Towards early prevention of lifestyle related diseases – a cohort study starting at the fetal stage

Q. (to Dr. Sakurai) Firstly, we would like to know about the cohort study in which the Center for Preventive Medical Sciences, Chiba University and you are involved.

A. We have been carrying out a cohort study from the fetal stage to childhood to investigate the effects of their environment on one’s health (Sakurai).

Q. (to Dr. Sakurai) What research are you currently involved in?

A. I am investigating the association of the environment in the fetal stage and DNA methylation and how it can affect obesity and diabetes (Sakurai).

I am currently focusing on the association between DNA methylation in the fetal stage and childhood disease, using Infinium™ MethylationEPIC BeadChip

The concept that “Developmental Origins of Health and Disease” (DOHaD), where environmental factors during the fetal and early stages of development are contributors to the risk factors of disease in adulthood has been gathering attention. “Epigenome”, which includes DNA methylation, histone acetylation, and miRNA modification has become the buzzword. Initial results from the cohort study showed that a low birth weight was associated with various diseases such as coronary artery disease, respiratory disease, and kidney diseases in adulthood.

I specialize in metabolic diseases such as diabetes and obesity, and research how the environment in the fetal stage and methylation are connected to diabetes and obesity in adulthood. It has been suggested that not only nutrition, but also chemical substances play a role in the development of diabetes and obesity, and therefore, environmental factors also constitute an important area of research.

Prevention of diseases from the fetal stage is the objective of both the EcoChil study and C-MACH. If the relationship between methylation in the fetal stage or immediately after birth and childhood obesity is understood, there may be a possibility of preventing the development of obesity and diabetes in the future. This could eventually lead to prevention of these diseases before birth.

As for information on methylation with regard to diabetes, several reports are available on the umbilical cord blood and peripheral blood of adults. However, reports relating to the umbilical cord itself are currently unavailable. Moreover, the tissue of the umbilical cord includes many mesenchymal stem cells. Since adipocytes are also included in the mesenchyme, the utility of the umbilical cord is being focused upon.

Another factor associated with DOHaD is the gut microbiota. The gut microbiota is transmitted from the mother to the child at the time of birth, and since families eat similar food, the influence of the parents can also be seen on the gut microbiota. As such, stool samples collected in C-MACH are used to also conduct research on the gut microbiota as well as on diabetes and obesity.

Q. (to Dr. Kamatani) What are the focuses of your research?

A. I am analyzing the traits of the complex association between multiple factors by using big data (Kamatani).

Q. (to Dr. Kamatani) You have been involved in the design of the SNP array which has been optimized for genome analysis in Japanese populations "Infinium Japanese Screening Array（JSA)” I believe you are currently conducting a study, together with Dr. Sakurai, by using this microarray.

A. I investigated the association between DNA methylation and SNP in some of the samples of C-MACH (Kamatani).

Kamatani: I was invited by Prof. Matsuda Fumihiko of the Graduate School of Medicine, Kyoto University, and worked with him in improving the imputation performance on polymorphisms in Japanese populations by modifying a part of the Infinium Asian Screening Array（ASA) Genome data forms the basis of the multi-layered omics research, and by combining various types of data, the interpretation range of research results becomes extremely vast. It is therefore important that a low-cost array with high accuracy is used. I think that the genome data of the Japanese will appear sharper by JSA.

Through a joint study with Dr. Sakurai, we are investigating the association between methylation of the samples of C-MACH and the genome information using EPIC and JSA. From the umbilical cord tissue of 91 people, we have identified the loci influencing the DNA methylation condition and have obtained results by which we can make an interpretation. Generally, it is difficult to obtain effective analysis results through analysis of the SNP array of 100 people, however, by combining with methylation, it is possible to achieve statistical significance even if the sample size is small.

Q. What do you think about the importance of combining the genome information, DNA methylation information, and the results of cohort study?

A. By combining the information about the genome, epigenome, disease, and the cohort study, the origin of the disease can be better understood (Sakurai).

Sakurai: Some people will get sick and others will not regardless of genetic predisposition. To understand this process, the genome information that forms the basis is of utmost importance. Information of environmental exposure, and the epigenome such as DNA methylation are also important factors. Since methylated DNA is retained for a longer time, if the tendency of onset of disease can be found from DNA methylation in the fetal stage, immediately after birth, or in childhood, it may be possible to prevent the disease. I think that by combining information about the genome and epigenome, environmental factors, and tracking this information through a cohort study over an extended period of time, we can get a better understanding of the prognosis.

Kamatani: A genome is complete at the time of fertilization. However that genomes are related to adult illness imply that the various stages from fertilization to adulthood can contribute to clinical conditions. Generally, adult data is collected in human genome research targeting adult illnesses. For example, even if specific methylation known from the umbilical cord blood is related to an illness, it cannot be seen in the adult genome research. Through the comparison between the genome analysis after reaching adulthood and the genome analysis of the umbilical cord blood, the relationship between the effect of the environment in the fetal stage or immediately after birth and the illness is better understood.

Sakurai: In the birth cohort study being conducted currently, the chemical substances of the samples of children and parents and various other types of information is gathered and accumulated in a database. Since we can investigate the combination between the genome and the exposome elements that deal with the exposures that a human being experiences including food, medicines, ultraviolet rays, noise, chemical substances, proceeding with the genome research through the birth cohort study is a huge achievement.

Kamatani: There are some historical genetic variants that provide different levels of reactivity to some environmental substances that can affect human beings. It is highly possible that such genetic variations may be rare among human populations as a result of natural selection. On the other hand, there may be genetic factors that react intensely to new substances. If such genetic factors are found, a person having those genetic factors can observe caution when dealing with such substances. If the genome can be investigated, we can get the sharper results from epidemiology, and that would make it easier to implement the results in society.

Q. What are your views on the social implementation of the results of genome research?

A. It is important to make progress in social understanding of the genome itself and build a social system without discrimination (Kamatani).

Kamatani: Social implementation has several stages. In terms of making use of the genome data in medical care, the data is almost in the implementation stage for cancer and monogenic diseases. Cancer and genetic diseases are special in the sense that cancer is a disease in which the genome changes at a later stage and genetic diseases occur when an extremely large genetic mutation occurs at the time of birth.

Therefore, diagnosis and treatment using genomes are in the process of implementation. In addition, the genetic factors for diseases involving a large number of genes are also being understood. What is left is the need to make some progress in the technological and cost aspects, and I can see that we have reached the stage where we are devising the specific means of actual usage in the society.

It is often said that there isn’t enough awareness in society with regard to genomes, and therefore we must also put in efforts to bring about this awareness.

Sakurai: If the relationship between the genome, epigenome, and traits can be understood, it would be useful in preventing diseases, and if this knowledge can be applied to education, it would lead to good health for all citizens of the country.

Kamatani: Currently, due to the progress of science, the understanding of human beings has been changing in a fundamental manner, and what exactly a genome is needs to be understood not only by researchers, but also by society. Otherwise, we would be unable to figure out what we are doing in the clinical environment. It is also important to build a social system in which discrimination is not caused by the genome.

Q. What kind of research would you be carrying out in the future?

A. I plan to add the analysis of environmental factors, such as analysis of the air inside a room, and genomes, and believe that single-cell analysis would also be interesting (Sakurai).

Learn more about the products and systems mentioned in this article:

DNA methylation analysis tool Infinium MethylationEPIC BeadChip and SNP array optimized for genome analysis in Japanese populations Infinium Japanese Screening Array（JSA)