jaime Wertman and Nicole Melong and Coombs, {Andrew J.} and Young, {Andrew L.} and David O'Leary and Chansey Veinotte and Robinson, {Carolyn Ann} and Ha, {Michael N.} and Graham Dellaire and Druley, {Todd E.} and Craig McCormick and Berman, {Jason N.}",

note = "Funding Information: E.S.P. was supported by a trainee award from the Beatrice Hunter Cancer Research Institute, with funds provided by the Canadian Imperial Bank of Commerce as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR. J.W. was supported by an IWK Health Center Graduate Scholarship. This work was supported by the Nova Scotia Health Research Foundation Development/Innovative Grant MED-Capacity-2012-8464, the Canadian Breast Cancer Foundation (CBCF)-Atlantic Chapter-Research Grant 14787, and the Canadian Institutes for Health Research Operating Grant MOP-84554. We thank Gretchen Wagner, David Malloy, and the Dalhousie Zebrafish CORE facility for animal husbandry and members of the Berman and McCormick laboratories for helpful discussions. We thank Sandy Edgar (Dalhousie) for helpful discussions about droplet digital PCR. Reagents were generously provided by Don Ganem (UCSF; Chan-Zuckerberg Biohub), David Lukac (Rutgers), Jae Jung (USC), and Didier Trono (EPFL). Funding Information: Funding: E.S.P. was supported by a trainee award from the Beatrice Hunter Cancer Research Institute, with funds provided by the Canadian Imperial Bank of Commerce as part of The Terry Fox Strategic Health Research Training Program in Cancer Research at CIHR. J.W. was supported by an IWK Health Center Graduate Scholarship. This work was supported by the Nova Scotia Health Research Foundation Development/Innovative Grant MED-Capacity-2012-8464, the Canadian Breast Cancer Foundation (CBCF)—Atlantic Chapter—Research Grant 14787, and the Canadian Institutes for Health Research Operating Grant MOP-84554. Publisher Copyright: {\textcopyright} 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).",

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AU - Wertman, Jaime

AU - Melong, Nicole

AU - Coombs, Andrew J.

AU - Young, Andrew L.

AU - O'Leary, David

AU - Veinotte, Chansey

AU - Robinson, Carolyn Ann

AU - Ha, Michael N.

AU - Dellaire, Graham

AU - Druley, Todd E.

AU - McCormick, Craig

AU - Berman, Jason N.

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N2 - Kaposi's sarcoma associated-herpesvirus (KSHV, also known as human herpesvirus-8) is a gammaherpesvirus that establishes life-long infection in human B lymphocytes. KSHV infection is typically asymptomatic, but immunosuppression can predispose KSHV-infected individuals to primary effusion lymphoma (PEL); a malignancy driven by aberrant proliferation of latently infected B lymphocytes, and supported by pro-inflammatory cytokines and angiogenic factors produced by cells that succumb to lytic viral replication. Here, we report the development of the first in vivo model for a virally induced lymphoma in zebrafish, whereby KSHV-infected PEL tumor cells engraft and proliferate in the yolk sac of zebrafish larvae. Using a PEL cell line engineered to produce the viral lytic switch protein RTA in the presence of doxycycline, we demonstrate drug-inducible reactivation from KSHV latency in vivo, which enabled real-time observation and evaluation of latent and lytic phases of KSHV infection. In addition, we developed a sensitive droplet digital PCR method to monitor latent and lytic viral gene expression and host cell gene expression in xenografts. The zebrafish yolk sac is not well vascularized, and by using fluorogenic assays, we confirmed that this site provides a hypoxic environment that may mimic the microenvironment of some human tumors. We found that PEL cell proliferation in xenografts was dependent on the host hypoxia-dependent translation initiation factor, eukaryotic initiation factor 4E2 (eIF4E2). This demonstrates that the zebrafish yolk sac is a functionally hypoxic environment, and xenografted cells must switch to dedicated hypoxic gene expression machinery to survive and proliferate. The establishment of the PEL xenograft model enables future studies that exploit the innate advantages of the zebrafish as a model for genetic and pharmacologic screens.

AB - Kaposi's sarcoma associated-herpesvirus (KSHV, also known as human herpesvirus-8) is a gammaherpesvirus that establishes life-long infection in human B lymphocytes. KSHV infection is typically asymptomatic, but immunosuppression can predispose KSHV-infected individuals to primary effusion lymphoma (PEL); a malignancy driven by aberrant proliferation of latently infected B lymphocytes, and supported by pro-inflammatory cytokines and angiogenic factors produced by cells that succumb to lytic viral replication. Here, we report the development of the first in vivo model for a virally induced lymphoma in zebrafish, whereby KSHV-infected PEL tumor cells engraft and proliferate in the yolk sac of zebrafish larvae. Using a PEL cell line engineered to produce the viral lytic switch protein RTA in the presence of doxycycline, we demonstrate drug-inducible reactivation from KSHV latency in vivo, which enabled real-time observation and evaluation of latent and lytic phases of KSHV infection. In addition, we developed a sensitive droplet digital PCR method to monitor latent and lytic viral gene expression and host cell gene expression in xenografts. The zebrafish yolk sac is not well vascularized, and by using fluorogenic assays, we confirmed that this site provides a hypoxic environment that may mimic the microenvironment of some human tumors. We found that PEL cell proliferation in xenografts was dependent on the host hypoxia-dependent translation initiation factor, eukaryotic initiation factor 4E2 (eIF4E2). This demonstrates that the zebrafish yolk sac is a functionally hypoxic environment, and xenografted cells must switch to dedicated hypoxic gene expression machinery to survive and proliferate. The establishment of the PEL xenograft model enables future studies that exploit the innate advantages of the zebrafish as a model for genetic and pharmacologic screens.

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The zebrafish xenograft platform-a novel tool for modeling KSHV-associated diseases

Resumen

Nota bibliográfica

ASJC Scopus Subject Areas

ODS de las Naciones Unidas

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