Allelic penetrance approach as a tool to model two-locus interaction in complex binary traits

Sepúlveda, Nuno; Paulino, Carlos Daniel; Carneiro, Jorge; Penha‐Gonçalves, Carlos

doi:10.1038/sj.hdy.6800979

Cited by 11 publications

(17 citation statements)

References 40 publications

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“…Since the same model is also the best according to PMP and DIC, we can state that infection susceptibility seems under control of an independent action between a dominant allele of the resistant strain at locus A and a type I recessive allele of the susceptible strain at locus B. Previously, IAM(A 2 /b 1 ) with b 1 as a type II recessive allele was considered to be the best model for the data (Sepúlveda et al, 2007). Therefore, this analysis improves on previous results by considering a type I recessive allele at locus B.…”

Section: Tablementioning

confidence: 99%

“…Moreover, the phenotypic expression of the alleles seems to be a stochastic event, which can be explained by the epigenetic state of the alleles (Rakyan et al, 2002) or to be an intrinsic property of loss-of-function alleles (Lalucque and Silar, 2004). Therefore, it is reasonable to put forward the notion of allelic penetrance, which embodies the probability of an allele being expressed at the level of the phenotype (Sepúlveda et al, 2007). By doing this, internal penetrance can be modeled as a function of allelic penetrances, describing different genetic mechanisms, as we will see below.…”

Section: The Allelic Penetrance Approachmentioning

confidence: 99%

“…In previous work, we adopted an alternative definition for the action of a recessive allele (Sepúlveda et al, 2007). There, the heterozygotes might manifest the phenotype by the expression of recessive allele a when the dominant allele b is not active.…”

Section: Single-locus Allelic Penetrance Modelsmentioning

confidence: 99%

“…The goal of the analysis is to infer the joint action of both loci with respect to susceptibility. Previously, we fitted the allelic penetrance models considering type II recessive alleles (Sepúlveda et al, 2007). We found an independent action between a dominant allele inherited from the resistant strain at locus A and a type II recessive allele derived from the susceptible strain at locus B.…”

Section: Immunoglobulin Deficienciesmentioning

confidence: 99%

“…Recently, we proposed an allelic penetrance approach to model penetrance in experimental populations (Sepúlveda et al, 2007). Under this new framework, the alleles themselves are assumed to have a probability of being expressed at the level of the phenotype.…”

Section: Introductionmentioning

confidence: 99%

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Bayesian analysis of allelic penetrance models for complex binary traits

Sepúlveda

Paulino

Penha‐Gonçalves

2009

Computational Statistics & Data Analysis

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a b s t r a c tComplex binary traits result from an intricate network of genetic and environmental factors. To aid their genetic dissection, several generalized linear models have been described to detect interaction between genes. However, it is recognized that these models have limited genetic interpretation. To overcome this problem, the allelic penetrance approach was proposed to model the action of a dominant or a recessive allele at a single locus, and to describe two-locus independent, inhibition, and cumulative actions. Classically, a recessive inheritance requires the expression of both recessive alleles in homozygotes to obtain the phenotype (type I recessiveness). In previous work, recessiveness was defined alternatively as a situation where a recessive allele is able to express the phenotype when the dominant allele is not active (type II recessiveness). Both definitions of recessiveness are then discussed under the allelic penetrance models.Bayesian methods are applied to analyze two data sets: one regarding the effect of the haplotype [HLA-B8, SC01, DR3] on the inheritance of IgD and IgG4 immunoglobulin deficiencies in humans, and other related to two-locus action in the control of Listeria infection susceptibility in mice.

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Section: Tablementioning

confidence: 99%

Section: The Allelic Penetrance Approachmentioning

confidence: 99%

Section: Single-locus Allelic Penetrance Modelsmentioning

confidence: 99%

Section: Immunoglobulin Deficienciesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Bayesian analysis of allelic penetrance models for complex binary traits

Sepúlveda

Paulino

Penha‐Gonçalves

2009

Computational Statistics & Data Analysis

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Dynamics of Peripheral Regulatory and Effector T Cells Competing for Antigen Presenting Cells

Sepúlveda

Carneiro²

2011

Mathematical Models and Immune Cell Biology

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A healthy immune system requires a balance between effector T (T E ) cells that mount immune responses, and regulatory T (T R ) cells that prevent them. Understanding this balance requires knowing how the repertoires of T E and T R cells in the periphery are patterned and related to each other. The present work addresses this issue in the framework of the Crossregulation model, which was formulated to contemplate the dynamics of a large number of T cell clones recognizing a non-exclusive set of antigen-presenting cells (APCs). Assuming a continuous thymic export, three distinct patterns for the peripheral repertoire emerge from the simulations. These patterns are distinguished by the composition of the resident population, i.e., the subset of clones that can persist in the periphery. On one extreme, there is a repertoire pattern characterised by a predominance of T E cell clones and a too small T R -cell pool only maintained in the periphery by the continuous thymus export. Thus, this repertoire pattern cannot be the basis of a healthy immune system, because peripheral tolerance to self antigens is not ensured. On the other extreme, there is a repertoire pattern showing a predominance of T R cells maintained by their T E counterparts coming from the thymus. In spite of ensuring peripheral tolerance, this repertoire pattern does not appear efficient to fight infections occurring throughout life. In the middle of these two extremes lies a third repertoire pattern exhibiting a partition of the peripheral compartment similar to the one suggested in a previous work. In this repertoire structure, a small subset of highly crossreactive T R -cell clones prevents expansion of T E -cell clones driven by body antigens, and a more diverse subset of T E -cell clones remains uncontrolled by T R cells, which allows the setup of immune responses against harmful pathogens. This repertoire pattern seems then the most adequate to represent a healthy immune system. For each emergent repertoire pattern, clear and testable predictions are given for different properties related to the diversity of T E and T R cells. For the most adequate repertoire pattern, a higher diversity of T E cells than of T R cells is expected as well J. Carneiro ( )

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