HomeDAVAO RESEARCH JOURNALvol. 15 no. 3 (2024)

Strategies for falcata (Falcataria falcata (L.) Greuter and R.Rankin) farmers to mitigate gall rust severity across elevations

Adrian M. Tulod | Jupiter V. Casas | Mark Jun A Rojo | Rico A. Marin | Bryan Allan M. Talisay | Eric N. Bruno | Nympha E. Branzuela | Edgar B. Solis | Sheryl S. Bayang | Joan S. Gilbero | Mhar O. Loquez | Espie M. Praca | Dennis M. Gilbero

Discipline: environmental sciences

 

Abstract:

The extent of gall rust severity in Falcata plantations across various elevations and locations in the country is insufficiently documented, posing challenges for developing an integrated disease management strategy. This study aimed to assess the conditions favorable for gall rust severity in Falcata plantations at different elevations in Mindanao. Our survey revealed that gall rust severity is significantly higher at elevations exceeding 400 m above sea level (asl), with potential yield losses estimated between 23% and 52% of the total log volume per hectare. Factors contributing to increased severity, regardless of elevation, include low stand density (<1000 trees/ha), extended distances from natural vegetation (>1000 m), low understorey species diversity, and low average temperatures (<24°C). These factors interact significantly with elevation, as higher severity was observed in plantations with greater understorey vegetation diversity and elevated temperatures (>24°C), particularly at elevations over 600 m (asl). Based on our findings, it is recommended to avoid planting Falcata in areas with elevations exceeding 400 m (asl). However, if planting at higher elevations is unavoidable, adequate tree spacing (3 m x 3 m or 3 m x 4 m) should be maintained to achieve a moderate stand density (1000-1500 trees/ha). This practice can help regulate air circulation within the plantation, mitigate pathogen spread, and control understory vegetation growth and temperature impacts. Additionally, establishing and maintaining native vegetation or forest within 1000 m around Falcata plantations is advisable to create a protective buffer zone, thereby reducing gall rust severity.



References:

  1. Avelino, J., Gagliardi, S., Perfecto, I., Isaac, M. E., Liebig, T., Vandermeer, J., Merle, I., Hajian-Forooshani, Z., and Motisi, N. (2023). Tree effects on coffee leaf rust at field and landscape scales. Plant Disease, 107(2), 247-261.https://doi.org/10.1094/PDIS-08-21-1804-FE
  2. FMB-DENR. (2022). Philippine Forestry Statistics. Forest Management Bureau-Department of Environment and Natural Resources (FMB-DENR), Philippines.
  3. Lacandula, L., Rojo, M. J., Casas, J., and Puno, G. R. (2017). Geospatial analysis on the influence of biophysical factors on the gall rust prevalence in falcata (Paraserianthes falcataria L. Nielsen) plantation in Gingoog city, Philippines. https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3588102
  4. Paler, D. A., Shinohara, T., Del Castillo, R. A., and Nomura, I. (1998). Development of industrial tree plantation in the administrative region No. 10, in mindanao island, philippines: With two case studies. Journal of Forest Research, 3(4), 193-197 https://link.springer.com/article/10.1007/BF02762192 .
  5. PCAARRD. (2010). Challenges and Recommendations in the Industrial Tree Plantations. Policy Brief.
  6. R Core Team. (2022). R: A language and environment for statistical computing. R Foundation for Statistical Computing.
  7. Rahayu, S., See, L., Shukor, N., and Saleh, G. (2018). Environmental factors related to gall rust disease development on falcataria moluccana (miq.) barneby and jw grimes at brumas estate, Tawau, Sabah, Malaysia. Applied Ecology and Environmental Research, 16(6), 7485-7499. https://www.epa.hu/02500/02583/00056/pdf/EPA02583_applied_ecology_2018_06_74857499.pdf
  8. Rahayu, S., Widiyatno, W., and Adriyanti, D. T. (2020). Pathogenesis of gall-rust disease on Falcataria moluccana in areas affected by Mount Merapi eruption in Indonesia. Biodiversitas Journal of Biological Diversity, 21(4). https://smujo.id/biodiv/article/view/5059
  9. Ratnadass, A., Fernandes, P., Avelino, J., and Habib, R. (2012). Plant species diversity for sustainable management of crop pests and diseases in agroecosystems: a review. Agronomy for sustainable development, 32, 273-303. https://link.springer.com/article/10.1007/s13593-011-0022-4
  10. Tulod, A. M., Casas, J. V., Rojo, M. J. A., Aribal, L. G., Libayao, U. K. Y. F., and Monteroso, B. R. L. (2022). Gall Rust Disease Incidence and Severity in a Falcata (Falcataria moluccana (Miq.) Barneby and JW Grimes) Plantation Grown from Select Mother Trees in Mindanao, Philippines. CMU Journal of Science, 26(2). https://js.cmu.edu.ph/CMUJS/article/view/136
  11. Vittinghoff, E., Glidden, D. V., Shiboski, S. C., and McCulloch, C. E. (2006). Regression methods in biostatistics: linear, logistic, survival, and repeated measures models. http://dspace.kottakkalfarookcollege.edu.in:8001/jspui/bitstream/123456789/4250/1/Vittinghoff2005_Book_RegressionMethodsInBiostatisti.pdf
  12. Vuorinen, P., and Helander, M. L. (1995). Variation in airborne urediniospore concentration of Melampsoridium betulinum. Aerobiologia, 11, 259-264. https://link.springer.com/article/10.1007/BF02447206

Tools


Copyright © 2025  KITE Digital Educational Solutions |  Exclusively distributed by CE-Logic