Variation in HIV-1 set-point viral load: Epidemiological analysis and an evolutionary hypothesis

Fraser, Christophe; Hollingsworth, T. Déirdre; Chapman, Richard C.; Wolf, Frank de; Hanage, William P.

doi:10.1073/pnas.0708559104

Cited by 374 publications

(587 citation statements)

References 30 publications

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“…The number of lineages with A or B labels that merge in the source population is therefore a random variable determined by the sample size, sampling time, and within-host dynamics. In general, this quantity will be smaller than the HIV-1 within-host population size (35)(36)(37), or effective population size (38)(39)(40), and consequently sampling plays an important role in the ability of genetic data to resolve an epidemiologic linkage. Furthermore, first principles predict that as the time between transmission and sampling increases, eventually old lineages will be lost in the derived populations, leading to loss of the paraphyletic signal (Fig.…”

Section: Paraphyletic Signal Predicts Direction Of Transmission But Dmentioning

confidence: 99%

Phylogenetically resolving epidemiologic linkage

Romero-Severson

Bulla

Leitner

2016

Proc. Natl. Acad. Sci. U.S.A.

134

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Although the use of phylogenetic trees in epidemiological investigations has become commonplace, their epidemiological interpretation has not been systematically evaluated. Here, we use an HIV-1 within-host coalescent model to probabilistically evaluate transmission histories of two epidemiologically linked hosts. Previous critique of phylogenetic reconstruction has claimed that direction of transmission is difficult to infer, and that the existence of unsampled intermediary links or common sources can never be excluded. The phylogenetic relationship between the HIV populations of epidemiologically linked hosts can be classified into six types of trees, based on cladistic relationships and whether the reconstruction is consistent with the true transmission history or not. We show that the direction of transmission and whether unsampled intermediary links or common sources existed make very different predictions about expected phylogenetic relationships: (i) Direction of transmission can often be established when paraphyly exists, (ii) intermediary links can be excluded when multiple lineages were transmitted, and (iii) when the sampled individuals' HIV populations both are monophyletic a common source was likely the origin. Inconsistent results, suggesting the wrong transmission direction, were generally rare. In addition, the expected tree topology also depends on the number of transmitted lineages, the sample size, the time of the sample relative to transmission, and how fast the diversity increases after infection. Typically, 20 or more sequences per subject give robust results. We confirm our theoretical evaluations with analyses of real transmission histories and discuss how our findings should aid in interpreting phylogenetic results.HIV-1 | transmission | paraphyly | coalescent | phylogeny

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Section: Paraphyletic Signal Predicts Direction Of Transmission But Dmentioning

confidence: 99%

Phylogenetically resolving epidemiologic linkage

Romero-Severson

Bulla

Leitner

2016

Proc. Natl. Acad. Sci. U.S.A.

134

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“…Possibly, one of the best studied pathogens in this regard is HIV. Data for HIV correlating the viral load in serum with probability of infection in a partner suggest a sigmoid relationship (figure 2; [42][43][44]). However, higher viral load also leads to more rapid progression to the terminal AIDS stage [43,45], therefore reducing the time during which transmission can occur (figure 2).…”

Section: Host Infectiousnessmentioning

confidence: 99%

Crossing the scale from within-host infection dynamics to between-host transmission fitness: a discussion of current assumptions and knowledge

Handel

Rohani

2015

Phil. Trans. R. Soc. B

109

181

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The progression of an infection within a host determines the ability of a pathogen to transmit to new hosts and to maintain itself in the population. While the general connection between the infection dynamics within a host and the population-level transmission dynamics of pathogens is widely acknowledged, a comprehensive and quantitative understanding that would allow full integration of the two scales is still lacking. Here, we provide a brief discussion of both models and data that have attempted to provide quantitative mappings from within-host infection dynamics to transmission fitness. We present a conceptual framework and provide examples of studies that have taken first steps towards development of a quantitative framework that scales from within-host infections to population-level fitness of different pathogens. We hope to illustrate some general themes, summarize some of the recent advances and—maybe most importantly—discuss gaps in our ability to bridge these scales, and to stimulate future research on this important topic.

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“…However, earlier models have shown that further assumptions would then be needed because if both virulence and transmission rates are linear functions of parasite load, natural selection will always favour the strains with the highest possible level of virulence [51]. One possibility could be to focus on a biological system where these relationships have been parametrized, such as HIV in humans [52], myxomatosis in rabbits [53], Ophryocystis elektroscirrha in monarch butterflies [54] or the cauliflower mosaic virus in turnips [55].…”

Section: Discussionmentioning

confidence: 99%

From within-host interactions to epidemiological competition: a general model for multiple infections

Sofonea

Alizon

Michalakis

2015

Phil. Trans. R. Soc. B

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One contribution of 17 to a theme issue 'Within-host dynamics of infection: from ecological insights to evolutionary predictions'. Many hosts are infected by several parasite genotypes at a time. In these coinfected hosts, parasites can interact in various ways thus creating diverse within-host dynamics, making it difficult to predict the expression and the evolution of virulence. Moreover, multiple infections generate a combinatorial diversity of cotransmission routes at the host population level, which complicates the epidemiology and may lead to non-trivial outcomes. We introduce a new model for multiple infections, which allows any number of parasite genotypes to infect hosts and potentially coexist in the population. In our model, parasites affect one another's within-host growth through density-dependent interactions and by means of public goods and spite. These within-host interactions determine virulence, recovery and transmission rates, which are then integrated in a transmission network. We use analytical solutions and numerical simulations to investigate epidemiological feedbacks in host populations infected by several parasite genotypes. Finally, we discuss general perspectives on multiple infections.

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Variation in HIV-1 set-point viral load: Epidemiological analysis and an evolutionary hypothesis

Cited by 374 publications

References 30 publications

Phylogenetically resolving epidemiologic linkage

Phylogenetically resolving epidemiologic linkage

Crossing the scale from within-host infection dynamics to between-host transmission fitness: a discussion of current assumptions and knowledge

From within-host interactions to epidemiological competition: a general model for multiple infections

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