Hostname: page-component-78c5997874-4rdpn Total loading time: 0 Render date: 2024-11-10T14:32:11.994Z Has data issue: false hasContentIssue false
  • English
  • Français

Community structure and topographic distribution of lianas in a watershed on Okinawa, south-western Japan

Published online by Cambridge University Press:  01 November 2008

Buntarou Kusumoto ,
Tsutomu Enoki  and
Yasushi Watanabe
Buntarou Kusumoto*
Affiliation:
Graduate School of Bioresource & Bioenvironmental Science, Kyushu University, 394 Tsubakuro, Sasaguri, Kasuya, Fukuoka, 811-2415 Japan
Tsutomu Enoki
Affiliation:
Faculty of Agriculture, Kyushu University, 394 Tsubakuro, Sasaguri, Kasuya, Fukuoka, 811-2415 Japan
Yasushi Watanabe
Affiliation:
GIS-Okinawa, Kochinda, Yaese, Shimajiri, Okinawa, Japan
*
1Corresponding author. Email: kusumoto03@forest.kyushu-u.ac.jp
Get access Rights & Permissions [Opens in a new window]

Abstract:

We investigated spatial distribution of lianas, and examined relationships between distribution and topography in a secondary forest on the northern part of the main island of Okinawa, south-west Japan. All lianas with a stem diameter exceeding 2 cm at a point 1.3 m from the root were inventoried, and stem diameter and root position were measured within a small watershed (16.0625 ha). Geographical information systems (GIS) were used to divide the watershed into 257 cells in total, each cell being 25 m × 25 m. Three topographic parameters were measured in each cell: slope angle, slope aspect and relief. In total, 930 stems from 20 species of lianas were recorded. Distribution of all liana stems and 14 of 15 species analysed were biased toward concave sites. Abundance of total lianas was higher in concave sites than in convex sites. Our results suggest that distribution and abundance of lianas are strongly affected by topography, and that lianas tend to be distributed in sites with more water and nutrients, which are formed by relief in the Okinawa forest. Factors affecting stem density differed among species.

Keywords

catchmentclimbing plantsridgesubtropical evergreen broad-leaved foresttopographyvalley
Type
Research Article
Information
Journal of Tropical Ecology , Volume 24 , Issue 6 , November 2008 , pp. 675 - 683
Copyright
Copyright © Cambridge University Press 2008

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

LITERATURE CITED

BABWETEERA, F., PLUMPTRE, A. & OBUA, J. 2000. Effect of gap size and age on climber abundance and diversity in Budongo Forest Reserve, Uganda. African Journal of Ecology 38:230237.CrossRefGoogle Scholar
BRUBAKER, S. C., JONES, A. J., LEWIS, D. T. & FRANK, K. 1993. Soil properties associated with landscape positions and management. Soil Science Society of America Journal 57:235239.CrossRefGoogle Scholar
BURKE, I. C., REINERS, W. A. & OLSON, R. K. 1989. Topographic control of vegetation in a mountain big sagebrush steppe. Vegetatio 84:7786.CrossRefGoogle Scholar
DEWALT, S. J., SCHNITZER, S. A. & DENSLOW, J. S. 2000. Density and diversity of lianas along a chronosequence in a central Panamanian lowland forest. Journal of Tropical Ecology 16:119.CrossRefGoogle Scholar
DEWALT, S. J., ICKES, K., NILUS, R., HARMS, K. E. & BURSLEM, D. F. R. P. 2006. Liana habitat associations and community structure in a Bornean lowland tropical forest. Plant Ecology 186:203216.CrossRefGoogle Scholar
ENOKI, T. 2003. Microtopography and distribution of canopy trees in a subtropical evergreen broad–leaved forest in the northern part of Okinawa Island, Japan. Ecological Research 18:103113.CrossRefGoogle Scholar
GENTRY, A. H. 1991. The distribution and evolution of climbing plants. Pp. 349 in Putz, F. E. & Mooney, H. A. (ed.). The biology of vines. Cambridge University Press, Cambridge.Google Scholar
GERWING, J. J., SCHNITZER, S. A., BURNHAM, R. J., BONGERS, F., CHAVE, J., DEWALT, S. J., EWANGO, C. E. N., FOSTER, R., KENFACK, D., MARTÍNEZ-RAMOS, M., PARREN, M., PARTHASARATHY, N., PÉREZ-SALICRUP, D. R., PUTZ, F. E. & THOMAS, D. W. 2006. A standard protocol for liana censuses. Biotropica 38:256261.CrossRefGoogle Scholar
GESSLER, P. E., CHADWICK, O. A., CHARMRAN, F., ALTHOUSE, F. & HOLMES, K. 2000. Modeling soil-landscape and ecosystem properties using terrain attributes. Soil Science Society of America Journal 64:20462056.CrossRefGoogle Scholar
GRACE, J. & RUSSELL, G. 1982. The effect of wind and a reduced supply of water on the growth and water relations of Festuca arundinacea Schreb. Annals of Botany 49:217225.CrossRefGoogle Scholar
HATUSIMA, S. & AMANO, T. 1994. Flora of the Ryukyus, South of Amami Island. The Biological Society of Okinawa, Nishihara. 393 pp. (in Japanese).Google Scholar
HAYES, M., MOODY, A., WHITE, P. S. & COSTANZA, J. L. 2007. The influence of logging and topography on the distribution of spruce-fir forests near their Southern limits in Great Smoky Mountains National Park, USA. Plant Ecology 189:5970.CrossRefGoogle Scholar
HAZLETT, P. W. & FOSTER, N. W. 2002. Topographic controls of nitrogen, sulfur, and carbon transport from a tolerant hardwood hillslope. Water Air and Soil Pollution 2:6380.CrossRefGoogle Scholar
HEGARTY, E. E. & CABALLÉ, G. 1991. Distribution and abundance of vines in forest communities. Pp. 313335 in Putz, F. E. & Mooney, H. A. (ed.). The biology of vines. Cambridge University Press, Cambridge.Google Scholar
HUNTER, J. C. & PARKER, V. T. 1993. The disturbance regime of an old-growth forest in coastal California. Journal of Vegetation Science 4:1924.CrossRefGoogle Scholar
IBARRA-MANRÍQUEZ, G. & MARTÍNEZ-RAMOS, M. 2002. Landscape variation of liana communities in a Neotropical rain forest. Plant Ecology 160:91112.CrossRefGoogle Scholar
ITÔ, Y. 1997. Diversity of forest tree species in Yanbaru, the northern part of Okinawa Island. Plant Ecology 133:125133.CrossRefGoogle Scholar
KOUAMÉ, F. N'., BONGERS, F., POORTER, L. & TRAORÉ, D. 2004. Climbers and logging in the Forêt Classée du Haut-Sassandra, Côte-d'Ivoire. Forest Ecology and Management 194:259268.CrossRefGoogle Scholar
KUBOTA, Y., MURATA, H. & KIKUZAWA, K. 2004. Effects of topographic heterogeneity on tree species richness and stand dynamics in a subtropical forest in Okinawa Island, southern Japan. Journal of Ecology 92:230240.Google Scholar
KUBOTA, Y., KATSUDA, K. & KIKUZAWA, K. 2005. Secondary succession and effects of clear-logging on diversity in the subtropical forests on Okinawa Island, southern Japan. Biodiversity and Conservation 14:879901.CrossRefGoogle Scholar
KUSUMOTO, B. & ENOKI, T. 2008. Contribution of a liana species, Mucuna macrocarpa Wall., to litterfall production and nitrogen input in a subtropical evergreen broad-leaved forest. Journal of Forest Research 13:3542.CrossRefGoogle Scholar
LAURANCE, W. F., PÉREZ-SALICRUP, D., DELAMÔNICA, P., FEARNSIDE, P. M., D'ANGELO, S., JEROZOLINSKI, A., POHL, L. & LOVEJOY, T. E. 2001. Rain forest fragmentation and the structure of Amazonian liana communities. Ecology 82:105116.CrossRefGoogle Scholar
NAGAMATSU, D. & MIURA, O. 1997. Soil disturbance regime in relation to micro-scale landforms and its effects on vegetation structure in a hilly area in Japan. Plant Ecology 133:191200.CrossRefGoogle Scholar
PEÑALOSA, J. 1983. Shoot dynamics and adaptive morphology of Ipomoea phillomega (Veil.) House (Convolvulaceae), a tropical rainforest liana. Annals of Botany 52:737754.CrossRefGoogle Scholar
PEÑALOSA, J. 1984. Basal branching and vegetative spread in two tropical rain forest lianas. Biotropica 16:19.CrossRefGoogle Scholar
PHILLIPS, O. L., MARTÍNEZ, R. V., MENDOZA, A. M., BAKER, T. R. & VARGAS, P. N. 2005. Large lianas as hyperdynamic elements of the tropical forest canopy. Ecology 86:12501258.CrossRefGoogle Scholar
PUTZ, F. E. 1984. The natural history of lianas on Barro Colorado Island, Panama. Ecology 65:17131724.CrossRefGoogle Scholar
PUTZ, F. E. & CHAI, P. 1987. Ecological studies of lianas in Lambir National Park, Sarawak, Malaysia. Journal of Ecology 75:523531.CrossRefGoogle Scholar
ROY, S. & SINGH, J. S. 1994. Consequences of habitat heterogeneity for availability of nutrients in a dry tropical forest. Journal of Ecology 82:503509.CrossRefGoogle Scholar
SAKAI, A., NOMIYA, H. & SUZUKI, W. 2002. Horizontal distribution of stolons of a temperate liana Wisteria floribunda DC. and its ecological significance. Journal of Forest Research 7:125130.CrossRefGoogle Scholar
SATAKE, Y., HARA, H., WATARI, S. & TOMINARI, T. 1989a. Wild flowers of Japan. Woody plants I. Heibonsha, Tokyo. 321 pp. (In Japanese).Google Scholar
SATAKE, Y., HARA, H., WATARI, S. & TOMINARI, T. 1989b. Wild flowers of Japan. Woody plants II. Heibonsha, Tokyo. 321 pp. (In Japanese).Google Scholar
SCHNITZER, S. A. & BONGERS, F. 2002. The ecology of lianas and their role in forests. Trends in Ecology and Evolution 17:223230.CrossRefGoogle Scholar
SCHNITZER, S. A., DALLING, J. W. & CARSON, W. P. 2000. The impact of lianas on tree regeneration in tropical forest canopy gaps: evidence for an alternative pathway of gap-phase regeneration. Journal of Ecology 88:655666.CrossRefGoogle Scholar
TATENO, R. & TAKEDA, H. 2003. Forest structure and tree species distribution in relation to topography-mediated heterogeneity of soil nitrogen and light at the forest floor. Ecological Research 18:559571.CrossRefGoogle Scholar
TERAMURA, A. H., GOLD, W. G. & FORSETH, I. N. 1991. Physiological ecology of mesic, temperate woody vines. Pp. 245285 in Putz, F. E. & Mooney, H. A. (ed.). The biology of vines. Cambridge University Press, Cambridge.Google Scholar
WEBB, E. L., STANFIELD, B. J. & JENSEN, M. L. 1999. Effects of topography on rainforest tree community structure and diversity in American Samoa, and implications for frugivore and nectarivore populations. Journal of Biogeography 26:887897.CrossRefGoogle Scholar
YOKOYAMA, R., SHIRASAWA, M. & PIKE, R. J. 2002. Visualizing topography by openness: a new application of image processing to digital elevation models. Photogrammetric Engineering and Remote Sensing 68:257265.Google Scholar