Hiking With A Field Microscope

Cryptobiotic Soil Unearthed in Utah

TABLE OF CONTENTS

Introduction

Secrets of a San Francisco Deck Garden

Giant Bacteria Found in Golden Gate Park Flowers...!

Revealing Films of Life in a Cliff-side Seep

A Hard Life Out in the Salt Flats

Vernal Pool Fantasies

Relax in California Tide Pool

Salt Marsh Mysteries

The Big Heat

Beneath the Tufas in Mono Lake

What is a Field Microscope?

Getting Out Into the Field

Little-known Techniques of Field Photomicrography

Candid Camera

Walking a “Fin”, as I discovered, was not my favorite mode of travel. Most of the Fin was about five-foot wide, except for those parts that were four-foot wide. I kept to the lee side, where the drop down was only about twenty-five feet. To starboard it was a sheer drop of 300-feet. The wind was up and kept buffeting me to starboard.

We were on a 6-mile hike along the Devil’s Garden Trail at Arches National Park, Utah. I have no pictures of the Fin we hiked on. The picture in the next panel shows a Fin that we saw on the Fiery Furnace Trail later that afternoon. It is a bit of an exaggeration, since the Fin we hiked on started and ended on solid footing, but I felt as unstable as the knob atop this one appears. Fins are created by erosion and, as you will see, erosion is an essential theme of this story.

What follows is a little geology, a little anthropology, a little natural history, and even more about Cryptobiotic Soils.

The Colorado Plateau is geologically and ecologically unique. It occupies a good part of the Four Corners area, where the four square corners of Utah, Colorado, New Mexico, and Arizona meet. It has been a single geological province 500-million years, much of that time under shallow seas [REF 1]. Most of its strata are marine-deposited sandstone. The Triassic Navajo Sandstone, 2,500-ft thick, is one such sandstone. Another is the Entrada Sandstone.

Still showing the “petrified dunes” of their shallow-sea history, water has eroded these formations from flat plateaus into Fins, Hoodos, Towers, Knobs, Arches, Bridges, and caves. Most of the excitement that produced the present-day exotic geology is water erosion that happened so recently as to be coincident with human evolution.

Our trip was a two-week spring visit to the US National Parks and Monuments in Utah. We hiked in Arches, Canyonlands, Natural Bridges, Cedar Mesa, Escalante Winding Staircase, Bryce Canyon, and Zion. We had driven from San Francisco and the bit of roadside art below shows about how we felt driving back.

The spring flowers were out, those brilliant desert plants that bloom the instant it rains [REF 2]. The picture below shows one of the most colorful of the desert spring flowers of the Colorado Plateau, Claret Cup.

Many of the animals were noticed by their leavings, which is why I carried my “Scats & Tracks” [REF 3]. This may seem prosaic, but there is some excitement in identifying the scat of a rare critter, even more rarely seen. That happened when I came upon the tiny leavings of a seldom-seen desert vole.

We did see many lizards and one female wild turkey. One of those lizards is shown below:

We also found a number of abandoned cliff dwellings. Over a span of 8,000-years the “ancestors” [called “Anasazi” by the Navajo] built stone houses and lived on flat-floored niches in the cliff faces of canyons [REF 4].

Most cliff dwellings are found clustered together at at specific sites the Colorado Plateau. Wind, cold and water Frequently they decorated vertical surfaces nearby with petroglyphs, which may have served as warnings, religious symbols,

or simply “news”. Petroglyphs are found throughout the Colorado Plateau, like this one, taken at “News Rock”, near Canyonlands.

My field microscopy started when we were hiking at Arches National Park and I began to notice a peculiar crusty soil that surrounded every hiking path. Many signs warned hikers not leave the path or disturb this soil.

Cryptobiotic Soil crusts [REF 2 and Jane Belnap's USGS Cryptobiotic Soils page] are now recognized as playing an important ecological role in the cold, dry deserts of the Colorado Plateau.

Shown below is a close-up of about a square-foot of mature Cryptobiotic Soil, mostly sand. The dark areas are typical of well-developed crust, and the lichens on the central clump of soil show maturity. While reading this chapter, you may want to download a Technical Reference in PDF format -

Jane Belnap, et. al. http://www.soilcrust.org/advanced.htm . This is a very good paper on cryptobiotic soils and includes many photographs and has a reference section for further study.

Although this soil community also contains lichen and mosses, it is initiated by and dominated by cyanobacteria.

On the Colorado Plateau, the species of cyanobacteria commonly found in cryptobiotic soil is Microcoleus vaginatus, shown above.

Microcoleus vaginatus is a large, filamentous green cyanobacterium. Each segment in a filament is an individual bacterium, as is more apparent in the close-up view shown below.

Cyanobacteria are photosynthetic and were originally called “blue-green algae”. At one time they were studied in botany departments, but got kicked over to the microbiology departments when it was discovered they were actually bacteria. Many are motile, but M. virginatus is not.

Filaments ranged considerably in length. Shown below is an entire short filament, but I found some filaments as long as 0.3-mm. <>

One of the more interesting and increasingly accepted hypotheses of evolution is that chloroplasts, the photosynthetic organelles of higher plants, were originally cyanobacteria [REF 5]. According to this hypothesis, some early non-photosynthetic eucaryotic cell ingested a cyanobacterium and the two negotiated a mutualism that, in plant cells, has lasted to this day.

In dry soil, M. vaginatus remains dormant in a cryptobiotic [desiccated] state. When water is provided, the bacterial filaments come out of dormancy and, given sunlight, begin growing rapidly.

I examined dry cryptobiotic sand and found no apparent cyanobacterial filaments. When water was added, filaments were evident within a matter of minutes.

Although the transition from a cryptobiotic state to an actively growing state is rapid, achieving a cryptobiotic state takes much longer and requires many physiological changes. The water content of soil is high, even as it dries out. During desiccation, it passes through a long phase during which the relative humidity of the atmosphere in the spaces between the grains is near 99%. This triggers the physiological changes that enable cryptobiotic organisms to survive desiccation and cold.

As they grow, the bacterial filaments produce a sticky mucilaginous polysaccharide sheath, usually covering a number of filaments.

This sheath is shown in the photomicrograph below..

This sticky mucilaginous sheath binds the filaments to soil particles, producing a matrix that is sufficiently strong to make the soil surface crusty. As the soil dries out, the filaments return to a cryptobiotic state, and the sheath around them remains connected to the soil grains, pulling the grains tightly together.

A photomicrograph of a bound soil particle is shown below.

The binding quality of the cyanobacteria is evident from the observation that the angle of repose for dry cryptobiotic sand is much steeper than for ordinary dry sand, which is about 34°. You can get a sense of this by examining the larger fragments in the picture of cryptobiotic soil shown earlier. The face of the dark mottled area to the right of the lichen-dotted fragment was almost perpendicular.

With time, fungi, algae, lichens, and mosses join the community and it becomes an inviting place for colonization by higher plants.

Notice that the Claret Cup in the photograph near the beginning of this article is growing on cryptobiotic soil. Cryptobiotic soil is the first step in producing arable soils in a desert ecosystem, playing an essential role in stabilizing desert soil and limiting erosion. When dry, however, cryptobiotic soil is brittle and does not resist footprints. Wind and water erosion follows quickly, once a careless hiker breaks the crust. The shortest recovery time for such disturbed soil is in the order of 5 years. A mature soil may take up to 50 years to form.

These photomicrographs of Microcoleus vaginatus were made in the field at Arches National Park, Utah [N 38-deg 46.925' W109-deg 35.677'], on the Devils Garden Loop Trail near Landscape Arch.

A hiker had left the trail and disturbed an area of cryptobiotic soil. Some of the cryptobiotic soil fragments had been kicked onto the trail from the disturbed area. I placed few grains of this soil onto a microscope slide and wet them with about 50-microliters of water. Then I put a cover slip over the soil/water mixture and placed the slide in a shady area for awhile before popping it under the microscope.

After observation and photographing, the contents of the slide were washed back onto the soil near the trail.

The National Park rules require that “nothing be taken out” and that you leave intact cryptobiotic soil crust undisturbed. If you want to observe the life in cryptobiotic soil, sample from the trail where hikers are already walking. If you want to keep a sample for extended observation, collect it outside the National Park areas [almost all sandy soil anywhere in the Colorado Plateau develops cryptobiotic crust].

My observations were made over a period of about 30-minutes, at 40X, 100X, 400X, and 800X under both brightfield and phase contrast.

Photomicrographs were taken at 400X bright field using my Nikon Coolpix 885 digital camera, with full optical zoom and either no “electronic zoom” or 2.0X electronic zoom.

About half the full optical zoom was necessary to prevent vignetting, but intermediate values of optical zoom are not calibrated and I found it simpler to always use the full value.

Because it is so complicated and different, one could easily spend a lifetime of vacations hiking the various parts of the Colorado Plateau and observing the many ways life has adapted to its harsh conditions. Everywhere, life struggles against the erosion that promises to wear the high plateau down to a low plain.

Besides cryptobiotic soil, in our brief trip I encountered new micro-flora in ephemeral pools, dry streambeds, vertical communities next to waterfalls, and seep communities.

Perhaps the most fascinating of these other communities were ephemeral pools: Shallow sandy-bottomed depressions in the rim rock above the canyons. I tried to photograph the Whiptail lizard shown earlier as it paused in such a depression, but it hurried on to bare rock.

A microscopic examination of the dry sand from one of these depressions shows only a few diatom skeletons. Such depressions fill with water after a rain, and from the sand explodes a community of microbes: Cyanobacteria of many kinds, diatoms, algae, fungi, lichens, protozoa, rotifers, nematodes, and higher creatures that have found ways of surviving periods of intense cold, heat, and desiccation. Some produce resistant spores or other propagules, some enter directly into cryptobiotic states, but all are equipped to rapidly return to active metabolism when the rains come and all complete a life cycle with the metronome ticking at “presto”.

In the photomicrograph below, green cyanobacteria were apparent within minutes of adding 100-microliters of water to a little dry sand in a depression slide. In less than an hour, these motile cells were dividing and moving at their slow and stately pace!

REFERENCES

[1] Fran A. Barnes (2000) Canyon Country Geology for the Layman and Rockhound: A guide to understanding the unique and spectacular geology of the canyon country of southeastern Utah and vicinity, with a special section on rockhounding. Arch Hunter Books, Thompson Springs, UT. 160-pp. $12.95.

[2] David Williams and Gloria Brown (2000) A Naturalist’s Guide to Canyon Country. Falconâ Publishing, Inc., Helena, MT, in cooperation with Canyonlands Natural History Association. 188-pp. $22.95. Note Gloria Brown’s excellent illustrations.

[3] James C. Halfpenny and Todd Telander (2000) Scats and Tracks of the Desert Southwest – A Field Guide to the Signs of 70 Wildlife Species. Falconâ Publishing, Inc., Helena, MT. 144-pp. $9.95.

[4] Val Brinkerhoff and A. Dudley Gardner (2000) Architecture of the Ancient Ones. Gibbs Smith, Layton, Utah. 80-pp. $19.95.

[5] Lynn Margulis and Dorion Sagon (1986) Microcosmos – Four Billion Years of Evolution from Our Microbial Ancestors. Simon & Schuster Touchstone Books, NY. 298-pp. $10.00. See Chapters 6 and 7.

INTERNET LINKS

[2] Southwest guide to Utah National Parks and Monuments: http://www.americansouthwest.net/utah/

[3] Chaco Culture National Historical Park: http://www.nps.gov/chcu/home.htm

[4] Biological Soil Crusts: http://www.soilcrust.org/

[5] Jane Belnap [1997] Cryptobiotic Soils: Holding the place in place. USGS: http://geochange.er.usgs.gov/sw/impacts/biology/crypto/

[6] Download a Technical Reference in PDF - Jane Belnap, et. al. [2001] Biological Soil Crusts: Ecology and Management. USDA Tech. Ref. 1730-2: http://www.soilcrust.org/advanced.htm This is a very good paper on cryptobiotic soils and includes many photographs and has a good reference section for further study.

[7] Sites dealing with cyanobacteria, including systematics:

http://www.ucmp.berkeley.edu/bacteria/cyanointro.html General

http://www-cyanosite.bio.purdue.edu/ Systematics

http://www.ucmp.berkeley.edu/bacteria/cyanolh.html Life History & Ecology