African cichlid fishes are some of the most diverse organisms on the planet, with more than 2,000 known species.
Some African lakes are home to hundreds of distinct species that evolved from a common ancestral species in the Nile River. Like Darwin’s finches, the cichlids are a dramatic example of adaptive radiation, the process by which multiple species radiate from an ancestral species through adaptation.
Researchers sequenced the genomes of five species of African cichlid fishes and identified a variety of features that enabled them to evolve and thrive in new habitats and ecological niches within the Great Lakes of East Africa.
“Our study reveals a spectrum of methods that nature uses to allow organisms to adapt to different environments,” says co-senior author Kerstin Lindblad-Toh, scientific director of vertebrate genome biology at the Broad Institute of Harvard and MIT.
“These mechanisms are likely also at work in humans and other vertebrates, and by focusing on the remarkably diverse cichlid fishes, we were able to study this process on a broad scale for the first time.”
The work was a collaboration between the Broad Institute, the Georgia Institute of Technology, and the Eawag Swiss Federal Institute for Aquatic Sciences, involving more than 70 scientists from the international cichlid research community. The new study appears in the journal Nature.
The sequenced species include the Nile tilapia, representing the ancestral lineage, and four East African species: a species that inhabits a river near Lake Tanganyika; a species from Lake Tanganyika colonized 10-20 million years ago; a cichlid species from Lake Malawi colonized 5 million years ago; and species from Lake Victoria where the fish radiated only 15,000 to 100,000 years ago.
Reservoir of mutations
The researchers found a number of genomic changes at play in the adaptive radiation. Compared to the ancestral lineage, the East African cichlid genomes possess an excess of gene duplications, alterations in regulatory elements in the genome, accelerated evolution of protein-coding elements in genes for pigmentation, and other distinct features that affect gene expression.
“It’s not one big change in the genome of this fish, but lots of different molecular mechanisms used to achieve this amazing adaptation and speciation,” says Federica Di Palma, co-senior author of the study and director of science in vertebrate and health genomics at The Genome Analysis Center in the UK.
Some changes in the genome appear to have accumulated before the species left the rivers to colonize lakes and radiated into hundreds of species.
This suggests that the cichlids were once in a period of reduced constraint. During this time, the fishes accumulated diversity through genetic mutations, and the relaxed constraint—in which all individuals thrived, not just the fittest—allowed genetic variation to accumulate.
As the fish later inhabited new environmental niches within the lakes, new species could form quickly through selection. In this way, a reservoir of mutations—and resultant phenotypes—represented a genomic toolkit that allowed quick adaptation.
More work remains to fully dissect the mutations that cause each of the varying phenotypes in cichlid fish, which could help explain how similar forms or traits evolved in parallel in different lakes.
“By learning how natural populations, such as fishes, adapt and evolve under selective pressures, we can learn how these pressures affect humans in terms of health and disease,” Di Palma says.
Todd Streelman, professor in the School of Biology at Georgia Tech and a co-author of the study, studies Lake Malawi cichlid species to address biological questions that are difficult to study in traditional model organisms.
“These fishes provide a great way to identify the genes that control traits in natural populations,” Streelman says. “Now that we understand the genome sequences of some of these species, it’s a lot easier to interpret all of the new genetic and genomic data we collect in the lab.”
His lab studies natural mechanisms of lifelong tooth replacement and the genomics of complex social behavior using closely-related Malawi cichlids. The new genome sequence of the Lake Malawi cichlid will allow Streelman’s lab to investigate which genes are turned on or off during these processes. Streelman’s research group cultures roughly 25 different Malawi cichlid.
The National Human Genome Research Institute, the Swiss National Science Foundation, the German Science Foundation, Biomedical Research Council of A*STAR-Singapore, the European Research Council, US National Institute of Dental and Craniofacial Research, and the Wellcome Trust partially funded the research.
Source: Georgia Tech