Effects of Light, Nutrient and Grass Competition on Growth of Seedlings of Four Tropical Tree Species

Rahul Bhadouria; Pratap Srivastava; Shivam Singh; Rishikesh Singh; A. S. Raghubanshi; J. S. Singh

doi:10.36808/if/2018/v144i1/121306

Effects of Light, Nutrient and Grass Competition on Growth of Seedlings of Four Tropical Tree Species

Authors

Rahul Bhadouria Ecosystems Analysis Laboratory, Department of Botany, Institute of Science, Banaras Hindu University, Varanasi-221005
Pratap Srivastava Ecosystems Analysis Laboratory, Department of Botany, Institute of Science, Banaras Hindu University, Varanasi-221005
Shivam Singh Ecosystems Analysis Laboratory, Department of Botany, Institute of Science, Banaras Hindu University, Varanasi-221005
Rishikesh Singh Institute of Environment and Sustainable Development (IESD), Banaras Hindu University, Varanasi-221005
A. S. Raghubanshi Institute of Environment and Sustainable Development (IESD), Banaras Hindu University, Varanasi-221005
J. S. Singh Ecosystems Analysis Laboratory, Department of Botany, Institute of Science, Banaras Hindu University, Varanasi-221005

DOI:

https://doi.org/10.36808/if/2018/v144i1/121306

Keywords:

Grass, Light, Nutrient, Plant Ecology, Seedlings, Tropical Dry Forest.

Abstract

The seedling stage is a sensitive and important stage in plant life. Hence, a thorough understanding of the ecology of individual species and environmental characteristics affecting seedling growth is necessary. Resources such as water, nutrient and light are the most important limiting factors that influence seedling survival and establishment. However, the effect of these environmental factors is modified by grass competition in tropical dry forests. In this study, we examined the effects of light and nutrient with and without grass on the growth of seedlings of four common dry tropical plant species, viz., Acacia catechu, Acacia nilotica ssp. indica, Ziziphus mauritiana and Terminalia arjuna. The growth parameters including height, girth, total dry weight, leaf area and number of leaves, relative growth rate in terms of height, diameter and dry weight were recorded for each species under different treatment combinations. All the species behaved differently under studied treatment combinations. Seedlings were more responsive to the nutrient addition in presence of light. Presence of grass had overall negative effect on growth of tree seedlings. Survival was found highest for A. nilotica ssp. indica and lowest for Z. mauritiana while reverse trend was observed for overall growth. We infer from the results that supplementation of nutrients have strong positive effect over the seedling survival and growth even under reduced light and presence of grass competition. Moreover, the findings also revealed that the regular weeding and nutrient supplementation under the existing forest vegetation may help in regeneration of the dry tropical vegetation by reducing seedling mortality even under dense canopy conditions.

References

Anderson J.M. and Ingram J.S.I. (1993). Tropical soil biology and fertility - A handbook of methods. Second Edition. United Kingdom, CAB International.

Barbosa E.R.M., van Langevelde F., Tomlinson K.W., Carvalheiro L.G., Kirkman K., de Bie S. and Prins H.H.T. (2014). Tree Species from Different Functional Groups Respond Differently to Environmental Changes during Establishment. Oecologia, 174:1345â€“57.

Bazzaz F.A. and Wayne P.M. (1994). Coping with environmental heterogeneity: the physiological ecology of tree seedling regeneration across the gap-understory continuum. In: Exploitation of environmental heterogeneity by plants. Ecophysiological processes above and belowground. Physiological ecology. A series of monographs, Texts and Treatises (Caldwell, M.M., R.W. Pearcy, Eds). New York, NY: Academic Press. 349â€“390 pp.

Bhadouria A., Singh R., Srivastava P. and Raghubanshi A.S. (2016). Understanding the ecology of tree-seedling growth in dry tropical environment: a management perspective. Energy Ecology and Environment, 1:296-309.

Bhadouria R., Srivastava P., Singh R., Tripathi S., Singh H. and Raghubanshi A.S. (2017a). Tree seedling establishment in dry tropics: an urgent need of interaction studies. Environment Systems and Decisions, 37: 88-100.

Bhadouria R., Singh R., Srivastava P., Tripathi S. and Raghubanshi A. S. (2017b). Interactive effect of water and nutrient on survival and growth of tree seedlings of four dry tropical tree species under grass competition. Tropical Ecology, 58(3) : 611-621.

Bloor J.M., Leadley P.W. and Barthes L. (2008). Responses of Fraxinus excelsior seedlings to grass-induced above- and below-ground competition. Plant Ecology, 194:293â€“304.

Bond W.J., Smythe K.A. and Balfour D.A. (2001). Acacia species turnover in space and time in an African Savanna, J. Biogeography, 28:117-128.

Brown J.R. and Archer S. (1999). Shrub invasion of grassland: recruitment is continuous and not regulated by herbaceous biomass and density. Ecology, 80:2385-2396.

Brown S. and Lugo A. (1990). Tropical secondary forests. J. Tropical Ecology, 6:1â€“32.

Ceccon E., Omstead I., Vazquez-Yanez C. and Campo-Alves J. (2002). Vegetation and soil properties in two tropical dry forests of differing regeneration status in Yucatan. Agrociencia, 36:621-631.

Chapin F.S. (1980). The mineral nutritional on wild plants. Annual Reviews in Ecology Evolution and Systematics, 11, 233-260.

Chapin F.S. (2003). Effect of plant traits on ecosystem and regional processes: A conceptual framework for predicting the consequences of global changes. Annals of Botany, 91:455-463.

Chaturvedi R.K., Raghubanshi A.S. and Singh J.S. (2011). Effect of Small-Scale Variations in Environmental Factors on the Distribution of Woody Species in Tropical Deciduous Forests of Vindhyan Highlands, India. J. Botany, 2011:1â€“10. Article ID 297097. DOI: http://dx.doi.org/10.1155/2011/297097.

Curt T., Coll L., Prevosto B., Balandier P. and Kunstler G. (2005). Plasticity in growth, biomass allocation and root morphology in beech seedlings as induced by irradiance and herbaceous competition. Annals of Forest Science, 62:51-60.

Dirzo R., Young H.S., Mooney H.A. and Ceballos G. (2011). Seasonally dry tropical forests: Ecology and conservation. Island Press. 408 pp.

Gerhardt K. (1993). Tree seedling development in tropical dry abandoned pasture and secondary forest in Costa Rica. J. Vegetation Science, 4:95-102.

Goodale U.M., Berlyn G.P., Ashton M.S., Gregoire T.G., Sinhakumara B.M.P. and Tennakoon K.U. (2012). Disturbance and tropical pioneer species: patterns of association across life history stages. Forest Ecology and Management, 227:54-66.

Goodale U.M., Berlyn G.P., Gregoire T.G., Tennakoon K.U. and Ashton M.S. (2014). Differences in seedling survival and growth among tropical rain forest pioneers in relation to canopy openness and herbivory. Biotropica, 46:183-193.

Grubb P.J., Lee W.G., Kollmann J. and Willson J.B. (1996). Interaction of irradiance and soil nutrient supply on growth of seedlings of ten European tall-shrub species and Fagus sylvatica. J. Ecology, 84:827â€“840.

Hammond D.S. (1995). Post-dispersal seed and seedling mortality of tropical dry forest trees after shifting agriculture, Chiapas, Mexico. J. Tropical Ecology, 11:295â€“313.

Hansen M.C., Stehman S. and Potapov P.V. (2011). Quantification of global gross forest cover loss, Proceedings of National Academy of Sciences (USA), 107:8650-8655.

Harmer R., Kiewitt A. and Morgan G. (2012). Effects of overstory retention on ash regeneration and bramble growth during conversion of a pine plantation to native broadleaved woodland. European J. Forest Research, 131:1833â€“1843.

Holdrige L.R. (1967). Life Zone Ecology. Tropical Science Centre San Jose, Costa Rica. 206 pp.

Huante P. and RincÃ³n E. (1998). Responses to light changes in tropical deciduous woody seedlings with contrasting growth rates. Oecologia, 113:53-66.

Hubbel S.P., Foster R.B., Oâ€™Brien S.T., Harms K.E., Condit R., Wechsler B., Wright S.J. and Loo De Lao S. (1999). Light-Gap Disturbances, Recruitment limitations, and tree diversity in a neotropical forest. Science, 283:554-557.

Jones R.H., Zaharitz R.R., Dixon M.P., Segal D.S. and Schneider R.L. (1994). Woody plant regeneration in four flooded forests. Ecological Monograph, 64:435-367.

Kalacska M., Sanchez-Azofeifa G.A., Calvo-Alvarado J.C., Quesada M., Rivard B. and Janzen D.H. (2004). Species composition, similarity and diversity in three successional stages of a seasonally dry tropical forest. Forest Ecology and Management, 200:227â€“247.

Kambatuku J.R., Cramer M.D. and Ward, D. (2011). Savanna tree-grass competition is modified by substrate type and herbivory. J. Vegetation Science, 22:225â€“237.

Khurana E. and Singh J.S. (2001). Ecology of seed and seedling growth for conservation and restoration of tropical dry forest: a review. Environmental Conservation, 28:39â€“52.

Khurana E. and Singh J.S. (2004). Germination and seedling growth of five tree species from tropical dry forest in relation to water stress: impact of seed size. J. Tropical Ecology, 20:385â€“396.

Khurana E. and Singh J.S. (2006). Impact of life-history traits on response of seedlings of five tree species of tropical dry forest to shade. J. Tropical Ecology, 22:653-661.

Kitajima K. and Tilman D. (1994). Seed bank and seedling establishment on an experimental productivity gradient seed bank and seedling on an experimental establishment productivity gradient. Oikos, 76:381-391.

Kraaij W.J. and Ward D. (2006). Effect of rain, nitrogen, fire, and grazing on tree recruitment and early survival in bush -encroached savanna, South Africa. Plant Ecology, 186:235-246.

Lawrence D. (2003). The response of tropical tree seedlings to nutrient supply: meta- analysis for understanding a changing tropical landscape. J. Tropical Ecology, 19:239-250.

Lieberman D. and Liberman M. (1984). The cause and consequences of synchronous flushing in dry tropical forest. Biotropica, 16:193-201.

Madsen P. (1995). Effects of soil water content, fertilization, light, weed competition and seedbed type on natural regeneration of beech (Fagus sylvatica). Forest Ecology and Management, 72:251â€“264.

Milberg P., Perez-Fernandez M.A. and Lamont B.B. (1998). Seedling growth response to added nutrients depends on seed size in three woody genera. J. Ecology, 86: 624-632.

Murphy P.G. and Lugo A.E. (1986). Ecology of tropical forest. Annual Reviews in Ecology Evolution and Systematics, 17:67-88.

Oâ€™Connor T.G. (1995). Acacia Karroo invasion of grassland: environmental and biotic effects influencing seedling emergence and establishment. Oecologia, 103:214â€“223.

Olsen S.R. and Sommers L.E. (1982). Phosphorus. In: Methods of soil analysis: Part 2. Chemical and microbiological properties. Agronomy mongraph No. 9, 2nd ed. (Page A.L., Miller R.H., Keeney D.R., Eds.), Madison, WI: American Society of Agronomy and Soil Science Society of America, 403â€“430 pp.

Raghubanshi A.S., Srivastava S.C., Singh R.S. and Singh J.S. (1990). Nutrient release in leaf litter. Nature, 346:227.

Rincon E. and Huante P. (1993). Growth responses of tropical deciduous tree seedling to contrasting light conditions. Trees, 7:202-207.

Sagar R., Archita S. and Singh J.S. (2008). Differential effect of woody plant canopies on species composition and diversity of ground vegetation: a case study. Tropical Ecology, 49:189-197.

Sahu P.K., Sagar R. and Singh J.S. (2008). Tropical forest structure and diversity in relation to altitude and disturbance in a Biosphere reserve in central India. Applied Vegetation Science, 11:461â€“470.

SÃ¡nchez-Azofeifa G.A., Quesada M., RodrÃguez J.P., Nassar J.M., Stoner K.E., Castillo A., Garvin T., Zent E.L., Calvo-Alvarado J.C., Kalacska M., Fajardo L., Gamon J.A. and Cuevas-Reyes P. (2005). Research Priorities for Neotropical Dry Forests. Biotropica, 37:477-485.

Sheldrick B.H. and Wang C. (1993). Particle size distribution. In: Soil sampling and methods of analysis (Carter M.R. Eds.). Boca Raton, FL: Canadian Society of Soil Science/Lewis Publishers, pp. 499â€“511

Singh A. (2006). Growth and leaf nutrient status of companion species as influenced by neighboring species in mixed plantations raised on mine spoil. Tropical Ecology, 47:259-269.

Singh J.S., Raghubanshi A.S., Singh R.S. and Srivastava S.C. (1989). Microbial biomass acts as a source of plant nutrients in dry tropical forests and savanna. Nature, 238:449â€“500.

Singh J.S. and Singh V.K. (1992). Phenology of seasonally dry tropical forest. Current Science, 63:684â€“689.

Singh K.P. and Singh J.S. (1988). Certain structural and functional aspects of dry tropical forests and savanna. Inter. J.Ecology and Environmental Sciences, 14:31â€“45.

Smith T.M. and Goodman P.S. (1987). Successional dynamics in an Acacia nilotica- Eucleadivinorum savannah in southern Africa. J. Ecology, 75:603-610.

Srivastava P., Singh P.K., Singh R., Bhadouria R., Singh D.K., Singh S., Afreen T., Tripathi S.N., Singh P., Singh H. and Raghubanshi A.S. (2016). Relative availability of inorganic N-pools shifts under land use change: an unexplored variable in soil carbon dynamics. Ecological Indicators, 64:228-236.

Stougaard J. (2000). Regulators and regulation of legume root nodule development. Plant Physiology, 124:531-540.

Tripathi S.N. and Raghubanshi A.S. (2013). Seedling growth of five tropical dry forest tree species in relation to light and nitrogen gradients. J. Plant Ecology, 7:250â€“263.

Tripathi S., Bhadauria R., Srivastava P., Singh R. and Raghubanshi A.S. (2017). Abiotic determinants of tree seedling growth in tropical dry forests. Advances in Plant Physiology, 17:119-131.

Troup R.S. (1921). The silviculture of Indian trees, Vols. 1â€“3. Oxford, UK: Clarendon Press.

van der Waal C., Kroon H.de., Boer W.F.de., HeitkÃ¶nig I.M.A., Skidmore A.K., Knegt H.J.de., van Langevelde F., van Wieren S.E., Grant R.C., Page B.R., Slotow R., Kohi E.M., Mwakiwa E. and Prins H.H.T. (2009). Water and nutrients alter herbaceous competitive effects on tree seedlings in a semi-arid savanna. J. Ecology, 97:430â€“439.

Van Hees A.F.M. and Clerkx A.P.P.M. (2003). Shading and root-shoot relations in saplings of silver birch, pedunculate oak and beech. Forest Ecology and Management, 176:439â€“448.

Vandenberghe C., FrelÃ©choux F. and Buttler A. (2008). The influence of competition from herbaceous vegetation and shade on simulated browsing tolerance of coniferous and deciduous saplings. Oikos, 117:415â€“423.

Walkley A. and Black I.A. (1934). An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Science, 37:9â€“38.

Walter M.B. and Reich P.B. (2000). Seed-size, nitrogen supply and growth rate affect tree seedling survival in deep shade. Ecology, 81:1887-1901.

Walters M.B. and Reich P.B. (1996). Are shade tolerance survival and growth linked? Low light and nitrogen effects on hardwood seedlings. Ecology, 77:841-853.

Winkler N., Weymann W., Auge H., Klotz S., Finkenbein P. and Heilmeier H. (2014). Drought resistance of native pioneer species indicates potential suitability for restoration of post-mining areas. Web Ecology, 14:65â€“74.

Zhang M., Zhu J., Li M., Zhang G. and Yan Q. (2013). Different light acclimation strategies of two coexisting tree species seedlings in a temperate secondary forest along five natural light levels. Forest Ecology and Management, 306:234â€“242.

Zhou Y., Tang J., Melillo J.M., Butler S. and Mohan J.E. (2011). Root standing crop and chemistry after six years of soil warming in a temperate forest, Tree Physiology, l31:707-717.