Primary Colonization of Volcanic Rocks by Plants in Arid Baja California, Mexico

 

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Abstract

In an arid region of Baja California Sur, Mexico, field observations, combined with chemical and physical analyses, mineral analysis and scanning electron microscopy of unweathered and weathered volcanic rocks, revealed the presence of rock-colonizing plants (most are tree-shaped cacti, possibly rock weathering), growing in volcanic rocks without benefit of soil. Many are at the seedling stage. At least four cactus species (Pachycereus pringlei [S. Wats] Britt. and Ross, Stenocereus thurberi [Engelm.] Buxb. subsp. thurberi, Mamillaria fraileana [Britt. and Rose] Boed., Opuntia cholla F. A. C. Weber), and one tree (wild fig, Ficus palmeri [S. Wats]) were capable of cracking, growing in and colonizing cliffs and rocks formed from ancient lava flows and, consequently, forming soil for succession by other plant species. This study shows that plant colonization of volcanic rocks may assist soil formation, which eventually leads to accumulation of soil, water and nutrients in a desert terrestrial ecosystem that otherwise lacks these essential plant-growth variables.

References

• 01 Adams,  J. B.,, Palmer,  F.,, and Staley,  J. T.. (1992);  Rock weathering in deserts: mobilization and concentration of ferric iron by microorganisms.  Geomicrobiology Journal. 10 99-114
  Google Scholar
• 02 Angers,  D. A., and Caron,  J.. (1998);  Plant-induced changes in soil structure: processes and feedbacks.  Biogeochemistry. 42 55-72
  Google Scholar
• 03 Ascaso,  C.,, Sancho,  L. G.,, and Rodríguez-Pascual,  C.. (1990);  The weathering action of saxicolous lichens in maritime Antarctica.  Polar Biology. 11 33-40
  Google Scholar
• 04 Bashan,  Y.,, Davis,  E. A.,, Carrillo-Garcia,  A.,, and Linderman,  R. G.. (2000);  Assessment of VA mycorrhizal inoculum potential in relation to the establishment of cactus seedlings under mesquite nurse-trees in the Sonoran desert.  Applied Soil Ecology. 14 165-176
  Google Scholar
• 05 Bashan,  Y.,, Gonzalez-Bashan,  L. E.,, and Leon de la Luz,  J. L.. (2001);  King cactus. The giant cardon cactus of Baja California.  Wildflower. 17 10-16
  Google Scholar
• 06 Bashan,  Y.,, Toledo,  G.,, and Holguin,  G.. (1995);  Flat top decay syndrome of the giant cardon cactus (Pachycereus pringlei): description and distribution in Baja California Sur, Mexico.  Canadian Journal of Botany. 73 683-692
  Google Scholar
• 07 Berthelin,  J.,, Leyval,  C.,, Laheurte,  F.,, and de Giudici,  P.. (1991) Involvement of roots and rhizosphere microflora in the chemical weathering of soil minerals. Plant root growth: an ecological perspective. Atkinson, D., ed. Oxford, U. K.; Blackwell Scientific Publications pp. 187-200
  Google Scholar
• 08 Best,  M. G.. (1982) Igneous and metamorphic petrology. New York; W.H. Freeman and Company
  Google Scholar
• 09 Carrillo-Garcia,  A.,, Leon de la Luz,  J. L.,, Bashan,  Y.,, and Bethlenfalvay,  G. J.. (1999);  Nurse plants, mycorrhizae and plant establishment in a distributed area of the Sonoran desert.  Restoration Ecology. 7 321-335
  Google Scholar
• 10 Carrillo-Garcia,  A.,, Bashan,  Y.,, and Bethlenfalvay,  G. J.. (2000 a);  Resource-island soils and the survival of the giant cactus, cardon, of Baja California Sur.  Plant and Soil. 218 207-214
  CrossrefPubMedGoogle Scholar
• 11 Carrillo-Garcia,  A.,, Bashan,  Y.,, Diaz-Rivera,  E.,, and Bethlenfalvay,  G. J.. (2000 b);  Effects of resource-island soils, competition, and inoculation with Azospirillum on survival and growth of Pachycereus pringlei, the giant cactus of the Sonoran desert.  Restoration Ecology. 8 65-73
  CrossrefPubMedGoogle Scholar
• 12 Chang,  T. T., and Li,  C. Y.. (1998);  Weathering of limestone, marble, and calcium phosphate by ectomycorrhizal fungi and associated microorganisms.  Taiwan Journal of Forest Science . 13 85-90
  PubMedGoogle Scholar
• 13 Chen,  J.,, Blume,  H.-P.,, and Beyer,  L.. (2000);  Weathering of rocks induced by lichens colonization - a review.  Catena. 39 121-146
  CrossrefPubMedGoogle Scholar
• 14 Danin,  A., and Caneva,  G.. (1990);  Deterioration of limestones walls in Jerusalem and marble monuments in Rome caused by cyanobacteria and cyanophilous lichens.  International Biodeterioration. 26 397-417
  CrossrefPubMedGoogle Scholar
• 15 Flores,  E. Z.. (1998) Geosudcaliforniana. Universidad Autonoma de Baja California Sur, Mexico; Geografia, agua y ciclones
  Google Scholar
• 16 Franklin,  J. F., and Dyrness,  C. T.. (1973) Natural vegetation of Oregon and Washington. USDA Forest Service; General Technical Report PNW-8 417 p.
  Google Scholar
• 17 García-Carreño,  F. L.,, Troyo-Dieguez,  E.,, and Ochoa,  J. L.. (1992);  Relationships between saline ground water, soil and leaf tissue composition of the phreatophyte mezquite.  Ground Waters. 30 676-682
  PubMedGoogle Scholar
• 18 Gobran,  C. R.,, Clegg,  S.,, and Courchesne,  F.. (1998);  Rhizospheric processes influencing the biogeochemistry of forest ecosystems.  Biogeochemistry. 42 107-120
  CrossrefPubMedGoogle Scholar
• 19 Goudie,  A. S., and Parker,  A. G.. (1999);  Experimental simulation of rapid rock block disintegration by sodium chloride in a foggy coastal desert.  Journal of Arid Environments. 40 347-355
  PubMedGoogle Scholar
• 20 Gregory,  P. J., and Hinsinger,  P.. (1999);  New approaches to studying chemical and physical changes in rhizospher: an overview.  Plant and Soil. 211 1-9
  CrossrefPubMedGoogle Scholar
• 21 Hinsinger,  P., and Gilkes,  R. J.. (1993);  Root-induced irreversible transformation of triactahedral mica in the rhizosphere of rape.  Journal of Soil Science. 44 535-545
  PubMedGoogle Scholar
• 22 Hinsinger,  P., and Gilkes,  R. J.. (1995);  Root-induced dissolution of phosphate rock in the rhizosphere of lupins grown in alkaline soil.  Australian Journal of Soil Research. 33 477-489
  CrossrefPubMedGoogle Scholar
• 23 Hirsch,  P.,, Eckhardt,  F. E. W.,, and Palmer,  R. J. Jr.. (1995);  Fungi active in weathering of rock and stone monuments.  Canadian Journal of Botany. 73 (Suppl. 1) S1384-S1390
  PubMedGoogle Scholar
• 24 Illmer,  P.,, Barbato,  A.,, and Schinner,  F.. (1995 a);  Solubilization of hardy-soluble AIPO₄ with P-solubilizing microorganisms.  Soil Biology and Biochemistry. 27 265-270
  CrossrefPubMedGoogle Scholar
• 25 Illmer,  P., and Schinner,  F.. (1995 b);  Solubilization of inorganic calcium phosphate-solubilization mechanisms.  Soil Biology and Biochemistry. 27 257-263
  CrossrefPubMedGoogle Scholar
• 26 Jongmans,  A. G.,, van Breemen,  N.,, Lundstrom,  U.,, van Hees,  P. A. W.,, Finlay,  R. D.,, Srinivasan,  M.,, Unestam,  T.,, Giesler,  R.,, Melkerund,  P. A.,, and Olsson,  M.. (1997);  Rock-eating fungi.  Nature. 389 682-683
  CrossrefPubMedGoogle Scholar
• 27 Kelly,  E. F.,, Chadwick,  O. A.,, and Hilinski,  T. E.. (1998);  The effect of plants on mineral weathering.  Biogeochemistry. 42 21-53
  CrossrefPubMedGoogle Scholar
• 28 Leyval,  C.,, Laheurte,  F.,, Belgy,  G.,, and Berthelin,  J.. (1990);  Weathering of micas in the rhizosphere of maize, pine and beech seedlings influenced by mycorrhizal and bacterial inoculation.  Symbiosis. 9 105-109
  PubMedGoogle Scholar
• 29 Lundstrom,  U. S.,, van Breemen,  N.,, Bain,  D. C.,, van Hees,  P. A. W.,, Giesler,  R.,, Gustafsson,  J. P.,, Ilvesniemi,  H.,, Karltun,  E.,, Melkerud,  P. A.,, Olsson,  M.,, Riise,  G.,, Wahlberg,  O.,, Bergelin,  A.,, Hishop,  K.,, Finlay,  R.,, Jongmans,  A. G.,, Magnusson,  T.,, Mannerkoski,  H.,, Nordgren,  A.,, Nyberg,  L.,, Star,  M.,, and Strand,  L. T.. (2000);  Advances in understanding the podzolization process resulting from multidisciplinary study of three coniferous forest soils in the Nordic Countries.  Geoderma. 94 335-353
  CrossrefPubMedGoogle Scholar
• 30 Palmer,  R. J. Jr.,, Siebert,  J.,, and Hirsch,  P.. (1991);  Biomass and organic acids in sandstone of a weathering building production by bacterial and fungal isolates.  Microbial Ecology . 21 253-266
  PubMedGoogle Scholar
• 31 Phillips,  D. H., and FitzPatrick,  E. A.. (1999);  Biological influences on the morphology and micromorphology of selected Podzols (Spodosols) and Cambisols (inceptisols) from the eastern United States and north-east Scotland.  Geoderma. 90 327-364
  CrossrefPubMedGoogle Scholar
• 32 Sagoe,  C. I.,, Ando,  T.,, Kouno,  K.,, and Nagaoka,  T.. (1998);  Relative importance of protons and solution calcium concentration in phosphate rock dissolution by organic acids.  Soil Science and Plant Nutrition. 44 617-625
  PubMedGoogle Scholar
• 33 Van Breemen,  N.,, Finlay,  R.,, Lundstrom,  U.,, Jongmans,  A. G.,, Giesler,  R.,, and Olsson,  M.. (2000);  Mycorrhizal weathering: a true case of mineral plant nutrition?.  Biogeochemistry. 49 53-67
  CrossrefPubMedGoogle Scholar
• 34 Van Loon,  J. C.. (1985) Selected methods for trace metals. New York; Wiley-Interscience Publications pp. 281-282
  Google Scholar
• 35 Vazquez,  P.,, Holguin,  G.,, Puente,  M. E.,, Lopez-Cortes,  A.,, and Bashan,  Y.. (2000);  Phosphate-solubilizing microorganisms associated with the rhizosphere of mangroves growing in a semiarid coastal lagoon.  Biology and Fertility of Soils. 30 460-468
  CrossrefPubMedGoogle Scholar
• 36 Verges,  V.. (1985);  Solution and associated features of limestone fragments in a calcareous soil (Lithic Calcixeroll) from southern France.  Geoderma. 36 109-122
  CrossrefPubMedGoogle Scholar
• 37 Welton,  J. E.. (1984) SEM Petrology Atlas. Tulsa, Oklahoma; American Association of Petroleum Geologists
  Google Scholar

Y. Bashan

Environmental Microbiology
The Center for Biological Research of the Northwest (CIB)

P.O. Box 128
La Paz
B.C.S. 23000
Mexico

Email: bashan@cibnor.mx

Section Editor: M. C. Ball