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Ch. 18 - Genomics, Bioinformatics, and Proteomics
Klug - Essentials of Genetics 10th Edition
Klug10th EditionEssentials of GeneticsISBN: 9780135588789Not the one you use?Change textbook
All textbooksKlug 10th EditionCh. 18 - Genomics, Bioinformatics, and ProteomicsProblem 14
Chapter 18, Problem 14

Explain differences between whole-genome sequencing (WGS) and whole-exome sequencing (WES), and describe advantages and disadvantages of each approach for identifying disease-causing mutations in a genome. Which approach was used for the Human Genome Project?

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Start by defining Whole-Genome Sequencing (WGS) as the process of determining the complete DNA sequence of an organism's genome at a single time, which includes both coding (exons) and non-coding regions (introns, regulatory sequences, intergenic regions).
Define Whole-Exome Sequencing (WES) as a targeted sequencing approach that focuses only on the exons, the protein-coding regions of the genome, which represent about 1-2% of the entire genome but contain a high proportion of known disease-causing mutations.
Compare the advantages of WGS: it provides a comprehensive view of the entire genome, allowing detection of mutations in coding and non-coding regions, structural variants, and regulatory elements. However, it is more expensive and generates a larger amount of data that requires more complex analysis.
Compare the advantages of WES: it is more cost-effective and faster than WGS, focusing on regions most likely to contain disease-causing mutations, which simplifies data analysis. The disadvantage is that it misses mutations outside the exons, such as those in regulatory or intronic regions that can also affect gene function.
Explain that the Human Genome Project primarily used a whole-genome sequencing approach to map the entire human genome, as its goal was to obtain a complete reference sequence rather than focusing only on coding regions.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Whole-Genome Sequencing (WGS)

WGS involves sequencing the entire DNA content of an organism's genome, including coding and non-coding regions. It provides a comprehensive view of all genetic variations, enabling detection of mutations anywhere in the genome. WGS is useful for discovering novel variants but is more expensive and generates large data sets requiring extensive analysis.
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Sequencing Overview

Whole-Exome Sequencing (WES)

WES targets only the exons, the protein-coding regions of the genome, which represent about 1-2% of the genome but harbor most known disease-causing mutations. It is more cost-effective and faster than WGS, focusing on regions most likely to affect protein function. However, it misses mutations in non-coding or regulatory regions.
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Sequencing Overview

Human Genome Project Sequencing Approach

The Human Genome Project primarily used whole-genome sequencing to map the entire human genome. This approach allowed comprehensive identification of all genetic elements, including coding and non-coding regions, providing a foundational reference for human genetics. The project’s scale and technology at the time made WGS the suitable choice.
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Human Genome Composition
Related Practice
Textbook Question

Recall that when the HGP was completed, more than 40 percent of the genes identified had unknown functions. The PANTHER database provides access to comprehensive and current functional assignments for human genes (and genes from other species).

Go to http://www.pantherdb.org/data/. In the frame on the left side of the screen locate the 'Quick links' and use the 'Whole genome function views' link to a view of a pie chart of current functional classes for human genes. Mouse over the pie chart to answer these questions. What percentage of human genes encode transcription factors? Cytoskeletal proteins? Transmembrane receptor regulatory/adaptor proteins?

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Textbook Question

The Human Genome Project has demonstrated that in humans of all races and nationalities approximately 99.9 percent of the genome sequence is the same, yet different individuals can be identified by DNA fingerprinting techniques. What is one primary variation in the human genome that can be used to distinguish different individuals? Briefly explain your answer.

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Textbook Question

Through the Human Genome Project (HGP), a relatively accurate human genome sequence was published from combined samples from multiple individuals. It serves as a reference for a haploid genome. How do results from personal genome projects (PGP) differ from those of the HGP?

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Textbook Question

Describe the significance of the Genome 10K project.

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Textbook Question

It can be said that modern biology is experiencing an 'omics' revolution. What does this mean? Explain your answer.

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Textbook Question

Metagenomics studies generate very large amounts of sequence data. Provide examples of genetic insight that can be learned from metagenomics.

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