In vitro and in vivo characterization of a recombinant rhesus cytomegalovirus containing a complete genome

Taher, Husam; Mahyari, Eisa; Kreklywich, Craig N.; Uebelhoer, Luke S.; McArdle, Matthew R.; Moström, Matilda J.; Bhusari, Amruta; Nekorchuk, Michael; Xiaofei, E; Whitmer, Travis; Scheef, Elizabeth A.; Sprehe, Lesli M.; Roberts, Dawn; Hughes, Colette M.; Jackson, Kerianne A.; Selseth, Andrea N.; Ventura, Abigail B.; Cleveland-Rubeor, Hillary C.; Yue, Yujuan; Schmidt, Kimberli A.; Shao, Jason; Edlefsen, Paul T.; Smedley, Jeremy; Kowalik, Timothy F.; Stanton, Richard J.; Axthelm, Michael K.; Estes, Jacob D.; Hansen, Scott G.; Kaur, Amitinder; Barry, Peter A.; Bimber, Benjamin N.; Picker, Louis J.; Streblow, Daniel N.; Früh, Klaus; Malouli, Daniel

doi:10.1371/journal.ppat.1008666

Cited by 24 publications

(56 citation statements)

References 109 publications

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“…SIV insert (SIVgag, retanef, 5'pol)-expressing vaccine vectors based on RhCMV 68-1 (GenBank #MT157325) have been described previously (6,33). All other RhCMV constructs used in this study were based on either the partially-repaired RhCMV 68-1.2 strain (GenBank #MT157326) or our fully reconstructed FL RhCMV clone (GenBank #MT157327) (13,18). Following the original 68-1 vector design, SIV inserts were introduced into the Rh211 open reading frame (ORF) in RhCMV 68-1.2 and transgene expression was driven by an EFIα promoter.…”

Section: Generation Of Recombinant Rhcmv Vectorsmentioning

confidence: 99%

Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

et al. 2021

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Simian immunodeficiency virus (SIV) insert–expressing, 68-1 rhesus cytomegalovirus (RhCMV/SIV) vectors elicit major histocompatibility complex E (MHC-E)– and MHC-II–restricted, SIV-specific CD8+ T cell responses, but the basis of these unconventional responses and their contribution to demonstrated vaccine efficacy against SIV challenge in the rhesus monkeys (RMs) have not been characterized. We show that these unconventional responses resulted from a chance genetic rearrangement in 68-1 RhCMV that abrogated the function of eight distinct immunomodulatory gene products encoded in two RhCMV genomic regions (Rh157.5/Rh157.4 and Rh158-161), revealing three patterns of unconventional response inhibition. Differential repair of these genes with either RhCMV-derived or orthologous human CMV (HCMV)–derived sequences (UL128/UL130; UL146/UL147) leads to either of two distinct CD8+ T cell response types—MHC-Ia–restricted only or a mix of MHC-II– and MHC-Ia–restricted CD8+ T cells. Response magnitude and functional differentiation are similar to RhCMV 68-1, but neither alternative response type mediated protection against SIV challenge. These findings implicate MHC-E–restricted CD8+ T cell responses as mediators of anti-SIV efficacy and indicate that translation of RhCMV/SIV vector efficacy to humans will likely require deletion of all genes that inhibit these responses from the HCMV/HIV vector.

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Section: Generation Of Recombinant Rhcmv Vectorsmentioning

confidence: 99%

Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

et al. 2021

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“…We next asked the question of whether abrogating both the PRC and non-PRC-related immune programming activities of Rh157.5 and Rh157.4 was sufficient to convert a wildtype-like RhCMV, with conventional MHC-Ia-restricted CD8 + T cell targeting, to a 68-1-like vector with exclusively MHC-IIand MHC-E-restricted CD8 + T cell responses. Using sequence information from primary RhCMV isolates, including the original 68-1 isolate (17), we reconstructed a full length RhCMV clone (RhCMV FL) in which all suspected deletions, inversions, frameshifts and premature termination codons affecting viral open reading frames were repaired and the Rh13.1 open reading frame (ORF) was replaced by an SIVgag insert (18). RhCMV FL has robust in vivo spread (18), and as expected for a wildtype genetic configuration (9), elicits MHC-Ia-restricted, CD8 + T cell responses (Fig.…”

mentioning

confidence: 99%

“…Using sequence information from primary RhCMV isolates, including the original 68-1 isolate (17), we reconstructed a full length RhCMV clone (RhCMV FL) in which all suspected deletions, inversions, frameshifts and premature termination codons affecting viral open reading frames were repaired and the Rh13.1 open reading frame (ORF) was replaced by an SIVgag insert (18). RhCMV FL has robust in vivo spread (18), and as expected for a wildtype genetic configuration (9), elicits MHC-Ia-restricted, CD8 + T cell responses (Fig. 2A).…”

mentioning

confidence: 99%

Cytomegaloviral determinants of CD8⁺T cell programming and RhCMV/SIV vaccine efficacy

Malouli

Hansen

Hancock

et al. 2020

Preprint

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Simian immunodeficiency virus (SIV) insert-expressing, 68-1 Rhesus Cytomegalovirus (RhCMV/SIV) vectors elicit major histocompatibility complex (MHC)-E- and -II-restricted, SIV-specific CD8+ T cell responses, but the basis of these unconventional responses and their contribution to demonstrated vaccine efficacy against SIV challenge in the rhesus monkeys (RMs) has not been characterized. We demonstrate that these unconventional responses resulted from a chance genetic rearrangement in 68-1 RhCMV that abrogated the function of eight distinct immunomodulatory gene products encoded in two RhCMV genomic regions (Rh157.5/.4 and Rh158-161). Differential repair of these genes with either RhCMV-derived or orthologous human CMV (HCMV)-derived sequences (UL128/130; UL146/147) leads to either of two distinct CD8+ T cell response types: MHC-Ia-restricted-only, or a mix of MHC-II- and MHC-Ia-restricted CD8+ T cells. Despite response magnitude and functional differentiation being similar to RhCMV 68-1, neither alternative response type mediated protection against SIV challenge. These findings implicate MHC-E-restricted CD8+ T cell responses as mediators of anti-SIV efficacy and indicate that translation of RhCMV/SIV vector efficacy to humans will likely require deletion of all the genes that inhibit these responses from the HCMV/HIV vector.

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“…A stock of the resulting virus was used to construct a primary BAC (RhCMV 68−1 BAC) 17 , from which all available RhCMV BACs are derived. A succession of studies has shown that RhCMV 68−1 and RhCMV 68−1 BAC are highly mutated [18][19][20][21][22][23] , with the detail having been revealed progressively by the genome sequences of RhCMV 68−1 , RhCMV 68−1 BAC, derivatives of RhCMV 68−1 BAC, viruses generated from RhCMV 68−1 -based BACs, and other RhCMV strains (Table 1). As a result, RhCMV 68−1 and RhCMV 68−1 BAC lack the functions of many genes required for cellular tropism and tness in vivo.…”

Section: Resultsmentioning

confidence: 99%

“…In order to ensure that the RhCMV component of the repaired RhCMV 68−1 /EBOV BAC was as close in sequence as possible to the original RhCMV 68−1 genome as perceived to have existed prior to isolation and serial passage in cell culture 25 , it was necessary to identify mutations in RhCMV 68−1 BAC (and hence in RhCMV 68−1 /EBOV BAC) that have resulted in inactivated ORFs. This involved detailed examination of an alignment of all available RhCMV genome sequences, which at the time did not include several reported since by Taher et al (2020) 23 ; these recent sequences were incorporated at the end of the study and identi ed no additional mutations. This comparative exercise revealed a total of 13 putatively inactivated ORFs (Table 2).…”

Section: Resultsmentioning

confidence: 99%

HHi-FiVe: A high-fidelity genetic engineering pipeline for construction of herpesvirus-based vaccines

Jarvis

Mauch

Ostermann

et al. 2021

Preprint

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Herpesvirus-based vectors are attractive for use both as conventional and as transmissible vaccines against emerging zoonoses in hard-to-reach animal populations. However, the threat of off-site mutations during genetic manipulation of vector genomes poses a significant challenge to vaccine construction. Herein, we present the HHi-FiVe (herpesvirus high-fidelity vector) construction pipeline for generating herpesvirus-based vectors by modifying bacterial artificial chromosomes (BACs) and monitoring integrity at each stage by complete genome sequencing. We used this pipeline to repair a highly mutated rhesus cytomegalovirus BAC containing an Ebola virus transgene. The vector derived from this BAC had been shown previously to protect rhesus macaques from lethal Ebola virus challenge by conventional vaccination. Repair of this BAC restored wild-type cellular tropism to the vector, which is essential for transmissible vaccination. Construction of this candidate transmissible vaccine against Ebola virus demonstrates the utility of the HHi-FiVe pipeline for creating precision-made herpesvirus-based vectors.

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In vitro and in vivo characterization of a recombinant rhesus cytomegalovirus containing a complete genome

Cited by 24 publications

References 109 publications

Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8⁺T cell programming and RhCMV/SIV vaccine efficacy

HHi-FiVe: A high-fidelity genetic engineering pipeline for construction of herpesvirus-based vaccines

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In vitro and in vivo characterization of a recombinant rhesus cytomegalovirus containing a complete genome

Cited by 24 publications

References 109 publications

Cytomegaloviral determinants of CD8 + T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8 + T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8+T cell programming and RhCMV/SIV vaccine efficacy

HHi-FiVe: A high-fidelity genetic engineering pipeline for construction of herpesvirus-based vaccines

Contact Info

Product

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Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8 ⁺ T cell programming and RhCMV/SIV vaccine efficacy

Cytomegaloviral determinants of CD8⁺T cell programming and RhCMV/SIV vaccine efficacy