Prioritizing analysis of forest genetic materials of seedlings of Falcataria moluccana (Miq.) Barneby and J. W. Grimes families in the secondary diffusion pathways

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Research Paper 01/08/2021
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Prioritizing analysis of forest genetic materials of seedlings of Falcataria moluccana (Miq.) Barneby and J. W. Grimes families in the secondary diffusion pathways

Jupiter V. Casas, Lowell G. Aribal, Enrique L. Tolentino Jr.
J. Bio. Env. Sci.19( 2), 51-66, August 2021.
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Abstract

Tree breeding program requires expediting laboratory analysis of genetic materials of Falcataria moluccana. This study was conducted to prioritize genetic materials for analysis by identifying the differences of families’/provenances’ seedling germination, diameter, root-shoot ratio, and biomass as influenced by growth stressors. Ten families from secondary diffusion pathways consisting of five provenances were used in the study. A nursery experiment laid out in completely randomized design was set up with four treatments: Treatment 1(acidic dry soil); Treatment 2(acidic wet soil); Treatment 3(alkaline dry soil); Treatment 4(alkaline wet soil). Ten seedlings in five replications were used for each treatment. Standardized protocol used pH of 4.2 acidic and 7.2 alkaline; every other day watering of 200ml/seedling for dry, and everyday watering of 200ml for wet. Results showed that soil pH had no significant effect to germination. The acidic wet soil treatment significantly resulted in the highest seedling height, diameter, and biomass. Root-shoot ratio was not significantly affected by the treatments. Significant variation among families was evident in seedling height and diameter, but not in root-shoot ratio and biomass. Difference among provenances was not significant indicating that families are possibly closely related with each other due to proximity of their locations. The genetic materials of Fm071, Fm078, Fm059, Fm085, and Davao Oriental and Compostela Valley provenances are priority for laboratory analyses. The protocol of the study is highly relevant to fast track and optimizes efficiency in genetic analysis.

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Alfas P, Jurga J, Lygis V, Suchockas V, Bajerkevičienė G, Verbylaite R. 2018. Response of juvenile progeny of seven forest tree species and their populations to simulated climate change-related stressors, heat, elevated humidity and drought. iForest 11, 374-388.

Anderegg LDHilleRisLambers J. 2016. Drought stress limits the geographic ranges of two tree species via different physiological mechanisms. Glob Chang Biol 22(3),1029-45. https://doi.org/10.1111/gcb.1318

Azad S, Nahar N, Mollick AS, Matin A. 2014.Variation in seedling growth of Tamarindus indica (L.): A threatening medicinal fruit tree species in Bangladesh. Journal of Ecosystems, 2014. Retrieved: January 20, 2021 from https:// www.hindawi.com/journals/jeco/2014/2709

Baskorowati L, Susanto M, Charomaini M. 2012. Genetic variability in resistance of Falcataria mollucana (Miq.). Journal of Forestry Research 9(1), 1-9. Retrieved: January 20, 2021 from: https://www.forda-mof.org/files/Baskorowati

Bhattacharya A. 2019. Changing environmental condition and phosphorus-use efficiency in plants. In. Changing climate and resource use efficiency in plants. Academic press. Elsevier Inc. U.K. and U.S p. 241-345. https://doi.org/10.1016/B978-0-12-816209

Calvo-Albarado JC, Arias DL, Richter DD. 2007. Early growth performance of native and introduced fast growing tree species in wet to sub-humid climates of the Southern region of Costa Rica. Forest Ecology Management 242(2-3), 227-235. Retrieved: January 20, 2021 from: https://www.academia.edu/7149895/

Carandang AP, Carandangmg, Camacho LD, Camacho SC, Aguilon BC, Gevaña DT. 2015. Profitability of smallholder private tree plantations in Talacogon, Agusan Del Sur, Philippines. Ecosystems and Development Journal, 5(3), 3–11. Retrieved: January 20, 2021.

Carles S, Lamhamedi M, Beaulieu J, Colas F, Stowe D, Margolis H. 2009. Genetic variation in seed size and germination patterns and their effect on white spruce seedling characteristics. Silvae Genetica 58(4), 152-161. DOI: 10.1515/sg-2009-0020

Casas JV, Aribal LG, Tolentino EL. 2020. Juvenile variation of Paraserianthes falcataria (L). Journal of Biodiversity and Environmental Sciences 16(5), 12-23.

Ch’ng HY, Amhed OH, Majid NM. 2014. Improving phosphorus availability in an acid soil using organic amendments produced from agro-industrial wastes. The Scientific World Journal, 2014. https://doi.org/10.1155/2014/506356

Fotelli M, Korakaki E, Paparrizos S, Radoglou K, Awada T, Matzarakis A. 2019. Environmental controls on the seasonal variation in gas exchange and water balance in a near-coastal Mediterranean Pinus halepensis Forest. Forests 10(13), 1-18.

Gentili R, Ambrosini R, Montagnani C, Caronni S, Citterio S. 2018. Effect of soil pH on the growth, reproductive investment and pollen allergenicity of Ambrosia artemisiifolia. L.Frontiers in Plant Science 9, 1335.

Ghaderi-Far F, Gherekloo J, Alimagham M. 2010. Influence of environmental factors on seed germination and seedling emergence of yellow sweet clover (Melilotus officinalis). Planta Daninha 28(3), 463-469.

Ivetić V, Devetaković J, Nonić M, Stanković D, Nikolić MS. 2016. Genetic diversity and forest reproductive material from seed source selection to planting. iForest Biogeosciences and Forestry 9(5), 801-812. https://doi.org/10.3832/ifor1577-009

Krisnawati H, Varis E, Kallio M, Kanninen M. 2011. Paraserianthes falcataria (L.) Nielsen ecology, silviculture and productivity. Center for International Forestry Research, Bogor, Indonesia. Retrieved: January 20, 2021 from: https://www.cabi.org/ ISC/FullTextPDF/2011/20113322381.pdf

Kupers SJ, Engelbrecht BMJ, Hernández A, Wright SJ, Wirth C, Rüger N. 2019. Growth responses to soil water potential indirectly shape local species distributions of tropical forest seedlings. Journal of Ecology 107, 860-874.

Kurinobu S, Chigira O, Matsune K, Miura M, Naiem M. 2013. Provenance variation in height development of Albizia falcataria under three levels of spacing in East Java, Indonesia. Silvae Genetica 62(1-2), 44-51. https://doi.org/10.1515/sg-2013-6

Lacandula LF, Rojo MJA, Puno GR, Casas JV. 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. Journal of Biodiversity and Environmental Science 11(4), 18-24.

Lin T, Zheng H, Huang Z, Wang J, Zhu J. 2018. Non-structural carbohydrate dynamics in leaves and branches of Pinus massoniana (Lamb.) following 3-year rainfall exclusion. Forests 9(6), 315.

Mašková T, Herben T. 2018. Root: shoot ratio in developing seedlings: How seedlings change their allocation in response to seed mass and ambient nutrient supply. Ecology and Evolution 8(4), 1-8.

Müller M, Gailing O. 2019. Abiotic genetic adaptation in the Fagaceae. Plan Biology 21(5), 783-795.

Navegantes PCA, De Oliveira MSP, Nunes JAR. 2018. Genetic parameters of traits at the juvenile stage of different assai palm tree progenies. Pesquisa Agropecuária Brasileira 53(7), 815-823.

Neina D. 2019. The role of soil pH in plant nutrition and soil remediation. Applied and Environmental Soil Science 2019. 1-9.

Ngulube MR. 1989. Genetic variation in seed germination and seedling growth of 24 Gliricidia sepium provenances. Forest Ecology and Management 28(1), 1-6.

Pessarakli M, Haghighi M, Sheibanirad A. 2015. Plant responses under environmental stress conditions. Advances in Plants & Agriculture Research 2(6), 276-286.

Pierce GL, Warren SL, Mikkelsen R, Linker HM. 1999. Effects of soil calcium and pH on seed germination and subsequent growth of large crabgrass (Digitaria sanguinalis). Weed Technology 13(2), 421-424. DOI:10.1017/S0890037X00041968

Polle A, Rennenberg H. 2019. Physiological responses to abiotic and biotic stress in forest trees. Forests 10 (9), 711. DOI: 10.3390/f10090711

Saboya P, Borghetti F. 2012. Germination, initial growth, and biomass allocation in three native Cerrado species. Brazilian Journal of Botany 35, 129-135. Retrieved: January 20, 2021 from: https://www.researchgate.net/publication/22833540

Sang W, Liu X, Axmacher JC. 2011. Germination and emergence of Ambrosia artemisiifolia L. under changing environmental conditions in China. Plant Spec. Biol, 26, 125-133.

Santosa S. 2016. Growth and physical quality of Paraserianthesfalcataria (L) Nielsen seedling on ten types of transplanting media. International Journal of Plant Biology 7(1), 36-39.

Shabrina H, Siregar UJ, Matra DD, Siregar IZ. 2019. The dataset of de novo transcriptome assembly of Falcataria moluccana cambium from gall-rust (Uromycladium falcatarium) infected and non-infected tree. Journal Data in Brief 26, 104489. https://doi.org/10.1016/j.dib.2019.104489

Siladan MU. 2010. Assessment of seed distribution, dissemination and diffusion pathways of priority tree plantation species in the Philippines. PhD thesis. University of the Philippines Los Baños, College Laguna, Philippines p. 225. Retrieved: January 20, 2021 from: https://agris.fao.org/agris-search/ search.do?recordID=PH2011000081

Silva DD, Kane ME, Beeson RC. 2012. Changes in root and shoot growth and biomass partition resulting from different irrigation intervals for Ligustrum japonicum Thunb. Hort Science 47(11), 1634-1640.

Sudrajat DJ. 2015. Genetic variation of fruit, seed, and seedling characteristics among 11 populations of white jabon in Indonesia. Forest Science and Technology 12(1), 9-15. https://doi.org/10.1080/ 21580103.2015.1007896

Sun HG, Liu J, Dong RX, Jiang JM, Diao S, Li YJ. 2014. Effects of water stress on seedling growth and biomass allocation of toonaciliata var. pubescens. Forest Research 27, 381-387. Retrieved: January 20, 2021 from https://www.researchgate.net/ publication/286808233

Turner GD, Lau RR, Young DR. 1988. Effect of acidity on germination and seedling growth of Paulownia tomentosa. Journal of Applied Ecology 25(2), 561-567. DOI: 10.2307/2403844

Wang H, Liu L, Zhou D. 2012. Effects of soil water deficit on seedlings of different Medicago falcata L. populations. African Journal of Agricultural Research 7(21), 3228-3236. Retrieved: January 20, 2021 from https://academicjournals.org/journal/AJAR/article-full-text-pdf/EC3168438882

Warwell MV, Shaw RG. 2019. Phenotypic selection on ponderosa pine seed and seedling traits in the field under three experimentally manipulated drought treatments. Evolutionary Applications 12, 159-174. DOI: 10.1111/eva.12685

Watanabe S, Kaneko Y, Maesako Y, Noma N. 2017. Detecting the early genetic effects of habitat degradation in small size remnant populations of Machilus thunbergii Sieb. etZucc. (Lauraceae). International Journal of Forestry Research 2017. https://doi.org/10.1155/2017/9410626

Wee A, Li, Dvorak C, Hong Yan W. 2011. Genetic diversity in natural populations of Gmelina arborea: Implications for breeding and conservation. New Forests 43(4), 411-428. doi: 10.1007/s11056-011-9288-2

Wu F, Bao W, Li F, Wu N. 2008. Effects of drought stress and N supply on the growth, biomass partitioning and water-use efficiency of Sophora davidii seedlings. Environmental and Experimental Botany 63(1-3), 248-255.

Yuskianti V, Shiraishi S. 2017. Genetic diversity and genetic relationship of Sengon (Falcataria moluccana) revealed using single nucleotide polymorphism (SNP) markers. Indonesian Journal of Forestry Research 4(2), 85-94. DOI: 10.20886/ ijfr.2017.4.2.85-94

Zytynska SE, Fay MF, Penney D, Preziosi RF. 2011. Genetic variation in a tropical tree species influences the associated epiphytic plant and invertebrate communities in a complex forest ecosystem. Philos Trans R SocLond B Biol Sci 366(1569), 1329-1336. DOI: 10.1098/rstb.2010.0183