24 April 2016

Incredible plants: Pleurophycus gardneri

Pleurophycus gardneri sporophyte with Laminaria
setchellii
and other seaweeds on low intertidal rocks
at Glass Beach, Fort Bragg, CA, April 2016.
I came across a rare treat tidepooling earlier this month at Glass Beach in Mendocino CountyPleurophycus gardneri!

Pleurophycus is a moderately-sized kelp, consisting of a single photosynthetic blade at the end of a stipe than can be up to a half meter long (Abbott and Hollenberg 1976). Like other kelps, it is attached to the rocks with a holdfast, a structure that resembles roots. Pleurophycus lacks branches or the pneumatocysts (floats) that are present in some other kelp species. Its distinguishing feature for identification in the field is the presence of a wide midrib on the blade with a ruffled blade surface immediately next to each edge of the midrib. The species is perennial and deciduous with blades dying back each year (Germann 1986, Lindeberg & Lindstrom 2010).

The species is distributed from central California into Alaska (Silva 2009) but in my experience it is uncommon in California, particularly in the intertidal zone where I stumbled across a single individual in a narrow channel.

Western phycologists first collected the species from San Juan and Whidbey Islands in Washington state and from Alaska in the late 1890s (Silva 2009). Setchell and Gardner (1925) described its distribution from Alaska to Coos Bay, Oregon. Decades later a large population was found in the low intertidal at Ft. Bragg (Kjeldsen 1972) and the species was later discovered to occur subtidally off of San Luis Obispo County and Big Sur (Silva 2009).

For me, finds like this make an early morning rise to catch the spring low tides well worth it. In fact, though I am not naturally a morning person, I can’t say I ever regret a 4 or 5 AM wake up for a low tide adventure along the coast. During intertidal exploration I often find something new, but even when I do not, my curiosity and love of natural history is re-invigorated by the cool salty air and the beauty and complexity of the rocky shores of the Pacific.

References

Abbott IA, Hollenberg GJ. 1976. Marine Algae of California. Stanford University Press, Stanford, CA.

Germann I. 1986. Growth phenology of Pleurophycus gardneri (Phaeophyceae, Laminariales), a deciduous kelp of the northeast Pacific. Canadian J Botany 64:2538-2547.

Kjeldsen CK. 1972. Pleurophycis gardneri Setchell & Saunders, a new alga for northern California. Madroño 21:416.

Lindeberg MR, Lindstrom SC. 2010. Field Guide to Seaweeds ofAlaska. Alaska Sea Grant College Program, Univ. Alaska, Fairbanks.

Setchell WA, Gardner NL. 1925. The Marine Algae of the Pacific Coast of North America. Part III Melanophyceae. UC Publications in Botany 8:383-898.

Silva PC. 2009. Historical, nomenclatural, and distributional notes on two Pacific coast kelps: Lessoniopsis littoralis and Pleurophycus gardneri (Phaeophyceae, Laminariales, Alariaceae). Madroño 56:112-117.

18 April 2016

Adaptations of the Cactaceae

Cacti are iconic plants of desert environments. These succulent plants occur in the family Cactaceae. There are about 1800 species worldwide in the family, grouped into 125 genera. The family is endemic to North and South America, distributed from southern Argentina to Canada. One additional species occurs in western Africa and some of the islands of the Indian Ocean.

As a group, the Cactaceae are believed to have evolved in South America about 65 million years ago (around the same time as the extinction of dinosaurs), though molecular data suggest a more recent origin of about 30 million years. 65 mya, South America was warm and dry, but disconnected from North America. Cacti spread north, using Cuba and other islands as dispersal stepping stones, arriving in Mexico about 36 million years ago. In North America, the western deserts expanded about 2-5 million years ago with further radiation of cactus species.

The beavertail cactus, Opuntia basilaris. Left: Plant with flower buds from Death Valley National Park, March 2016.
Right: Plant from Joshua Tree National Park, February 2012.

Cacti are excellent plant examples of structural adaptations to meet unique environmental circumstances. The fleshy part of a cactus is actually the stem. In many species the stem is succulent, allowing for water storage in the dry habitats where they live. Water is stored in the stem's parenchyma cells. Stems have additional adaptations to minimize water loss such as the presence of a thick waxy outer cuticle and stomata that are sunken. Individuals can withstand water loss of up to 70-95% because the tissues have so much water storage potential. The longitudinal ribs present in some species are capable of expanding and contracting like an accordion without damaging the protective cuticle as water content in the plant varies.

Mammillaria tetracistra from Panamint Valley in
Death Valley National Park, March 2016. The
black spines on this species are hooked.
The spines of cacti are actually modified leaves. They are non-photosynthetic but have several other functions. The most obvious is defense against herbivores. Spines can also help a cactus acquire water when dew condenses on them, or help shade the plant. The spines may assist with dispersal of segments of the plant when they are caught in the fur of animals and transported around. Some "gland spines" produce nectar which help the plant attract pollinators.

Cacti also couple physiological adaptations with anatomical and structural modifications to deal with arid growing conditions. Plants acquire carbon dioxide (needed to build sugars and other organic molecules) from the air through their stomata, but having stomata open in a hot dry environment makes plants susceptible to water loss. One way to acquire CO2 but minimize water loss is through CAM photosynthesis, a variation of C3 photosynthesis present in most other plants. In CAM species the stomata remain closed during the day, but then open at night to acquire CO2 when the potential for water loss is reduced. Carbon dioxide captured at night is temporarily stored as an acid in the cells and later used to build sugars.

According to the recent Jepson manual, California has 37 native species of cacti. On my trip to Death Valley last month, I observed at least five of those species. Two species were particularly common: the beavertail cactus and the clustered barrel cactus. The beaver tail belongs to the genus Opuntia, plants which are also known as prickly pears. Prickly pear stems grow as segments, appearing as upside down tear-shaped fleshy leaves. In early March flower buds were forming on the beaver tails (O. basilaris) but I was too early to see open flowers.

Examples of Echinocactus polycephalus from Death Valley National Park. Incidentally, the Greek
etymology of this species name is fun: 'spiny cactus of many heads'.

Another relatively common cactus at Death Valley was the cholla, a group of cacti classified in the genus Cylindropuntia. I was first introduced to chollas as an undergraduate student when my marine ecology field class traveled from Santa Cruz to northern Mexico through the Arizona desert. We were warned to avoid touching these plants because of their menacing barbed spines which can be difficult to remove from the skin. Chollas have cylindrical stems that also occur in segments like the prickly pears. The small stem segments break off and lay on the desert floor. California has 10 species of cholla and I've also observed specimens of this genus in Joshua Tree National Park, northern Arizona, and Sonora Mexico.

Cholla from Joshua Tree National Park, Feb 2012. These plants are so densley covered  in light-colored spines
that one can hardly see the green stem. It is possible that the dense covering of spines helps reduce water
 loss from the plant.

References

Baldwin BG, Goldman DH, Keil DJ, Patterson R, Rosatti TJ, Wilken DH. 2012. The Jepson Manual. Vascular Plants of California. 2nd ed., University of California Press, Berkeley, CA.

Ingram S. 2008. Cacti, agaves, and yuccas of California and Nevada. Cachuma Press, Los Olivos, CA.

Zomlefer WB 1999. Guide to Flowering Plant Families. The University of North Carolina Press, Chapel Hill, NC.