RICHARDS Stephen's profile
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RICHARDS StephenORCID_LOGO

  • Human Genome Sequencing Center, Baylor College of Medicine, Houston, TX, United States of America
  • Arthropods, Bioinformatics, Evolutionary genomics, Structural genomics
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Recommendation:  1

Reviews:  0

Areas of expertise
I have a long history in genome sequencing and assembly, with a focus on arthropod genomics. My educational background is a B.Sc. in Biochemistry from Bath University, a PhD in Biochemistry and Cell Biology from Rice University. Work background includes a stint at Lawrence Berkeley National Lab with Susan Celniker and Gerry Rubin on the Drosophila Genome Project, and a long period with Richard Gibbs at the Baylor College of Medicine Human Genome Sequencing Center working on many projects, but a focus on insect genomes including Drosophila pseudoobscura, the Honey Bee, and man other speeches, as well as the Drosophila Genetic Reference Panel with Trudy Mackay. I am currently (2019) working with Harris Lewin at UC Davis to promote and execute the Earth BioGenome Project, which will revolutionize Biology overs the next decade.

Recommendation:  1

06 Feb 2024
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The need of decoding life for taking care of biodiversity and the sustainable use of nature in the Anthropocene - a Faroese perspective

Why sequence everything? A raison d’être for the Genome Atlas of Faroese Ecology

Recommended by based on reviews by Tereza Manousaki and 1 anonymous reviewer

When discussing the Earth BioGenome Project with scientists and potential funding agencies, one common question is: why sequence everything? Whether sequencing a subset would be more optimal is not an unreasonable question given what we know about the mathematics of importance and Pareto’s 80:20 principle, that 80% of the benefits can come from 20% of the effort. However, one must remember that this principle is an observation made in hindsight and selecting the most effective 20% of experiments is difficult. As an example, few saw great applied value in comparative genomic analysis of the archaea Haloferax mediterranei, but this enabled the discovery of CRISPR/Cas9 technology (1). When discussing whether or not to sequence all life on our planet, smaller countries such as the Faroe Islands are seldom mentioned. 
 
Mikalsen and co-authors (2) provide strong arguments to appreciate, investigate and steward genetic diversity, from a Faroese viewpoint, a fishery viewpoint, and a global viewpoint. As readers, we learn to cherish the Faroe Islands, the Faroese, and perhaps by extension all of nature and the people of the world. The manuscript describes the proposed Faroese participation in the European Reference Genome Atlas (ERGA) consortium through Gen@FarE – the Genome Atlas of Faroese Ecology. Gen@FarE aims to: i) generate high-quality reference genomes for all eukaryotes on the islands and in its waters; ii) establish population genetics of all species of commercial or ecological interest; and iii) establish a “databank” for all Faroese species with citizen science tools for participation.


In the background section of the manuscript, the authors argue that as caretakers of the earth (and responsible for the current rapid decrease in biodiversity), humanity must be aware of the biodiversity and existing genetic diversity, to protect these for future generations. Thus, it is necessary to have reference genomes for as many species as possible, enabling estimation of population sizes and gene flow between ecosystem locations. Without this the authors note that “…it is impossible to make relevant management plans for a species, an ecosystem or a geographical area…”. Gen@FarE is important. The Faroe nation has a sizable economic zone in the North Atlantic and large fisheries. In terms of biodiversity and conservation, the authors list some species endemic to other Faroe islands, especially sea birds. The article discusses ongoing marine environmental-DNA-based monitoring programs that started in 2018, and how new reference genome databases will help these efforts to track and preserve marine biodiversity. They point to the lack of use of population genomics information for Red List decisions on which species are endangered, and the need for these techniques to inform sustainable harvesting of fisheries, given collapses in critical food species such as Northwest Atlantic cod and herring. In one example, they highlight how the herring chromosome 12 inversion contains a “supergene” collection of tightly linked genes associated with ecological adaptation. Genetic tools may also help enable the identification and nurturing of feeding grounds for young individuals. Critically, the Faroe Islands have a significant role to play in protecting the millions of tons of seafood caught annually upon which humanity relies. As the authors note, population genomics based on high-quality reference sequences is “likely the best tool” to monitor and protect commercial fisheries. There is an important section discussing the role of interactions between visible and “invisible" species in the marine ecosystem on which we all depend. Examples of “invisible” species include a wide range of morphologically similar planktonic algae, and invasive species transported by ballast water or ship hulls.​ As biologists, I believe we forget that our population studies of life on the earth have so far been mostly in the dark. Gen@FarE is but one light that can be switched on. 


The authors conclude by discussing Gen@FarE plans for citizen science and education, perhaps the most important part of this project if humanity is to learn to cherish and care for the earth. Where initiatives such as the Human Genome Project did not need the collaborative efforts of the world for sample access, the Earth BioGenome Project most certainly does. In the same way, at a smaller scale, Gen@FarE requires the support and determination of the Faroese. 
 


References    

1          Mojica, F. J., Díez-Villaseñor, C. S., García-Martínez, J. & Soria, E. Intervening sequences of regularly spaced prokaryotic repeats derive from foreign genetic elements. J Mol Evol 60, 174-182 (2005).

2          Mikalsen, S-O., Hjøllum, J. í., Salter, I., Djurhuus, A. & Kongsstovu, S. í. The need of decoding life for taking care of biodiversity and the sustainable use of nature in the Anthropocene – a Faroese perspective. EcoEvoRxiv (2024), ver. 3 peer-reviewed and recommended by Peer Community in Genomics. https://doi.org/10.32942/X21S4C

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RICHARDS StephenORCID_LOGO

  • Human Genome Sequencing Center, Baylor College of Medicine, Houston, TX, United States of America
  • Arthropods, Bioinformatics, Evolutionary genomics, Structural genomics
  • recommender

Recommendation:  1

Reviews:  0

Areas of expertise
I have a long history in genome sequencing and assembly, with a focus on arthropod genomics. My educational background is a B.Sc. in Biochemistry from Bath University, a PhD in Biochemistry and Cell Biology from Rice University. Work background includes a stint at Lawrence Berkeley National Lab with Susan Celniker and Gerry Rubin on the Drosophila Genome Project, and a long period with Richard Gibbs at the Baylor College of Medicine Human Genome Sequencing Center working on many projects, but a focus on insect genomes including Drosophila pseudoobscura, the Honey Bee, and man other speeches, as well as the Drosophila Genetic Reference Panel with Trudy Mackay. I am currently (2019) working with Harris Lewin at UC Davis to promote and execute the Earth BioGenome Project, which will revolutionize Biology overs the next decade.