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Ferns’ ability to evolve ‘backward’ offers insights into the meandering path of evolution
Ferns’ ability to evolve ‘backward’ offers insights into the meandering path of evolution
Imagine a photograph of your great-grandparents, grandparents and parents side by side. You’d see a resemblance, but each generation would look distinct from its predecessors. This is the process of evolution in its simplest form: descent with modification.
Over many generations, a staggering amount of modification is possible. This is how the diversity of life on Earth came to be.
This idea, though, has long been misunderstood as a path that leads in one direction toward “higher” or “better” organisms. For example, Rudolph Zallinger’s famous 1965 Time-Life illustration “The Road to Homo Sapiens” shows humans evolving in a stepwise fashion from ape-like ancestors to modern man.
Extending this perspective beyond humans, early paleontological theories about ancient life supported the idea of orthogenesis, or “progressive evolution,” in which each generation of a lineage advanced toward more sophisticated or optimized forms.
But evolution has no finish line. There is no end goal, no final state. Organisms evolve by natural selection acting at a specific geologic moment, or simply by drift without strong selection in any direction.
In a recently published study that I carried out with Makaleh Smith, then an undergraduate research intern at Harvard University who was funded by the National Science Foundation, we sought to study whether a one-way model of reproductive evolution always held true in plants. To the contrary, we found that in many types of ferns – one of the oldest groups of plants on Earth – evolution of reproductive strategies has been a two-way street, with plants at times evolving “backward” to less specialized forms.
The path of evolution is not linear
Selection pressures can change in a heartbeat and steer evolution in unexpected directions.
Take dinosaurs and mammals, for instance. For over 150 million years, dinosaurs exerted a strong selection pressure on Jurassic mammals, which had to remain small and live underground to avoid being hunted to extinction.
Then, about 66 million years ago, the Chicxulub asteroid wiped out most nonavian dinosaurs. Suddenly, small mammals were relieved of their strong predatory selection pressure and could live above ground, eventually evolving into larger forms, including humans.
In 1893, Belgian paleontologist Louis Dollo introduced the idea that once an organism progresses to a certain point, it does not revert to a previous state in the exact way in which it evolved – even if it encounters conditions identical to those it once experienced. Dollo’s law, as it came to be known, implies that specialization is largely a one-way street, with organisms accumulating layers of complexity that make backward evolution impossible.
While Dollo’s law has been criticized, and its original idea has largely faded from popular discourse, this perspective still influences aspects of biology today.
Plants and the march of progress
Museums often depict animal evolution as a straight-line progression toward higher stages, but they’re not the only sources of this narrative. It also appears in teaching about the evolution of reproduction in plants.
The earliest vascular plants – those with tissues that can move water and minerals throughout the plant – had leafless, stemlike structures called telomes, with capsules at their tips called sporangia that produced spores. The telomes did both of the plants’ big jobs: converting sunlight to energy through photosynthesis and releasing spores to produce new plants.
Fossil records show that over time, plants developed more specialized structures that divided these reproductive and photosynthetic functions. Moving through plant lineages, from spore-bearing lycophytes to ferns to flowering plants, reproduction becomes more and more specialized. Indeed, the flower is often diagrammed as the end goal of botanical evolution.
Across the plant kingdom, once species evolved reproductive structures such as seeds, cones and flowers, they did not revert to simpler, undifferentiated forms. This pattern supports a progressive increase in reproductive complexity. But ferns are an important exception.
Evolving, but not always forward
Ferns have multiple reproductive strategies. Most species combine spore development and photosynthesis on a single leaf type – a strategy called monomorphism. Others separate these functions to have one leaf type for photosynthesis and another for reproduction – a strategy called dimorphism.
If the patterns of specialization seen broadly across plants were universal, we would expect that once a lineage of ferns evolved dimorphism, it could not shift course and revert to monomorphism. However, using natural history collections and algorithms for estimating evolution in ferns, Smith and I found exceptions to this pattern.
Within a family known as chain ferns (Blechnaceae), we found multiple cases in which plants had evolved highly specialized dimorphism, but then reverted to the more general form of monomorphism.
Lacking seeds gives ferns flexibility
Why might ferns have such flexible reproductive strategies? The answer lies in what they lack: seeds, flowers and fruits. This distinguishes them from the more than 350,000 species of seed plants living on Earth today.
Imagine taking a fertile fern leaf, shrinking it down and wrapping it up tightly into a tiny pellet. That’s basically what an unfertilized seed is – a highly modified dimorphic fern leaf, in a capsule.
Seeds are just one highly specialized structure in a suite of reproductive traits, each building on the last, creating a form so specific that reversal becomes nearly impossible. But because living ferns don’t have seeds, they can modify where on their leaves they place their spore-producing structures.
Our findings suggest that not all reproductive specialization in plants is irreversible. Instead, it may depend on how many layers of specialization plants have acquired over time.
In today’s rapidly changing world, knowing which organisms or traits are “locked in” could be important for predicting how species respond to new environmental challenges and human-imposed habitat changes.
Organisms that have evolved down “one-way” paths may lack the flexibility to respond to new selection pressures in particular ways and have to figure out new strategies to change. In lineages such as ferns, species may retain their ability to “evolve backward,” even after specialization.
Ultimately, our study underscores a fundamental lesson in evolutionary biology: There is no “correct” direction in evolution, no march toward an end goal. Evolutionary pathways are more like tangled webs, with some branches diverging, others converging, and some even looping back on themselves.
Jacob S. Suissa, Assistant Professor of Plant Evolutionary Biology, University of Tennessee
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Planning for spring’s garden? Bees like variety and don’t care about your neighbors’ yards
Planning for spring’s garden? Bees like variety and don’t care about your neighbors’ yards
In order to reproduce, most flowering plants rely on animals to move their pollen. In turn, pollinators rely on flowers for food, including both nectar and pollen. If you’re a gardener, you might want to support this partnership by planting flowers. But if you live in an area without a lot of green space, you might wonder whether it’s worth the effort.
I study bees and other pollinators. My new research shows that bees, in particular, don’t really care about the landscape surrounding flower gardens. They seem to zero in on the particular types of flowers they like, no matter what else is around.
To design a garden that supports the greatest number and diversity of pollinators, don’t worry about what your neighbors are doing or not doing. Just focus on planting different kinds of flowers – and lots of them.
Comparing different landscapes
To test whether bees are more plentiful in natural areas, my team and I planted identical gardens – roughly 10 feet by 6½ feet (3 x 2 meters) – in five different landscapes around eastern Tennessee that ranged from cattle pastures and organic farms to a botanical garden and an arboretum. All five gardens were planted in March of 2019 and contained 18 species of native perennials from the mint, sunflower and pea families.
Over the course of the flowering season, we surveyed pollinators by collecting the insects that landed on the flowers, so we could count and identify them. The sampling took place in a carefully standardized way. Each week we sampled every flowering plant in every garden, in every landscape, for five minutes each. We used a modified, hand-held vacuum we called the “Bug Vac” and repeated this sampling every week that flowers were in bloom for three years.
We wanted to test whether the area immediately surrounding the gardens – the floral neighborhood – made a difference in pollinator abundance, diversity and identity. So we also surveyed the area around the gardens, in a radius of about 160 feet (roughly 50 meters).
To our surprise, we found the surrounding terrain had very little influence on the abundance, diversity and composition of the pollinators coming to our test gardens. Instead, they were mostly determined by the number and type of flowers. Otherwise, pollinators were remarkably similar at all sites. A sunflower in a cattle pasture had, by and large, the same number and types of visitors as a sunflower in a botanical garden.
Menu planning for pollinators
We used native perennial plants in our study because there’s evidence they provide the best nutrition for flower-visiting insects. We chose from three plant families because each offers different nourishment.
Plants in the mint family (Lamiaceae), for example, provide a lot of sugary nectar and have easily accessible flowers that attract a wide variety of insects. I’d recommend including plants from the mint family if you want to provide a large and diverse group of insects energy for flight. If you live in Tennessee, some examples are mountain mint, wood mint and Cumberland rosemary. You can easily search for perennial plants native to your area.
While some pollinators enjoy nectar, others get all their fat and protein from eating just the pollen itself. Flowers from the sunflower family (Asteraceae), including asters and coreopsis, offer large quantities of both pollen and nectar and also have very accessible flowers. Plants from this family are good for a range of pollinators, including many specialist bees, such as the blue-eyed, long-horned bee (Melissodes denticulatus), which feasts primarily on ironweed (Vernonia fasciculata), also a member of the sunflower family.
If you want to offer flowers that have the highest protein content to nourish the next generation of strong pollinators, consider plants from the pea family (Fabaceae), such as dwarf indigo, false indigo and bush clover. Some of the plants in this family do not even offer nectar as a reward. Instead, they provide high protein pollen that’s accessible only to the most effective pollinators. If you include plants from the pea family in your garden, you may observe fewer visitors, but they will be receiving pollen with high protein levels.
Selecting a few native perennials from each of these three families, all widely available in garden centers, is a good place to start. Just as a diversity of food is important for human health, a mixture of flower types offers pollinators a varied and healthy diet. Interestingly, the diversity of human diets is directly linked to pollinators, because most of the color and variety in human diets comes from plants pollinated by insects.
Plant it and they will come
Maybe you’ve heard that insects worldwide are declining in number and variety. This issue is of particular concern for humans, who rely on insects and other animals to pollinate food crops. Pollinators are indeed facing many threats, from habitat loss to pesticide exposure.
Thankfully, gardeners can provide an incredible service to these valuable animals just by planting more flowers. As our research shows, small patches of garden can help boost pollinators – even when the surrounding landscape has few resources for them. The one constant in all our research is that insects love flowers. The more flowers and the more types of flowers, the more pollinators Earth will have.
Laura Russo, Assistant Professor of Ecology and Evolutionary Biology, University of Tennessee
This article is republished from The Conversation under a Creative Commons license. Read the original article.