Are you an international student? Are you interested in learning more about Nutrigenomics? Do you get overwhelmed by the amount of conflicting information you see online? If so, you need not search further because you will find the answer to that question in the article below.
To get more information on Nutrigenomics. You can also find up-to-date, related articles on Collegelearners.
The search for knowledge regarding healthy/adequate food has increased in the last decades among the world population, researchers, nutritionists, and health professionals. Since ancient times, humans have known that environment and food can interfere with an individual’s health condition, and have used food and plants as medicines. With the advance of science, especially after the conclusion of the Human Genome Project (HGP), scientists started questioning if the interaction between genes and food bioactive compounds could positively or negatively influence an individual’s health. In order to assess this interaction between genes and nutrients, the term “Nutrigenomics” was created. Hence, Nutrigenomics corresponds to the use of biochemistry, physiology, nutrition, genomics, proteomics, metabolomics, transcriptomics, and epigenomics to seek and explain the existing reciprocal interactions between genes and nutrients at a molecular level. The discovery of these interactions (gene-nutrient) will aid the prescription of customized diets according to each individual’s genotype. Thus, it will be possible to mitigate the symptoms of existing diseases or to prevent future illnesses, especially in the area of Nontransmissible Chronic Diseases (NTCDs), which are currently considered an important world public health problem.
1. Introduction
Food intake and the environment are the two main factors that affect the health or illness of an individual [1]. Studies in nutritional area have increased the understanding of how to maintain healthy a group of individuals that live in different dietary conditions . However, after the conclusion of the Human Genome Project (HGP), new insights about the influence of nutrients into people’s diet were postulated, which included (i) will gene expression in response to metabolic process, at cellular level, influence the health of an individual? (ii) Are gene expression and metabolic response the result of the interaction between genotype and environment/nutrient? (iii) Understanding how this interaction process occurs between gene and nutrient could lead to the prescription of specific diets for each individual. Hence, in order to answer those questions, Nutrigenomics was introduced . The studies on Nutrigenomics are focused on the effects of the nutrients over the genome, proteome, and metabolome, as illustrated on Figure .
Figure 1 “Omics” sciences used in understanding the relationship between nutrition versus health versus disease , with modifications; with modifications).
Therefore, Nutrigenomics is the area of nutrition that uses molecular tools to search, access, and understand the several responses obtained through a certain diet applied between individuals or population groups . It seeks to elucidate how the components of a particular diet (bioactive compound) may affect the expression of genes, which may have increased its potential or which can be suppressed . This response will depend on how genes will show a changed activity or alter gene expression . Some examples of this gene-nutrient interaction are their capacity on binding to transcription factors. This binding enhances or interferes with the ability of transcription factors on interacting with elements that will lead to the binding control of RNA polymerase. Earlier studies performed with vitamins A, D and fatty acids have shown that they can trigger direct actions in activating nuclear receptors and induce gene transcription . Compounds such as resveratrol present in wine and soy genistein may indirectly influence the molecular signaling pathways, such as the fac. The involvement of these factors in the activation and regulation of key molecules is associated with diseases ranging from inflammation to cancer .
With information obtained from the HGP, it was found that humans have 99.9% identity between their genomes. A distinct difference between their weight, height, eye color/hair, and other features is only 0.1% of the gene sequence and this difference, among other factors, also determines the nutritional requirements and the risk of developing some of the NTCDs . Single Nucleotide Polymorphisms (SNPs) are the main reason for this genetic variation, and it can often change the encoded protein . Studies have shown that certain genes and their variants can be regulated or are influenced by nutrients/food compounds from the diet and that these molecular variations may have beneficial actions to the health of an individual .
Nutrigenomics Might Be the Future of How You Eat
If there’s one thing the last several decades of nutrition research have proven, it’s that there’s no one-size-fits-all diet. While many factors are at play, one reason certain eating plans work for one person but not another may have to do with our genetics.
Nutrigenomics is a fascinating, up-and-coming field that uses genetic testing to determine the interplay between genes, nutrition, and health. This information is used to help pinpoint the ideal diet for each individual.
Here’s a look at what nutrigenomics is, what you can expect if you try it, and how it might shape the future of personalized nutrition.
What is nutrigenomics?
“Nutrigenomics is the study of the relationship between genomics, nutrition, and health,” says geneticist Jan Lim, MS, of CRI Genetics. “The field includes both the study of how the whole body responds to micro- and macronutrients, as well as the relationship between single genes and single gene/food compound interactions.”
You may sometimes hear this field referred to as “nutrigenetics.”
Technically, nutrigenomics refers to how nutrients influence your body to express genes, while nutrigenetics refers to how your body responds to nutrients because of your existing genetic makeup. However, many people use the terms interchangeably.
History of nutrigenomics
Though the science of nutrition genetics is still in its infancy, the idea that our genes can determine our best diet isn’t as space-age as it might seem.
In fact, as far back as the early 20th century, British physician Archibald Garrod is credited with establishing a connection between nutrition, genetics, and phenotype.
The Human Genome Project of the 1990s, which mapped out human DNA, paved the way for the modern era of nutrigenomics. Since then, hundreds of studies have examined genes’ influence on the body’s response to diet, as well as the other way around.
Today, it’s not uncommon for practitioners like dietitians and doctors to use genetic testing to assess patients’ dietary needs and set customized health goals.
Benefits
Genetic testing as part of nutrition counseling might sound rather extreme. A genetic workup just to see if you should eat low carb or get more vitamin C?
However, as part of an integrative nutrition approach, nutrigenomics can shed light on issues a simple health history can’t. This includes everything from a predisposition to heart disease to why you’re not losing weight when you’ve tried everything.
“Genomic testing truly is useful for anyone wanting to be proactive about their health,” says dietitian and certified genomic medical clinician Andrea Chernus, MS, RD, CGMC. “Genomic testing can help to explain why situations exist for a patient, such as which style of eating might suit them best.”
By looking at your genetic makeup, a practitioner may be able to advise you on certain eating patterns that will or won’t work well for you. For example, gene variants might mean your body wouldn’t benefit from a vegan diet or wouldn’t adapt well to a keto diet due to genomic tendencies for fat metabolism.
A nutrigenomic test can even uncover your personal best sources of both macro- and micronutrients.
Perhaps your body is unable to optimally use omega-3 fatty acids from plant sources, or you have trouble converting sunshine into vitamin D. With this data, a trained practitioner can instruct you on which foods to eat or supplements to take to meet your needs.
Likewise, predispositions toward certain diseases may show up on a nutrigenomics test.
“We may be able to see gene variants that increase one’s risk for breast cancer due to the genes involved in estrogen metabolism, for example,” Chernus notes. Heart disease, diabetes, obesity, and mental health have all been linked to genetic expressions, and all have dietary prevention strategies.
Empowered with this information, you can make preventative choices to mitigate risk through diet.0 seconds of 0 secondsVolume 0%
What to expect
Interested in pursuing a genetic approach to nutrition, but not sure what to expect? Nutrition counseling using nutrigenomics is surprisingly painless.
“The experience should start with a detailed health questionnaire so the practitioner has a complete understanding of the patient’s health status, history, family history, and current and past lifestyles,” says Chernus. “The actual test involves an at-home cheek swab. It’s typical for a test to evaluate anywhere from 80 to 150 or more genes. It’s quite simple to do.”
In some cases, if your results raise additional questions, a blood test may follow.
Once your test results are back, your dietitian or other health professional will evaluate them and work with you to develop an action plan for eating.
Potential drawbacks of nutrigenomics
Although extensive research has been conducted on the connection between genetics, diet, and health, the science of nutrigenomics is still emerging. “Nutrigenomics is a relatively new field of research, so we still have a lot to learn,” says Lim.
This isn’t to say that genetics aren’t a helpful piece of the puzzle when it comes to nutrition counseling. Just recognize that nutrigenomics won’t solve every diet conundrum, and that genes are just one of many factors that influence health and ideal dietary choices.
“Genomic testing should not be the sole criteria used to make recommendations,” says Chernus. “We need to include lifestyle, health history, health status, personal preferences, cultural identity, willingness of the patient to change, and their own health goals in our work.”
The availability of direct-to-consumer genetic testing for diet purposes, while it may seem exciting and convenient, is another potential drawback.
“The main drawback [of these tests] is that they’re not interpreted by a skilled clinician,” Chernus says. “Skilled practitioners use a polygenic approach: how all of the genes are part of bigger systems in the body. They interpret how these systems work together in the totality of one’s health.”
To understand the relationship between your own genome and diet, it’s always best to consult with a health professional who specializes in nutrition genetics.
Nutritional genomics, also known as nutrigenomics, is a science studying the relationship between human genome, human nutrition and health. People in the field work toward developing an understanding of how the whole body responds to a food via systems biology, as well as single gene/single food compound relationships. Nutritional genomics or Nutrigenomics is the relation between food and inherited genes, it was first expressed in 2001.
Introduction
The term “nutritional genomics” is an umbrella term including several subcategories, such as nutrigentics, nutrigenomics, and nutritional epigenetics. Each of these subcategories explain some aspect of how genes react to nutrients and express specific phenotypes, like disease risk. There are several applications for nutritional genomics, for example how much nutritional intervention and therapy can the successfully used for disease prevention and treatment.
Background and preventive health
Nutritional science originally emerged as a field that studied individuals lacking certain nutrients and the subsequent effects, such as the disease scurvy which results from a lack of vitamin C. As other diseases closely related to diet (but not deficiency), such as obesity, became more prevalent, nutritional science expanded to cover these topics as well. Nutritional research typically focuses on preventative measure, trying to identify what nutrients or foods will raise or lower risks of diseases and damage to the human body.
For example, Prader–Willi syndrome, a disease whose most distinguishing factor is insatiable appetite, has been specifically linked to an epigenetic pattern in which the paternal copy in the chromosomal region is erroneously deleted, and the maternal loci is inactivated by over methylation. Yet, although certain disorders may be linked to certain single-nucleotide polymorphisms (SNPs) or other localized patterns, variation within a population may yield many more polymorphisms.
Applications
The applications of nutritional genomics are multiple. With personalized assessment some disorders (diabetes, metabolic syndrome) can be identified. Nutrigenomics can help with personalized health and nutrition intake by assessing individuals and make specific nutritional requirements. The focus is in the prevention and the correction of specific genetic disorders. Examples of genetic related disorders that improve with nutritional correction are obesity, coronary heart disease (CHD), hypertension and diabetes mellitus type 1. Genetic disorders that can often be prevented by proper nutritional intake of parents include spina bifida, alcoholism and phenylketouria.
Coronary heart disease
Genes tied to nutrition manifest themselves through the body’s sensitivity to food. In studies about CHD, there is a relationship between the disease and the presence of two alleles found at E and B apolipoprotein loci. These loci differences result in individualized reactions to the consumption of lipids. Some people experience increased weight gain and greater risk of CHD whereas others with different loci do not. Research has shown a direct correlation between the decrease risk of CHD and the decrease consumption of lipids across all populations.
Obesity
Obesity is one of the most widely studied topics in nutritional genomics. Due to genetic variations among individuals, each person could respond to diet differently. By exploring the interaction between dietary pattern and genetic factors, the field aims to suggest dietary changes that could prevent or reduce obesity.
There appear to be some SNPs that make it more likely that a person will gain weight from a high fat diet; for people with AA genotype in the FTO gene showed a higher BMI compared those with TT genotype when having high fat or low carbohydrate dietary intake. The APO B SNP rs512535 is another diet-related variation; the A/G heterozygous genotype was found to have association with obesity (in terms of BMI and waist circumference) and for individuals with habitual high fat diet (>35% of energy intake), while individuals with GG homozygous genotype are likely to have a higher BMI compared to AA allele carriers. However, this difference is not found in low fat consuming group (<35% of energy intake).
Phenylketonuria
Phenylketonuria, otherwise known as PKU, is a uncommon autosomal recessive metabolic disorder that takes effect postpartum but the debilitating symptoms can be reversed with nutritional intervention
Cancer Genomics And Precision Oncology
Are you an international student? Are you interested in learning more about Nutrigenomics? Do you get overwhelmed by the amount of conflicting information you see online? If so, you need not search further because you will find the answer to that question in the article below.
To get more information on Nutrigenomics. You can also find up-to-date, related articles on Collegelearners.
The search for knowledge regarding healthy/adequate food has increased in the last decades among the world population, researchers, nutritionists, and health professionals. Since ancient times, humans have known that environment and food can interfere with an individual’s health condition, and have used food and plants as medicines. With the advance of science, especially after the conclusion of the Human Genome Project (HGP), scientists started questioning if the interaction between genes and food bioactive compounds could positively or negatively influence an individual’s health. In order to assess this interaction between genes and nutrients, the term “Nutrigenomics” was created. Hence, Nutrigenomics corresponds to the use of biochemistry, physiology, nutrition, genomics, proteomics, metabolomics, transcriptomics, and epigenomics to seek and explain the existing reciprocal interactions between genes and nutrients at a molecular level. The discovery of these interactions (gene-nutrient) will aid the prescription of customized diets according to each individual’s genotype. Thus, it will be possible to mitigate the symptoms of existing diseases or to prevent future illnesses, especially in the area of Nontransmissible Chronic Diseases (NTCDs), which are currently considered an important world public health problem.
1. Introduction
Food intake and the environment are the two main factors that affect the health or illness of an individual [1]. Studies in nutritional area have increased the understanding of how to maintain healthy a group of individuals that live in different dietary conditions . However, after the conclusion of the Human Genome Project (HGP), new insights about the influence of nutrients into people’s diet were postulated, which included (i) will gene expression in response to metabolic process, at cellular level, influence the health of an individual? (ii) Are gene expression and metabolic response the result of the interaction between genotype and environment/nutrient? (iii) Understanding how this interaction process occurs between gene and nutrient could lead to the prescription of specific diets for each individual. Hence, in order to answer those questions, Nutrigenomics was introduced . The studies on Nutrigenomics are focused on the effects of the nutrients over the genome, proteome, and metabolome, as illustrated on Figure .
Figure 1 “Omics” sciences used in understanding the relationship between nutrition versus health versus disease , with modifications; with modifications).
Therefore, Nutrigenomics is the area of nutrition that uses molecular tools to search, access, and understand the several responses obtained through a certain diet applied between individuals or population groups . It seeks to elucidate how the components of a particular diet (bioactive compound) may affect the expression of genes, which may have increased its potential or which can be suppressed . This response will depend on how genes will show a changed activity or alter gene expression . Some examples of this gene-nutrient interaction are their capacity on binding to transcription factors. This binding enhances or interferes with the ability of transcription factors on interacting with elements that will lead to the binding control of RNA polymerase. Earlier studies performed with vitamins A, D and fatty acids have shown that they can trigger direct actions in activating nuclear receptors and induce gene transcription . Compounds such as resveratrol present in wine and soy genistein may indirectly influence the molecular signaling pathways, such as the fac. The involvement of these factors in the activation and regulation of key molecules is associated with diseases ranging from inflammation to cancer .
With information obtained from the HGP, it was found that humans have 99.9% identity between their genomes. A distinct difference between their weight, height, eye color/hair, and other features is only 0.1% of the gene sequence and this difference, among other factors, also determines the nutritional requirements and the risk of developing some of the NTCDs . Single Nucleotide Polymorphisms (SNPs) are the main reason for this genetic variation, and it can often change the encoded protein . Studies have shown that certain genes and their variants can be regulated or are influenced by nutrients/food compounds from the diet and that these molecular variations may have beneficial actions to the health of an individual .
Nutrigenomics Might Be the Future of How You Eat
If there’s one thing the last several decades of nutrition research have proven, it’s that there’s no one-size-fits-all diet. While many factors are at play, one reason certain eating plans work for one person but not another may have to do with our genetics.
Nutrigenomics is a fascinating, up-and-coming field that uses genetic testing to determine the interplay between genes, nutrition, and health. This information is used to help pinpoint the ideal diet for each individual.
Here’s a look at what nutrigenomics is, what you can expect if you try it, and how it might shape the future of personalized nutrition.
What is nutrigenomics?
“Nutrigenomics is the study of the relationship between genomics, nutrition, and health,” says geneticist Jan Lim, MS, of CRI Genetics. “The field includes both the study of how the whole body responds to micro- and macronutrients, as well as the relationship between single genes and single gene/food compound interactions.”
You may sometimes hear this field referred to as “nutrigenetics.”
Technically, nutrigenomics refers to how nutrients influence your body to express genes, while nutrigenetics refers to how your body responds to nutrients because of your existing genetic makeup. However, many people use the terms interchangeably.
History of nutrigenomics
Though the science of nutrition genetics is still in its infancy, the idea that our genes can determine our best diet isn’t as space-age as it might seem.
In fact, as far back as the early 20th century, British physician Archibald Garrod is credited with establishing a connection between nutrition, genetics, and phenotype.
The Human Genome Project of the 1990s, which mapped out human DNA, paved the way for the modern era of nutrigenomics. Since then, hundreds of studies have examined genes’ influence on the body’s response to diet, as well as the other way around.
Today, it’s not uncommon for practitioners like dietitians and doctors to use genetic testing to assess patients’ dietary needs and set customized health goals.
Benefits
Genetic testing as part of nutrition counseling might sound rather extreme. A genetic workup just to see if you should eat low carb or get more vitamin C?
However, as part of an integrative nutrition approach, nutrigenomics can shed light on issues a simple health history can’t. This includes everything from a predisposition to heart disease to why you’re not losing weight when you’ve tried everything.
“Genomic testing truly is useful for anyone wanting to be proactive about their health,” says dietitian and certified genomic medical clinician Andrea Chernus, MS, RD, CGMC. “Genomic testing can help to explain why situations exist for a patient, such as which style of eating might suit them best.”
By looking at your genetic makeup, a practitioner may be able to advise you on certain eating patterns that will or won’t work well for you. For example, gene variants might mean your body wouldn’t benefit from a vegan diet or wouldn’t adapt well to a keto diet due to genomic tendencies for fat metabolism.
A nutrigenomic test can even uncover your personal best sources of both macro- and micronutrients.
Perhaps your body is unable to optimally use omega-3 fatty acids from plant sources, or you have trouble converting sunshine into vitamin D. With this data, a trained practitioner can instruct you on which foods to eat or supplements to take to meet your needs.
Likewise, predispositions toward certain diseases may show up on a nutrigenomics test.
“We may be able to see gene variants that increase one’s risk for breast cancer due to the genes involved in estrogen metabolism, for example,” Chernus notes. Heart disease, diabetes, obesity, and mental health have all been linked to genetic expressions, and all have dietary prevention strategies.
Empowered with this information, you can make preventative choices to mitigate risk through diet.0 seconds of 0 secondsVolume 0%
What to expect
Interested in pursuing a genetic approach to nutrition, but not sure what to expect? Nutrition counseling using nutrigenomics is surprisingly painless.
“The experience should start with a detailed health questionnaire so the practitioner has a complete understanding of the patient’s health status, history, family history, and current and past lifestyles,” says Chernus. “The actual test involves an at-home cheek swab. It’s typical for a test to evaluate anywhere from 80 to 150 or more genes. It’s quite simple to do.”
In some cases, if your results raise additional questions, a blood test may follow.
Once your test results are back, your dietitian or other health professional will evaluate them and work with you to develop an action plan for eating.
Potential drawbacks of nutrigenomics
Although extensive research has been conducted on the connection between genetics, diet, and health, the science of nutrigenomics is still emerging. “Nutrigenomics is a relatively new field of research, so we still have a lot to learn,” says Lim.
This isn’t to say that genetics aren’t a helpful piece of the puzzle when it comes to nutrition counseling. Just recognize that nutrigenomics won’t solve every diet conundrum, and that genes are just one of many factors that influence health and ideal dietary choices.
“Genomic testing should not be the sole criteria used to make recommendations,” says Chernus. “We need to include lifestyle, health history, health status, personal preferences, cultural identity, willingness of the patient to change, and their own health goals in our work.”
The availability of direct-to-consumer genetic testing for diet purposes, while it may seem exciting and convenient, is another potential drawback.
“The main drawback [of these tests] is that they’re not interpreted by a skilled clinician,” Chernus says. “Skilled practitioners use a polygenic approach: how all of the genes are part of bigger systems in the body. They interpret how these systems work together in the totality of one’s health.”
To understand the relationship between your own genome and diet, it’s always best to consult with a health professional who specializes in nutrition genetics.
Nutritional genomics, also known as nutrigenomics, is a science studying the relationship between human genome, human nutrition and health. People in the field work toward developing an understanding of how the whole body responds to a food via systems biology, as well as single gene/single food compound relationships. Nutritional genomics or Nutrigenomics is the relation between food and inherited genes, it was first expressed in 2001.
Introduction
The term “nutritional genomics” is an umbrella term including several subcategories, such as nutrigentics, nutrigenomics, and nutritional epigenetics. Each of these subcategories explain some aspect of how genes react to nutrients and express specific phenotypes, like disease risk. There are several applications for nutritional genomics, for example how much nutritional intervention and therapy can the successfully used for disease prevention and treatment.
Background and preventive health
Nutritional science originally emerged as a field that studied individuals lacking certain nutrients and the subsequent effects, such as the disease scurvy which results from a lack of vitamin C. As other diseases closely related to diet (but not deficiency), such as obesity, became more prevalent, nutritional science expanded to cover these topics as well. Nutritional research typically focuses on preventative measure, trying to identify what nutrients or foods will raise or lower risks of diseases and damage to the human body.
For example, Prader–Willi syndrome, a disease whose most distinguishing factor is insatiable appetite, has been specifically linked to an epigenetic pattern in which the paternal copy in the chromosomal region is erroneously deleted, and the maternal loci is inactivated by over methylation. Yet, although certain disorders may be linked to certain single-nucleotide polymorphisms (SNPs) or other localized patterns, variation within a population may yield many more polymorphisms.
Applications
The applications of nutritional genomics are multiple. With personalized assessment some disorders (diabetes, metabolic syndrome) can be identified. Nutrigenomics can help with personalized health and nutrition intake by assessing individuals and make specific nutritional requirements. The focus is in the prevention and the correction of specific genetic disorders. Examples of genetic related disorders that improve with nutritional correction are obesity, coronary heart disease (CHD), hypertension and diabetes mellitus type 1. Genetic disorders that can often be prevented by proper nutritional intake of parents include spina bifida, alcoholism and phenylketouria.
Coronary heart disease
Genes tied to nutrition manifest themselves through the body’s sensitivity to food. In studies about CHD, there is a relationship between the disease and the presence of two alleles found at E and B apolipoprotein loci. These loci differences result in individualized reactions to the consumption of lipids. Some people experience increased weight gain and greater risk of CHD whereas others with different loci do not. Research has shown a direct correlation between the decrease risk of CHD and the decrease consumption of lipids across all populations.
Obesity
Obesity is one of the most widely studied topics in nutritional genomics. Due to genetic variations among individuals, each person could respond to diet differently. By exploring the interaction between dietary pattern and genetic factors, the field aims to suggest dietary changes that could prevent or reduce obesity.
There appear to be some SNPs that make it more likely that a person will gain weight from a high fat diet; for people with AA genotype in the FTO gene showed a higher BMI compared those with TT genotype when having high fat or low carbohydrate dietary intake. The APO B SNP rs512535 is another diet-related variation; the A/G heterozygous genotype was found to have association with obesity (in terms of BMI and waist circumference) and for individuals with habitual high fat diet (>35% of energy intake), while individuals with GG homozygous genotype are likely to have a higher BMI compared to AA allele carriers. However, this difference is not found in low fat consuming group (<35% of energy intake).
Phenylketonuria
Phenylketonuria, otherwise known as PKU, is a uncommon autosomal recessive metabolic disorder that takes effect postpartum but the debilitating symptoms can be reversed with nutritional intervention