Forward, backward selection and variation analysis of growth traits in half-sib Larix kaempferi families

Achere V (2004) Chloroplast and mitochondrial molecular tests identify Europe­an× Japanese larch hybrids. Theor Appl Genet 108: 1643-1649 https://doi.org/10.1007/s00122-004-1595-y10.1007/s00122-004-1595-y14991107Open DOISearch in Google Scholar

Bai TD, Xu LA, Wang ZR, Lin NQ, Zhang SH (2012) Estimation of parents genetic gain by open-pollinated progeny test of seedling seed orchard of Masson pine. Forest Research 25(4): 449-455Search in Google Scholar

Balocchi C, Bridgwater F, Zobel B, Jahromi S (1993) Age trends in genetic param­eters for tree height in a nonselected population of loblolly pine. Forest Sci 39(2): 231-251Search in Google Scholar

Cao Y (2016) Preliminary selection of superior families of Hybrid Larix gmelinii. Protection Forest Science and Technology 12: 26-36Search in Google Scholar

Collet C, Chenost C (2006) Using competition and light estimates to predict di­ameter and height growth of naturally regenerated beech seedlings grow­ing under changing canopy conditions. Forestry 79(5): 489-502 https://doi.org/10.1093/forestry/cpl03310.1093//cpl033Open DOISearch in Google Scholar

Cornelius J (1994) Heritabilities and additive genetic coefficients of variation in forest trees. Canadian Journal of Forest Research 24: 372-379 https://doi.org/10.1139/x94-05010.1139/x94-050Open DOISearch in Google Scholar

Dean CA, Stonecypher RW (2006) Early selection of Douglas-fir across south central coastal Oregon, USA. Silvae Genetica 55(3): 135-140 https://doi.org/10.1515/sg-2006-001910.1515/sg-2006-0019Open DOISearch in Google Scholar

Dhillon G, Singh A, Singh P, Sidhu DS (2010) Field evaluation of Populus deltoides Bartr. ex Marsh. at two sites in Indo-gangetic plains of India. Silvae Genetica 59: 1-7. https://doi.org/10.1515/sg-2010-000110.1515/sg-2010-0001Open DOISearch in Google Scholar

Diao S, Hou YM, Xie YH, Sun XM (2016) Age trends of genetic parameters, early selection and family by site interactions for growth traits in Larix kaempferi open-pollinated families. BMC Genetics 17: 104-115 https://doi.org/10.1186/s12863-016-0400-710.1186/s12863-016-0400-7493628627388017Open DOISearch in Google Scholar

Ding ZF, Wang JZ, Fang HF, Zhang XT, Yin YQ (2002) The growth of half-sib prog­eny in Larix kaempferi primary seed orchard. Journal of Forestry University 30(2): 9-12Search in Google Scholar

Falconer DS, Mackey TFC (1996) Introduction to quantitative genetics. 4th ed. Longman Group, London, UK. 463Search in Google Scholar

Fernando PG, James HR, Oliver F, Randi F, Brian JS, Richard S, Robert S, Mark FD, David BN (2016) Analysis of the genetic variation in growth, ecophysiology, and chemical and metabolomic composition of wood of Populus trichocar­pa provenances. Tree Genetics & Genomes 15: 965-972 https://doi.org/10.1007/s11295-015-0965-810.1007/s11295-015-0965-8Open DOISearch in Google Scholar

Fujimoto T, Kita K, Uchiyama K (2006) Age trends in the genetic parameters of wood density and the relationship with growth rates in hybrid larch (Larix gmelinii var. japonica × L. kaemferi) F1. The Japanese Forest Society and Springer Verlag Tokyo 11: 157-163 https://doi.org/10.1007/s10310-005-0200-910.1007/s10310-005-0200-9Open DOISearch in Google Scholar

Fukatsu E, Tsubomura M, Fujisawa Y, Nakada R (2013) Genetic improvement of wood density and radial growth in Larix kaempferi: results from a diallel mating test. Annals of Forest Science 70: 451-459 https://doi.org/10.1007/s13595-013-0278-810.1007/s13595-013-0278-8Open DOISearch in Google Scholar

Gapare WJ, Ivkovi´c M, Powell MB, McRae TA, Wu HX (2008) Genetics of shrink­age in juvenile trees of Pinus radiata D. Don from two test sites in Australia. Silvae Genet 57:145-151. https://doi.org/10.1515/sg-2008-002210.1515/sg-2008-0022Open DOISearch in Google Scholar

Goncalves P, Bortoletto N, Cardinal A, Gouvea L, Costa R, MoraesM (2005) Age-age correlation for early selection of rubber tree genotypes in Sao Paulo State, Brazil. Genet Mol Biol 28: 758-764 https://doi.org/10.1590/s1415-4757200500050001810.1590/s1415-47572005000500018Open DOISearch in Google Scholar

Guan LH, Pan HX, Huang, Shi JS (2005) Research on growth and wood proper­ties joint genetic improvement of new clones of Poplus deltoids (I-69) × P. euramericana (I-45). Journal of Nanjing Forestry University 29(2):6-10Search in Google Scholar

Gwaze DP, Bridgwater FE (2002) Determining optimum selection age for diame­ter and height in loblolly pine (Pinus taeda). For Genet 9:159-165Search in Google Scholar

Gwaze DP, Wolliams JA, Kanowski PJ, Bridgwater FE (2001) Interactions of geno­type with site for height and stem straightness in Pinus taeda in Zimbabwe. Silvae Genet 50:135-140Search in Google Scholar

Haapanen M (2001) Time trends in genetic parameter estimates and selection efficiency for Scots pine in relation to field testing method. Forest Genetics 8: 129-144Search in Google Scholar

Hannrup B, Elberg I, Persson A (2000) Genetic correlations among wood, growth capacity and stem traits in Pinus sylvetris. Scand. J. For. Res 15: 161-170 https://doi.org/10.1080/02827580075001496610.1080/028275800750014966Open DOISearch in Google Scholar

Hansen J, Roulund H (1996) Genetic parameters for spiral grain, stem form, pilo­dyn and growth in 13 years old clones of Sitka Spruce (Picea sitchensis (Bong.) Carr.). Silvae Genet 46: 107-113Search in Google Scholar

Hodge GR and White TL (1993) Advanced generation wind-pollinated seed or­chard design. New Forests 7: 213-236 . https://doi.org/10.1007/bf0012738710.1007/bf00127387Open DOISearch in Google Scholar

Hortensia S, Jordi S, Marcos B, Ciria MP, Isabel C (2011) Genetic variation and genotype-environment interactions in short rotation Populus plantations in southern Europe. New Forests 42: 163-177 https://doi.org/10.1007/s11056-010-9244-610.1007/s11056-010-9244-6Open DOISearch in Google Scholar

Hou YM, Quan YS, Cao J, Guan LH (2012) Study on superior family selection of Larix kaempferi. Journal of Central South University of Forestry and Technol­ogy 3(9): 6-10Search in Google Scholar

Huang SW, Zhong WH, Chen BQ (2006) Estimation on genetic gains of com­bined selection for growth traits of half-sib progrny of Pinus taeda. Scientia Silvae Sinicae 42(4): 33-37Search in Google Scholar

Isik K, Kleinschmit J, Steiner W (2010) Age-age correlations and early selection for height in a clonal genetic test of Norway spruce. Forest Science 56(2): 212-221Search in Google Scholar

Israel C, Weller JI (2000) Effect of misidentification on genetic gain and estima­tion of breeding value in dairy cattle populations. Journal of Dairy Science 83(1):181-188. https://doi.org/10.3168/jds.s0022-0302(00)74869-710.3168/jds.s0022-0302(00)74869-7Open DOISearch in Google Scholar

Jansson G, Li B, Hannrup B (2003) Time trends in genetic parameters for height and optimum age for parental selection in Scots pine. For Sci 49: 696-705Search in Google Scholar

Jonah P, Aliyu B, Jibung G, et al. (2011) Phenotypic and genotypic correlation in bambara groundnut (Vigna subterranea (L.) Verdc) in Mubi, Adamawa State, Nigeria. World Journal of Agricultural Sciences, 7 (3) : 298-303Search in Google Scholar

Kang H (1985) Juvenile selection in tree breeding: some mathematical models. Silvae Genet 34:75-84Search in Google Scholar

Kaushik N, Deswal RPS, Malik S, Kumar K (2015) Genetic variation and heritabili­ty estimation in Jatropha curcas L. progenies for seed yield and vegetative traits. Journal of Applied and Natural Science 7(2):567-573 https://doi.org/10.31018/jans.v7i2.64610.31018/jans.v7i2.646Search in Google Scholar

Kroon J, Ericsson T, Jansson G, Andersson B (2011) Patterns of genetic parame­ters for height in field genetic tests of Picea abies and Pinus sylvestris in Swe­den. Tree Genet Genomes 7(6): 1099-1111 https://doi.org/10.1007/s11295-011-0398-y10.1007/s11295-011-0398-ySearch in Google Scholar

Kumar D, Singh NB (2001) Age-age correlation for early selection of clones of Populus in India. Silvae Genet 50:103-108Search in Google Scholar

Kumar S, Lee J (2002) Age-age correlation and early selection for end of rotation wood density in radiata pine. Forest Genetics 9(4): 323-330Search in Google Scholar

Kung FH (1979) Improved estimators for provenance breeding values. Silvae Ge­netiea 28(2/3): 114-116Search in Google Scholar

Kurinobu S (2005) Forest tree breeding for Japanese larch. Euras J Forest Res 8: 127-134Search in Google Scholar

Lai M, Sun X, Chen D, Xie Y, Zhang S (2014) Age-related trends in genetic param­eters for Larix kaempferi and their implications for early selection. BMC Gen­et 15 Suppl 1:S10. https://doi.org/10.1186/1471-2156-15-s1-s1010.1186/1471-2156-15-S1-S10411863625078869Search in Google Scholar

Lee SJ, Woolliams J, Samuel CJ, Malcom DC (2002) A study of population varia­tion and inheritance in sitka spruce. Part III. Age trends in genetic parame­ters and optimum selection ages for wood density, and genetic correlations with vigour traits. Silvae Genet 51:143-151Search in Google Scholar

Leksono B, Kurinobu S, Ide Y (2006) Optimum age for selection base on a time trend of genetic parameters related to diameter growth in seedling seed or­chards of Eucalyptus pellita in Indonesia. Journal of Forest Research 11: 359- 363. https://doi.org/10.1007/s10310-006-0223-x10.1007/s10310-006-0223-xOpen DOISearch in Google Scholar

Liang DY, Zhang XX, Wang C, Wang XW, Li KL, Liu GF, Zhao XY, Qu GZ (2018 a) Evaluation of Betula platyphylla families based on growth and wood prop­erties traits. For. Sci. 64(6): 663-670. https://doi.org/10.1093/forsci/fxy02710.1093/forsci/fxy027Open DOISearch in Google Scholar

Liang DY, Ding CJ, Zhao GH, Leng WW, Zhang M, Zhao XY, Qu GZ (2018 b) Varia­tion and selection analysis of Pinus koraiensis clones in northeast China. J. For. Res. 29(3): 611-622. https://doi.org/10.1007/s11676-017-0471-y10.1007/s11676-017-0471-yOpen DOISearch in Google Scholar

Liu HW, Wang GY (2016) Fine families selectiong in half-sib progeny test of Larix gmelinii. Forestry Science and Technology 41(5):12-14Search in Google Scholar

Liu MR, Yin SP, Si DJ, Shao LT, Li Y, Zheng M, Wang FW, Li SC, Liu GF, Zhao XY (2015) Variation and genetic stability analyses of transgenic TaLEA poplar clones from four different sites in China. Euphytica 2: 331-342 https://doi.org/10.1007/s10681-015-1471-710.1007/s10681-015-1471-7Open DOISearch in Google Scholar

Louzada J, Fonseca F (2002) The heritability of wood density components in Pi­nus pinaster Ait, and the implications for tree breeding, Ann. For. Sci. 59:867- 873. https://doi.org/10.1051/forest:200208510.1051/forest:2002085Open DOISearch in Google Scholar

Ma S (2006) Studies on genetic variation and early selection of Japanese larch clones. M.S. Thesis of Henan Agricultural UniversitySearch in Google Scholar

Marques OG, Andrade HB, Ramalho MAP (1996) Assessment of the early selec­tion efficiency in Eucalyptus cloeziana F. Muell. in the northwest of Minas Gerais state (Brazil). Silvae Genet 45(5-6):359-361Search in Google Scholar

Montes CS, Hernandez RE, Beaulieu J, Weber JC (2008) Genetic variation in wood color and its correlations with tree growth and wood density of Caly­cophyllum spruceanum at an early age in the Peruvian Amazon. New Forest 35: 57-73. https://doi.org/10.1007/s11056-007-9060-910.1007/s11056-007-9060-9Open DOISearch in Google Scholar

Moriguchi Y, Kita K, Uchiyama K, Kuromaru M, Tsumura Y (2008) Enhanced hy­bridization rates in a Larix gmelinii var. japonica × L. kaempferi interspecific seed orchard with a single maternal clone revealed by cytoplasmic DNA markers. Tree Genetics and Genomes 4: 637-645 https://doi.org/10.1007/s11295-008-0139-z10.1007/s11295-008-0139-zOpen DOISearch in Google Scholar

Nakada R, Fujisawa Y, Taniguchi T (2005) Variations of wood properties between plus-tree clones in Larix kaempferi (Lamb.) Carrière. Bull For Tree Breed Cent 21: 85-105Search in Google Scholar

Pan XQ (2014) Genetic variation and selection of resin traits in Pinus elliottii. Mas­ter Thesis of Jiangxi Agricultural UniversitySearch in Google Scholar

Cáceres C B, Hernández R E, Fortin Y, et al. (2017) Wood density and extractive content variation among Japanese larch (Larix kaempferi [Lamb.] Carr.) progenies / provenances trials in eastern Canada. Wood & Fiber Science Journal of the Society of Wood Science & Technology 49(4): 363-372.10.1007/s00107-018-1302-3Search in Google Scholar

Silva F, Pereira MG, Ramos HC, Damasceno J, Pereira T, Gabriel A, Viana AP, Fer­reguetti GA (2008) Selection and estimation of the genetic gain in segregat­ing generations of papaya (Carica papaya L.). Crop Breeding & Applied Bio­technology 8:1-8. https://doi.org/10.12702/1984-7033.v08n01a0110.12702/1984-7033.v08n01a01Search in Google Scholar

Sumida A, Miyaura T, Torii H (2013) Relationships of tree height and diameter at breast height revisited: analyses of stem growth using 20-year data of an even-aged Chamaecyparis obtusa stand. Tree Physiol 33: 106-118 https://doi.org/10.1093/treephys/tps12710.1093/treephys/tps127355698523303367Open DOISearch in Google Scholar

Sun XM (2003) Selection of superior Larix kaempferi families for pulpwood pur­pose and family based growth simulation. Ph.D. Thesis of Chinese Academy of ForestrySearch in Google Scholar

Sun XM, Zhang SG, Hou YM, Li SY (2004) Age trends of genetic parameters for growth traits in short rotation Larix kaempferi families. Scientia Silvae Sini­cae 40 (6): 68-74Search in Google Scholar

Svensson J, McKeand S, Allen H, Campbell R (1999) Genetic variation in height and volume of loblolly pine open-pollinated families during canopy clo­sure. Silvae Genet 48:204-8Search in Google Scholar

Du CQ, Xu YZ, Sun XM, Liu YH, Xie PS (2015) Variation of growth traits and early selection of Larix kaempferi clones in sub-alpine area of western Hubei Province. Journal of Huazhong Agricultural University 34 (3): 19-23Search in Google Scholar

Teruyoshi N, Kazutoshi N, Hiroshi Y, Yoshihiko T (2014) Provenance tests for sur­vival and growth of 50-year-old Japanese larch (Larix kaempferi) trees relat­ed to climatic conditions in central Japan. Tree Genetics & Genomes 10: 87- 99. https://doi.org/10.1007/s11295-013-0666-010.1007/s11295-013-0666-0Search in Google Scholar

Toda R, Mikami S (1976) The provenance trials of Japanese larch established in Japan and the tentative achievements. Silvae Genet 25: 209-216Search in Google Scholar

Wang YC, Dong XG, Wang XS, Ma H (2000) Study on seed production and fruit­ing law of seed orchard in Larix kaempferi (Lamb.) carr. Scientia Silvae Sini­cae 36(2): 53-59Search in Google Scholar

Watanabe M, Watanabe Y, Kitaoka S, et al. (2011) Growth and photosynthetic traits of hybrid larch F1 (Larix gmelinii var. japonica × L. kaempferi) under ele­vated CO2 concentration with low nutrient availability. Tree Physiology 31(9): 965. https://doi.org/10.1093/treephys/tpr05910.1093/treephys/tpr05921813517Open DOISearch in Google Scholar

Wright JW (1976) Introduction to forest genetics. Academic Press 463 Xia H, Zhao GH, Zhang LS, Sun XY, Yin SP, Liang DY, Li Y, Zheng M, Zhao XY (2016) Genetic and variation analyses of growth traits of half-sib Larix olgensis fam­ilies in northeastern China. Euphytica. https://doi.org/10.1007/s10681-016-1765-410.1007/s10681-016-1765-4Open DOISearch in Google Scholar

Xiang B, Li B, Isik F (2003) Time trend of genetic parameters in growth traits of Pi­nus taeda L. Silvae Genetica 52(3-4): 114-120Search in Google Scholar

Yin SP, Zhao GH, Xia H, Sun XY, Pan YY, Wang FW, Li SC, Zhao XY (2016) Study on progeny test of half-sib families in Larix olgensis. Journal of Southwest For­estry University 36(1):63-68Search in Google Scholar

Zas Arregui R, Merlo Sánchez E, Fernández López J (2004) Genetic parameter es­timates for Maritime pine in the Atlantic coast of North-west Spain. Forest Genet 11(1): 45-5310.1515/sg-2004-0032Search in Google Scholar

Zeng LH, Zhang Q, He BX, Lian HM, Cai YL, Wang YS, Luo M (2013) Age trends in genetic parameters for growth and resin-yielding capacity in Masson Pine. Silvae Genetica 62:7-18. https://doi.org/10.1515/sg-2013-000210.1515/sg-2013-0002Open DOISearch in Google Scholar

Zhang ZG, Ma JW, Jin XC, Wang HC, Ding PJ, Hu MH, Pan CL, Lei SG (2013) Analy­sis and selection of progeny test forest of the open pollinated family of Jap­anese larch. Journal of Northwest Forestry University 28(4): 74-79Search in Google Scholar

Zhang KZ (2013) Selection and open-pollinated progeny test for plus trees of Pi­nus massoniana. Journal of Fujian Forestry Science and Technology (4): 41- 44Search in Google Scholar

Zhao XY, Bian XY, Liu MR, Li ZX, Li Y, Zheng M, Teng WH, Jiang J, Liu GF (2014) Analysis of genetic effects on complete diallel cross test of Betula platyphyl­la. Euphytica 200:221-229. https://doi.org/10.1007/s10681-014-1147-810.1007/s10681-014-1147-8Open DOISearch in Google Scholar

Zhao XY, Hou W, Zheng HQ, Zhang ZY (2013a) Analyses of genotypic variation in white poplar clones at four sites in china. Silvae Genetica 62, 4-5: 187-195 https://doi.org/10.1515/sg-2013-002310.1515/sg-2013-0023Open DOISearch in Google Scholar

Zhao XY, Li Y, Zhao L, Wu RL, Zhang ZY (2013b) Analysis and evaluation of growth and adaptive performance of white poplar hybrid clones in differ­ent sites. Journal of Beijing Forestry University 35: 7-14Search in Google Scholar

Zhao XY, Xia H, Wang XW, Wang C, Liang DY, Li KL, Liu GF (2015) Variance and stability analyses of growth characters in half-sib Betula platyphylla families at three different sites in China. Euphtyica 208 (1): 173-186 https://doi.org/10.1007/s10681-015-1617-710.1007/s10681-015-1617-7Open DOISearch in Google Scholar

Zheng R, Shi J, Xiao H, Huang JH, Su SD, Xu LP, OU YL ,Zhang ZC, Ye DQ, Fang YH (2014) Genetic variation and early selection of growth traits in 8-year-old open-pollinated progenies of the (3rd) germplasm of Chinese fir. Journal of Nanjing Forestry University 38(6): 38-42Search in Google Scholar

Zhou H, Fries A, Harry X (2014) High negative genetic correlations between growth traits and wood properties suggest incorporating multiple traits se­lection including economic weights for the future Scots pine breeding pro­grams. Annals of Forest Science 71: 463-472 https://doi.org/10.1007/s13595-014-0359-3.10.1007/s13595-014-0359-3Open DOISearch in Google Scholar