MAKING LARVAE COUNT
Genetic barcodes are used to quantify crucial populations in a coral reef ecosystem
REHOVOT, ISRAEL—December 18, 2017— Almost all the wildly varied, colorful fish that populate coral reefs start life as tiny, colorless, tadpole-like larvae. Telling one from the other is nearly impossible – even for experts – and this presents a difficult challenge to those who study the ecology of the reefs. Prof. Rotem Sorek of the Weizmann Institute of Science; Prof. Roi Holzman of the School of Zoology and the Steinhardt Museum of Natural History, Tel Aviv University; and Dr. Moshe Kiflawi of Ben Gurion University have now produced a way to understand precisely which species of larvae are present in the water around reefs. Their study, which involved genetic “barcoding” of nearly all the fish species in the gulf between Eilat and Aqaba, not only showed which larvae were in the gulf, but how many of each were swimming around, at what time of year, and at what depths. This study was published in the journal Nature Ecology and Evolution.
“Understanding the types and distribution of the larvae is important for a number of reasons,” says Prof. Holzman. He and Dr. Kiflawi are resident researchers at the Interuniversity Institute for Marine Sciences (IUI) in Eilat. For one, it is only the larvae that disperse, washed by currents and flows, while adult reef fish tend to stay close to their home reef. To the marine ecologists who monitor the larvae, they are an integral part of the ecosystem – as well as its future. And since larvae numbers can reveal something about the prospective populations of adult fish, monitoring them might be useful to fishery management as well.
The researchers used the IUI’s research vessel, which is equipped with sophisticated gear that can sample larvae from set depths. They sampled larvae twice a month over the course of a full year at various sites and depths near the two coasts of the narrow gulf, as well as in its deep middle. “We had over 10,000 sampled larvae,” says Dr. Kiflawi, “but current techniques involve inspecting larvae under a microscope and counting their spines – which can point to the taxonomic family, but not the species, and also takes a lot of time. Luckily, we had discussed this with Sorek, who was then visiting the IUI.”
Prof. Sorek’s lab in Weizmann’s Department of Molecular Genetics normally deals with different genomes – those of bacteria. “I thought that the techniques from the genomic research we employ in my lab could determine the identity of larvae by sequencing a ‘barcode’ from their genomes,” he says. Research student Naama Kimmerling from Dr. Kiflawi’s lab, staff scientist Tamara Gurevitch from Prof. Holzman’s lab, research student Omer Zuqert and staff scientists Dr. Gil Amitai and Sarah Melamed from Prof. Sorek’s lab, together with their research groups and colleagues, adapted these techniques to identifying fish larvae.
“But before we could apply the method,” says Prof. Sorek, “we had to create a database of ‘barcodes’ for all the reef fish in the gulf. That was a feat in itself. For it, the team members took up diving in the gulf to clip the fins of adult fish for DNA analysis. Ultimately, we managed to create a database of barcodes for around 80% of the main fish species (420 of about 540) known to frequent the reef.” Genetic barcoding is a technique based on comparing the DNA of one specific gene, whose sequence varies from species to species. This convenient, very precise “labeling” technique has numerous uses in the world of biological research, and was an incontrovertible way to match larvae to their adult forms.
The sequencing of the larval genomes was conducted in the advanced facilities of the Stephen and Nancy Grand Israel National Center for Personalized Medicine on the Weizmann campus.
Until now, using barcoding to analyze large samples has been impractical. But in this study, all of the DNA in each sample was sequenced together using a “metagenomics” technique, whether the sample contained one individual or 500 larvae. “We invented a ‘trick’ that matches pictures of the larvae to their DNA sequence,” says Prof. Sorek, “and this enabled us to tell exactly how many individual larvae of each species were in the sample. But to get that one for each, we had to sequence trillions of DNA bases.”
Altogether, the team sequenced the genomes of around 10,000 larvae in 400 different samples. Ultimately, they created a sort of map that could tell them, species by species, how many could be found, at what time of year, at which particular location and depth.
“Because we could now analyze thousands of larvae at a much finer resolution than was previously possible,” says Dr. Kiflawi, “we could now zoom in on ecological differences between species. If the larvae of one family of fish had been presumed to live in both shallow and deep waters, we could now see that some species in the family prefer the shallow waters, while others prefer deeper waters – a difference that can affect their survival and dispersal.”
The findings also solved several mysteries – for example, the invasion into the Mediterranean of a small puffer fish known as a Spiny blaasop. The adult fish live at depths of several hundred meters, yet they presumably cross over through the Suez Canal, which is only around 25 meters (82 feet) deep. The study shows that the larvae can dwell in the shallows, and it is probably these that have moved along the shipping lanes. The sampling also turned up larvae of fish that are found farther south in the Red Sea, but not in the gulf. This finding raised new questions about why these larvae do not make it to adulthood there.
“Although the initial process was a bit arduous,” says Prof. Sorek, “we now have an excellent tool for monitoring the health of the reef ecosystem, and other reef researchers may follow suit.”
Prof. Rotem Sorek’s research is supported by the David and Fela Shapell Family Foundation INCPM Fund for Preclinical Studies; the Y. Leon Benoziyo Institute for Molecular Medicine; the Dana and Yossie Hollander Center for Structural Proteomics; the Abisch Frenkel Foundation for the Promotion of Life Sciences; the Leona M. and Harry B. Helmsley Charitable Trust; Martin Kushner Schnur; and the European Research Council.
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The Weizmann Institute of Science in Rehovot, Israel, is one of the world’s top-ranking multidisciplinary research institutions. The Institute’s 3,800-strong scientific community engages in research addressing crucial problems in medicine and health, energy, technology, agriculture, and the environment. Outstanding young scientists from around the world pursue advanced degrees at the Weizmann Institute’s Feinberg Graduate School. The discoveries and theories of Weizmann Institute scientists have had a major impact on the wider scientific community, as well as on the quality of life of millions of people worldwide.