Source: Weeden 1996
San Francisco State University
Geography 316: Biogeography
The Biogeography of
Canyon Liveforever (Dudleya cymosa)
Source: Weeden 1996
by: Tiffany Meyer
San Francisco State University
Geography 316
November 30, 1999
Canyon Liveforever: The Inside Story
Kingdom: Plantae
Division: Magnoliophyta (Angiosperms)
Class: Magnoliopsida
Subclass: Rosidae
Order: Rosales
Family: Crassulaceae (stonecrop)
Genus: Dudleya
Species: Dudleya cymosa
Common name: Canyon liveforever or Hens and chickens
Natural History of Dudleya cymosa:
Dudleya cymosa is a small, herbaceous perennial plant with furry,
thick, blue-gray, teardrop shaped leaves that grow in rosettes close to the ground.
The flower, which is seen from April to June, rises above the rosette about 4 to 6 inches
on a thick reddish tinted stalk (Weeden 1996). It is brightly colored in orange and
red and even at full bloom has the appearance of a flower that has not quite bloomed
yet. These odd looking blossoms that almost have beak like appearances and sit on
straight, thick leggy stems have won the plant the unattractive name of
Hens-and-chickens. It has also been given the common name Canyon Liveforever.
Source: CalFlora Occurrence Database
Dudleya cymosa is in the class of angiosperms; it is a
flowering plant that produces a seed-filled fruit. The genus Dudleya was
described in 1903 by Britton and Rose (Jacobsen 1960), who honored W. R. Dudley of
Stanford University, by naming it after the professor (Martin & Chapman 1977).
There are forty species within the genus, and many subspecies within those forty.
Some of the subspecies of D. cymosa, such as crebiflora, are uncommon, and
some are even considered rare, such as the subspecies ovatiflora, which is found
only on harsh granitic slopes (Jepson 1993).
Dudleya cymosa belongs to the Crassulaceae family, of which many
members fall into a well-known category of plants called succulents. The term
succulent refers to a group of plants that share similar morphologies but are not
necessarily related to each other. In fact there are many succulents that belong to
different plant families and genera. The most familiar succulents are cacti, and
like these rugged desert plants, Dudleya cymosa has been very successful in using a
variety of methods to survive its harsh environments of low precipitation and high light
intensity. The thick, sclerophyllous leaves of the small plant grow in little
rosettes close to the ground. This creates less surface area and allows it to
conserve water. Dudleya cymosa also has a fine layer of hairs on its thick,
fleshy leaves that reduce evaporation by reflecting sunlight away and slowing down air
movement across the leaf (Whitney 1979). These hairs are what give the plant its
soft, blue gray appearance.
Dudleya cymosa also combats its dry habitat by flowering in the
early spring, around April, to take advantage of the moist time of the year. The
insects that pollinate it must be quick because it is an ephemeral plant, meaning that its
growing season does not last very long. The plant becomes withered by the summer
time, for like most desert shrubs, it has a short life cycle (Hickman 1993).
Dudleya cymosa shares many physical (and physiological)
similarities to cacti which makes it a superb and frequently used plant for ornamental
cultivation. Dudleya cymosa requires excellent drainage and is intolerant of
frequent summer water, so it should not be grown near lawns or other water loving
plants. It can be successfully grown just about anywhere with in California, except
the extremely cold, high elevations of the Klamath, Cascade or Sierra Nevada mountain
ranges or the high desert (Hickman 1993). This makes it ideal for gardeners who
frequently forget to water their gardens or enjoy drought tolerant plants. I have
some lovely Dudleya in my own yard that add a wild, natural look to the landscape
instead of the harsh, dangerous appearance a thorny, prickly cactus can project. The
stems and leaves even become edible after cooking (Weeden 1996).
Distribution
Dudleya cymosa is a special plant because not only is it native to California, it is also endemic to California, meaning that it is only found naturally in this State. It is distributed throughout the more mountainous parts of the State such as the North Coast Ranges, the volcanic Cascade Range, the Sierra Nevada, San Francisco Bay Area including Mount Tamalpais, the Diablo Range, and the Santa Cruz Mountains. There are also subspecies found in Southern California and Baja California.
Although the Crassulaceae family that the Dudleya cymosa
belongs to is distributed in a cosmopolitan fashion and is found throughout the world on
various continents, the species Dudleya cymosa has a very limited ecological
tolerance. Since it prefers xeric sites and is found only in California, it tends to
be dispersed in small aggregations giving it a stenotopic distribution.
Being rather small, and practically the same color as its surroundings,
a plant like the Dudleya cymosa would not normally be considered a very conspicuous
plant, but it has chosen an environment that allows it to stand out and catch the eye
immediately. Since it is generally found on steep, rocky limestone outcrops and
talus slopes, there are not many other plants around to divert ones attention from
it. It can be found at elevations ranging from 300 feet up to 8000 feet (Jepson
1993). These types of dry, rocky sites, that Dudleya cymosa established
themselves in are called xeric. In the Sierra, xeric sites are alpine gravel
patches, rock outcrops, grasslands with moist soils, chaparral, foothill woodland and
sagebrush (Weeden 1996). This type of environment can experience extreme
temperatures, from freezes, snow and low, unpredictable rainfall in the winter, to hot,
dry direct sun light in the summer months.
Dudleya cymosa is considered a xerophyte because it grows in
these arid climates. Xerophytes have made unique adaptations to be able to survive
areas of low precipitation, high temperatures and frequent drought (Stern 1988). In
fact the Dudleya cymosa requires and is limited to areas of high sun exposure and
well draining soils. Because it lives in these harsh conditions, it does not’t
have to compete very readily with other plants. Other xerophytes that endure these
conditions are rock-cress, mountain mahogany, fremontia, bedstraw (Galium), various
types of penstemons, blazing star, poison oak, and bead fern (Cheilanthes) which is
a type of fern found on dry, rocky habitat. These plants are commonly found in
association with Dudleya cymosa (Bartel & Shecock 1990)
Source: CalFlora Occurrence Database
In addition to conserving limited resources, Dudleya cymosa
uses Crassulacean Acid Metabolism (CAM) photosynthesis to create its food and energy.
The CAM process was first discovered in the Crassulaceae plant family so that is what it
is named after (Hart, Eggli 1995). Most plants do all of their work during the day,
taking up carbon dioxide through their plant pores, called stomata, and using the energy
from sun light to convert the gas into food and oxygen. But Dudleya cymosa and
its fellow CAM relatives only open their stomata at night to take up carbon dioxide.
They keep their stomata closed during the hot days, allowing the plant to conserve
tremendous amounts of water (Stern 1988). The plant assimilates the carbon dioxide
at night and converts it to a variety of organic acids. In the morning when the
stomata close, the organic acids break down and carbon dioxide is released. With the
energy of the new days sun light, the plant uses the Calvin cycle to convert the carbon
dioxide it has been accumulating all night into sugars (Campbell 1990). Dudleya
cymosa’s stomatal circadian rhythm is out of phase with non CAM plants by about
12 hours (Campbell 1990). By adapting the method of CAM photosynthesis, Dudleya
cymosa is able to live in areas where the air is so dry that the light intensity is
extremely high because there is less atmospheric water vapor to filter out some of the
sun’s rays (Stern 1988).
Evolution
Like all flowering, seed bearing angiosperms, Dudleya cymosa’s
evolutionary record is difficult to trace because it abruptly appears in the fossil record
120 million years ago, during the Cretaceous period, with no sign of previous ancestral
links (Campbell 1996). Charles Darwin calls the evolutionary history of angiosperms
an “abominable mystery,” one that is yet to be solved. Once established,
angiosperms diverged into the dominant plants on earth, and now make up about 99% of the
plant species known today. D. cymosa showed up somewhere during this time of
rapid and expansive diversification during the Cretaceous period. However, it is
extremely hard to say exactly when, because the Dudleya fossil record is even more
elusive then its angiosperm relatives. The hot, dry climate that Dudleya cymosa
prefer does not seem to be very conducive to fossil formation (Winter& Smith 1996).
Since the Dudleya’s fossil record is not able to tell us
much, scientists have turned to other methods of trying to determine the history of these
sun loving plants. Because Dudleya cymosa is a xerophytic plant that prefers
hot, dry climates, it may have evolved during the early to mid Cretaceous period when the
climate became drier and seasonally arid after the era of lots of rain and moisture ended.
Dudleya cymosa has an incredible ability to conserve carbon dioxide because it uses
CAM photosynthesis, which could be another hint as to when it evolved. Most plants
lose excessive carbon dioxide on hot days through photorespiration, but D. cymosa
conserves carbon dioxide by closing its stomata at night so it requires a much smaller
amount of carbon dioxide then the c3 photosynthesizers and is considered a “CO2
concentrating mechanisms.” It probably evolved during a time when the carbon
dioxide to oxygen ratio was low (Smith & Winter 1996). There is evidence that
the Silurian period had low levels of carbon dioxide, but flowering plants were not in
existence 450 million years ago (MYA). During the glacial epoch of the Pliocene
Epoch, five MYA, the CO2:O2 ratios were significantly lower, which was the next
advantageous time for succulents (Smith & Winter 1996). The hypothesis that
succulents evolved during periods of low carbon dioxide levels contradict the idea that
they evolved during the hot, arid times of the early to mid Cretaceous period, because
there were high levels of carbon dioxide during those times. So contradicting time
lines and lack of fossil records makes it very difficult to give a time for
succulents’ arrival.
Because succulents are found in a variety of families, they are thought
to be polyphyletic which means they evolved out of different plant families. Our
plant of interest probably evolved from a Central American primitive Sedum taxa, a
Crassulaceae with a much broader distribution then Dudleya (Winter & Smith
1996). Because of their large scattering of relatives and very specific
specialization, we can deduce that CAM plants most likely evolved from C3 photosynthesis
plants, which are the most common, wide spread type of plants (Winter & Smith
1996). Before being permanent CAM photosynthesizers, CAMs were probably originally
C3 plants that started intermittently switching to CAM methods of photosynthesis during
times of drought and low rainfall. Eventually those species evolved into species
that solely depended on CAM photosynthesis (Smith & Winter 1996). Dudleya
belongs to the Crassulaceae family’s western U.S. branch of the Leucosedum-clade,
which includes a variety of species of its Sedum parent. This clade share the
characteristics of being glandular pubescent and having equal length, basally connate
sepals (t’Hart & Eggli 1995).
Despite its esthetic beauty and elegant method of photosynthesis, there
has been little information published on Dudleya cymosa. Its specialized
habitat requirements of arid, xeric sites tend to be found in localized patches that are
often steep, rocky and difficult to access. This isolation not only initiates new,
interesting speciation, like the D. cymosa sub-species minor, which is a dwarf with
orange flowers (Bartel & Shevock 1983), but it also gives D. cymosa the
advantage of having little competition, particularly with humans. Hopefully it will
be left to flourish timelessly as an endemic California native.
References
Barbour, M.G., Major, J. 1995 Terrestrial Vegetation of California. UC Davis, CA. California Native Plant Society.
Bartel, J.A., Shevock, J.R. 1983. “Dudleya calcicola (Crassulaceae), a new species from the Southern Sierra.” Madrono 30:210-216
Bartel, J.A. Shevock, J.R. 1990 “Dudleya cymosa subsp. costafolia (Crassulaceae), a new subspecies from the southern Sierra Nevada, Tulare County, California” Aliso 12(4): 701 –704.
Britt, Rose, Biological names, October 27, 1999.[Online]. Integrated Taxanomic Information Systems (ITIS). http://www.itis.usda.gov/plantproj/itis/cgi_bin/CBI.cgi?kingdom=Plantae&input%5ftype=T&input=502170
Cal Flora Occurrence Database August 18, 1999 http://www.calflora.org/calflora/occ/
Campbell, N. A. 1990 Biology second edition. Riverside, CA. The Benjamin/Cummings Publishing Company, inc.
Chapman, P.R., Martin, M.I., 1977 Succulents and their Cultivation. Charles Scribner’s Sons.
Hickman, J. C. (editor) 1993. The Jepson manual: higher plants of California. Berkeley, CA. University of California Press.
Jacobsen, Hermann. 1954. A Handbook of Succulent Plants. London, England, Blandford Press.
Smith, J.A.C., Winter, K. 1996. Crassulacean Acid Metabolism, Biochemistry, Ecophysiology and Evolution. Berlin Heidelberg, Germany, Springer-Verlag.
Stern, K.R. 1988. Introductory Plant Biology. Dubuque, IA. Wm. C. Brown Publishers.
‘t Hart, H., Eggli, U., 1995 Evolution and Systematics of the Crassulaceae. Leiden, The Netherlands, Backhuys publishers.
Weeden, Norman F. 1996. A Sierra Nevada Flora. Berkeley, CA. Wilderness Press.
Whitney, S. 1979. A Sierra Club naturalist’s guide to
the Sierra Nevada. San Francisco, CA. Sierra Club Books.
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