Abstract
Synthetic biology is an area of biological research that combines science and engineering. Here, I merge the principles of synthetic biology and regulatory evolution to create a new species with a minimal set of known elements. Using preexisting transgenes and recessive mutations of Drosophila melanogaster, a transgenic population arises with small eyes and a different venation pattern that fulfils the criteria of a new species according to Mayr’s Biological Species Concept. The population described here is the first transgenic organism that cannot hybridize with the original wild type population but remains fertile when crossed with other identical transgenic animals. I therefore propose the term “synthetic species” to distinguish it from “natural species”, not only because it has been created by genetic manipulation, but also because it may never be able to survive outside the laboratory environment. The use of genetic engineering to design artificial species barriers could help us understand natural speciation and may have practical applications. For instance, the transition from transgenic organisms towards synthetic species could constitute a safety mechanism to avoid the hybridization of genetically modified animals with wild type populations, preserving biodiversity.
Highlights
It has been argued that reconstructing a system is the ultimate way of understanding it [1,2]
In order to further comprehend the origin of new species, and to explore possible applications in modern biotechnology, I engineered reproductive isolation between populations of Drosophila melanogaster by generating a synthetic species boundary
Propose the term ‘‘synthetic species’’ to distinguish it from ‘‘natural species’’, because it has been created in the laboratory, and because it may never be able to survive in the wild, unlike ‘‘natural species’’
Summary
It has been argued that reconstructing a system is the ultimate way of understanding it [1,2]. In order to further comprehend the origin of new species, and to explore possible applications in modern biotechnology, I engineered reproductive isolation between populations of Drosophila melanogaster by generating a synthetic species boundary. Previous work in several species of Drosophila produced fundamental contributions regarding the genetics of speciation [7,8,9,10]. Speciation has been given no attention as a tool for biotechnology and in the context of genetically engineered organisms. A parthenogenetic species of lizard was generated [15], but, again, its speciation genetics are not understood, does not involve transgenesis nor synthetic design and its components can not be reliably and predictably manipulated
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