Looking different to your parents can provide species with a way to escape evolutionary dead ends, according to new research from Queen Mary University of London (QMUL) and the University of California, Riverside.
The work, which is outlined in a paper published on August 8 in the journal Nature Plants, looked at polyploid hybrids in the genus Nicotiana, the group that includes tobacco.
Unlike humans, which are diploids – with two copies of each of their 23 chromosomes (one from each parent) – polyploids can have three, four or more copies of each chromosome. This makes them particularly prone to producing hybrids and – in contrast to better-known hybrids such as the mule (the sterile product of a cross between a male donkey and a female horse) – means that crosses between polyploids are often fertile.
While hybrids might be expected to be a blend of the two parent species, the researchers found that they tended to have shorter and wider flower openings than both of the parent species which means that a wider range of pollinators can enter the flowers.
By allowing a wider range of insects to pollinate them, hybrids make themselves much less vulnerable to the extinction of a single pollinator.
Elizabeth McCarthy, who carried out the work as part of her Ph.D. at QMUL and is now a post-doctoral researcher at UC Riverside, said:
“Some plants evolve increasingly specialized relationships with the species that pollinate them. A classic example is Darwin’s Madagascan orchid, first discovered in 1798. Its exceptionally long nectar spur led Charles Darwin to propose that it was pollinated by a moth whose proboscis – the organ that extracts the nectar – was longer than that of any moth known at the time. Darwin’s prediction was spectacularly verified 21 years after his death when just such a moth was discovered.”
The problem with this sort of specialized relationship – which we now term coevolution – is that if one of the two species involved becomes extinct, the other is also doomed.
The Nature Plants paper is called “Transgressive phenotypes and generalist pollination in the floral evolution of Nicotiana polyploids.”
Co-authors are: Amy Litt, an assistant professor of botany and plant sciences at UC Riverside whom McCarthy works with; Andrew Leitch and Steven Le Comber at the School of Biological and Chemical Sciences at Queen Mary University of London; Mark Chase at the Royal Botanic Gardens, Kew; and Sandra Knapp at the Natural History Museum in London.
Source: UC Riverside