Introduction

Now that the Human Genome and the HapMap Projects have been completed, the international scientific community is turning its attention to the 1000 Genomes Project [1], an international collaboration between China, Germany, the UK, and the USA. The initial goal was to discover most of the genetic variation that occurs at a population frequency greater than 1% by deep sequencing at least 1,000 individuals from different worldwide populations using next-generation platforms and technologies. The genomes of approximately 2,000 individuals, from at least 20 different populations representing Africa, Europe, East Asia, and the Americas, are being collected and sequenced. The populations included will each have approximately 60 to 100 samples sequenced. For some populations, trios (both biological parents and an adult child) have been collected. Many of the samples, including some from the children, are going to be densely genotyped using genome-wide arrays. The goal of this study design is to reconstruct the parental chromosomal phase using the information provided by the child.

Discussion

Promising results have already arisen from the Pilot 1 analysis, which has been referred to as the '1000 Genomes Low Coverage Pilot'. This analysis consists of 180 individuals from the four original HapMap populations sequenced at 2× to 4× coverage, meaning that an average number of two to four sequences are generated for every genomic position. In this initial phase, more than 9 million new single-nucleotide poly mor phisms (SNPs), many novel indels (insertions/deletions), and some large structural variants have been identified.

The results that arise from the completion of this project will lead to a great leap in our knowledge of human genetic variation. At first, the results will allow scientists to identify population-specific genetic variation at an unprecedented degree of resolution. Of the 9 million novel SNPs identified so far from Pilot 1 analysis alone, approximately 8 million are seen in only one HapMap population. Most common variants have already been identified; the novel variants are disproportionately rare and thus more likely to be observed in only one of the studied populations. The identification of these variants will help the development of new population-specific genotyping arrays. This will maximize genome coverage while minimizing the ascertainment bias that affects currently available arrays, especially for non-European populations. This unbiased survey of polymorphism in diverse groups will also help improve the imputation methods for genetic variants that are not represented on current arrays.

In addition to improving the resolution of population genetics, the clinical implications are endless. For example, genome-wide association studies (GWASs) are now routinely used to identify genomic regions associated with common human diseases. However, these studies rarely identify the precise causative genes or sequence variants. The reason for this is that the human genome contains regions of strong linkage disequilibrium, and a disease-associated locus can encompass several genes and multiple tightly associated polymorphisms. In addition, current arrays emphasize so-called 'tag SNPs', or SNPs that are highly correlated with their local linkage disequilibrium structure to provide more even coverage across the genome. These SNPs can usually be found in introns or intergenic regions, not coding regions or known regulatory elements that are likely to be functional. This makes it difficult to pinpoint causal variants by association mapping using genotyping arrays alone. Deep sequencing studies will identify novel or rare functional variants, thereby allowing scientists to find all potential disease-causing variants and genes. However, the strong associations among genetic variants in a given genomic region will require experimental studies to be performed to determine which of the associated genetic variants are actually functionally causal. Recent work has shown on a small level that resequencing of candidate regions from GWASs can often uncover rarer variants with higher effects and more direct functional consequences in common diseases [2].

The unprecedented level of sequence information that will arise from the 1000 Genomes Project will also improve our knowledge of genomic configurations that were shaped by evolutionary processes. For example, analyses of the distribution of SNP density along chromosomes will inform us about chromosomal regions that are more susceptible to selective pressures or differential patterns as a result of the expansion of humans throughout different continents. Recent findings from exonic resequencing have shown that patterns of population-specific rare, deleterious mutations (such as those that cause Mendelian recessive diseases) in coding regions can be largely explained by historical processes affecting specific populations [3]. However, understanding how these processes occur, which genes are affected, and which other populations in the future could have a higher prevalence of diseases caused by rare variants requires a large-scale resource for validation of population genetics methods, a resource such as the 1000 Genomes Project. The samples that are included in the 1000 Genomes Project do not have identifying information, phenotypes, or clinical data available. The project is providing a resource about human genetic variation that will be used in many studies of particular phenotypes, such as complex diseases or drug response.

The availability of full genome sequences from worldwide samples will directly improve the accuracy of direct-to-consumer genetic ancestry tests. Medical applications, such as determining drug efficacy and/or toxicity and prediction of disease and prognosis, will need further deep sequencing in clinical projects before public benefits from these new technologies are developed. The attention from the media will probably increase the public's expectations of the 1000 Genomes Project and its potential applications. However, scientists should take advantage of the increased public awareness to highlight the importance of genetic research and to encourage the participation of all communities in future research. Larger follow-up studies will be needed to achieve the required statistical power to establish conclusions in datasets that will include billions of variables integrating genomic data with future transcriptomic, proteomic, and epigenetic information.

The recent improvements in sequencing technology, which allow the sequencing of samples for the 1000 Genomes Project, presage the forthcoming availability of whole genome sequences at affordable prices. The sequencing of individual genomes raises concerns about potential threats to privacy and other ethical issues. Although the USA recently passed the Genetic Infor mation Nondiscrimination Act (GINA), prohibiting genetic discrimination in employment and health insurance [4], the protection of individual rights varies from country to country. For example, the European Commission strongly recommends the prevention of discrimination as a result of genetic testing in insurance and employment [5]. However, the EU does not have uniform legislation regarding whether it is legal for insurance companies or employers to access genetic testing results or other medical records. Rather, the decision on whether to legislate the use of genetic test results has been left to the discretion of each individual country.

Conclusions

The information that the 1000 Genomes Project and the next generation of deep sequencing platforms will provide is unprecedented and will have important implications for genetics and healthas we move closer and closer to the era of the ubiquitous personal genome as part of our medical record.

Despite our best intentions, history has demonstrated that it will be very difficult to get the genie back into the bottle once it is opened. This is has been true for all scientific and medical advances. Although there are potential social costs associated with linking informative genetic data to individuals or populations, we believe that these potential costs are outweighed by the benefits in terms of diagnosis and research. Scientists should continue to use the genetic diversity that exists within humans as starting points for further research. We cannot stall scientific progress for fear of potential misuses of knowledge. Rather, we should keep rigorous safeguards in place to ensure that scientific advancements proceed and serve to benefit all humanity. Finally, it is important to establish a fluent communication with the general public and engage participation in genetic research.