Everything about Nutrigenomics totally explained
Nutrigenomics is the study of molecular relationships between
nutrition and the response of
genes, with the aim of extrapolating how such subtle changes can affect
human health. Nutrigenomics focuses on the effect of nutrients on the
genome,
proteome, and
metabolome. By determining the mechanism of the effects of
nutrients or the effects of a nutritional regime, Nutrigenomics tries to define the
relationship between these specific nutrients and specific nutrient regimes (diets) on human health. Nutrigenomics has been associated with the idea of personalized nutrition based on genotype. While there's hope that nutrigenomics will ultimately enable such personalised dietary advice, it's a science still in its infancy and its contribution to
public health over the next decade is thought to be minor.
Definitions
Nutrigenomics focuses on the effect of nutrients on the
genome,
proteome, and
metabolome. It is applying the sciences of
genomics,
transcriptomics,
proteomics and
metabolomics to human
nutrition in order to understand the
relationship between
nutrition and
health. Nutrigenomics is a new science and has several different definitions. Nutrigenomics has been defined as the application of high-throughput genomic tools in
nutrition research.
Background and preventive health
Throughout the 20th century,
nutritional science focused on finding
vitamins and
minerals, defining their use and preventing the
deficiency diseases that they caused. As the nutrition related health problems of the
developed world shifted to
overnutrition,
obesity and
type two diabetes, the focus of
modern medicine and of nutritional science changed accordingly.
In order to address the increasing
incidence of these diet-related-diseases, the role of diet and nutrition has been and continues to be extensively studied. To prevent the development of disease, nutrition research is investigating how nutrition can optimize and maintain cellular, tissue, organ and whole body
homeostasis. This requires understanding how nutrients act at the molecular level. This involves a multitude of nutrient-related interactions at the gene, protein and metabolic levels. As a result, nutrition research has shifted from
epidemiology and
physiology to
molecular biology and
genetics and nutrigenomics was born.
The emergence and development of nutrigenomics has been possible due to powerful developments in
genetic research. Inter-individual differences in genetics, or
genetic variability, which have an effect on metabolism and on phenotypes were recognized early in nutrition research, and such phenotypes were described. With the progress in genetics, biochemical disorders with a high nutritional
relevance were linked to a genetic origin.
Genetic disorders which cause pathological effects were described. Such genetic disorders include the polymorphism in the gene for the hormone
Leptin which results in gross obesity. Other gene
polymorphisms were described with consequences for human nutrition. The
folate metabolism is a good example, where a common polymorphism exists for the gene that encodes the
methylene-tetrahydro-folate reductase (MTHFR).
It was realized however, that there are possibly thousands of other gene polymorphisms which may result in minor deviations in nutritional biochemistry, where only marginal or additive effects would result from these deviations. The tools to study the physiological impact were not available at the time and are only now becoming available enabling the development of nutrigenomics. Such tools include those that measure the transcriptome -
DNA microarray,
Exon array, Tiling arrays,
single nucleotide polymorphism arrays and
genotyping. Tools that measure the
proteome are less developed. These include methods based on
gel electrophoresis,
chromatography and
mass spectrometry. Finally the tools that measure the
metabolome are also less developed and include methods based on
nuclear magnetic resonance imaging as well as
gas and liquid chromatography.
Rationale and aims of nutrigenomics
In nutrigenomics, nutrients are seen as
signals that tell a specific
cell in the body about the
diet. The nutrients are detected by a sensor system in the cell. Such a sensory system works like
sensory ecology whereby the cell obtains information through the signal, the nutrient, about its environment, which is the
diet. The sensory system that interprets information from nutrients about the dietary environment include
transcription factors together with many additional proteins. Once the nutrient interacts with such a sensory system, it changes
gene,
protein expression and metabolite production in accordance with the level of nutrient it senses. As a result, different diets should elicit different patterns of gene and
protein expression and metabolite production. Nutrigenomics seeks to describe the patterns of these effects which have been referred to as
dietary signatures. Such dietary signatures are examined in specific cells, tissues and organisms and in this way the manner by which nutrition influences
homeostasis is investigated. Genes which are affected by differing levels of nutrients need first to be identified and then their
regulation is studied. Differences in this regulation as a result of differences in genes between individuals are also studied.
It is hoped that by building up knowledge in this area, nutrigenomics will promote an increased understanding of how nutrition influences
metabolic pathways and homeostatic control, which will then be used to prevent the development of
chronic diet related diseases such as
obesity and
type two diabetes. Part of the approach of nutrigenomics involves finding
markers of the early phase of diet related diseases; this is the phase at which
intervention with nutrition can return the patient to
health. As nutrigenomics seeks to understand the effect of different
genetic predispositions in the development of such diseases, once a
marker has been found and measured in an individual, the extent to which they're
susceptible to the development of that disease will be quantified and personalized dietary recommendation can be given for that person.
The aims of nutrigenomics also includes being able to demonstrate the effect of
bioactive food compounds on health and the effect of health foods on health, which should lead to the development of
functional foods that will keep people healthy according to their individual needs.
As of yet, nutrigenomics is in its infancy. The tools to study protein expression and metabolite production have not yet developed to the point as to enable efficient and reliable measurements. Also once such research has been achieved, it'll need to be integrated together in order to produce results and dietary recommendations. All of these technologies are still in the process of development.
Further Information
Get more info on 'Nutrigenomics'.
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