Experimental Evolution

Selection and Fitness

Mutation

Evolutionary Patterns

Methods

100

These organisms are often used in evolutionary experiments because of their ability to rapidly reproduce.

Microbes

100

This evolutionary force favors organisms with traits better suited for survival.

Natural selection

100

In this process primarily present in asexual populations, beneficial mutations compete with each other.

Clonal interference

100

These specific phenotypic changes were seen in the LTEE.

Increased biofilm production, higher metabolic capacity, cell size gains, thermal tolerance

100

This process involves transferring a small fraction of a microbial population into fresh medium each day

Serial transfer

200

The Long-Term Evolutionary Experiment (LTEE) uses this species of bacteria.

E. coli

200

This coefficient measures the fitness of a certain mutation in a population.

Selection coefficient (s)

200

These DNA changes create genetic variation and can be beneficial, harmful, or neutral

mutations

200

This evolutionary pattern occurs when the same mutation appears independently in multiple populations

parallel evolution

200

These population reductions occur during daily transfers and increase the effects of genetic drift

population bottlenecks

300

Evolutionary experiments often start with this type of strain so that the starting genetics of the organism are known.

Ancestral strain

300

When the product of effective population size and selection coefficient is much greater than one, this evolutionary force dominates over genetic drift

Natural Selection

300

In rapidly growing microbial populations, this biological process is responsible for generating most new mutations

DNA replication

300

This is common in asexual populations where beneficial mutations compete against each other because recombination cannot combine them

clonal interference

300

This technology allows researchers to identify mutations in evolved populations.

genome sequencing

400

This type of media is used to transfer and grow E. coli in the LTEE.

Glucose minimal media

400

This term describes the process where a mutation reaches a frequency high enough to escape loss by genetic drift.

mutation establishment

400

This type of mutation improves an organism’s fitness and is likely to increase in frequency through natural selection

Beneficial Mutation

400

In the LTEE, some evolved E. coli developed this structural lifestyle that increases surface attachment and community growth

biofilm formation

400

This famous experiment started in 1988 and continues today with E. coli populations evolving for tens of thousands of generations

Long-Term Evolution Experiment

500

This method combines evolution experiments with genome sequencing to identify adaptive mutations in populations

evolve-and-resequence

500

This variable represents the effective number of individuals contributing genes to the next generation.

effective population size (Ne)

500

Because bacteria divide rapidly, experimental populations can generate thousands of new mutations during this time period

a single generation

500

When a mutation spreads through a population until every individual carries it, this evolutionary outcome has occurred

fixation

500

This bacterial species is used in the LTEE because it grows quickly and is easy to culture in the lab.

Escherichia coli