Biology:Rosaceae

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Short description: Rose family of flowering plants

Rosaceae
Temporal range: Turonian - present[1][2]
Rosa pouzinii FlowerCloseup SierraMadrona.jpg
Flower of Rosa pouzinii
Scientific classification e
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Eudicots
Clade: Rosids
Order: Rosales
Family: Rosaceae
Juss.
Subfamilies
Map-Rosaceae.PNG
Global distribution of Rosaceae
Synonyms[3]
  • Amygdalaceae D. Don 1825
  • Coleogynaceae J. Agardh 1858
  • Fragariaceae Richard ex Nestler 1816
  • Lindleyaceae J. Agardh 1858
  • Malaceae Small ex Britton 1903
  • Pomaceae Lindl.
  • Potentillaceae Sprengel ex Weinmann 1824
  • Prunaceae Martinov
  • Spiraeaceae Bertuch 1801

Rosaceae (/rˈzs., -si./),[4] the rose family, is a medium-sized family of flowering plants that includes 4,828 known species in 91 genera.[5][6][7]

The name is derived from the type genus Rosa. Among the most species-rich genera are Alchemilla (270), Sorbus (260), Crataegus (260), Cotoneaster (260), Rubus (250),[7] and Prunus (200), which contains the plums, cherries, peaches, apricots, and almonds.[8] However, all of these numbers should be seen as estimates—much taxonomic work remains.

The family Rosaceae includes herbs, shrubs, and trees. Most species are deciduous, but some are evergreen.[9] They have a worldwide range but are most diverse in the Northern Hemisphere.

Many economically important products come from the Rosaceae, including various edible fruits, such as apples, pears, quinces, apricots, plums, cherries, peaches, raspberries, blackberries, loquats, strawberries, rose hips, hawthorns, and almonds. The family also includes popular ornamental trees and shrubs, such as roses, meadowsweets, rowans, firethorns, and photinias.[9]

Description

Rosaceae can be woody trees, shrubs, climbers or herbaceous plants.[10] The herbs are mostly perennials, but some annuals also exist, such as Aphanes arvensis.[11]:200[12]

Leaves

The leaves are generally arranged spirally, but have an opposite arrangement in some species. They can be simple or pinnately compound (either odd- or even-pinnate). Compound leaves appear in around 30 genera. The leaf margin is most often serrate. Paired stipules are generally present, and are a primitive feature within the family, independently lost in many groups of Amygdaloideae (previously called Spiraeoideae).[13] The stipules are sometimes adnate (attached surface to surface)[14] to the petiole. Glands or extrafloral nectaries may be present on leaf margins or petioles. Spines may be present on the midrib of leaflets and the rachis of compound leaves.

Flowers

Flowers of plants in the rose family are generally described as "showy".[15] They are radially symmetrical, and almost always hermaphroditic. Rosaceae generally have five sepals, five petals, and many spirally arranged stamens. The bases of the sepals, petals, and stamens are fused together to form a characteristic cup-like structure called a hypanthium. They can be arranged in spikes, or heads. Solitary flowers are rare. Rosaceae have a variety of color petals, but blue is almost completely absent.[10]

Fruits and seeds

The fruits occur in many varieties and were once considered the main characters for the definition of subfamilies amongst Rosaceae, giving rise to a fundamentally artificial subdivision. They can be follicles, capsules, nuts, achenes, drupes (Prunus), and accessory fruits, like the pome of an apple, or the hip of a rose. Many fruits of the family are edible, but their seeds often contain amygdalin, which can release cyanide during digestion if the seed is damaged.[16]

Taxonomy

Taxonomic history

The family was traditionally divided into six subfamilies: Rosoideae, Spiraeoideae, Maloideae (Pomoideae), Amygdaloideae (Prunoideae), Neuradoideae, and Chrysobalanoideae, and most of these were treated as families by various authors.[17][18] More recently (1971), Chrysobalanoideae was placed in Malpighiales in molecular analyses and Neuradoideae has been assigned to Malvales. Schulze-Menz, in Engler's Syllabus edited by Melchior (1964) recognized Rosoideae, Dryadoideae, Lyonothamnoideae, Spireoideae, Amygdaloideae, and Maloideae.[19] They were primarily diagnosed by the structure of the fruits. More recent work has identified that not all of these groups were monophyletic. Hutchinson (1964)[20] and Kalkman (2004) [21] recognized only tribes (17 and 21, respectively). Takhtajan (1997) delimited 21 tribes in 10 subfamilies:[3] Filipenduloideae, Rosoideae, Ruboideae, Potentilloideae, Coleogynoideae, Kerroideae, Amygdaloideae (Prunoideae), Spireoideae, Maloideae (Pyroideae), Dichotomanthoideae. A more modern model comprises three subfamilies, one of which (Rosoideae) has largely remained the same.

While the boundaries of the Rosaceae are not disputed, there is no general agreement as to how many genera it contains. Areas of divergent opinion include the treatment of Potentilla s.l. and Sorbus s.l.. Compounding the problem is that apomixis is common in several genera. This results in an uncertainty in the number of species contained in each of these genera, due to the difficulty of dividing apomictic complexes into species. For example, Cotoneaster contains between 70 and 300 species, Rosa around 100 (including the taxonomically complex dog roses), Sorbus 100 to 200 species, Crataegus between 200 and 1,000, Alchemilla around 300 species, Potentilla roughly 500, and Rubus hundreds, or possibly even thousands of species.

Genera

Main page: Biology:List of Rosaceae genera

Identified clades include:

  • Subfamily Rosoideae: Traditionally composed of those genera bearing aggregate fruits that are made up of small achenes or drupelets, and often the fleshy part of the fruit (e.g. strawberry) is the receptacle or the stalk bearing the carpels. The circumscription is now narrowed (excluding, for example, the Dryadoideae), but it still remains a diverse group containing five or six tribes and 20 or more genera, including rose, Rubus (blackberry, raspberry), Fragaria (strawberry), Potentilla, and Geum.
  • Subfamily Amygdaloideae: Within this group remains an identified clade with a pome fruit, traditionally known as subfamily Maloideae (or Pyroideae) which included genera such as apple, Cotoneaster, and Crataegus (hawthorn). To separate it at the subfamily level would leave the remaining genera as a paraphyletic group, so it has been expanded to include the former Spiraeoideae and Amygdaloideae.[13] The subfamily has sometimes been referred to by the name "Spiraeoideae", but this is not permitted by the International Code of Nomenclature for algae, fungi, and plants.
  • Subfamily Dryadoideae: Fruits are achenes with hairy styles, and includes five genera (Dryas, Cercocarpus, Chamaebatia, Cowania, and Purshia), most species of which form root nodules which host nitrogen-fixing bacteria from the genus Frankia.

Phylogeny

The phylogenetic relationships between the three subfamilies within Rosaceae are unresolved. There are three competing hypotheses:

Amygdaloideae basal Dryadoideae basal Rosoideae basal

Amygdaloideae

Rosoideae

Dryadoideae

Dryadoideae

Amygdaloideae

Rosoideae

Rosoideae

Dryadoideae

Amygdaloideae

Amygdaloideae basal

Amygdaloideae has been identified as the earliest branching subfamily by Chin et al. (2014),[22] Li et al. (2015),[23] Li et al. (2016),[24] and Sun et al. (2016).[25] Most recently Zhang et al. (2017) recovered these relationships using whole plastid genomes:[26]

Rosaceae
Amygdaloideae
Malodae

Maleae

Gillenieae

Spiraeeae

Sorbarieae

Amygdaleae

Kerriodae

Kerrieae

Exochordeae

Neillieae

Lyonothamneae

Rosoideae
Rosodae

Potentilleae

Roseae

Agrimonieae

Rubeae

Colurieae

Ulmarieae

Dryadoideae

Dryadeae

outgroup

The sister relationship between Dryadoideae and Rosoideae is supported by the following shared morphological characters not found in Amygdaloideae: presence of stipules, separation of the hypanthium from the ovary, and the fruits are usually achenes.[26]

Dryadoideae basal

Dryadoideae has been identified as the earliest branching subfamily by Evans et al. (2002)[27] and Potter (2003).[28] Most recently Xiang et al. (2017) recovered these relationships using nuclear transcriptomes:[29]

Rosaceae
Amygdaloideae
Malodae

Maleae

Gillenieae

Kerriodae

Kerrieae

Exochordeae

Sorbarieae

Amygdaleae

Lyonothamneae

Spiraeeae

Neillieae

Rosoideae
Rosodae

Agrimonieae

Potentilleae

Roseae

Colurieae

Rubeae

Ulmarieae

Dryadoideae

Dryadeae

outgroup

Rosoideae basal

Rosoideae has been identified as the earliest branching subfamily by Morgan et al. (1994),[30] Evans (1999),[31] Potter et al. (2002),[32] Potter et al. (2007),[13] Töpel et al. (2012),[33] and Chen et al. (2016).[34] The following is taken from Potter et al. (2007):[13]

Rosaceae
Rosoideae
Rosodae

Agrimonieae

Potentilleae

Roseae

Colurieae

Rubeae

Ulmarieae

Amygdaloideae

Sorbarieae

Malodae

Maleae

Gillenieae

Spiraeeae

Kerriodae

Kerrieae

Exochordeae

Amygdaleae

Neillieae

Lyonothamneae

Dryadoideae

Dryadeae

outgroup

The sister relationship between Amygdaloideae and Dryadoideae is supported by the following shared biochemical characters not found in Rosoideae: production of cyanogenic glycosides and production of sorbitol.[26]

Distribution and habitat

The Rosaceae have a cosmopolitan distribution, being found nearly everywhere except for Antarctica. They are primarily concentrated in the Northern Hemisphere in regions that are not desert or tropical rainforest.[7]

Uses

The rose family is considered one of the six most economically important crop plant families,[35] and includes apples, pears, quinces, medlars, loquats, almonds, peaches, apricots, plums, cherries, strawberries, blackberries, raspberries, sloes, and roses.

Many genera are also highly valued ornamental plants. These include trees and shrubs (Cotoneaster, Chaenomeles, Crataegus, Dasiphora, Exochorda, Kerria, Photinia, Physocarpus, Prunus, Pyracantha, Rhodotypos, Rosa, Sorbus, Spiraea), herbaceous perennials (Alchemilla, Aruncus, Filipendula, Geum, Potentilla, Sanguisorba), alpine plants (Dryas, Geum, Potentilla) and climbers (Rosa).[9]

However, several genera are also introduced noxious weeds in some parts of the world, costing money to be controlled. These invasive plants can have negative impacts on the diversity of local ecosystems once established. Such naturalised pests include Acaena, Cotoneaster, Crataegus, and Pyracantha.[9]

In Bulgaria and parts of western Asia, the production of rose oil from fresh flowers such as Rosa damascena, Rosa gallica, and other species is an important economic industry.[10]

Gallery

The family Rosaceae covers a wide range of trees, bushes and plants.

References

  1. Zhang S.-D.; Jin J.-J.; Chen S.-Y. et al. (2017). "Diversification of Rosaceae since the Late Cretaceous based on plastid phylogenomics". New Phytol 214 (3): 1355–1367. doi:10.1111/nph.14461. PMID 28186635. 
  2. "Rosales". http://www.mobot.org/MOBOT/research/APweb/orders/rosalesweb.htm. 
  3. 3.0 3.1 Takhtajan A. (1997). Diversity and Classification of Flowering Plants. New York: Columbia University Press. pp. 1–620. ISBN 978-0-231-10098-4. 
  4. "Rosaceae". Merriam-Webster Dictionary. https://www.merriam-webster.com/dictionary/Rosaceae. 
  5. "The Plant List: Rosaceae". Royal Botanic Gardens, Kew and Missouri Botanic Garden. http://www.theplantlist.org/1.1/browse/A/Rosaceae/. 
  6. Christenhusz, M. J. M.; Byng, J. W. (2016). "The number of known plants species in the world and its annual increase". Phytotaxa 261 (3): 201–217. doi:10.11646/phytotaxa.261.3.1. http://biotaxa.org/Phytotaxa/article/download/phytotaxa.261.3.1/20598. 
  7. 7.0 7.1 7.2 "Angiosperm Phylogeny Website". mobot.org. http://www.mobot.org/mobot/research/apweb/welcome.html. 
  8. Bortiri, E.; Oh, S.-H.; Jiang, J.; Baggett, S.; Granger, A.; Weeks, C.; Buckingham, M.; Potter, D. et al. (2001). "Phylogeny and Systematics of Prunus (Rosaceae) as Determined by Sequence Analysis of ITS and the Chloroplast trnLtrnF Spacer DNA". Systematic Botany 26 (4): 797–807. doi:10.1043/0363-6445-26.4.797. 
  9. 9.0 9.1 9.2 9.3 Watson, L.; Dallwitz, M.J. (1992). "The families of flowering plants: Rosaceae L.". http://delta-intkey.com/angio/www/rosaceae.htm. 
  10. 10.0 10.1 10.2 Heywood, V.H.; Brummitt, R.K.; Culham, A.; Seberg, O. (2007). Flowering Plant Families of the World. Ontario, Canada: Firefly Books. pp. 280–282. ISBN 978-1-55407-206-4. 
  11. Stace, C. A. (2019). New Flora of the British Isles (Fourth ed.). Middlewood Green, Suffolk, U.K.: C & M Floristics. ISBN 978-1-5272-2630-2. 
  12. "Rosaceae Juss.: FloraBase: Flora of Western Australia". calm.wa.gov.au. http://florabase.calm.wa.gov.au/browse/profile/22834. 
  13. 13.0 13.1 13.2 13.3 "Phylogeny and classification of Rosaceae". Plant Systematics and Evolution 266 (1–2): 5–43. 2007. doi:10.1007/s00606-007-0539-9. http://biology.umaine.edu/Amelanchier/Rosaceae_2007.pdf. 
  14. Beentje, H. (2010). The Kew Plant Glossary, an Illustrated Dictionary of Plant Terms. Kew, London, U.K.: Kew publishing. ISBN 978-1-842-46422-9. 
  15. Genetics and Genomics of Rosaceae (1 ed.). New York: Springer. 2008. p. 2. ISBN 978-0-387-77490-9. 
  16. TOXNET: CASRN: 29883-15-6
  17. Caratini, Roger. La Vie de plantes. 1971. Encyclopédie Bordas.
  18. Lawrence, G.H.M. 1960. Taxonomy of Vascular Plants. Macmillan.
  19. Schulze-Menz GK. (1964). "Rosaceae". in Melchior H. Engler's Syllabus der Pflanzenfamilien. II (12 ed.). Berlin: Gebrüder Borntraeger. pp. 209–218. 
  20. Hutchinson J. (1964). The Genera of Flowering Plants. 1, Dicotyledons. Oxford: Clarendon Press. pp. 1–516. 
  21. Kalkman C. (2004). "Rosaceae". in Kubitzki K. Flowering plants—Dicotyledons: Celastrales, Oxalidales, Rosales, Cornales, Ericales. The Families and Genera of Vascular Plants. 6 (1 ed.). Berlin Heidelberg: Springer-Verlag. pp. 343–386. doi:10.1007/978-3-662-07257-8. ISBN 978-3-540-06512-8. 
  22. "Diversification of almonds, peaches, plums and cherries—Molecular systematics and biogeographic history of Prunus (Rosaceae)". Mol Phylogenet Evol 76: 34–48. 2014. doi:10.1016/j.ympev.2014.02.024. PMID 24631854. 
  23. "Large-scale phylogenetic analyses reveal multiple gains of actinorhizal nitrogen-fixing symbioses in angiosperms associated with climate change". Sci Rep 5: 14023. 2015. doi:10.1038/srep14023. PMID 26354898. Bibcode2015NatSR...514023L. 
  24. "Global versus Chinese perspectives on the phylogeny of the N-fixing clade". Journal of Systematics and Evolution 54 (4): 392–399. 2016. doi:10.1111/jse.12201. 
  25. Sun Miao; Naeem Rehan; Su Jun-Xia; Cao Zhi-Yong; Burleigh J. Gordon; Soltis Pamela S.; Soltis Douglas E.; Chen Zhi-Duan (2016). "Phylogeny of the Rosidae: A dense taxon sampling analysis". Journal of Systematics and Evolution 54 (4): 363–391. doi:10.1111/jse.12211. 
  26. 26.0 26.1 26.2 "Diversification of Rosaceae since the Late Cretaceous based on plastid phylogenomics". New Phytol 214 (3): 1355–1367. 2017. doi:10.1111/nph.14461. PMID 28186635. 
  27. "A Rosaceae phylogeny". Botany 2002—Botany in the Curriculum: Integrating Research and Teaching. Madison, Wisconsin: Botanical Society of America, St. Louis. 2–7 August 2002. p. 108. 
  28. Potter D. (2003). "Molecular phylogenetic studies in Rosaceae". Plant Genome: Biodiversity and Evolution. 1, Part A: Phanerogams. Enfield, NH: Scientific Publications. pp. 319–351. ISBN 978-1-578-08238-4. 
  29. "Evolution of Rosaceae fruit types based on nuclear phylogeny in the context of geological times and genome duplication". Mol Biol Evol 34 (2): 262–281. 2017. doi:10.1093/molbev/msw242. PMID 27856652. 
  30. "Systematic and evolutionary implications of rbcL sequence variation in Rosaceae". Am J Bot 81 (7): 890–903. 1994. doi:10.2307/2445770. 
  31. Evans R. (1999). "Rosaceae Phylogeny: Origin of Subfamily Maloideae". Botany Department, University of Toronto. http://labs.eeb.utoronto.ca/dickinson/rosaceaeevolution/phylogeny.html. 
  32. "Phylogenetic relationships in Rosaceae inferred from chloroplast matK and trnLtrnF nucleotide sequence data". Plant Syst Evol 231 (1–4): 77–89. 2002. doi:10.1007/s006060200012. 
  33. "Past climate change and plant evolution in Western North America: A case study in Rosaceae". PLOS One 7 (12): e50358. 2012. doi:10.1371/journal.pone.0050358. PMID 23236369. Bibcode2012PLoSO...750358T. 
  34. "Tree of life for the genera of Chinese vascular plants". Journal of Systematics and Evolution 54 (4): 277–306. 2016. doi:10.1111/jse.12219. 
  35. B.C. Bennett (undated). Economic Botany: Twenty-Five Economically Important Plant Families. Encyclopedia of Life Support Systems (EOLSS) e-book

External links

Wikidata ☰ Q46299 entry