| [1] | Brown G R, Kadel III E E, BassoniD L, et al. Anchored referenceloci in loblolly p ine (Pinus taeda L.) for integrating p ine genomics[J]. Genetics, 2001, 159: 799~809 |
| [2] | 潘志刚,游应天. 湿地松、火炬松、加勒比松引种栽培[M]. 北京:北京科学技术出版社, 1991 |
| [3] | Mckeand S E,Bridgwater F E. Third-generation Breeding Strategy forthe North Carilina State University-Industry Cooperative Tree Imp rovement Program [A]. In: Proc IUFRO Con. S2. 02-07 BreedingTrop ical Trees [C]. 1992: 234~240 |
| [4] | Tarbert J T, Weir R J, Arnold R D. Costs and benefits of a matureFirst-generation loblolly p ine tree imp rovement p rogram [J]. J For,1985, 83: 162~166 |
| [5] | Wier R J, Todd D. Third cycle breeding strategy: a descrip tion andeconomic app raisal for the North Carolina State University-IndustryCooperative Tree Imp rovement Program [A]. In: Proc 24 th Can TreeImp rov Ass [C]. Fredricton, New Brunswich, Canada. August 15- 19, 1993: 41~51 |
| [6] | Shelbourne C J A, Burdon R D, Carson S D, et al. Developmentp lan for radiata p ine breeding [M]. Forest Research Institute, Rotorua, New Zealand, 1986 |
| [7] | Hains R J. Mass p ropagation by cuttings, biotechnologies, and thecap ture of genetic gain [A]. In: Proc AFOCEL-IUFRO Symposium“Mass p roduction technology for genetically imp roved fast growingforest tree species”[C]. Bordeaux, France, 14 - 18 Sep t. 1992, 2:137~150 |
| [8] | NiklesD G. The first 50 years of the evolution of forest tree imp rovement in Queensland [A]. In: DietersM J, Matheson A C,NiklesDG, et al. Tree Imp rovement for Sustainable Trop ical Forestry [C].Proceedings of the QFR I-IUFRO Conference, 27 October-1November1996, Caloundra, Queensland, Australia: 51~64 |
| [9] | Nikles D G. Experience with some Pinus hybrids in Queensland,Australia[A]. In: Dungey H S, DietersM J, Nikles D G. Hybridand Genetics of Forest Trees [C]. Proceedings of QFR I/CRC2SPFSymposium, 9 - 14 Ap ril 2000, Noosa, Queensland, Australia: 27~43 |
| [10] | 李宪政, 赵奋成, 张应中,等. 湿地松与加勒比松杂种第一代生长研究初报[J]. 广东林业科技, 1999, 15 (1) : 1~7 |
| [11] | 张应中, 赵奋成, 钟岁英,等. 湿地松×加勒比松杂种扦插繁殖技术研究[J]. 林业科学研究, 2002, 15 (4) : 437~443 |
| [12] | 黄少伟. 杂种松重要性状QTL定位与标记辅助选择研究[D].广州:华南农业大学, 2004 |
| [13] | 甘四明, 苏晓华. 林木基因组学研究进展[J]. 植物生理与分子生物学学报, 2006, 32 (2) : 133~142 |
| [14] | HarryD E, Temesgen B,NealeD B. Codominant PCR-basedmarkers for Pinus taeda developed from mapped cDNA clones [J]. TheorApp l Genet, 1998, 97: 327~336 |
| [15] | Temesgen T, Brown G R, Harry D E, et al. Genetic mapp ing ofexp ressed sequence tag polymorphism (ESTp) markers in loblollyp ine (Pinus taeda L.) [J]. Theor App l Genet, 2001, 102: 664~675 |
| [16] | Lesp inasse D, Rodier-GoudM, GriverL, et al. A saturated geneticlinkage map of rubber tree (Havea spp.) based on RFLP, AFLP,microsatellite, and isozyme markers [J]. Theor App l Genet,2000, 100: 127~138 |
| [17] | Kaya Z, NealD B. Linkage mapp ing in Turkish p ine (Pinus brutiaTen.) using random amp lified polymorphic DNA (RAPD) markers[J]. Silvae Genetica, 1995, 44: 110~116 |
| [18] | Li C, Yeh F C. Construction of a framework map in Pinus contortaSubsp. Latifolia using random amp lified polymorphic DNA markers[J]. Genome, 2001, 44: 147~153 |
| [19] | Nelson C D, NanceW L, Doudrick R L. Apartial genetic linkagemap of slash p ine (Pinus elliottii Engelmann var. elliottii) based onrandom amp lified polymorphic DNAs [J]. Theor App l Genet,1993, 87: 145~151 |
| [20] | Travis S E, Ritland K, Whiteham T G, et al. A genetic map ofPinyon p ine (Pinus edulis) based on amp lified fragment length polymorphisms [J]. TheorApp l Genet, 1998, 97: 871~880 |
| [21] | DeveyM, Carson S, Nolan M, et al. Random amp lified polymorphic DNA markers tightly linked to a gene for resistance to whitep ine blister rust in sugar p ine [J]. Proc Natl Acad Sci USA,1995, 92: 2066~2070 |
| [22] | 尹佟明, 朱立煌, 黄敏仁. 利用RAPD标记和单株树大配字体构建马尾松的分子标记连锁图谱[J]. 植物学报, 1997, 39(7) : 607~612 |
| [23] | Nelson C D, Kubisiak TL, StineM, et al. A Genetic LinkageMapof Longleaf Pine (Pinus palustrisMill.) Based on Random Amp lified Polymorphic DNAs [J]. Journal of Heredity, 1994, 85: 433~439 |
| [24] | Plomion C, Bahuman N, Durel C E, et al. Genomic mapp ing inmaritime p ine (Pinus pinaster) using RAPD markers [J]. Heredity, 1995, 74: 661~668 |
| [25] | Plomion C, O’MalleyDM, Durel C E1 Genomic mapp ing in maritime p ine (Pinus pinaster) Comparison of two RAPD map s usingselfed and open-pollinated seeds of the same individual [J]. TheorApp l Genet, 1995, 90: 1028~1034 |
| [26] | DeveyM E, Bell J C, Smith D N, et al. A genetic map for Pinusradiata based on RFLP, RAPD, and microsatellite markers [J].TheorApp l Genet, 1996, 92: 673~679 |
| [27] | DeveyM, SewellM M, Uren T L, et al. Comparative mapp ing inloblolly and radiata p ine using RFLP and microsatellite markers[J]. TheorApp l Genet, 1999, 99: 656~662 |
| [28] | Yin TM, Wang X R, Anderson B, et al. Nearly comp lete geneticmap s of Pinus sylvestris L. (Scots p ine) constructed by AFLPmarker analysis in a full-sib family [J]. TheorApp l Genet, 2003,106: 1075~1083 |
| [29] | Komulainen P, Brown G R, MikkonenM, et al. Comparing ESTbased genetic map s between Pinus sylvestris and Pinus taeda [J].TheorApp l Genet, 2003, 107 (4) : 667~678 |
| [30] | Echt C S, Nelson C D. Linkage mapp ing and genome length ineastern white p ine (Pinus strobes L.) [J]. Theor App l Genet,1997, 94 (8) : 3~37 |
| [31] | DeveyM E, Fiddler TA, Liu B H, et al. A RFLP linkagemap forloblolly p ine based on a three2generation outbred pedigree [J].TheorApp l Genet, 1994, 88: 273~278 |
| [32] | GrooverA M, DeveyM E, Lee J, et al. Identification of quantitative trait loci influencing wood specific gravity in an outbred pedigree of loblolly p ine [J]. Genetics, 1994, 138: 1293~1300 |
| [33] | Remington D L, Whetten RW, Liu B H, et al. Construction of anAFLP genetic map with nearly comp lete genome coverage in Pinustaeda [J]. TheorApp l Genet, 1999, 98: 1279~1292 |
| [34] | SewellMM, Sherman B K,Neale D B. A consensusmap for loblolly p ine (Pinus taeda L.) I. Construction and integration of individual linkage map s from two outbred three2generation pedigree[J]. Genetics, 1999, 151: 321~330 |
| [35] | SewellM M, Bassoni D L, Megraw R A, et al. Identification ofQTLs influencingwood p roperty traits in loblolly p ine (Pinus taedaL.) I. Physical wood p roperties [J]. Theor App l Genet, 2000,101: 1273~1281 |
| [36] | Zhou Y, Gwaze D P, Bui T, et al. No clustering for linkage mapbased on low-copy and undermethylated microsatellites [J]. Genome, 2003, 45: 809~816 |
| [37] | Kondo T, Terada K, Hayashi E, et al. RAPD markers linked to agene for resistance to p ine needle gallmidge in Japanese black p ine(Pinus thunbergii) [J]. Theor App l Genet, 2000, 100: 391~395 |
| [38] | Hayashi E, Kondo T, Terada K, et al. Linkage map of Japaneseblack p ine based on AFLP and RAPD markers including markerslinked to resistance against the p ine needle gall midge [J]. TheorApp l Genet, 2001, 102: 871~875 |
| [39] | Kim Y Y, Choi H S, Kang B Y. An AFLP2based linkage map ofJapanese red p ine (Pinus densiflora) using hap loid DNA samp les ofmegagametophytes from a single maternal tree [J]. Molecules andCells, 2005, 20 (2) : 201~209 |
| [40] | Dale G. Genetic mapp ing in an interspecific hybrid between Pinuscaribaea and Pinus elliottii [D]. University of Queensland, Brisbane, Queensland, Australia, 1994 |
| [41] | ShepherdM, CrossM, DietersM J, et al. Genetic map s for Pinuselliottii var. elliottii and P. caribaea var. hondurensis using AFLPand microsatellite markers [J]. Theor App l Genet, 2003, 106:1409~1419 |
| [42] | Kubisiak TL, Nelson C D, NanceW L. RAPD linkagemapp ing ina longleaf p ine′slash p ine F1 family [J]. TheorApp l Genet, 1995,90: 1119~1127 |
| [43] | Bradshaw H D J, Stettler R F. Molecular genetics of growth and development in Populus I. Trip loidy in hybrid pop lar [J]. TheorApp l Genet, 1993, 86: 301~307 |
| [44] | Bradshaw H D J, VillarM, Watson B D, et al. Molecular geneticsof growth and development in Populus III. A genetic linkagemap ofa hybrid pop lar composed of RFLP, STS, and RAPD markers [J].TheorApp l Genet, 1994, 89: 167 |
| [45] | Kriebel H B. DNA sequence components of the Pinus strobes nuclear genome [J]. Can J For Res, 1985, 15: 1~4 |
| [46] | Wakamiya I, Newton R J, Johnston J S. Genome size and environment factors in the genus Pinus [J]. Am J Bot, 1993, 80: 1235~1241 |
| [47] | Williams C G. Peculiarity of the p ine genome: relevance for biotechnology p rogram [A]. In: Dungey H S, DietersM J, NiklesDG. Hybrid and Genetics of Forest Trees[C]. Proceedings ofQFR I/CRC-SPF Symposium, 9 - 14 Ap ril 2000, Noosa, Queensland,Australia: 168 |
| [48] | 王明庥. 林木遗传育种学[M]. 北京: 中国林业出版社, 2001:336~367 |
| [49] | Sax K, Sax H J. Chromosome number and morphology in the conifers [J]. J Arnold Arbor, 1933, 14: 356~375 |
| [50] | Auckland L, Bui T, Zhou Y, et al. ConiferMicrosatellite Handbook [M]. TexasA&M, College Station, Texas, 2002 |
| [51] | DeveyM, Bell J, Moran G. A set ofmicrosatellite markers for fingerp rinting and breeding app lications in Pinus radiata [J]. Genome, 2001, 45: 984~989 |
| [52] | ShepherdM, CrossM, Maguire TL, et al. Transpecificmicrosatellites for hard p ines [J]. TheorApp l Genet, 2002, 104: 819~827 |
| [53] | WilliamsC G. How will genomicmapp ing shape forest tree breedingstrategy? [A] In: DietersM J,Matheson A C, Nikles D G, et al.Tree Imp rovement for Sustainable Trop ical Forestry [C]. Proceedings of the QFR I2IUFRO Conference, 27 October21November 1996,Caloundra, Queensland, Australia: 464~466 |
| [54] | Lagercrantz U. Comparative mapp ing between A rabidopsis thalianaand B rassica nigra indicates that Brassica genome have evolvedthrough extensive genome rep lication accompanied by chromosomefusions and frequent rearrangements [J]. Genetics, 1998, 150:1217~1228 |
| [55] | Prager EM, FowlerD P, Wilson A C. Rates of evolution of conifers [J]. Evolution, 1976, 30: 637~649 |
| [56] | Krutovsky K V, TroggioM, Brown G R, et al. Comparative mapp ing in the Pinaceae [J]. Genetics, 2004, 168: 447~461 |
| [57] | Pederick L. Chromosomal relationship s among Pinus species [J].Silvi Genet, 1972, 21: 171~180 |
| [58] | ConkleM T. Isozyme variation and linkage in six confiner species[A]. In: Proc of the Symposium on Isozymes in North AmericanForest Trees and Forest Insects[C]. USDA For Serv Gen Tech RepPSW248, 1981: 11~17 |
| [59] | AhujaM, DeveyM, GrooverA, et al. Mapped DNA from loblollyp ine can be used for restriction fragment length polymorphisms inother conifers [J]. TheorApp l Genet, 1994, 88: 279~282 |
| [60] | Lerceteau E, Plomion C, Andresson B. AFLP mapp ing and detection of quantitative trait loci (QTLs) for economically importanttraits in Pinus sylvestris: a p reliminary study [J]. Mol Breed,2001, 6: 451~458 |
| [61] | Yazdani R, Yeh F C, Rimsha J. Genomic mapp ing of Pinus sylvestris (L.) using random amp lified polymorphic DNA markers [J].For Genet, 1995, 2: 109~116 |
| [62] | LuM Z, Szmidt A E, Wang X2R. Inheritance of RAPD fragmentsin hap loid and dip loid tissue of Pinus sylvestris (L.) [J]. Heredity, 1995, 74: 582~589 |
| [63] | Hurme P, Savolainen O. Comparison of homology and linkage ofRAPD markers between individual trees of Scots p ine (Pinus sylvestris L.) [J]. Mol Ecol, 1999, 8: 15~22 |
| [64] | Echt C S, Vendramin G G, Nelson C D, et al. MicrosatellitesDNAas shared genetic markers among conifer species [J]. Can J ForRes, 1999, 29: 365~371 |
| [65] | Cato S A, Gardner R C, Kent J, et al. A rap id PCR-based methodfor geneticallymapp ing ESTs [J]. TheorApp l Genet, 2001, 102:296~306 |
| [66] | Perry D J, Bousquet J. Sequence-tagged-site markers of arbitrarygenes: development, characterization and analysis of linkage inblzck sp ruce [J]. Genetics, 1998, 149: 1089~1098 |
| [67] | PavyN, Laroche J, Bousquet J, et al. Large-scale statistical analysis of secondary xylem ESTs in p ine [J]. PlantMol Bio, 2005,57: 203~224 |
| [68] | Bradshaw H D J, Foster G S. Marker-aided selection and p ropagation systems in tree: advantages of cloning for studying quantitativeinheritance [J]. Can J For Res, 1992, 22: 1044~1049 |
| [69] | Bradshaw H D J, Stettler R F. Molecular genetics of growth and development in Populus IV. Mapp ing QTLs with large effects ongrowth, form, and phenology traits in a forest tree [J]. Genetics,1995, 139: 963~973 |
| [70] | Soller M, Meckmann J S. Marker-based mapp ing of quantitativetrait loci using rep licated p rogenies [J]. TheorApp l Genet, 1990,80: 205~208 |
| [71] | 苏晓华, 李金花, 陈伯望,等. 杨树叶片数量性状相关联标记及其图谱定位研究[J]. 林业科学, 2000, 36 (1) : 33~70 |
| [72] | 黄秦军, 苏晓华, 黄烈健,等. 美洲黑杨×青杨木材性状QTLs定位研究[J]. 林业科学, 2004, 40 (2) : 55~60 |
| [73] | ByrneM, Murrell J C, Owen J V, et al. Identification and mode ofaction of quantitative trait loci affecting seedling height and leaf areain Eucalyptus nitens [J]. TheorApp l Genet, 1997, 94: 674~681 |
| [74] | ByrneM, Murrell J C, Owen J V, et al. Mapp ing of quantitativetrait loci influencing frost tolerance in Eucalyptus nitens [J]. TheorApp l Genet, 1997, 95: 975~979 |
| [75] | DeveyM E, Carson S, NolanM, et al. QTL association for densityand diameter in Pinus radiata and the potential formatker-aided selection [A]. In: Wilton A. 49 th Annual meeting of the GeneticsSociety of Australia [C]. GSA, University of New South Wale,Sydney, New SouthWales, Australia, 2002: 28 |
| [76] | Grattapaglia D, Bertolucci F L, Sederoff R R. Genetic mapp ing ofQTls controlling vegetative p ropagation in Eucalyptus grandis andE. urophylla using a p seudo-testcross strategy and RAPD markers[J]. TheorApp l Genet, 1995, 90: 933~947 |
| [77] | Grattapaglia D, Bertolucci F L G, Penchel R, et al. Genetic mapp ing of quantitative trait loci controlling growth and wood qualitytraits in Eucalyptus grandis using a maternal half-sib family andRAPD markers [J]. Genetics, 1996, 144: 1205~1214 |
| [78] | Plomion C, Durel C E. Estimation of the average effects of specificalleles detected by the p seudo-testcrossQTL mapp ing strategy [J].Genet Sel Evol, 1996, 28: 223~235 |
| [79] | Plomion C, Durel C E, O’MalleyD M. Genetic dissection of heightin maritime p ine seedlings raised under accelerated growth conditions [J]. TheorApp l Genet, 1996, 93: 849 |
| [80] | Shepherd M, Chaparro J X, Teasdale R. Genetic mapp ing ofmonoterpene composition in an interspecific eucalyp t hybrid [J].TheorApp l Genet, 1999, 99: 1207~1215 |
| [81] | ShepherdM, CrossM, DietersM J, et al. Branch architecture QTLfor Pinus elliottii var. elliottii ×Pinus caribaea var. hondurensis hybrids [J]. Ann For Sci, 2002, 59: 617~625 |
| [82] | Shepherd M, CrossM, Dieters M J, et al. Genetics of physicalwood p roperties and early growth in a trop ical p ine hybrid [J]. CanJ For Res, 2003, 33: 1923~1932 |
| [83] | Thamarus KA, Groom K, Merrell J, et al. A genetic linkage mapdfor Eucalyptus globuleswith candidate loci forwood, fibre, and floral traits [J]. TheorApp l Genet, 2002, 104: 379~387 |
| [84] | DeveyM E, Groom KA, NolanM F, et al. Detection and verification of quantitative trait loci for resistance to Dothistroma needleblight in Pinus radiate [J]. TheorApp l Genet, 2004, 108: 1056~1063 |
| [85] | Wheeler N C, Jermstad K D, Krutovsky K, et al. Mapp ing ofquantitative trait loci controlling adap tive traits in coastalDouglas-firⅣ. Cold-hardiness QTL verification and candidate gene mapp ing[J]. Mol Breed, 2005, 15: 145~156 |
| [86] | Bradshaw H D J. Case history in genetics of long-lived p lants: molecular app roaches to domestication of a fast-growing forest tree:Populus [A]. In: Paterson A H. MolecularDissection of Comp lexTraits [M]. Boca Raton: CRC Press, 1998: 219~228 |
| [87] | Bernatzky R, Mulcahy K L. Marker-aided selection in a backcrossbreeding p rogram for resistance to chestnut blight in the Americanchestnut [J]. Can J For Res, 1992, 22: 1332~1337 |
| [88] | Strauss S H, Lande R, Namkoog G. Limitations ofmolecular-aidedselection in forest tree breeding [J]. Can J For Res, 1992, 22:1050~1061 |
| [89] | ShepherdM, Huang S, Eggler P, et al. Congruence in QTL for adventitious rooting in Pinus elliottii ×Pinus caribaea hybrids resolvesbetween and within-species effects [J]. MolBreed, Published Online: 29 June, 2006 (http: / /dx. doi. org/10. 1007 / s11032-0069006-5) |