Skip to main content
Pearson+ LogoPearson+ Logo
Ch. 15 - Recombinant DNA Technology and Its Applications
Sanders - Genetic Analysis: An Integrated Approach 3rd Edition
Sanders3rd EditionGenetic Analysis: An Integrated ApproachISBN: 9780135564172Not the one you use?Change textbook
All textbooksSanders 3rd EditionCh. 15 - Recombinant DNA Technology and Its ApplicationsProblem 34
Chapter 15, Problem 34

Would a gene drive system spread rapidly through a population in a species that tends to self-mate (e.g., Arabidopsis, C. elegans)? In a species in which the breeding cycle is slow (e.g., humans)?

Verified step by step guidance
1
Understand the concept of a gene drive system: A gene drive is a genetic engineering technology that promotes the inheritance of a particular gene to increase its prevalence in a population, even if it provides no selective advantage. It works by biasing the inheritance process during reproduction.
Consider the impact of self-mating species: In species that predominantly self-mate, such as Arabidopsis or C. elegans, genetic diversity is limited because offspring inherit nearly identical genetic material from the parent. Gene drives rely on heterozygosity (having different alleles at a locus) to spread effectively. Therefore, self-mating species may limit the efficiency of gene drive systems.
Analyze the breeding cycle speed: In species with slow breeding cycles, such as humans, the spread of a gene drive would be slower because fewer generations occur over a given time period. Gene drives rely on successive generations to propagate the engineered gene, so a slow breeding cycle would delay its spread.
Evaluate the interaction between mating system and breeding cycle: The effectiveness of a gene drive system depends on both the mating system and the breeding cycle. In self-mating species, the gene drive may struggle to spread due to limited genetic mixing. In species with slow breeding cycles, the spread would be delayed, but genetic mixing (e.g., sexual reproduction) could still facilitate its propagation over time.
Conclude with the implications for gene drive design: For self-mating species, alternative strategies such as targeting specific loci or using synthetic gene drives tailored to their reproductive biology may be necessary. For species with slow breeding cycles, long-term monitoring and modeling would be required to predict the spread and impact of the gene drive system.

Verified video answer for a similar problem:

This video solution was recommended by our tutors as helpful for the problem above.
Video duration:
1m
Was this helpful?

Key Concepts

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

Gene Drive System

A gene drive system is a genetic engineering technology that promotes the inheritance of a particular gene to increase its prevalence in a population. This is achieved by biasing the normal Mendelian inheritance patterns, allowing the modified gene to be passed on to a greater proportion of offspring. Gene drives can be used for purposes such as controlling pest populations or spreading beneficial traits.
Recommended video:
Guided course
09:09
Mapping Genes

Self-Mating and Reproductive Strategies

Self-mating, or self-fertilization, occurs when an organism fertilizes its own eggs, leading to reduced genetic diversity. In species like Arabidopsis and C. elegans, self-mating can facilitate the rapid spread of gene drives since the modified gene can be directly passed to all offspring. Understanding the reproductive strategy of a species is crucial for predicting how quickly a gene drive might disseminate within a population.
Recommended video:
Guided course
07:55
Non-Random Mating

Population Dynamics and Breeding Cycles

Population dynamics refers to the changes in population size and composition over time, influenced by factors such as reproduction rates and lifespan. In species with slow breeding cycles, like humans, the spread of a gene drive would be slower due to longer generation times and lower reproductive rates. This concept is essential for assessing the potential impact and effectiveness of gene drives in different species.
Recommended video:
Guided course
04:29
Bacteriophage Life Cycle
Related Practice
Textbook Question

You have cloned a gene for an enzyme that degrades lipids in a bacterium that normally lives in cold temperatures. You wish to transfer this gene into E. coli to produce industrial amounts of enzyme for use in laundry detergent.

You have managed to produce transgenic E. coli expressing mRNA of your gene, but only a low level of protein is produced. Why might this be so? How could you overcome this problem?

529
views
Textbook Question
About 1% of occurrences of nonautoimmune type 1 diabetes are due to loss-of-function alleles in the insulin gene. Individuals heterozygous for such mutations develop diabetes as infants or in the first few years of their lives. Outline how you might approach gene therapy for such a disease and what difficulties you might encounter.
396
views
Textbook Question

Describe how having the Cas9 gene at a genomic locus unlinked to the guide RNA and target site locus in an engineered gene drive system could slow the propagation of the gene drive allele in a population into which a small number of individuals carrying both the gene drive allele and the Cas9 locus are released.

471
views