Nutrition Research and the Impact of Computational Systems Biology

Auley, Mark T. Mc

doi:10.4172/jcsb.1000122

Cited by 31 publications

(27 citation statements)

References 109 publications

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“…Furthermore, this model could be combined with other pre-existing models, or further developed to include other compartments such as the gallbladder, or other interconnected metabolic pathways such as fatty acid or carbohydrate metabolism, or cortisol homeostasis. For example, cortisol is synthesised from cholesterol and is involved in provoking the breakdown of lipids, and a wide variety of other metabolites, therefore this model could be connected to a previously developed computational model of whole-body cortisol metabolism (Mc Auley et al, 2013;McAuley et al, 2009). …”

Section: Discussionmentioning

confidence: 99%

Mathematically modelling the dynamics of cholesterol metabolism and ageing

et al. 2016

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Section: Discussionmentioning

confidence: 99%

Mathematically modelling the dynamics of cholesterol metabolism and ageing

et al. 2016

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“…Thus, it is imperative if we are to gain a more in-depth appreciation of cholesterol metabolism and its interaction with ageing, that we investigate this system in a more integrated manner. The systems biology paradigm contrasts with the more traditional reductionist approach, commonly used in nutrition research, and offers a more integrated way to study this multifaceted system (14,113,114) . A fundamental element of this paradigm shift is the close coupling of computational modelling with experimental work (115)(116)(117)(118) .…”

Section: Applying Systems Biology To Our Understanding Of Cholesterolmentioning

confidence: 99%

Investigating cholesterol metabolism and ageing using a systems biology approach

et al. 2016

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CVD accounted for 27 % of all deaths in the UK in 2014, and was responsible for 1·7 million hospital admissions in 2013/2014. This condition becomes increasingly prevalent with age, affecting 34·1 and 29·8 % of males and females over 75 years of age respectively in 2011. The dysregulation of cholesterol metabolism with age, often observed as a rise in LDL-cholesterol, has been associated with the pathogenesis of CVD. To compound this problem, it is estimated by 2050, 22 % of the world's population will be over 60 years of age, in culmination with a growing resistance and intolerance to pre-existing cholesterol regulating drugs such as statins. Therefore, it is apparent research into additional therapies for hypercholesterolaemia and CVD prevention is a growing necessity. However, it is also imperative to recognise this complex biological system cannot be studied using a reductionist approach; rather its biological uniqueness necessitates a more integrated methodology, such as that offered by systems biology. In this review, we firstly discuss cholesterol metabolism and how it is affected by diet and the ageing process. Next, we describe therapeutic strategies for hypercholesterolaemia, and finally how the systems biology paradigm can be utilised to investigate how ageing interacts with complex systems such as cholesterol metabolism. We conclude by emphasising the need for nutritionists to work in parallel with the systems biology community, to develop novel approaches to studying cholesterol metabolism and its interaction with ageing.

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“…Fortunately, there is a growing appreciation that complex biological process can be studied in a holistic manner by adopting a systems biology approach [45]. Computational modelling resides at the centre of this paradigm shift, as it provides a framework for representing and exploring the dynamics of complex systems [46][47][48][49][50]. In this review, we discuss the role computational modelling has played in developing our understanding of FOCM and DNA methylation.…”

Section: Introductionmentioning

confidence: 99%

Computational modelling folate metabolism and DNA methylation: implications for understanding health and ageing

2016

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Dietary folates have a key role to play in health, as deficiencies in the intake of these B vitamins have been implicated in a wide variety of clinical conditions. The reason for this is folates function as single carbon donors in the synthesis of methionine and nucleotides. Moreover, folates have a vital role to play in the epigenetics of mammalian cells by supplying methyl groups for DNA methylation reactions. Intriguingly, a growing body of experimental evidence suggests that DNA methylation status could be a central modulator of the ageing process. This has important health implications because the methylation status of the human genome could be used to infer age-related disease risk. Thus, it is imperative we further our understanding of the processes which underpin DNA methylation and how these intersect with folate metabolism and ageing. The biochemical and molecular mechanisms, which underpin these processes, are complex. However, computational modelling offers an ideal framework for handling this complexity. A number of computational models have been assembled over the years, but to date, no model has represented the full scope of the interaction between the folate cycle and the reactions, which governs the DNA methylation cycle. In this review, we will discuss several of the models, which have been developed to represent these systems. In addition, we will present a rationale for developing a combined model of folate metabolism and the DNA methylation cycle.

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Nutrition Research and the Impact of Computational Systems Biology

Cited by 31 publications

References 109 publications

Mathematically modelling the dynamics of cholesterol metabolism and ageing

Mathematically modelling the dynamics of cholesterol metabolism and ageing

Investigating cholesterol metabolism and ageing using a systems biology approach

Computational modelling folate metabolism and DNA methylation: implications for understanding health and ageing

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