Salty Succulents

December 16, 2019

Succulent plants come in a variety of shapes, sizes, and colors. They also hail from a variety of plant families. If there is one thing that unites these plants (other than their succulent habit) its that the vast majority of them around found growing in dry places. Whether its the heart of a desert or up in the canopy of a tree, succulence has evolved as a means of storing water. However, those of you living near salt marshes may recognize that a handful of salt marsh plants are succulent as well. How is it that plants so frequently found growing in standing water have evolved a succulent habit? The answer lies in salt.

Salt water is pretty bad for most plants. Just like we get dehydrated from drinking or eating high amount of salt, so too do plants. In general, salt both dehydrates plants and causes issues with nutrient uptake. Such is not the case for genera like Salicornia. Commonly referred to as glassworts, pickleweeds, or picklegrass, the various Salicornia are true salt-lovers.

Taxonomically speaking, the genus Salicornia has been called a “taxonomic nightmare.” Thanks to their highly reduced morphology and extreme phenotypic plasticity, delineating species among the genus is something best left to Salicornia experts. What we do know is that they all belong in the amaranth family, Amaranthaceae. All of this confusion should not take away from your enjoyment of Salicornia. Indeed, there is a lot worth appreciating in this family, including their ability to grow in conditions that would kill most other plants.

Salicornia are not simply salt tolerators that can hang on under saline conditions. They are true salt lovers or ‘halophytes.’ In fact, experiments have shown that various Salicornia grow much better when salt levels are high. This all has to do with the way in which these plants deal with their salty environment. Like all succulents, Salicornia have enlarged vacuoles that store water. However, these large vacuoles store more than good ol H2O. They also store salts and lots of them.

Photo by S.Ahmadihayeri licensed by CC BY-SA 3.0

The secret to Salicornia’s salty success has to do with osmosis. As you may remember from science class, substances in our universe like to move from areas of high concentration to areas of low concentration. In the case of water within the tissues of an organism, this often occurs between biological membranes. As you add salt to water, it actually displaces water molecules such that the more salt you add, the less concentrated the water becomes. That is why salt water dehydrates us. When you surround a cell with salt, water will diffuse out of the cell to balance out the concentrations on both sides of the cell membrane. Salicornia use this to their advantage.

These plants actively take up salt from their environment and dump it into their vacuoles. This means that the concentration of water within the vacuole is less than the concentration of water outside of the cell. Osmosis then takes over and water rushes into the plant’s cells. By concentrating salt in their vacuoles, Salicornia are always ensuring that they are on the receiving end of the water gradient. Water is always moving into these salty plants and not the other way around. By co-opting morphological adaptation to drought, Salicornia are able to conquer a niche that is largely unavailable to most other plant species. It also means that, despite all of the water in their environment, these plants maintain a pleasingly succulent habit.

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

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

Evolving For City Life

October 30, 2016

Photo by Stefan.lefnaer licensed under CC BY-SA 4.0

Urban environments pose unique challenges to any plant. Cities are generally warmer, have significantly higher CO2 levels, and experience altered levels of disturbance and precipitation patterns than do rural areas nearby. Still, many plants have taken to these concrete jungles, popping up wherever they can eke out an existence. Although we are not reinventing ecological principals in urban areas, they nonetheless present distinct selective pressures on every living thing within their jurisdiction. Evidence now suggests that urban environments are actually shaping the evolution of at least some plant species.

Motivated by a desire to better understand how urban conditions are influencing evolution, a team of researchers based out of the University of Minnesota decided to take a closer look at a common mustard called Virginia pepperweed (Lepidium virginicum). This hardy little annual is at home wherever disturbance occurs. As such, it can be found throughout most of North America and beyond. Because it self pollinates readily, researchers were able to quantify phenotypic differences between populations growing in dense urban centers and compare them to those growing in more rural areas.

They collected seeds from numerous urban and rural populations and grew them together in a greenhouse experiment. By exposing each population to the same conditions in the greenhouse, the team were able to tease out the true phenotypic differences between these populations.

What their data revealed were distinct differences between urban and rural populations. For starters, urban plants had larger rosettes but fewer leaves. They also bolted sooner than rural plants but then exhibited a much longer period of time between bolting and flowers. Previous studies have shown that the inflorescence of related species "accounted for 55% of a plants photosynthetic activity but only 25% of water loss." Coupled with the reduction in the number of leaves, these results suggest that urban plants are maximizing photosynthesis under drier conditions.

Another interesting difference is that urban plants produced far more seed than their rural counterparts. This very well may be due to the fact that urban plants tended to be larger. This could also be due to reduced herbivory in urban environments, though such pressures may vary from city to city. Due to the urban heat island effect, it is likely that this could be a result of more stable temperature conditions than those experienced by their rural counterparts. Taken together, these results show that there is indeed selection for traits that allow plants to not only survive but thrive in urban environments.

Photo Credit: Wikimedia Commons

Further Reading: [1]

Plant Plasticity

March 6, 2016

One of the central tenets of evolutionary science is that individuals within a species vary, however slightly, in their form, physiology, and behavior. Without variability, life would languish, remaining static in a soupy ooze somewhere in the oceans. Perhaps it may not have evolved in the first place. Regardless, observation and experimentation has taught us a lot about how variation among individuals or populations can drive evolution. Today I would like to introduce you to a tiny plant native to northern and western North America that is teaching us a lot about how mating systems develop in plants.

Meet Collinsia parviflora, the maiden blue eyed Mary. Few plants are as iconic to my time living out west than this wonderful little plant. Indeed, C. parviflora is highly variable. It ranges in size from 5 for 40 centimeters in height and produces lovely little flowers that range from 4 to 7 millimeters in length. The size range of these flowers is key to investigating variations in pollination strategies.

C. parviflora has evolved what researchers refer to as a mixed mating strategy. Populations differ in that some plants self pollinate whereas others fully outcross with the help of a variety of bees. Exactly why these plants would maintain both strategies can tell us a lot about how mating systems develop in plants. What researchers have found is that there seems to be a tradeoff.

Populations that frequently self are often located in the harshest environments. Cold temperatures and a short growing season make investing in complex floral development a risky strategy. Indeed, plants growing where environmental conditions are harshest produce smaller flowers. These small flowers pack all of their reproductive bits close together, thus increasing the chances of self fertilization. It has been found that despite the risk of inbreeding, these plants produce far more seeds than plants that produce larger flowers and experience high rates of insect pollination.

The reasons for this are quite complex and more work is needed to be certain but it would seem that this is all an evolutionary adaptation to dealing with varied climates. With wide ranging species like C. parviflora, populations can experience highly varied environmental conditions. It would seem maladaptive to focus in on one particular reproductive strategy. As such, C. parviflora has evolved a range of possible anatomies as a way of adapting to many unique local conditions. If times are good and pollinators are abundant, it makes more sense to hedge bets on sexual reproduction whereas when conditions are poor and pollinators are scarce, it makes sense to produce offspring with a genome identical to that of the parents. If they can exist in a harsh location then so can the cloned offspring.

Investigations into the mating system of this tiny plant has revealed that big things can really come in small packages. I miss seeing this species. Its amazing how these tiny little flowers can be so numerous as to turn wide swaths of its habitat a pleasing shade of blue.

Further Reading:
http://www.amjbot.org/content/90/6/888.full

http://plants.usda.gov/core/profile?symbol=COPA3