Impact of CCR5delta32 Host Genetic Background and Disease Progression on HIV-1 Intrahost Evolutionary Processes: Efficient Hypothesis Testing through Hierarchical Phylogenetic Models

Edo-Matas, Diana; Lemey, Philippe; Tom, Jennifer; Serna-Bolea, Cèlia; Blink, Agnes E. van den; Wout, Angélique B. van ′t; Schuitemaker, Hanneke; Suchard, Marc A.

doi:10.1093/molbev/msq326

Cited by 39 publications

(56 citation statements)

References 62 publications

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“…To this end, we compiled a large collection of datasets for previously described HIV-1 transmission chains. We describe the viral evolutionary histories with a recently introduced transmission model in BEAST [17] and test for transmission bottleneck size differences with a Bayesian hierarchical phylogenetic model (HPM) approach [27] that incorporates fixed effects [28]. We find no support for a difference in the loss of genetic diversity between the HET and MSM groups.…”

Section: Introductionmentioning

confidence: 99%

Disentangling the impact of within-host evolution and transmission dynamics on the tempo of HIV-1 evolution

Vrancken

Baele

Vandamme

et al. 2015

Aids

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Background Although evidence exists for a selective component at transmission, it is clear that HIV-1 transmission is also to a large extent driven by drift. The variation in inoculum size among different risk groups therefore implies that the adaptation rate of HIV may vary between epidemics with different risk group compositions. Furthermore, factors that govern the rate of within-host evolution may also vary by risk group and therefore contribute to evolutionary differences at the epidemic level. Methods We adopted a population genetic approach to test whether the different proportions of multi-variant transmissions are reflected by varying proportions of transmitted diversity between men-having-sex-with-men (MSM), heterosexual (HET) and direct blood contact (BC) sub-populations. To this purpose, we collected all available transmission chain clonal sequence data sets (n = 70) available at the Los Alamos HIV website and through an extensive literature search. To assess evolutionary rate differences among different risk groups, we compiled risk group datasets for several subtypes and directly compared the absolute substitution rate and its synonymous and non-synonymous components. Results There was sufficient demographic signal to inform the transmission model in BEAST using env data to compare the transmission bottleneck size between the MSM and HET risk groups, i.e. the largest contributors to HIV spread. We find no indications for a different proportion of transmitted genetic diversity at the population level between these groups. In the direct rate comparisons between risk groups, however, we consistently recover a higher evolutionary rate in the male dominated risk group compared to the HET datasets. Conclusions We find that the risk group composition impacts the viral evolutionary rate and therefore potentially also the adaptation rate. In particular, risk group-specific sex ratios, and the variation in within-host evolutionary rates between males and females, imposes evolutionary rate differences at the epidemic level, but we cannot exclude a role of varying transmission rates.

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Section: Introductionmentioning

confidence: 99%

Disentangling the impact of within-host evolution and transmission dynamics on the tempo of HIV-1 evolution

Vrancken

Baele

Vandamme

et al. 2015

Aids

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“…HPMs have been used in phylodynamic studies of the intrahost behaviour of HIV-1 [15,26]. The long timespan of HIV-1 infections, which sometimes last more than 10 years, combined with high mutation rates, makes phylodynamics a useful tool for assessing viral intrahost biology.…”

Section: Discussionmentioning

confidence: 99%

“…These hierarchical phylogenetic models (HPMs) generally have the property of reducing variability in estimates for phylogenetic parameters of individual partitions, while providing a framework for assessing overall tendencies. Examples of HPMs involving the sequence substitution processes in infectious diseases include examining selective pressures in HIV intrahost data, where information pools across multiple patients [15], and estimating the time to most recent common ancestor across the multiple gene segments of influenza [16].…”

Section: Introductionmentioning

confidence: 99%

Graph hierarchies for phylogeography

Cybis

Sinsheimer

Lemey

et al. 2013

Phil. Trans. R. Soc. B

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One contribution of 18 to a Discussion Meeting Issue 'Next-generation molecular and evolutionary epidemiology of infectious disease'. Bayesian phylogeographic methods simultaneously integrate geographical and evolutionary modelling, and have demonstrated value in assessing spatial spread patterns of measurably evolving organisms. We improve on existing phylogeographic methods by combining information from multiple phylogeographic datasets in a hierarchical setting. Consider N exchangeable datasets or strata consisting of viral sequences and locations, each evolving along its own phylogenetic tree and according to a conditionally independent geographical process. At the hierarchical level, a random graph summarizes the overall dispersion process by informing which migration rates between sampling locations are likely to be relevant in the strata. This approach provides an efficient and improved framework for analysing inherently hierarchical datasets. We first examine the evolutionary history of multiple serotypes of dengue virus in the Americas to showcase our method. Additionally, we explore an application to intrahost HIV evolution across multiple patients.

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“…The potential effect of vaccination on viral evolution was explored using a fixed-effects extension of Bayesian hierarchical phylogenetic models (HPMs) [17,18] implemented in BEAST (Bayesian Evolutionary Analysis Sampling Trees) [19]. By specifying hierarchical prior distributions, HPMs allow pooling information across different patients to improve estimate precision of withinhost viral evolutionary parameters, in this case the HIV evolutionary rate, in individual patients.…”

Section: Evolution At the Whole Gene Levelmentioning

confidence: 99%

HIV-1 evolution in patients undergoing immunotherapy with Tat, Rev, and Nef expressing dendritic cells followed by treatment interruption

Goede

Deutekom

Vrancken

et al. 2013

Aids

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Impact of CCR5delta32 Host Genetic Background and Disease Progression on HIV-1 Intrahost Evolutionary Processes: Efficient Hypothesis Testing through Hierarchical Phylogenetic Models

Cited by 39 publications

References 62 publications

Disentangling the impact of within-host evolution and transmission dynamics on the tempo of HIV-1 evolution

Disentangling the impact of within-host evolution and transmission dynamics on the tempo of HIV-1 evolution

Graph hierarchies for phylogeography

HIV-1 evolution in patients undergoing immunotherapy with Tat, Rev, and Nef expressing dendritic cells followed by treatment interruption

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