A szárazföldi növények evolúciója és rendszertana Vezérfonal egy nem is olyan könnyű tárgy tanulásához Podani, János a szárazföldi növények evolúciója és rendszertana: Vezérfonal egy nem is olyan könnyű tárgy tanulásához

[] Hennig, W.. Grundzüge einer Theorie der philogenetischen Systematik. . Deutscher Zentralverlag. Berlin . 1950. . .

[] Hennig, W.. Phylogenetic Systematics. . Univ. Illinis Press. Urbana . 1966. . .

[] Heywood, V. H. és Moore, D. M.. Current Concepts in Plant Taxonomy. . Academic. London . 1984. . .

[] Heywood, V. H., Brummitt, R. K., Culham, A., és Seberg, O.. Flowering Plant Families of the World. . Royal Botanic Gardens. Kew, UK . 2007. . .

Hill, C. R.. „A plant with flower-like organs from the Wealden of the Weald (Lower Cretaceous), southern England”. 27-38. Cretaceous Res.. . . 1996. . 17. .

Hill, K. D., Chase, M. W., Stevenson, D. W., Hills, H. G., és Schutzman, B.. „The families and genera of cycads: a molecular phylogenetic analysis of Cycadophyta based on nuclear and plastid dna sequences”. 933-948. Int. J. Plant Sci.. . . 2003. . . 164.

Hillis, D. M.. „Misuse and modification of Nei's genetic distance”. 238-240. Syst. Zool.. . . 1984. . 33. .

Hillis, D. M. és Bull, J. J.. „An empirical test of bootstrapping as a method for assessing confidence in phylogenetic analysis”. 182-192. Syst. Biol.. . . 1993. . 42. .

[] Hollingsworth, P. M., Bateman, R. M., és Gornall, R. J.. Molecular Systematics and Plant Evolution. . Taylor and Francis. London . 1999. . .

Hoot, S. B., Magallon, S., és Crane, P. R.. „Phylogeny of basal eudicots based on three molecular data sets: atpB, rbcL, and 18S nuclear ribosomal DNA sequences”. 1-32. Ann. Mo. Bot. Gard.. . . 1999. . 86. .

[] Horánszky, A. és Járainé Komlódi, M.. Növényrendszertani praktikum. . Tankönyvkiadó. Budapest . 1991. . .

Howe, C. J., Barbrook, A. C., és Spencer, M.. „Manuscript evolution”. 147-152. Trends Genet.. . . . . 17. 3.

Howell, G. J., Slater, A. T., és Knox, R. B.. „Secondary pollen presentation in angiosperms and its biological significance”. 417-438. Aust. J. Bot.. . . 1993. . 41. 4-5.

Hörandl, E.. „Paraphyletic versus monophyletic classifications - evolutionary versus cladistic classifications”. 564-570. Taxon. . . 2006. . 55. .

Hull, D. L.. „Hypotheses that blur and grow”. 5-23. Duncan and Stuessy. . . 1984. . . .

Humphries, C. J., Ladiges, P. Y., Roos, M., és Zandee, M.. „Cladistic biogeography”. 371-404. Analytical Biogeography. Chapman and Hall. London . 1988. . . .

Igersheim, A., Buzgo, M., és Endress, P. K.. „Gynoecium diversity and systematics in basal monocots”. 1-65. Bot. J. Linn. Soc.. . . 2001. . 136. .

[] Ingrouille, M. és Eddie, B.. Plants: Evolution and Diversity. . Cambridge University Press. Cambridge, UK . 2006. . .

[] Iwatsuki, K. és Raven, P. H.. Evolution and Diversification of Land Plants. . Springer. Berlin . 1997. . .

[] Jacob, F., Jager, E. I., és Ohmann, E.. Botanikai kompendium. . Natura. Budapest . 1985. . .

[] Jardine, N. és Sibson, R.. Mathematical Taxonomy. . Wiley. New York . 1971. . .

Járainé Komlódi, M.. „A növényvilág fejlődéstörténete”. 37-110. Az élővilág evolúciója. Natura. Budapest . 1982. . . . Vida, G..

[] Jávorka, S. és Csapody, V.. Iconographia Florae Partis Austro-Orientalis Europae Centralis. . Akadémiai Kiadó. Budapest . 1975. . .

[] Judd, W. S., Campbell, C. S., Kellogg, E. A., és Stevens, P. F.. Plant Systematics. A Pbylogenetic Appoach. . Sinauer. Mass. . 1999. . .

[] Judd, W. S., Campbell, C. S., Kellogg, E. A., Stevens, P. F., és Donoghue, M. J.. Plant Systematics. A Phylogenetic Approach. 2nd ed.. . Sinauer. Mass. . 2002. . .

Judd, W. S. és Manchester, S. R.. „Circumscription of Malvaceae (Malvales) as determined by a preliminary cladistic analysis of morphological, anatomical, palynological, and chemical characters”. 384-405. Brittonia. . . 1998. . 49. .

Jukes, T. H. és Cantor, C. R.. „Evolution in protein molecules”. 21-123. Mammalian Protein Metabolism. Academic. New York . 1969. . . . Munro , H. N..

Kallersjö, M., Bergqvist, G., és Anderberg, A. A.. „Generic realignment in primuloid families of the Ericales s.l.: A phylogenetic analysis based on DNA sequences from three chloroplast genes and morphology”. 1325-1341. Amer. J. Bot.. . . 2000. . 87. .

Kallersjö, M., Farris, J. S., és Chase, M. W.. „Simultaneous parsimony jackknife analysis of 2538 rbcL DNA sequences reveals support for major clades of green plants, land plants, seed plants and flowering plants”. 259-287. Plant Syst. Evol.. . . 1998. . . 213.

Karol, K. G., McCourt, R. M., és Cimino, M. T.. „The closest living relatives of land plants”. 2351-2353. Science. . . 2001. . 294. 5550.

Kenrick, P.. „Botany - The family tree flowers”. 358-359. Nature. . . 1999. . . 402 (6760).

Kenrick, P.. „The relationships ofvascular plants”. 847-855. Philos. T Roy. Soc. B.. . . 2000. . . 355 (1398).

Kenrick, P. és Crane, P. R.. „Water-conducting cells in early fossil land plants - Implications for the early evolution of tracheophytes”. 335-356. Bot. Gaz.. . . 1991. . 152. 3.

Kenrick, P. és Crane, P. R.. „The origin and early evolution ofplants on land”. 33-39. Nature. . . 1997a. . . 389 (6646).

[] Kenrick, P. és Crane, P. R.. The Origin and Early Diversification of Land Plants. . Smithsonian Inst. Press. Washington DC . 1997. . .

Kenrick, P. és Graham, L. K. E.. „The origin of alternation of generations in land plants: a focus on matrotrophy and hexose transport - Discussion”. 766-767. Philos. T Roy. Soc. B.. . . 2000. . . 355 (1398).

Kishino, H. és Hasegawa, M.. „Evaluation of the maximum likelihood estimate of the evolutionary tree topologies from DNA sequence data, and the branching order in Hominoidea”. 170-179. J. Mol. Evol.. . . 1989. . 29. .

Klak, C., Khunou, A., Reeves, G., és Hedderson, T.. „A phylogenetic hypothesis for the Aizoaceae (Caryophyllales) based on four plastid DNA regions”. 1433-1445. Amer. J. Bot.. . . 2003. . 90. .

Klesius, M. és Blair, J.. „The big bloom. How flowering plants changed the world”. 102-121. National Geographic. . . 2002. . . 202(1).

Kluge, A. G.. „Higher taxonomic categories of gekkonid lizards and their evolution”. 1-59. Bull. Amer. Mus. Nat. Hist.. . . 1967. . . 135.

Kluge, A. G.. „The relevance of parsimony to phylogenetic inference”. 24-38. Duncan and Stuessy. . . 1984. . . .

Kluge, A. G. és Farris, J. S.. „Quantitative phyletics and the evolution of the anurans”. 1-32. Syst. Zool.. . . 1969. . 18. .

Knapp, S. és Bateman, R. M.. „Taxonomy needs evolution, not revolution - Some changes are clearly necessary, but science cannot be replaced by informatics”. 559-569. Nature. . . 2002. . . 419 (6907).

Knox, E. B., Downie, S. R., és Palmer, J. D.. „Chloroplast genome rearrangements and the evolution of giant lobelias from herbaceous ancestors”. 414-430. Mol. Biol. Evol.. . . 1993. . 10. 2.

Knox, E. B. és Palmer, J. D.. „The origin of Dendrosenecio within the Senecioneae (Asteraceae) based on chloroplast DNA evidence”. 1567-1573. Am. J. Bot.. . . 1995. . 82. 12.

Krajewski, C. és Dickerman, A. W.. „Bootstrap analysis of phylogenetic trees derived from DNA hybridization distances”. 383-390. Syst. Zool.. . . 1990. . 39. .

Kron, K. A., Judd, W. S., és Stevens, P. F.. „Phylogenetic classification of Ericaceae: Molecular and morphological evidence”. 335-423. Bot. Rev.. . . 2002. . 68. .

Kusumi, J., Tsumura, Y., és Yoshimaru, H.. „Phylogenetic relationships in Taxodiaceae and Cupressaceae sensu stricto based on matK gene, chlL gene, trnL-trnF IGS region, and trnL intron sequences”. 1480-1488. Am. J. Bot.. . . 2000. . 87. .

Kuzoff, R. K. és Gasser, C. S.. „Recent progress in reconstructing angiosperm phylogeny”. 330-336. Trends Plant Sci.. . . 2000. . 5. .

Lake, J. A.. „A rate-independent technique for analysis of nucleic acid sequences: evolutionary parsimony”. 167-191. Mol. Biol. Evol.. . . 1987. . 4. .

[] Lee, R. E.. Phycology. 3rd edition. . Cambridge Univ. Press. Cambridge . 1999. . .

Leitch, I. J. és Hanson, L.. „DNA C-values in seven families fill phylogenetic gaps in the basal angiosperms”. 175-179. Bot. J. Linn. Soc.. . . 2002. . 140. .

Le Quesne, W. J.. „A method of se1ection of characters in numerical taxonomy”. 201-205. Syst. Zool.. . . 1969. . 18. .

Le Quesne, W. J.. „Further studies based on the uniquely derived character concept”. 281-288. Syst. Zool.. . . 1972. . 21. .

Le Quesne, W. J.. „The uniquely evolved character concept and its cladistic application”. 513-517. Syst. Zool.. . . 1974. . 23. .

Lewis, H. R. és C. H. Papadimitriou, C. H.. „The efficiency of algorithms”. 96-109. Scientific Amer.. . . 1978. . . 238(1).

Li, P. és Johnston, M. O.. „Heterochrony in plant evolutionary studies through the twentieth century”. 57-88. Bot. Rev.. . . 2000. . 66. .

Ligrone, R., Duckett, J. G., és Renzaglia, K. S.. „Conducting tissues and phyletic relationships of bryophytes”. 795-813. Philos. T Roy. Soc. B. . . 2000. . . 355 (1398).

Ligrone, R., Vaughn, K. C., és Renzaglia, K. S.. „Diversity in the distribution of polysaccharide and glycoprotein epitopes in the cell walls of bryophytes: new evidence for the multiple evolution of water-conducting cells”. 491-508. New Phytol.. . . 2002. . 156. 3.

Lipscomb, D., Platnick, N., és Wheeler, Q.. „The intellectual content of taxonomy: a comment on DNA taxonomy”. 65-66. Trends Ecol. Evol.. . . 2003. . 18. 2.

[] Llamas, K. A.. Tropical Flowering Plants. A Guide to Identification and Cultivation. . Timber Press. Portland, Oregon, USA . 2003. . .

Lynch, M.. „Phylogenetic hypotheses under the assumption of neutral quantitative-genetic vartation”. 1-17. Evolution. . . 1989. . 43. .

Mable, B. K. és Otto, S. P.. „The evolution of life cycles with haploid and diploid phases”. 453-462. BioEssays. . . 1998. . 20. .

[] Maddison , W. P. és Maddison, D. R.. MacClade. Analysis of Phylogeny and Character Evolution. . Sinauer. Sunderland . 1992. . .

Magombo, Z. L. Z.. „The phylogeny of basal peristomate mosses: Evidence from cpDNA, and implications for peristome evolution”. 24-38. Syst. Bot.. . . 2003. . 28. 1.

Mallet, J. és Willmott, K.. „Taxonomy: renaissance or Tower of Babel?”. 57-59. Trends Ecol. Evol.. . . 2003. . 18. 2.

Margush, T. és McMorris, F. R.. „Consensus n-trees”. 239-244. Bull. Math. Biol.. . . 1981. . 43. .

Mathews, S. és Donoghue, M. J.. „The root of angiosperm phylogeny inferred from duplicate phytochrome genes”. 947-950. Science. . . 1999. . . 286 (5441).

Mathews, S. és Donoghue, M. J.. „Basal angiosperm phylogeny inferred from duplicate phytochromes A and C”. 541-555 Suppl.. Int. J. Plant Sci.. . . 2000. . 161. .

[] Mayr, E.. Systematics and the Origin of Species f om the Viewpoint of a Zoologist. . Columbia Univ. Press. New York . 1942. . .

[] Mayr, E.. The Gowth of Biological Thought: Diversity, Evolution and Inheritance. . Harvard Univ. Press. Cambridge, Mass. . 1982. . .

[] Mayr, E. és Ashlock, P. D.. Principles of Systematic Zoology. . McGraw-Hill. New York . 1991. . .

McCourt, R. M.. „Green algal phylogeny”. 159-163. Trends in Ecology and Evolution. . . 1995. . 10. .

Meacham, C. A. és Estabrook, G. F.. „Compatibility methods in systematics”. 431-446. Ann. Rev. Ecol. Syst.. . . 1985. . 16. .

Mészáros, S., deLaet, J., és Smets, E.. „Phylogeny of temperate Gentianaceae: A morphological approach”. 153-168. Syst. Bot.. . . 1996. . 21. 2.

Mickevich, M. F.. „Taxonomic congruence: Rohlf and Sokal's misunderstanding”. 162-176. Syst. Zool.. . . 1980. . 29. .

Mishler, B. D.. „Deep phylogenetic re!ationships among "plants" and their imp!ications for classification”. 661-683. Taxon. . . 2000. . 49. .

Mishler, B. D. és Churchill, S. P.. „Transition to a land flora: phy!ogenetic re!ationships of the green algae and bryophyes”. 305-328. Cladistics. . . 1985. . 1. .

Mishler, B. D., Thrall, P. H., és Hopple, J. S.. „A molecular approach to the phylogeny of bryophytes - Cladistic-analysis of chloroplast-encoded 16S and 23S ribosomal-RNA genes”. 172-180. Bryologist. . . 1992. . 95. 2.

Miyahara, K.. „Molecular evolution of human paramyxoviruses”. 255-268. Arch. Virol.. . . 1992. . 124. .

[] Miyamoto, M .M. és Cracraft, J.. Phylogenetic Analysis of DNA Sequences. . Oxford Univ. Press. Oxford . 1991. . .

Muller, K. és Borsch, T.. „Phylogenetics of Amaranthaceae based on matK/trnK sequence data - Evidence from Parsimony, likelihood, and Bayesian analyses”. 66-102. Annals Missouri Bot. Gard.. . . 2005. . 92. .

Nandi, O. I., Chase, M. W., és Endress, P. K.. „A combined cladistic analysis of angiosperms using rbcL and non-molecular data sets”. 137-212. Ann. Mo. Bot. Gard.. . . 1998. . 85. .

Needleman, S. B. és Wunsch, C. D.. „A general method applicable to the search for similarities in the aminoacid sequence oftwo proteins”. 443-453. J. Mol. Biol.. . . 1970. . 48. .

Nei, M.. „Relative efficiencies of different trec-making methods for molecular data”. 90-128. Miyamoto and Cracraft. . . 1991. . . .

[] Nei, M. és Kumar, S.. Molecular Evolution and Phylogenetics. . Oxford Univ. Press. Oxford . 2000. . .

Nelson, G.. „Historical biogeography: an alternative formalization”. 555-558. Syst. Zool.. . . 1975. . 23. .

[] Nelson, G. és Platnick, N. I.. Systematics and Biogeography: Cladistics and Vicariance. . Columbia Univ. Press. New York . 1981. . .

[] Nelson, G. és Rosen, D. E.. Vicariance Biogeography: A Critique. . Columbia Univ. Press. New York . 1981. . .

Neumann, D. A.. „Faithful consensus methods for n-trees”. 271-287. Math. Biosci.. . . 1983. . 63. .

Newton, A. E., Cox, C. J., és Duckett, J. G.. „Evolution of the major moss lineages: Phylogenetic analyses based on multiple gene sequences and morphology”. 187-211. Bryologist. . . 2000. . 103. 2.

Neyland, R.. „A phylogeny inferred from large ribosomal subunit (26S) rDNA sequences suggests that Cuscuta is a derived member of Convolvulaceae”. 108-115. Brittonia. . . 2001. . 53. 1.

Nickrent, D. L., Parkinson, C. L., és Palmer, J. D.. „Multigene phylogeny of land plants with special reference to bryophytes and the earliest land plants”. 1885-1895. Mol. Biol. Evol.. . . 2000. . 17. .

Nickrent, D. L. és Starr, E. M.. „High-rates of nucleotide substitution in nuclear small-subunit (18S) rDNA from holoparasitic flowering plants”. 62-70 JUL. J. Mol. Evol.. . . 1994. . 39. 1.

Nickrent, D. L., Yan, O. Y., és Duff , R. J.. „Do nonasterid holoparasitic flowering plants have plastid genomes?”. 717-729. Plant. Mol. Biol.. . . 1997. . 34. 5.

Niklas, K. J.. „Számítógéppel szimulált növények”. 70-78. Tudomány. . . 1986. . . 5.

[] Niklas, K. J.. Evolutionary Biology of Plants. . Univ. Chicago Press. Chicago . 1997. . .

Nyffeler, R.. „A new ordinal classification ofthe flowering plants”. 168-170. Trends Ecol. Evol.. . . 1999. . 14. .

O'Hara, R. J.. „Homage to Clio, or toward an historical philosophy for evolutionary biology”. 142-155. Syst. Zool.. . . 1988. . 31. .

Olmstead, R. G., DePamphilis, C. W., és Wolfe, A. D.. „Disintegration of the Scrophulariaceae”. 348-361. Amer. J. Bot.. . . 2001. . 88. .

[] Orbán, S.. Általános biológia. . EKTF Líceum Kiadó. Eger . 1999. . .

Page, R. D. M.. „Comments on component-compatibility in historical biogeography”. 167-182. Cladistics. . . 1989. . 5. .

[] Page, R. D. M. és Holmes, E. C.. Molecular Evolution. A Phylogenetic Approach. . Blackwell. Oxford . 1998. . .

[] Panchen, A. L.. Classification, Evolution, and the Nature of Biology. . Cambridge Univ. Press. Cambridge . 1992. . .

Panero, J. L., Francisco-Ortega, J., Jansen, R. K., és Santos-Guerra, A.. „Molecular evidence for multiple origins of woodiness and a New World biogeographic connection of the Macaronesian Island endemic Pericallis (Asteraceae : Senecioneae)”. 13886-13891. P. Natl. Acad. Sci. USA. . . 1999. . 96. 24.

[] Pankhurst, R. J.. Practical Taxonomic Computing. . Cambridge Univ. Press. Cambridge . 1991. . .

Parenti, L.. „A phylogenetic and biogeographic analysis of cyprinodontiform fishes (Teleostei, Atherinomorpha)”. 341-557. Bull. Am. Mus. Nat. Hist.. . . 1981. . . 168.

Parkinson, C. L., Adams, K. L., és Palmer, J. D.. „Multigene analyses identify the three earliest lineages of ex-tant flowering plants”. 1485-1488. Curr. Biol.. . . 1999. . 9. 24.

[] Pálfy, J.. Kihaltak és túlélők. Félmilliárd év nagy fajpusztulásai. . Vince Kiadó. Budapest . 2000. . .

Penny, D., Foulds, L. R., és Hendy, M. D.. „Testing the theory of evolution by comparing phylogenetic trees constructed from five protein sequences”. 197-200. Nature. . . 1982. . . 297.

Penny, D., Hendy, M. D., és Steel, M. A.. „Testing the theory of descent”. 155-183. Miyamoto and Cracraft . . . 1991. . . .

Penny, D., Watson, E. E., és Steel, M. A.. „Trees from languages and genes are very similar”. 382-384. Syst. Biol.. . . 1993. . 42. .

Phipps, J. B.. „Dendrogram topology”. 306-308. Syst. Zool.. . . 1971. . 20. .

Phipps, J. B.. „The numbers of classifications”. 686-688. Can. J. Bot.. . . 1975. . 54. .

[] Podani, J.. Bevezetés a többváltozós biológiai adatfeltárás rejtelmeibe. . Scientia. Budapest . 1997. . .

[] Podani, J.. Földindulás a szárazföldi növények osztályozásában. . Eötvös Kiadó. Budapest . 2005. . 88.

Price, R. A.. „Systematics of the Gnetales: A review of morphological and molecular evidence”. S40-S49 Suppl.. Int. J. Plant Sci.. . . 1996. . . 157.

Pruchner, D., Nassal, B., és Schindler, M.. „Mosses share mitochondrial group II introns with flowering plants, not with liverworts”. 608-613. Mol. Genet. Genomics. . . 2001. . . 266 (4).

Pryer, K. M.. „Phylogeny of marsileaceous ferns and relationships of the fossil Hydropteris pinnata reconsidered”. 931-954. Int. J. Plant Sci.. . . 1999. . 160. .

Pryer, K. M., Schneider, H., és Smith, A. R.. „Horsetails and ferns are a monophyletic group and the closest living relatives to seed plants”. 618-622. Nature. . . 2001. . . 409 (6820).

Pryer, K. M., Smith, A. R., és Skog, J. E.. „Phylogenetic relationships of extant ferns based on evidence from morphology and rbcL sequences”. 205-282. Am. Feni J.. . . 1995. . 85. .

Qiu, Y. L., Cho, Y. R., és Cox, J. C.. „The gain of three mitochondrial introns identifies liverworts as the earliest land plants”. 671-674. Nature. . . 1998. . 394 (6694). .

Qiu, Y. L. és Lee, J.. „Transition to a land flora: A molecular phylogenetic perspective”. 799-802. J. Phycol.. . . 2000. . 36. .

Qiu, Y. L., Lee, J., és Bernasconi-Quadroni, F.. „Phylogeny of basal angiosperms: Analyses of five genes from three genomes”. S3-S27 Suppl.. Int. J. Plant Sci.. . . 2000. . 161. .

Qiu, Y. L., Lee, J., és Bernasconi-Quadroni, F.. „The earliest angiosperms: evidence from mitochondrial, plastid and nuclear genomes”. 101-120. Nature. . . 2000. . . 405 (6782).

Qiu, Y. L., Lee, J., és Whitlock, B. A.. „Was the ANITA rooting of the angiosperm phylogeny affected by long-branch attraction?”. 1745-1753. Mol. Biol. Evol.. . . 2001. . 18. .

Qiu, Y. L. és J. D. Palmer, J. D.. „Phylogeny of early land plants: insights from genes and genomes”. 26-30. Trends in Plant Science. . . 1999. . 4. .

[] Quicke, D. L. J.. Principles and Techniques of Contemporary Taxonomy. . Blackie Academic. London . 1993. . .

[] Rédei, Gy.. Genetika. . Mezőgazdasági Kiadó - Gondolat. Budapest . 1987. . .

Reeves, P. A. és Olmstead, R. G.. „Evolution of novel morphological and reproductive traits in a clade containing Antirrhinum majus (Scrophulariaceae)”. 1047-1056. Amer. J. Bot.. . . 1998. . 85. .

Renzaglia, K. S., Dengate, S. B., és Schmitt, S. J.. „Novel features of Equisetum arvense spermatozoids: insights into pteridophyte evolution”. 159-174. New. Phytol.. . . 2002. . . 154.

Renzaglia, K. S., Duff, R. J., és Nickrent, D. L.. „Vegetative and reproductive innovations of early land plants: implications for a unified phylogeny”. 769-793. . Philos. T Roy. Soc. B. . . 2000. . . 355 (1398).

Rodman, J., Price, R. A., és Karol, K.. „Nucleotide-sequences of the rbcl gene indicate monophyly of mustard oil plants”. 686-699. Ann. Mo. Bot. Gard.. . . 1993. . 80. 3.

Rohlf, F. J.. „Consensus indices for comparing classifications”. 131-144. Math. Biosci.. . . 1982. . 59. .

Rohlf, F. J., Chang, W. S., Sokal, R. R., és Kim, J.. „Accuracy of estimated phylogenies: effects of tree topology and evolutionary model”. 1671-1684. Evolution. . . 1990. . 44. .

Rosen, D. E.. „Vicariant patterns and historical explanation in biogeography”. 159-188. Syst. Zool.. . . 1978. . 27. .

Rothwell, G. W. és Stockey, R. A.. „The role of Hydropteris pinnata gen. et sp. nov. in reconstructing the cladistics of heterosporous ferns”. 479-492. Am. J. Bot.. . . 1994. . 81. .

Rothwell, G. W., Van Atta, M. R., Ballards, H. E., Jr., és Stockey, R. A.. „Molecular phylogeneteic relationships among Lemnaceae and Araceae using the chloroplast trnL-trnF intergeneric spacer”. 378-385. Molec. Phyl. Evol.. . . 2004. . 30. .

Rydin, C. és Kallersjo, N.. „Taxon sampling and seed plant phylogeny”. 485-513. Cladistics. . . 2002. . 18. 5.

Rydin, C., Kallersjo, M., és Friist, E. M.. „Seed plant relationships and the systematic position of Gnetales based on nuclear and chloroplast DNA: Conflicting data, rooting problems, and the monophyly of conifers”. 197-214. Int. J. Plant Sci.. . . 2002. . 163. 2.

Saitou, N. és Imanishi, T.. „Relative efficiencies of the Fitch-Margoliash, maximum parsimony, maximumlikelihood, minimum evolution, and neighbor joining methods of phylogenetic tree construction in obtaining the correct tree”. 514-525. Mol. Biol. Evol.. . . 1989. . 6. .

Saitou, N. és Nei, M.. „The neighbor-joining method: a new method for reconstructing phylogenetic trees”. 406-425. Mol. Biol. Evol.. . . 1987. . 4. .

Samigullin, T. K., Martin, W. F., és Troitsky, A. V.. „Molecular data from the chloroplast rpoCl gene suggest deep and distinct dichotomy of contemporary spermatophytes into two monophyla: Gymnosperms (including Gnetales) and angiosperms”. 310-315. J. Mol. Evol.. . . 1999. . 49. .

Sanderson, M. J.. „Confidence limits on phylogenies: The bootstrap revisited”. 113-129. Cladistics. . . 1989. . 5. .

Sanderson, M. J.. „Flexible phylogeny reconstruction: a review of phylogenetic inference packages using parsimony”. 414-420. Syst. Zool. . . . 1990. . 39. .

Sanderson, M. J. és Doyle, J. A.. „Sources of error and confidence intervals in estimating the age of angiosperms from rbcL and 18S rDNA data”. 1499-1516. Am. J. Bot... . . 2001. . 88. .

[] Sanderson, M. J. és Hufford, L.. Homoplasy. The Recurrence of Similarity in Evolution. . Academic Press. London . 1996. . .

Sarich, V. M.. „Pinniped origins and the rate of evolution of carnivore albumins”. 286-295. Syst. Zool.. . . 1969. . 18. .