Alligators Increase Plant Diversity

Photo by mbarisson licensed under CC BY-ND 2.0.

Photo by mbarisson licensed under CC BY-ND 2.0.

When you think of gardening, alligators don’t readily jump to mind. Hang out long enough in places like the Everglades and that might change. I was only recently introduced to the concept of a “gator hole” and I must say, I was surprised what a quick search of the literature revealed. It turns out that alligators are important ecosystem engineers and do a wonderful job at increasing plant diversity in the wetlands they inhabit.

Throughout southeastern North America, gators change their behaviors with the seasons. During the rainy season, alligators can be found floating in open water or sunning themselves on land. Except when hunting, they don’t seem to do anything with much urgency. Their activity level changes during the dry season when water is in short supply. Gators don’t sit back and let nature take its course. They spring into action and create their own aquatic refuges.

As the surrounding landscape begins to dry, gators will excavate holes or pits in the soggy ground called gator holes. These holes hold onto water when most of the surrounding landscape isn’t. The process of digging a gator hole may seem destructive but it all must be placed in the context of the surrounding environment. Most gator habitat exists in low lying areas. In places like the Everglades, there isn’t much topography to speak of. When a gator excavates a gator hole, it creates variation in both hydrology and soil conditions.

Photo by Anita Gould licensed under CC BY-ND 2.0.

Photo by Anita Gould licensed under CC BY-ND 2.0.

Soils that have built up over time are lifted out of the hole and piled into mounds. Mounded soils are not only rich in nutrients, they also dry at different rates, creating a gradient in water availability. Plants that normally can’t germinate and grow in saturated soils find suitable spots to live up on the soil mounds while emergent aquatic vegetation fills in along the parameter. Plants that normally prefer to grow in deeper water can also establish within the gator hole itself. In the midst of fairly uniform marsh vegetation, a gator hole quickly becomes a hotbed of plant diversity. The differences in vegetation can be so stark compared to the surrounding landscape that some scientists can actually map gator holes using aerial scans simply by measuring the differences in infrared radiation given off by the leaves of all the different plants that establish around them.

Of course, all of that plant diversity has a huge effect on other organisms as well. Gator holes become important areas for various reptiles, amphibians, birds, and so much more. The paths that alligators take to and from their holes even act like fire breaks, changing the way fire moves through the landscape, which only increases the heterogeneity of the immediate area. Fish, though occasionally eaten, greatly benefit from the stability of water levels within a gator hole. All in all, gator holes are extremely important habitats. Not only do they support a high diversity of plants and animals alike, they make places like the Everglades even more dynamic than they already are.

Photo Credits: [1] [2]

Further Reading: [1] [2] [3] [4]

Should We Be Calling Aquatic Bladderworts Omnivores Instead of Carnivores?

Photo by Leonhard Lenz licensed under CC BY-NC 2.0

Photo by Leonhard Lenz licensed under CC BY-NC 2.0

As is so often the case in nature, the closer we start to look at things, the more interesting they become. Take, for instance, the diet of some carnivorous bladderworts (Utricularia spp.). These wonderful organisms cover their photosynthetic tissues in tiny bladder traps that rapidly spring open whenever a hapless invertebrate makes the mistake of coming too close to a trigger hair. The unlucky prey is quickly sucked into the trap and subsequently digested.

This is how most bladderworts supplement their growth. As cool as this mechanism truly is, our obsession with the idea that these plants are strict carnivores has historically biased the kinds of investigations scientists attempt with these plants. Over the last decade or so, closer inspection of the contents of aquatic bladderwort traps has revealed that a surprising amount of plant material gets trapped as well. Most of this material consists of single celled algae. Is it possible that at least some aquatic bladderworts also gain nutrients from all of that “vegetable” matter?

The answer to this question is a bit more nuanced than expected. Yes, it does appear that non-animal material frequently ends up in bladderwort traps. Much of this comes in the form of a wide variety of algae species. What’s more, it does appear that algae are broken down within the traps themselves, suggesting that the bladderworts are actively digesting this material. The main question that needs to be answered here is whether or not the bladderworts actually benefit from the breakdown of algae.

Evidence of a nutritive benefit from algae digestion is mixed. Some studies have found that the bladderworts don’t appear to benefit at all from the breakdown of algae within their traps. Alternatively, others have found that bladderworts may benefit from digesting at least some types of algae. These authors noted that there doesn’t seem to be any benefit in terms of additional nitrogen for the bladderwort but instead suggest that other trace nutrients might be obtained in this way.

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One of the biggest hurdles in this line of research arises from the fact that we still don’t fully understand the digestive mechanisms of bladderworts. It is possible that some of the algal degradation within bladderwort traps has nothing to do with digestion at all. Instead, it could simply be that algae stuck in the traps eventually dies and rots away. Another major question raised by these observations is how tiny organisms like single celled algae even make it into the traps in the first place. What we can say for sure is most algae are far too small to actually trigger the bladder traps. As such, algae is either getting into the traps passively via some form of diffusion or they are sucked in when other, larger prey is captured.

Some research has even suggested that the benefit of trapping algae may depend on the habitats in which bladderworts are growing. Bladderworts living in more acidic water have shown to capture far more algae than bladderworts in more neutral or alkaline water. This has to do with acidity. Numerically speaking, there is far less zooplankton living in acidic water than algae, which means algae is more likely to end up in the bladders. It could be that the benefits of algae are thus greater for plants living in places where little zooplankton is available. Certainly more work will be needed before we can call bladderworts omnivores but the idea itself is exciting.

Photo Credits: [1] [2] [3]

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



Eelgrass Sex is Strange

Photo by Fredlyfish4 licensed by CC BY-SA 4.0

Photo by Fredlyfish4 licensed by CC BY-SA 4.0

Pollination may seem like a strange thing to us humans. Whereas we only require two of us to accomplish reproduction, plants have to utilize a third party. The most familiar cases include insects like bees and butterflies. Unique examples include birds, bats, and even lizards. Many plants forego the need of an animal and instead rely on wind to broadcast copious amounts of pollen into the air in hopes that it will randomly bump into a receptive female organ.

This has worked very well for terrestrial plants but what about their aquatic relatives? Water proves to be quite an obstacle for the methods mentioned above. Some species get around this by thrusting their flowers above the surface but others don't bother. One genus in particular has evolved a truly novel way of achieving sexual reproduction without having to leave its aquatic environment in any way.

Photo by eyeweed licensed by CC BY-NC-ND 2.0

Photo by eyeweed licensed by CC BY-NC-ND 2.0

Meet the Vallisnerias. Commonly referred to as tape or eelgrasses, this genus of aquatic plants has been made famous the world over by their use in the aquarium trade. In the wild they grow submerged with their long, grass-like leaves dancing up into the water column. Where they are native, eelgrasses function as an important component of aquatic ecology. Everything from fish and crustaceans all the way up to manatees utilize tape grass beds for both food and shelter. Eelgrasses stabilize stream beds and shorelines and even act as water filters.

All this is quite nice but, to me, the most interesting aspect of Vallisneria ecology is their reproductive strategy. Whereas they will reproduce vegetatively by throwing out runners, it is their method of sexual reproduction that boggles the mind. Vallisneria are dioecious, meaning individual plants produce either male or female flowers. The female flowers are borne on long stalks that reach up to the water surface. Once there they stop growing and start waiting. Because of their positioning, water tension causes a slight depression around the flowers at the surface. The depression resembles a little dimple with a tiny white flower in the center.

A female Vallisneria flower. Photo by eyeweed licensed by CC BY-NC-ND 2.0

A female Vallisneria flower. Photo by eyeweed licensed by CC BY-NC-ND 2.0

Male Vallisneria flowers floating on the water surface. Photo by eyeweed licensed by CC BY-NC-ND 2.0

Male Vallisneria flowers floating on the water surface. Photo by eyeweed licensed by CC BY-NC-ND 2.0

Male flowers are very different. Much smaller than the female flowers, a single inflorescence can contain thousands of individual male organs. As they mature underwater, the male flowers break off from the inflorescence and float to the surface. Similar to wind pollinated terrestrial plants, Vallisneria use water currents to disperse their pollen. Once at the surface, the tiny male flowers float around like little pollen-filled rafts.

If a male flower floats near the dimple created by a female flower, it will slide down into the funnel-like depression where it will contact with the female flowers. This is how pollination is achieved. Once pollinated, hormonal changes signal the stem of the female flower to begin to coil up like a spring, drawing the developing seeds safely underwater where they will mature. Eventually hundreds of seeds are released into the water currents.

After pollination, the stem of the female flower coils up, drawing the ripening ovaries safely underwater. Photo by Peter M. Dziuk [source]

After pollination, the stem of the female flower coils up, drawing the ripening ovaries safely underwater. Photo by Peter M. Dziuk [source]

The Vallisneria are incredible aquatic plants. Their bizarre reproductive strategy has ensured that these plants never really have to leave the water. The fact that they can also reproduce vegetatively means that many species are very successful plants. In fact, some species have become noxious invasive weeds where they have been introduced far outside of their native range. If you own these plants in any way, do take the necessary measures to ensure that they never have the chance to become invasive.

Photo Credits: [1] [2] [3] [4]

Further Reading: [1]

Botanical Buoys

Photo by Doug McGrady licensed under CC BY 2.0

Photo by Doug McGrady licensed under CC BY 2.0

American featherfoil (Hottonia inflata) is a fascinating aquatic plant. It can be found in wetlands ranging from the coastal plains of Texas all the way up into Maine. Though widespread, American featherfoil is by no means common. Today I would like to introduce you to this gorgeous member of the primrose family (Primulaceae).

American featherfoil may look like a floating plant but it is not. It roots itself firmly into the soil and spends much of its early days as a vegetative stem covered in wonderful feathery leaves. It may be hard to find during this period as no part of it sticks above the water. To find it, one must look in shallow waters of ponds, ditches, and swamps that have not experienced too much disturbance. More on this in a bit.

Photo by Doug McGrady licensed under CC BY 2.0

Photo by Doug McGrady licensed under CC BY 2.0

American featherfoil lives life in the fast lane. It is what we call a winter annual. Seeds germinate in the fall and by late October, juveniles can be seen sporting a few leaves. There it will remains throughout the winter months until early spring when warming waters signal the growth phase. Such growth is rapid. So rapid, in fact, that by mid to late April, plants are beginning to flower. To successfully reproduce, however, American featherfoil must get its flowers above water.

The need to flower out of water is exactly why this plant looks like it is free floating. The flower stalks certainly do float and they do so via specialized stems, hence the specific epithet “inflata.” Each plant grows a series of large, spongy flowering stalks that are filled with air. This helps buoy the stems up above the water line. It does not float about very much as its stem and roots still anchor it firmly into place. Each inflorescence consists of a series of whorled umbels that vary in color from white to yellow, and even violet. Following pollination, seeds are released into the water where they settle into the mud and await the coming fall.

Photo by Doug McGrady licensed under CC BY 2.0

Photo by Doug McGrady licensed under CC BY 2.0

As I mentioned above, American featherfoil appreciates wetland habitats that haven’t experienced too much disturbance. Thanks to our wanton disregard for wetlands over the last century or so, American featherfoil (along with countless other species) has seen a decline in numbers. One of the biggest hits to this species came from the trapping of beavers. It turns out, beaver ponds offer some of the most ideal conditions for American featherfoil growth. Beaver ponds are relatively shallow and the water level does not change drastically from month to month.

Historically unsustainable levels of beaver trapping coupled with dam destruction, wetland draining, and agricultural runoff has removed so much suitable habitat and with it American featherfoil as well as numerous wetland constituents. Without habitat, species cannot persist. Because of this, American featherfoil has been placed on state threatened and endangered lists throughout the entirety of its range. With the return of the beaver to much of its former range, there is hope that at least some of the habitat will again be ready for American featherfoil. Still, our relationship with wetlands remains tenuous at best and until we do more to protect and restore such important ecosystems, species like American featherfoil will continue to suffer. This is why you must support wetland protection and restoration in your region!

Photo Credits: [1] [2] [3]

Further Reading: [1] [2]

 

A New Species of Waterfall Specialist Has Been Discovered In Africa

A. habit, whole plant, in fruit, showing the flat root, a pillar-like ‘haptera’, and a shoot with three inflorescences, B. detail of shoot with three branches, C. view of upper surface of a flattened root, with six short, erect shoots, each with 1–2…

A. habit, whole plant, in fruit, showing the flat root, a pillar-like ‘haptera’, and a shoot with three inflorescences, B. detail of shoot with three branches, C. view of upper surface of a flattened root, with six short, erect shoots, each with 1–2 1-flowered inflorescences emerging from spathellum remains, D. side view of plant showing, on the lower surface of the flattened root, the pillar-like haptera, branched at base; upper surface of root with spathellum-sheathed inflorescence base, E. plant attached to rock by weft of thread-like root hairs (indicated with arrow) from base of pillar-like haptera; upper surface of flattened root with two shoots, F. side view of flower showing one of two tepals in full frontal view, G. as F. with tepal removed, exposing the gynoecium with, to left, the arched-over androecium, H. side view of flower with androecium in centre, two tepals flanking the gynoecium, I. androecium (leftmost of three anthers missing), J. transverse section of andropodium, K. view of gynoecium from above showing funneliform style-stigma base, L. fruit, dehisced, M. transverse section of bilocular fruit, showing septum and placentae, N. placentae with seeds, divided by septum, O. seeds, P. seed with mucilage outer layer. Drawn by Andrew Brown from Lebbie A2721 [SOURCE]

At first glance, this odd plant doesn’t look very special. However, it is the first new member of the family Podostemaceae to be found in Africa in over 30 years. It has been given the name Lebbiea grandiflora and it was discovered during a survey to assess the impacts of a proposed hydroelectric dam. By examining the specimen, Kew botanists quickly realized this plant was unique. Sadly, if all goes according to plan, this species may not be long for this world unless something is done to preserve it.

Members of the family Podostemaceae are strange plants. Despite how delicate they look, these plants specialize in growing submersed on rocks in waterfalls, rapids, and other fast flowing bodies of water. They are generally small plants, though some species can grow to lengths of 3 ft. (1 m) or more. The best generalization one can make about this group is that they like clean, fast-flowing water with plenty of available rock surfaces to grow on.

Lebbiea grandiflora certainly fits this description. It is native to a small portion of Sierra Leone and Guinea where it grows on slick rock surfaces only during the wet season. As the dry season approaches and the rivers shrink in size, L. grandiflora quickly sets seed and dies.

As mentioned, the area in which this plant was discovered is slated for the construction of a large hydroelectric dam. The building of this dam will most certainly destroy the entire population of this plant. As soon as water slows, becomes more turbid, and sediments build up, most Podostemaceae simply disappear. Unfortunately, I appears this plant was in trouble even before the dam came into the picture.

As mentioned, Podostemaceae need clean rock surfaces on which to germinate and grow. Without them, the seedlings simply can’t get established. Mining operations further upstream of the Sewa Rapids have been dumping mass quantities of sediment into the river for years. All of this sediment eventually makes it down into L. grandiflora territory and chokes out available germination sites.

Alarmed at the likely extinction of this new species, the Kew team wanted to try and find other populations of L. grandiflora. Amazingly, one other population was found growing in a river near Koukoutamba, Guinea. Sadly, the discovery of this additional population is bitter sweet as the World Bank is apparently backing another hydro-electric dam project on that river as well.

The only hope for the continuation of this species currently will be to (hopefully) find more populations and collect seed to establish ex situ populations both in other rivers as well as in captivity if possible. To date, no successful purposeful seeding of any Podostemaceae has been reported (if you know of any, please speak up!). Currently L. grandiflora has been given “Critically Endangered” status by the IUCN and the botanists responsible for its discovery hope that, coupled with the publication of this new species description, more can be done to protect this small rheophytic herb.

Photo Credit: [1] [2]

Further Reading: [1]

Getting to Know Elodea

Photo by Christian Fischer licensed under CC BY-SA 3.0

Photo by Christian Fischer licensed under CC BY-SA 3.0

When I think back on it, one of the first plants I ever actively tried growing was waterweed (Elodea canadensis). My 4th grade teacher had invested in a unit on the ecosystem concept. We all brought in 2 liter soda bottles that we craftily turned into mini terrariums. The top half of the terrarium was filled with soil and planted with some grass seed. The bottom half was filled with water and some gravel. In that portion we placed a single guppy and a few sprigs of Elodea

The idea was to teach us about water and nutrient cycles. It didn't work out too well as most of my classmates abandoned theirs not long after the unit was over. Being the avid little nerd that I was, I fell deeply in love with my new miniature ecosystem. The grass didn't last long but the guppy and the Elodea did. Since then, I have kept Elodea in various aquariums throughout the years but never gave it much thought. It is easy enough to grow but it never did much. Today I would like to make up for my lack of concern for this plant by taking a closer look at Elodea

An example of the soda bottle terrariums. Photo by Kara Nelson [source]

An example of the soda bottle terrariums. Photo by Kara Nelson [source]

The genus Elodea is one of 16 genera that make up the family Hydrocharitaceae and is comprised of 6 species. All 6 of these plants are native to either North or South America, with Elodea canadensis preferring the cooler regions of northern North America. They are adaptable plants and can grow both rooted or floating in a variety of aquatic conditions. It is this adaptability that has made them so popular in the aquarium trade. It is also the reason why the genus is considered a nasty aquatic invasive throughout the globe. For this reason, I do not recommend growing this plant outdoors in any way, shape, or form unless that species is native to your region. 

Believe it or not, Elodea are indeed flowering plants. Small white to pink flowers are borne on delicate stalks at the water's surface. They are attractive structures that aren't frequently observed. In fact, it is such a rare occurrence that trying to figure out what exactly pollinates them proved to be quite difficult. What we do know is that sexual reproduction and seed set is not the main way in which these plants reproduce. 

Photo by R a mueller licensed under CC BY-SA 3.0

Photo by R a mueller licensed under CC BY-SA 3.0

Anyone who has grown them in an aquarium knows that it doesn't take much to propagate an Elodea plant. They have a remarkable ability for cloning themselves from mere fragments of the stem. This is yet another reason why they can become so invasive. Plants growing in temperate waterways produce a thick bud at the tips of their stems come fall. This is how they overwinter. Once favorable temperatures return, this bud "germinates" and grows into a new plant. In more mild climates, these plants are evergreen. 

One of the most interesting aspects of Elodea ecology is that at least two species, E canadensis and E. nuttallii, are considered allelopathic. In other words, these plants produce secondary chemicals in their tissues that inhibit the growth of other photosynthetic organisms. In this case, their allelopathic nature is believed to be a response to epiphytic algae and cyanobacteria.

Slow growing aquatic plants must contend with films of algae and cyanobacteria building up on their leaves. Under certain conditions, this buildup can outpace the plants' ability to deal with it and ends up completely blocking all sunlight reaching the leaves. Researchers found that chemicals produced by these two species of Elodea actually inhibited the growth of algae and cyanobacteria on their leaves, thus reducing the competition for light in their aquatic environments. 

Elodea make for a wonderful introduction to the world of aquatic plants. They are easy to grow and, if cared for properly, look really cool. Just remember that their hardy nature also makes them an aggressive invader where they are not native. Never ever dump the contents of an aquarium into local water ways. Provided you keep that in mind, Elodea can be a wonderful introduction to the home aquarium. If you are lucky enough to see them in flower in the wild, take the time to enjoy it. Who knows when you will see it again. 

Photo Credits: [1] [2] [3]

Further Reading: [1] [2] 

Semi-Aquatic Orchids

By Jim Fowler. Copyright © 2017

By Jim Fowler. Copyright © 2017

Orchids have conquered nearly every continent on this planet except for Antarctica. In fact, there seems to be no end to the diversity in color, form, and habit of the world's largest family of flowering plants. Still, it might surprise many to learn that some orchids have even taken to water. Indeed, at least three species of orchid native to Latin and North America as well as a handful of islands have taken up a semi-aquatic lifestyle.

Most commonly encountered here in North America is the water spider orchid (Habenaria repens). It is a relatively robust species, however, considering that even its flowers are green, it is often hard to spot. Though it will root itself in saturated soils along the shore, it regularly occurs in standing water throughout the southeast. Often times, it can be found growing amidst other aquatic plants like pickerel weed (Pontederia cordata) and duck potato (Sagittaria latifolia). Because it can reproduce vegetatively, it isn't uncommon to find floating mats of comprised entirely of this orchid.  

By Jim Fowler. Copyright © 2017

By Jim Fowler. Copyright © 2017

Living in aquatic habitats comes with a whole new set of challenges. One of these is exposure to a new set of herbivores. Crayfish are particularly keen on nibbling plant material. In response to this, the water spider orchid has evolved a unique chemical defense. Coined "habenariol," this ester has shown to deter freshwater crayfish from munching on its leaves and roots. Another challenge is partnering with the right fungi. Little work has been done to investigate what kinds of fungi these aquatic orchids rely on for germination and survival. At least one experiment was able to demonstrate that the water spider orchid is able to partner with fungi isolated from terrestrial orchids, which might suggest that as far as symbionts are concerned, this orchid is a generalist.

The flowers of the water spider orchid are relatively small and green. What they lack in flashiness they make up for in structure and scent. The flowers are quite beautiful up close. The slender petals and long nectar spur give them a spider-like appearance. At night, they emit a vanilla-like scent that attracts their moth pollinators. 

Photo Credits: Jim Fowler. Copyright © 2017 www.jfowlerphotography.com

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

Underwater Pollinators

Modern day aquatic plants are highly derived organisms. Similar to dolphins and whales, today's aquatic plants did not originate in their watery environment. Instead, they gradually evolved from land plants living close to the water's edge. One of the biggest challenges for fully aquatic plants involves pollination. Many species overcome this hurdle by thrusting their flowers up and out of the water where there are far more pollen vectors. Others rely on water currents and a little bit of chance. For aquatic plants whose flowers open under water, water pollination, or "hydrophily", has long been the only proposed mechanism. Surely aquatic animals could not be involved in aquatic pollination. Well, a newly published study on a species of seagrass known scientifically as Thalassia testudinum suggests otherwise.

Seagrasses are ecological cornerstones in marine environments. They form vast underwater meadows and are considered one of the world's most productive ecosystems. Most seagrasses are clonal. Because of this, sexual reproduction in this group has mostly been overlooked. However, they do produce flowers that are tucked down in among their leaves. The production of flowers coupled with a surprising amount of genetic diversity have led some researchers to take a closer look at their reproduction.

A team of researchers based out of the National Autonomous University of Mexico decided to look at potential pollen vectors in Thalassia testudinum, a dominant seagrass species throughout the Caribbean and western Atlantic regions. T. tetidinum is dioecious, producing male and female flowers are separate plants. Flowers open for short periods of time and males produce pollen in sticky, mucilaginous strands. The research team had noticed that a wonderfully diverse group of aquatic animals visit these flowers during the night and began to wonder if it was possible that at least some of these could be effective pollinators.

Photo by James St. John licensed under CC BY 2.0

Photo by James St. John licensed under CC BY 2.0

The team was up against a bit of a challenge with this idea. A simple visit to a flower doesn't necessarily mean pollination has been achieved. To be an effective pollinator, an animal must a) visit both male and female flowers, b) carry pollen on their bodies, c) effectively transfer that pollen, and d) that pollen transfer must result in fertilization. To quantify all four steps, the team used a series of cameras, aquariums, and natural mesocosm experiments. What they discovered was truly remarkable.

Not only did a diverse array of marine invertebrates visit the flowers during the duration of the study, they also carried pollen, which stuck to their bodies thanks to the thick mucilage. What's more, that pollen was then deposited on the female flowers, which rake up these invertebrates with their tentacle-like stigmas. Finally, pollen deposited on female flowers did in fact result in fertilization. Taken together, these data clearly demonstrate that animal pollinators do in fact exist in aquatic environments. It is likely that these invertebrates are most effective during periods when water movement is minimized. Water currents likely still make up a significant portion of the pollen transfer between individual plants. Still, this evidence changes the paradigm of aquatic pollination in a big way.

Photo Credits: [1] [2]

Further Reading: [1]