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Chapter 18: Problem 17

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

Short Answer

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Short Answer: Metagenomics is the study of genetic material directly recovered from environmental samples, allowing researchers to investigate uncultivated microorganisms' genomes. Genetic insights that can be learned from metagenomics include the identification of novel antibiotic resistance genes, the discovery of new enzymes with industrial applications, understanding microbial community function and diversity, and tracking disease-causing microbes in outbreaks.

Step by step solution

01

Understanding Metagenomics

Metagenomics is the study of genetic material directly recovered from environmental samples, which allows researchers to study the genomes of uncultivated microorganisms. It involves sequencing the genetic material obtained from a sample, without the need for individual organism isolation and culturing. This generates a large amount of sequence data from the diverse communities of microorganisms present in the sample.
02

Example 1: Identification of Novel Antibiotic Resistance Genes

Metagenomic studies can help identify previously unknown antibiotic resistance genes in microbial communities. By analyzing the sequence data, researchers can find genes that have similar sequences to known antibiotic resistance genes, or genes that have the potential to degrade antibiotics. This information can then be used to develop new strategies to combat antibiotic resistance.
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Example 2: Discovery of New Enzymes with Industrial Applications

Another genetic insight that can be gained from metagenomic studies is the identification of novel enzymes with potential industrial applications. Environmental samples often contain microorganisms that produce enzymes capable of degrading and transforming various substrates like cellulose or plastic. By studying the sequence data, researchers can discover genes that encode these potentially useful enzymes and further study their properties.
04

Example 3: Understanding Microbial Community Function and Diversity

Metagenomics can provide insights into the functional capabilities and diversity of microbial communities across different environments, such as the human gut, soil, and oceans. By analyzing the sequences, researchers can identify the types of microorganisms present, their relative abundances, and the metabolic pathways they possess. This information can help understand the role of microorganisms in various processes, such as nutrient cycling and maintaining ecosystem balance.
05

Example 4: Tracking Disease-Causing Microbes in Outbreaks

Metagenomics can be used to track the spread of infectious diseases caused by bacteria, viruses, and other microbes. In the event of an outbreak, the analysis of metagenomic data from affected individuals or environments can help identify the causative agent and its source. This information can help public health officials to implement strategies to control and prevent the spread of the disease.

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Most popular questions from this chapter

What are DNA microarrays? How are they used?

What is functional genomics? How does it differ from comparative genomics?

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

What is bioinformatics, and why is this discipline essential for studying genomes? Provide two examples of bioinformatics applications.

Annotation of the human genome sequence reveals a discrepancy between the number of protein-coding genes and the number of predicted proteins actually expressed by the genome. Proteomic analysis indicates that human cells are capable of synthesizing more than 100,000 different proteins and perhaps three times this number. What is the discrepancy, and how can it be reconciled?
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