Pollination with a Twist

Ensuring that pollen from one flower makes it to another flower of that species is paramount to sexual reproduction in plants. It's one of the main drivers of the diversity in shapes, sizes, and colors we see in flowers across the globe. Sometimes the mechanism isn't so obvious. Take, for instance, the flowers of Impatiens frithii.

The flowers of this Cameroonian endemic have been a bit of a puzzle since its discovery. Like all Impatiens, they have a long nectar spur. However, the spur on I. frithii is uniquely curved. This puzzled botanists because most of the Impatiens in this region are pollinated by sunbirds. The curved spur would appear to make accessing the nectar within quite difficult for a bird. Still, just because we can't imagine it, doesn't mean that it's impossible. Something must pollinate this lovely little epiphyte in one way or another. This is where close observation comes in handy.

Thanks to remote cameras and lots of patience, botanists were able to record pollination events. They quickly realized that sunbirds are indeed the primary pollinator of this species. This was a bit of a surprise given the shape of the flower. However, the way in which the flowers deposit pollen on this birds is what is most remarkable. As it turns out, successful reproduction in I. frithii all comes down to that curved nectar spur. 

When a sunbird probes the flower for nectar, its beak follows the contour of the spur and this causes the entire flower to twist. As it twists, the anthers and stigma make contact with the chin of the bird. This is unlike other Impatiens which deposit the pollen on top of the heads of visiting birds.

Such an adaptation is quite remarkable in many ways. For one, it is elegantly simple. Such a small alteration of floral architecture is all that is required. Second, by placing pollen on the underside of the head, the plant guarantees that only pollen from its species will ever come into contact with the stigma. This is what we call reproductive isolation, which is an important driver in speciation.

Photo Credit: [1]

Further Reading: [1]

Important Lessons From Ascension Island

Located in the middle of the South Atlantic, Ascension Island is probably not on the top of anyone's travel list. This bleak volcanic island doesn't have much to offer the casual tourist but what it lacks in amenities it makes up for in a rich and bizarre history. Situated about 2,200 km east of Brazil and 3,200 km west of Angola, this remote island is home to one of the most remarkable ecological experiments that is rarely talked about. The roots of this experiment stem back to a peculiar time in history and the results have so much to teach the human species about botany, climate, extinction, speciation, and much more. What follows is not a complete story; far from it actually. However, my hope is that you can take away some lessons from this and, at the very least, use it as a jumping off point for future discussions. 

Ascension Island is, as land masses go, quite young. It arose from the ocean floor a mere 1 million years ago and is the result of intense volcanic activity. Estimates suggest that volcanism was still shaping this island as little as 1000 years ago. Its volcanic birth, young age, isolated conditions, and nearly non-existent soils meant that for most of its existence, Ascension Island was a depauperate place. It was essentially a desert island. Early sailors saw it as little more than a stopover point to gather turtles and birds to eat as they sailed on to other regions. It wasn't until 1815 that any permanent settlements were erected on Ascension. 

Photo by Drew Avery licensed under CC BY 2.0

Photo by Drew Avery licensed under CC BY 2.0

In looking for an inescapable place to imprison Napoleon Bonaparte, the Royal Navy claimed Ascension in the name of King George III. Because Napoleon had a penchant for being an escape artist, the British decided to build a garrison on the island in order to make sure Napoleon would not be rescued. In doing so, the limitations of the island quickly became apparent. There were scant soils in which to grow vegetables and fresh water was nearly nonexistent. 

The native flora of Ascension was minimal. It is estimated that, until the island was settled, only about 25 to 30 plant species grew on the island. Of those 10 (2 grasses, 2 shrubs, and 6 ferns) were considered endemic. If the garrison was to persist, something had to be done. Thus, the Green Mountain garden was established. British marines planted this garden at an elevation of roughly 2000 feet. Here the thin soils supported a handful of different fruits and vegetables. In 1836, Ascension was visited by a man named Charles Darwin. Darwin took note of the farm that had developed and, although he admired the work that was done in making Ascension "livable" he also noted that the island was "destitute of trees."

One of Ascension Island's endemic ferns - Pteris adscensionis. Photo by Drew Avery licensed under CC BY 2.0

One of Ascension Island's endemic ferns - Pteris adscensionis. Photo by Drew Avery licensed under CC BY 2.0

Others shared Darwin's sentiment. The prevailing view of this time period was that any land owned by the British empire must be transformed to support people. Thus, the wheels of 'progress' turned ever forward. Not long after Darwin's visit, a botanist by the name of Joseph Hooker paid a visit to Ascension. Hooker, who was a fan of Darwin's work, shared his sentiments on the paucity of vegetation on the island. Hooker was able to convince the British navy that vegetating the island would capture rain and improve the soil. With the support of Kew Gardens, this is exactly what happened. Thus began the terraforming of Green Mountain.

Photo by LordHarris licensed under CC BY-SA 3.0

Photo by LordHarris licensed under CC BY-SA 3.0

For about a decade, Kew shipped something to the tune of 330 different species of plants to be planted on Ascension Island. The plants were specifically chosen to withstand the harsh conditions of life on this volcanic desert in the middle of the South Atlantic. It is estimated that 5,000 trees were planted on the island between 1860 and 1870. Most of these species came from places like Argentina and South Africa. Soon, more plants and seeds from botanical gardens in London and Cape Town were added to the mix. The most incredible terraforming experiment in the world was underway on this tiny volcanic rock. 

By the late 1870's it was clear the the experiment was working. Trees like Norfolk pines (Araucaria heterophylla), Eucalyptus spp. and figs (Ficus spp.), as well as different species of banana and bamboo had established themselves along the slopes of Green Mountain. Where there was once little more than a few species of grass, there was now the start of a lush cloud forest. The vegetation community wasn't the only thing that started to change on Ascension. Along with it changed the climate. 

Photo by Drew Avery licensed under CC BY 2.0

Photo by Drew Avery licensed under CC BY 2.0

Estimates of rainfall prior to these terraforming efforts are sparse at best. What we have to go on are anecdotes and notes written down by early sailors and visitors. These reports, however, paint a picture of astounding change. Before terraforming began, it was said that few if any clouds ever passed overhead and rain rarely fell. Those living on the island during the decade or so of planting attested to the fact that as vegetation began to establish, the climate of the island began to change. One of the greatest changes was the rain. Settlers on the island noticed that rain storms were becoming more frequent. Also, as one captain noted "seldom more than a day passes over now without a shower or mist on the mountain." The development of forests on Ascension were causing a shift in the island's water cycle. 

Plants are essentially living straws. Water taken up by the roots travels through their tissues eventually evaporating from their leaves. The increase in plant life on the island was putting more moisture into the air. The humid microclimate of the forest understory cooled the surrounding landscape. Water that would once have evaporated was now lingering. Pools were beginning to form as developed soils retained additional moisture.

Photo by Ben Tullis licensed under CC BY 2.0

Photo by Ben Tullis licensed under CC BY 2.0

Now, if you are anything like me, at this point you must be thinking to yourself "but what about the native flora?!" You have every right to be concerned. I don't want to paint the picture that everything was fine and dandy on Ascension Island. It wasn't. Even before the terraforming experiment began, humans and other trespassers left their mark on the local biota. With humans inevitably comes animals like goats, donkeys, pigs, and rats. These voracious mammals went to work on the local vegetation. The early ecology that was starting to develop on Ascension was rocked by these animals. Things were only made worse when the planting began.

Of the 10 endemic plants native to Ascension Island, 3 went extinct, having been pushed out by all of the now invasive plant species brought to the island. Another endemic, the Ascension Island parsley fern (Anogramma ascensionis) was thought to be extinct until four plants were discovered in 2010. The native flora of Ascension island was, for the most part, marginalized by the introduction of so many invasive species. This fact was not lost of Joseph Hooker. He eventually came to regret his ignorance to the impacts terraforming would have on the native vegetation stating “The consequences to the native vegetation of the peak will, I fear, be fatal, and especially to the rich carpet of ferns that clothed the top of the mountain when I visited it." Still, some plants have adapted to life among their new neighbors. Many of the ferns that once grew terrestrially, can now be found growing epiphytically among the introduced trees on Green Mountain. 

The Ascension Island parsley fern (Anogramma ascensionis). Photo by Ascension Island Government Conservation Department licensed under CC BY-SA 3.0

The Ascension Island parsley fern (Anogramma ascensionis). Photo by Ascension Island Government Conservation Department licensed under CC BY-SA 3.0

Today Ascension Island exists as a quandary for conservation ecologists. On the one hand the effort to protect and conserve the native flora and fauna of the island is of top priority. On the other hand, the existence of possibly the greatest terraforming effort in the world begs for ecological research and understanding. A balance must be sought if both goals are to be met. Much effort is being put forth to control invasive vegetation that is getting out of hand. For instance, the relatively recent introduction of a type of mesquite called the Mexican thorn (Prosopis juliflora) threatens the breeding habitat of the green sea turtle. Efforts to remove this aggressive species are now underway. Although it is far too late to reverse what has been done to Ascension Island, it nonetheless offers us something else that may be more important in the long run: perspective.

If anything, Ascension Island stands as a perfect example of the role plants play in regulating climate. The introduction of these 330+ plant species to Ascension Island and the subsequent development of a forest was enough to completely change the weather of that region. Where there was once a volcanic desert there is a now a cloud forest. With that forest came clouds and rain. If adding plants to an island can change the climate this much, imagine what the loss of plants from habitats around the world is doing. 

Each year an estimated 18 million acres of forest are lost from this planet. As human populations continue to rise, that number is only going to get bigger. It is woefully ignorant to assume that habitat destruction isn't having an influence on global climate. It is. Plants are habitat and when they go, so does pretty much everything else we hold near and dear (not to mention require for survival). If the story of Ascension does anything, I hope it serves as a reminder of the important role plants play in the function of the ecosystems of our planet. 

The endemic Ascension spurge (Euphorbia origanoides). Photo by Drew Avery licensed under CC BY 2.0

The endemic Ascension spurge (Euphorbia origanoides). Photo by Drew Avery licensed under CC BY 2.0

Photo by DCSL licensed under CC BY-NC 2.0

Photo by DCSL licensed under CC BY-NC 2.0

Photo Credits: [1] [2] [3] [4] [5] [6] [7] [8]

Further Reading: [1] [2] [3]

 

A Green Daffodil From Spain

Photo by A. Barra licensed under CC BY 3.0

Photo by A. Barra licensed under CC BY 3.0

There are some plants that are so ubiquitous in horticulture that I almost forget that they have wild constituents. Every plant in our gardens can trace its lineage back to the wild. As is often the case, I find the wild congeners of our most beloved horticultural curiosities to be far more fascinating. Take, for instance, the genus Narcissus. Who doesn't recognize a daffodil? The same cannot be said for their wild cousins. In fact, there exists some pretty fantastic species within this genus including a small handful of species that flower in autumn. 

A unique fall flowering daffodil is a species known scientifically as Narcissus viridiflorus. This lovely little plant is quite restricted in its range. You will only find it growing naturally in a small region around Gibraltar where it is restricted to rich, clay and/or rocky soils. During years when it is not in flower, N. viridiflorus produces spindly, rush-like leaves. As such, it can be hard to find. 
 

When Narcissus viridiflorus does decide to flower, it forgoes leaf production. From the bulb arises a single green scape. From that scape emerges the flower. The flowers of this bizarre daffodil are decidedly not very daffodil-like. They are rather reduced in form, with long, slender green petals and a nearly nonexistent daffodil cone. Also, they are green. Though I have not seen this investigated directly, it has been suggested that the green scape and flowers contain enough chlorophyll that they plant can recoup at least some of the energy involved in producing flowers and eventually seed. 

The flowers themselves open at night and are said to be very fragrant. Again, no data exists on who exactly pollinates this species but the timing, color, and smell all suggest nocturnal insects like moths. Like the other daffodils of this region, Narcissus viridiflorus is poorly understood. Taken in combination with its limited distribution one can easily see how such a species may be quite vulnerable to human disturbance. As it stands now, this species and many of its cousins are no more than horticultural curiosities for more niche bulb societies. In other words, Narcissus viridiflorus is in need of some real attention. 

Photo Credit: [1] [2]

Further Reading: [1]

On the Wood Rose and its Bats

New Zealand has some weird nature. It is amazing to see what an island free of any major terrestrial predators can produce. Unfortunately, ever since humans found their way to this unique island, the ecology has suffered. One of the most unique plant and animal interactions in the world can be found on this archipelago but for how much longer is the question.

The story starts with a species of bat. In fact, this bat is New Zealand's only native terrestrial mammal. That's right, I said terrestrial. The New Zealand lesser short-tailed bat spends roughly 40% of its time foraging for insects on the ground. It has lots of specialized adaptations that I won't go into here but the cool part is they forage in packs, stirring up insects from the leaf litter until they reach a level of feeding frenzy that I thought was only reserved for sharks or piranhas. Along with using echo location, they also have a highly developed sense of smell. This is important for our second player in this forest floor drama.

Enter Dactylanthus taylorii, the wood rose. This plant is not a rose at all but rather a member of the tropical family Balanophoraceae. More importantly, it is parasitic. It produces no chlorophyll and lives most of its life wrapped around the roots of its host tree underground. Every once in a while a small patch of flowers break through the dirt and just barely peak above the leaf litter. This give this species it's Māori name of "pua o te reinga" or "pua reinga", which translates to "flower of the underworld." The flowers emit a musky, sweet smell that attracts these ground foraging bats. The bats are one of the only pollinators left on the island. They sniff out the flowers and dine on the nectar, all the while being dusted with pollen. Recently, it has been found that New Zealand's giant ground parrot, the kakapo, is also believed to have been a pollinator of this plant. Sadly, today the kakapo exists solely on one small island of the New Zealand archipelago.

Both the wood rose and the New Zealand lesser short-tailed bat are considered at risk for extinction. When modern man came to these islands they brought with them the general suite of mammalian invasives like rats, mongoose, cats, and pigs, which are exacting a major toll on the local ecology. The plants and animals native to New Zealand have not shared an evolutionary history with such aggressive mammalian invaders and thus have no adaptations for coping with their sudden presence. The future of the wood rose, the New Zealand lesser short-tailed bat, and the kakapo, along with many other uniquely New Zealand species are for now uncertain.

Photo Credits: Joseph Dalton Hooker (1859) and Nga Manu Nature Reserve (http://www.ngamanu.co.nz/)

Further Reading:

http://bit.ly/2bBw8FT

http://bit.ly/2bKRY90

http://bit.ly/2bKpxfE

Meeting Amborella trichopoda

When I found out I would be seeing a living Amborella, a lump formed in my throat. There I was standing in one of the tropical houses at the Atlanta Botanical Garden trying to keep my cool. No amount of patience was ample enough to quell my excitement. How was I going to react? How big were these plants? Would I see flowers? Could I touch them? What were they growing in? My curiosity was through the roof.

Naturally this sort of excitement is reserved for those of us familiar with Amborella trichopoda. This strange shrub is not something that would readily stand out against a backdrop of tropical flora. However, if life history and ecology were to be translated into outward appearances, Amborella would likely be one of the most gaudy plants on this planet. What I was about the lay eyes on is the only member of the sole genus belonging to the family Amborellaceae, which is the sole member of the order Amborellales.

Even more exciting is its position on the angiosperm family tree. As flowering plants go, Amborella is thought to be the oldest alive today. Okay, so maybe this shrub isn't the oldest flowering plant in the world. It is likely that at one time, many millions of years ago, there were more representatives of Amborellaceae growing on this planet. Until we turn up more fossil evidence it is nearly impossible to say. Still, Amborella's place in the story of flowering plant evolution is consistently located at the base.

That is not to say that this shrub is by any means primitive. I think the first thing that shocked me about these plants is just how "normal" they appear. Sans flowers, I didn't see much out of the ordinary about them. They certainly look like they belong on our timeline. Without proper training in plant anatomy and physiology, there is little one could deduce about their evolutionary position. Regardless of my ignorance on plant morphology, there is plenty to look at on Amborella.

For starters, Amborella has tracheids but no vessel elements, making its vascular system more like that of a gymnosperm than an angiosperm. Its small flowers are borne in the axils of the evergreen leaves. It has no petals, only bracts arranged into a spiral of tepals. The female flowers consist of 4 to 8 free carpels and do not produce a style. Male flowers look like nothing more than a spiral cluster of stamens borne on short filaments.

If plant anatomy isn't enough to convince you, then the genetic analyses tell a much more compelling story. DNA sequencing consistently places Amborella at the base of the flowering plant family tree. Again, this is not to say that this shrub is by any means "primitive" but rather its lineage diverged long before what we would readily recognize as a flowering plant evolved. As such, Amborella offers us a window into the early days of flowering plants. By comparing traits present in more derived angiosperms to those of Amborella, researchers are able to better understand how the most dominant group of plants found their place in this world.

Another interesting thing happened when researchers looked at the DNA of Amborella. What they found was more than just Amborella genes. Inside the mitochondrial DNA are an unprecedented amount of foreign DNA from algae, lichens and mosses. In fact, an entire chunk of DNA corresponded to an entire mitochondrial genome of a moss! Researchers now believe that this is a case of extreme horizontal gene transfer between Amborella and its neighbors both growing on and around it. Both in the wild and in cultivation, Amborella is covered in a sort of "biofilm." Whether or not such gene transfer has assisted in the conservatism of this lineage over time remains to be seen.

At this point you may be asking how this lineage has persisted for over 130 million years. For the most part, it is probably due to chance. However, there is one aspect of its ecology that really stands out in this debate and that is its geographic distribution. Amborella is endemic to Grande Terre, the main island of New Caledonia. This is a very special place for biodiversity.

New Caledonia is a small fragment of the once great super-continent Gondwana. New Caledonia, which was part of Australia at that time, broke away from Gondwana when the super-continent began to break up some 200-180 million years ago. New Caledonia then broke away from Australia some 66 million years ago and has not been connected to another land mass since. A warm, stable climate has allowed some of the most unique flora and fauna to persist for all that time. Amborella is but one of the myriad endemic plants that call New Caledonia home. For instance, 43 species of tropical conifers that grow on these small islands are found nowhere else in the world. The whole region is a refugia of a long lost world.

Being a biodiversity hot spot has not spared New Caledonia from the threats of modern man. Mining, agriculture, urbanization, and climate change are all threatening to undo much of what makes this place so unique. The loss of a species like Amborella would be a serious blow to biodiversity, conservation, and the world as whole. We cannot allow this species to exist only in cultivation. New Caledonia is one place we must desperately try to conserve. Meeting this species has left a mark on me. Being able to observe living Amborella up close and personal is something I will never forget as my chances of seeing this species in the wild are quite slim. I am so happy to know that places like the Atlanta Botanical Garden are committed to understanding and conserving this species both in the wild and in cultivation. For now Amborella is here to stay. Long may it be that way.

 

Further Reading:

http://bit.ly/29MuMuw

http://bit.ly/29MuML0

http://bit.ly/29ZKNJS

 

Lovely Lomatium

I officially learned how to botanize in the American west. Before then my skills were limited to "hey, look at the pretty flower" and then Googling my way to an answer. As such, I have a real soft spot for western botany. Despite the fact that I have not had the chance to exercise those muscles in some time, I nonetheless revisit the few groups that I do remember via the massive photo collection I built up during my tenure in Wyoming. One group I am particularly fond of are members of the genus Lomatium.

I had never really paid attention to members of the carrot family. I always associated that group with the Queen Anne's lace (Daucus carota) I encountered growing in ditches. In other words, I found them boring. All of that changed when I moved to Wyoming. Spring was slow to start that year. I mean really slow. I thought I had it bad in western New York where spring snow storms and freezing temperatures often delayed plant growth well into May. That year in Wyoming, the last snow storm hit on June 29th. Because of this, most of the plants we were trying to locate were biding their time underground waiting for favorable weather to kick off the growing season.

By mid June I was starving for plant life. I needed to see some greenery. That is when I first laid eyes on a Lomatium. They began appearing as tight clusters of highly dissected, rubbery leaves. Once I knew what to look for, I began finding them throughout the foothill regions where we were working. Since I was just getting familiar with the local flora, I was hard pressed to key anything out. Instead I just waited for flowers. I didn't have to wait very long. 

Soon entire hillsides were covered in little yellow umbels. They were squat plants, never growing too high. The constant winds that whipped across the terrain made sure of that. It soon became apparent that Lomatiums don't waste any time. Water is limited in these habitats and they have to make quick work of it while it is available. Another interesting thing to note is the sex of the flowers. Generally when I see a dense umbel like that, I just assumed they were hermaphroditic. In at least some Lomatium, this is actually not the case. The sex of the flowers is determined by age. 

Smaller plants tend to produce male flowers, whereas larger plants will produce hermaphrodites. This makes a lot of sense as producing only pollen requires much fewer resources than producing ovaries and eventually seeds. Needless to say, larger plants also produce the most seed and are often the driving force in population persistence and growth. The seeds themselves are quite interesting. They are winged and often quite fleshy until they dry. Wind is the predominant seed dispersal mechanism and there is no shortage of wind in sagebrush country. 

The phylogeny of this genus is quite confusing. I certainly haven't gotten my head wrapped around it. Individuals are notoriously hard to identify both physically and genetically. There is a large degree of genetic variation between plants and "new species" are still being discovered. At the same time, there is also a lot of endemism and some species like Lomatium cookii and Lomatium dissectum are of conservation concern. Aside from habitat destruction, over-grazing, and limited ranges, over-collection for herbal uses poses considerable threat to many species. 

Further Reading:

http://bit.ly/1VWvMfV

http://bit.ly/1VE24MF

http://bit.ly/1WUzohQ

http://bit.ly/1qXSVS8

http://bit.ly/245NDpH

Screw Pines, Volcanism, and Diamonds

The association between geology and botany has always fascinated me. The closer you look, the more you can't separate the two. Rocks and minerals influence soil characteristics, which in turn influences which plant species will grow and where, which in turn influences soil properties. Take for instance the case of kimberlite.

Kimberlite is a volcanic rock whose origin is quite intense. Kimberlite is found in the form of large vertical columns, often referred to as pipes. They are the result of some seriously explosive volcanism. Intense heat and pressure builds deep within the mantle until it explodes upward, forming a column of this igneous rock. 

Over long spans of time, these pipes begin to weather and erode. This results in soil that is rich in minerals like magnesium, potassium, and phosphorous. As anyone who gardens can tell you, these are the ingredients of many fertilizers. In Africa where these sorts of pipes are well known, there is a species of plant that seems to take advantage of these conditions. 

It has been coined Pandanus candelabrum and it belongs to a group of plants called the screw pines. They aren't true pines but are instead a type of angiosperm. Now, the taxonomy of the genus Pandanus is a bit shaky. Systematics within the family as a whole has largely been based on fragmentary materials such as fruits and flowers. What's more, for much of its taxonomic history, each new collection was largely regarded as a new species. You might be asking why this is important. The answer has something to do with the kimberlite P. candelabrum grows upon. 

There is something other than explosive volcanic activity that makes kimberlite famous. It is mostly known for containing diamonds. In a 2015 paper, geologist Stephen E. Haggerty made this connection between P. candelabrum and kimberlite. As far as anyone can tell, the plant is a specialist on this soil type. As such, prospectors are now using the presence of this plant as a sort of litmus test for finding diamond deposits. This is why I think taxonomy becomes important. 

If P. candelabrum turns out not to be a unique species but rather a variation then perhaps this discovery doesn't mean much for the genus as a whole. However, if it turns out that P. candelabrum is a truly unique species then this new-found association with diamond-rich rocks may spell disaster. Mining for diamonds is a destructive process and if every population of P. candelabrum signals the potential for diamonds, then the future of this species lies in the balance of how much our species loves clear, shiny chunks of carbon. A bit unsettling if you ask me. 


Further Reading:
http://econgeol.geoscienceworld.org/content/110/4/851.full

An Introduction to Cephalotus follicularis - A Strange Carnivore From Australia

Photo by H. Zell licensed under CC BY-SA 3.0

Photo by H. Zell licensed under CC BY-SA 3.0

In a small corner of western Australia grows a truly unique carnivorous plant. Commonly referred to as the Albany pitcher plant, Cephalotus follicularis is, evolutionarily speaking, distinct among the pitcher plants. It is entirely unrelated to both the Sarraceniaceae and the Nepenthaceae.

This stunning case of convergent evolution stems from similar ecological limitations. Cephalotus grows in nutrient poor areas and thus must supplement itself with insect prey. It does so by growing modified leaves that are shaped into pitchers. The lid of each pitcher has two main functions. It keeps rain from diluting the digestive enzymes within and it also confuses insects.

A close inspection of the lid will reveal that it is full of clear spots. These spots function as windows, allowing light to penetrate, which confuses insects that have landed on the trap. As they fly upwards into the light, they crash into the lid and fall back down into the trap.

Photo by Lucas Arrrrgh licensed under CC BY-NC-ND 2.0

Photo by Lucas Arrrrgh licensed under CC BY-NC-ND 2.0

The relationship of Cephalotus to other plants has been the object of much scrutiny. Though it is different enough to warrant its own family (Cephalotaceae), its position in the greater scheme of plant taxonomy originally had it placed in Saxifragales. Genetic analysis has since moved it out of there and now places it within the order Oxalidales. What is most intriguing to me is that the closest sister lineage to this peculiar little pitcher plant are a group of trees in the family Brunelliaceae. Evolution can be funny like that.

Regardless of its relationship to other plants, Cephalotus follicularis has gained quite a bit of attention over the last few years. Its strange appearance and carnivorous habit have earned it a bit of stardom in the horticultural trade. A single specimen can fetch a hefty price tag. As a result, collecting from wild populations has caused a decline in numbers that are already hurting due to habitat destruction. Luckily they are easy to culture in captivity, which will hopefully take pressure off of them in the wild.

What's more, the loss of Cephalotus from the wild is hurting more than just the plant. A species of flightless, ant-mimicking fly requires Cephalotus pitchers to rear its young. They don't seem to mind growing up in the digestive enzymes of the pitchers and to date, their larvae have been found living nowhere else. If you are lucky enough to grow one of these plants, share the wealth. Captive reared specimens not only take pressure off wild populations, they are also much hardier. Lets keep wild Cephalotus in the wild!

Photo by Holger Hennern licensed under CC BY-SA 3.0

Photo by Holger Hennern licensed under CC BY-SA 3.0

Photo Credits: Holger Hennern (Wikimedia Commons) and Lucas Arrrrgh (https://www.flickr.com/photos/chug/2121092119/)

Further Reading: [1] [2] [3]

The Darth Vader Begonia

Cue the Imperial March, it is time to talk about the Darth Vader Begonia. This atramentous plant had only been known to the world since 2014. The discovery of this species (as well as two other new Begonia species) occured in Sarawak, on the island of Borneo. This region is a hot spot for plant diversity and this is especially true for begonias. A combination of diverse terrain and varied microclimates have led to an explosion of speciation events resulting in endemic species found nowhere else in the world.

With its leaves so deeply green that they almost appear black and deep red flowers it's not a stretch to imagine why this begonia has been named Begonia darthvaderiana. Until 2014, no one had ever laid eyes on this species, not even the locals. It was found growing in the deep shade of a forested cliff mixed in among other shade-loving vegetation. It is likely that the dark coloration of its leaves enables it to take advantage of what little sunlight makes it down to the forest floor.

Not long after its discovery was reported, something alarming happened. The so-called Darth Vader begonia began appearing for sale online. With a price tag of $80+, this is one expensive little plant. Apparently a plant poacher from Taiwan managed to smuggle some plants out of the country. This is especially upsetting because of its extreme rarity. Despite its namesake, the force is not strong enough to protect this species from greedy collectors. If you have somehow managed to obtain one of these plants, please do everything in your power to propagate it. Plants produced in captivity take pressure off of wild populations.

This was not the only new begonia species to be named after a Star Wars character. A larger species with green and silver leaves was given the scientific name of Begonia amidalae after Queen Amidala. It too is endemic to the region. The future of these plants as well as many others hangs in the balance. A growing human population is putting pressure on the rainforests of Borneo. As more and more forest is lost to development, countless endemic species are disappearing with it. This is yet another example of why land conservation is a must. Please consider lending your support to organizations such as the Rainforest Trust. Together, we can ensure that there are wild spaces left.

CLICK HERE TO HELP LAND CONSERVATION EFFORTS IN BORNEO

Photo Credit: Che-Wei Lin, Shih-Wen Chung, & Ching-I Peng

Further Reading: [1] [2]

 

The Bells of Oconee

Photo by Philip Bouchard licensed under CC BY-NC-ND 2.0

Photo by Philip Bouchard licensed under CC BY-NC-ND 2.0

The whole point of In Defense of Plants is to remove the human element and tell the story of plants for what they are. I find their stories to be far more interesting than any anthropocentric use they might have. However, the following tale was just far too compelling to ignore. It is a story of passion and, in the end, really encompasses the reality of the species it centers around.

Asa Gray was an eminent 19th century botanist. In 1838, Gray left America for Europe in order to examine herbarium specimens which would reveal the original sources of American flora. While in Paris, Gray was pouring over collections made by Andre Michaux when he came across a poorly preserved specimen of an unnamed plant "with a habit of Pyrola and the foliage of Galax" originating from the "High Mountains of Carolina."

For whatever reason, Gray became enamored with this small pressed plant. He knew it had to be a new species. Upon returning to America, Gray went about organizing expeditions to rediscover this odd little botanical wonder. Sadly it would be another 40 years before he would see a living specimen. 

The species in question is Shortia galacifolia, better known as Oconee bells. A member of the family Diapensiaceae, Shortia is often described as a small, spreading, evergreen sub-shrub. In early spring, each plant produces a beautiful whiteish-pink, bell shaped flower. Today, Shortia is only known from a small handful of populations growing along a couple stream banks in the Southern Appalachians. The original population that Michaux collected from now lies under 980 feet of water, lost forever by the damming of the Keowee River. 

There has been a lot of speculation over why this plant is endemic. A lot of it has to do with Shortia's germination requirements. It is a plant of disturbance, relying on things like blowdowns or minor landslides to open the canopy just enough to create the perfect microclimate. As canopies close, populations languish and disappear. Fortunately for Shortia, collections have been out-planted at a handful of botanical gardens throughout the region where they grow and persist in great numbers. 

Further Reading:
http://arnoldia.arboretum.harvard.edu/pdf/articles/1991-51-4-asa-gray-and-his-quest-for-shortia-galacifolia.pdf

http://www.jstor.org/stable/2483507?seq=1#page_scan_tab_contents

http://www.jstor.org/stable/4033240?seq=1#page_scan_tab_contents

http://www.jstor.org/stable/23306488?seq=1#page_scan_tab_contents

Blowout Penstemon

Photo by Vernon Jenewein Vljenewein Public domain

Photo by Vernon Jenewein Vljenewein Public domain

While living and working in Wyoming, I had the chance to meet so many amazing plant species. Many of these were quite unique to the high desert environments where we were assigned. Countless hours were spent searching large swaths of land rarely visited by humans. One species of plant managed to elude me during my time in that beautiful part of the country. The plant is incredibly rare and thus a focus of federal protection and restoration efforts. 

Based on first impressions, blowout penstemon (Penstemon haydenii) may look like any other penstemon. The similarities stop there and indeed, this is one of the most unique species of penstemon I have ever heard of. Originally it was only known from a few locations in the Sand Hills of Nebraska. Recently, a few populations were discovered in Wyoming but it is by no means common. 

As its common name suggests, P. haydenii is a specialist of blowouts. These depressions in the sand are caused by blustering winds that carve out and remove all vegetation. Most plants cannot survive in these conditions. There is very little water, the sands are constantly shifting, and as the wind kicks up sand at high speeds, the abrasive force can actually cut down frail vegetation. This is where P. haydenii excels. 

It has a thick, waxy cuticle covering its stem and leaves that protect it from this sandblasting effect as well as drought. The seeds of these species are dispersed by wind and have extreme longevity in the soil. They can remain dormant for decades until the right conditions are present for them to germinate. P. haydenii seeds need at least 2 weeks of steady moisture and lots of abrasion from sand in order to break dormancy. Research has shown that these conditions are only ever present one out of every 8 to 10 years. As a result, P. haydenii has a debilitatingly small recruitment window. 

This rarity has placed it on the endangered species list. Ironically, the very regulations that were put into place to control range degradation by cattle ranchers may have caused serious declines in this species. It was once common practice to over-graze the land where P. haydenii is found and as a result, vegetation became sparse. This increased the likelihood of blowout formation, which favored P. haydenii. Fire suppression is another threat. Regular fires help kill back vegetation that would otherwise outcompete P. haydenii

With droughts on the increase and human activities expanding into areas where the few remaining populations of P. haydenii occur, the future of this strange little endemic is uncertain. There has been a lot of effort to save and restore this species numbers but it is by no means the end of the story. Only time will tell...

Photo Credit: Vernon Jenewein Vljenewein

Further Reading:
http://plants.usda.gov/core/profile?symbol=peha12

http://ecos.fws.gov/speciesProfile/profile/speciesProfile.action?spcode=Q2EX

The Tallest of Palms

High up in a mountain valley in Colombia grows one of the most remarkable palms in the world. Known scientifically as Ceroxylon quindiuense, the Quindío wax palm towers like a lanky monolith above the surrounding vegetation. Not only is this the tallest species of palm in the world, it is, by extension, the tallest monocot as well.

Standing at heights of over 160 feet, the Quindío wax palm looks all the stranger with its narrow trunk and tuft of fronds all the way at the top. It is called a wax palm because members of this genus produce a waxy substance from their trunk. In the past, this wax was harvested for its use in making torches. Until electricity became widely available, these palms were felled en masse for this purpose.

Quindío wax palms are slow to mature. For at least 15 years they focus much of their energy on radial or outward growth of the trunk. For 15 years, all the tree puts out are three pinnate leaves. Things change once the tree hits 15. It will begin its climb into the sky. Every year it sheds leaves, which creates a dark ring around the trunk. Because of this, it is easy to estimate the approximate age of any given wax palm. Count the rings and add 15 years for stem development plus another 5 for a full crown. It is believed that these palms can take upwards of 80 years to reach sexual maturity!

Because of its limited geographic range, Quindío wax palms are at risk of extinction. The young fronds are favorites among Catholics of the region for their use in Palm Sunday ceremonies. Stands that exhibit heavy harvesting have a hard time of recovering. At the same time, their native range is quickly being converted to pasture land as well as other forms of agriculture. Even if trees are left standing, their seeds find it difficult to germinate and survive under the altered microclimates of these human environments.

Luckily for Ceroxylon quindiuense, the government of Colombia recognizes how special this species is. Not only is it now the national tree and emblem of Colombia, its is now a protected species. All logging of Quindío wax palms is illegal. Still, major portions of their remaining populations are located within pasture lands.

Photo Credit: nuria mpascual (http://bit.ly/1CImC7T)

Further Reading:
http://bit.ly/1CImCEP

http://www.iucnredlist.org/details/38467/0

A Strange Gymnosperm From Africa

Photo by Petr Kosina licensed under CC BY-NC 2.0

Photo by Petr Kosina licensed under CC BY-NC 2.0

What you are looking at here is not just a pile of discarded leaves. It is indeed a living plant. Would you believe me if I told you that it is a distant relative of pines, spruces, larches and firs? It's true! This right here is Welwitschia mirabilis, a representative of an ancient lineage of gymnosperm!

Photo by Petr Kosina licensed under CC BY-NC 2.0

Photo by Petr Kosina licensed under CC BY-NC 2.0

Welwitschia is endemic to the Namib Desert of Africa. It is hard to picture any plant living in such a dry area. In some years it never even rains. Welwitschia persists despite this fact. It tends to grow in watercourses and outcrops, thus enabling it to gather what precious little rain does fall. It has a deep taproot suggesting that it relies heavily on ground water. The leaves of Welwitschia also have high amounts of stomata on both surfaces enabling it to absorb water directly from the fog that regularly blows through when colder air currents mix with hot air from the desert.

For a long time it was believed that Welwitschia represented true neoteny, which is the retention of juvenile characteristics into adulthood. It was thought that Welwitschia was nothing more than a sexually mature seedling with exaggerated cotyledons. This idea was later abandoned when Martens showed that Welwitschia do develop further than the seedling stage. What really happens is the apical bud, which is responsible for vertical growth in plants, dies quite early on in development. In essence, Welwitschia has lost its "head."

I was not kidding when I said that Welwitschia is a gymnosperm. Once sexual maturity is reached, cones are produced. Individual plants are either male or female and unlike many of its relatives, Welwitschia is not wind pollenated. Instead it relies on insects to transfer pollen from male cones to female cones.

Probably the most remarkable aspect of Welwitschia ecology is its longevity. Individual plants can live well over 1000 years. Some individuals are estimated at around 2000 years old! In such a harsh desert environment, persistence is the key to survival for Welwitschia.

Photo Credit: Petr Kosina

Further Reading:
http://www.jstor.org/discover/10.2307/2442386…

http://www.plantzafrica.com/plantwxyz/welwitschia.htm

A Mallow Called Kankakee

In the spirit of this week's podcast I would like to take a look at a very special plant. It happens to be one of the rarest plant species in the lower 48. What may surprise you even more is that this species is endemic to a small island in the middle of the Kankakee River of Illinois called Langham Island. I am, of course, talking about the Kankakee mallow (Iliamna remota).

It is strange to think of something endemic to a 20 acre island in the midwest but that seems to be the case. Though disjunct populations have been located in Indiana, experts feel that these were the result of early attempts at saving this species from extinction. In fact, the rarity of this plant was realized quite early on. A series of taxonomic revisions made it so that by the early 1920's, botanists knew that Iliamna remota was distinct from similar species such as liamna rivularis and Iliamna corei.

Despite its uniqueness, there doesn't seem to be too many explanations as to why this species is limited to Langham Island. Perhaps our recent glacial past has something to do with it. It very well could also be due to the fact that roughly 80% of Illinois has been converted to farmland. It is also due, in part, to the lack of life-giving fires that the prairies so desperately need. Indeed, after decades of attention, Langham Island and the Kankakee mallow seemed to have faded from the spotlight.

In 1981, botanists realized that most of the plants on the island had disappeared. Only 109 individuals remained and no seedlings were found. It was starting to look like this species was doomed to extinction. Growing up in their place were thick stands of Japanese honeysuckle and multiflora rose. Luckily a handful of concerned biologists decided to light some fires. Wherever the fires burned away the invasive competition, seedlings began to emerge. Close inspection would reveal that these were the next generation of Kanakakee mallow!

A missing piece of this biological puzzle had been restored. The mallow seeds were waiting in the soil for a fire to release them from the tyranny of these invaders. It would seem that the future of this species was a bright one. Sadly, another round of budget cuts coupled with a decrease in public interest had swept through the region. When a group of botanists again went looking for this species in the summer of 2014, they realized that, to their horror, history seemed to have repeated itself. Gone were the remaining populations of the Kankakee mallow. Honeysuckle and multiflora rose had returned with vengeance.

It was clear that if this species were to be saved, Langham Island would need more dedicated attention. Thus the Friends of Langham Island was born. Since then, brush cutting and controlled burns have meant that the Kankakee mallow has once again rose from the ashes, literally. Ongoing attention from a concerned group of citizens may be the only means left at saving this endangered plant.

Photo Credit: Prairie Moon Nursery

Further Reading:
www.habitat2030.org

Check out The Brain Scoop's video about this plant

Listen to a podcast episode dedicated to the restoration of these species' habitat