EXTANT SEED PLANTS
Plant woody, evergreen; nicotinic acid metabolised to trigonelline; primary cell walls rich in xyloglucans and/or glucomannans, 25-30% pectin [Type I walls]; lignins rich in guaiacyl units; true roots present, xylem exarch, branching endogenous; arbuscular mycorrhizae +; shoot apical meristem complex; stem with ectophloic eustele, endodermis 0, xylem endarch, branching exogenous; vascular tissue in t.s. discontinuous by interfascicular regions; vascular cambium + [xylem ("wood") differentiating internally, phloem externally]; wood homoxylous, tracheids +; tracheid/tracheid pits circular, bordered; sieve tube/cell plastids with starch grains; phloem fibers +; stem cork cambium superficial, root cork cambium deep seated; nodes ?; stomata ?; leaf vascular bundles collateral; leaves spiral, simple, axillary buds?, prophylls [including bracteoles] two, lateral, veins -5(-8) mm/mm2; plant heterosporous, sporangia eusporangiate, on sporophylls, sporophylls aggregated in indeterminate cones/strobili; true pollen [microspores] +, grains mono[ana]sulcate, exine and intine homogeneous, ovules unitegmic, crassinucellate, megaspore tetrad tetrahedral, only one megaspore develops, megasporangium indehiscent; male gametophyte development first endo- then exosporic, tube developing from distal end of grain, to ca 2 mm from receptive surface to egg, gametes two, with cell walls, with many flagellae; female gametophyte endosporic, initially syncytial, walls then surrounding individual nuclei; seeds "large", first cell wall of zygote transverse, embryo straight, endoscopic [suspensor +], short-minute, with morphological dormancy, white, cotyledons 2; plastid transmission maternal; two copies of LEAFY gene, PHY gene duplication, mitochondrial nad1 intron 2 and coxIIi3 intron present.
MAGNOLIOPHYTA
Plant woody, evergreen; lignans, O-methyl flavonols, dihydroflavonols, triterpenoid oleanane, non-hydrolysable tannins, quercetin and/or kaempferol +, apigenin and/or luteolin scattered, cyanogenesis via tyrosine pathway [ANITA grade?], lignins derived from both coniferyl and sinapyl alcohols, containing syringaldehyde [in positive Maüle reaction, syringyl:guaiacyl ratio less than 2-2.5:1], and hemicelluloses as xyloglucans; root apical meristem intermediate-open; root vascular tissue oligarch [di- to pentarch], lateral roots arise opposite or immediately to the side of [when diarch] xylem poles; origin of epidermis with no clear pattern [probably from inner layer of root cap], trichoblasts [differentiated root hair-forming cells] 0; stem with 2-layered tunica-corpus construction; wood fibers and wood parenchyma +; reaction wood ?, with gelatinous fibres; starch grains simple; primary cell wall mostly with pectic polysaccharides; tracheids +; sieve tubes eunucleate, with sieve plate, companion cells from same mother cell that gave rise to the tube, the sieve tube with P-proteins; nodes unilacunar; stomata with ends of guard cells level with aperture, paracytic; leaves with petiole and lamina [the latter formed from the primordial leaf apex], development of venation acropetal, 2ndary veins pinnate, fine venation reticulate, vein endings free; flowers perfect, polysymmetric, parts spiral [esp. the A], free, development in general centripetal, numbers unstable, P not differentiated, outer members not enclosing the rest of the bud, A many, with a single trace, introrse, filaments stout, anther ± embedded in the filament, tetrasporangiate, dithecal, with at least outer secondary parietal cells dividing, each theca dehiscing longitudinally by action of hypodermal endothecium, endothecial cells elongated at right angles to long axis of anther, tapetum glandular, binucleate, microspore mother cells in a block, microsporogenesis successive, pollen subspherical, binucleate at dispersal, trinucleate eventually, tectum continuous or microperforate, exine columellar, endexine thin, compact, lamellate only in the apertural regions, pollen germinating in less than 3 hours, tube elongated, growing at 80-600 µm/hour, with callose plugs and callose-based walls, penetrating between cells, siphonogamy, penetration of ovules within ca 18 hours , nectary 0, G free, several, ascidiate, with postgenital occlusion by secretion, few [?1] ovules/carpel, ovules marginal, anatropous, bitegmic, micropyle endostomal, integuments 2-3 cells thick, megasporocyte single, megaspore lacking sporopollenin and cuticle, chalazal, female gametophyte ?type, stylulus short, stigma ± decurrent, wet [secretory]; P deciduous in fruit; seed exotestal; double fertilisation +, endosperm ?diploid, cellular [first division oblique, micropylar end initially with a single large cell, chalazal end more actively dividing], copious, oily and/or proteinaceous, embryo cellular ab initio; germination hypogeal, seedlings/young plants sympodial; Arabidopsis-type telomeres [(TTTAGGG)n]; whole genome duplication, single copy of LEAFY and RPB2 gene, knox genes extensively duplicated [A1-A4], AP1/FUL gene, paleo AP3 and PI genes [paralogous B-class genes] +, with "DEAER" motif, SEP3/LOFSEP and PHYA/PHYC gene pairs.
Possible apomorphies are in bold. Note that the actual level to which many of these features, particularly the more cryptic ones, should be assigned is unclear, because some taxa basal to the [magnoliid + monocot + eudicot] group have been surprisingly little studied. Furthermore, details of relationships among gymnosperms will affect the level at which some of these characters are pegged.
NYMPHAEALES [AUSTROBAILEYALES [[CHLORANTHALES + MAGNOLIIDS] [MONOCOTS [CERATOPHYLLALES + EUDICOTS]]]]: vessels +, elements with scalariform perforation plates; nucleus of egg cell sister to one of the polar nuclei; ?genome duplication; "DEAER" motif in AP3 and PI genes lost, gaps in these genes.
AUSTROBAILEYALES [[CHLORANTHALES + MAGNOLIIDS] [MONOCOTS [CERATOPHYLLALES + EUDICOTS]]]: ethereal oils in spherical idioblasts [lamina and P ± pellucid-punctate]; tension wood 0; tectum reticulate-perforate, nucellar cap + [character lost where in eudicots?]; 12BP [4 amino acids] deletion in P1 gene.
[CHLORANTHALES + MAGNOLIIDS] [MONOCOTS [CERATOPHYLLALES + EUDICOTS]] : benzylisoquinoline alkaloids +; P more or less whorled, 3-merous [possible position], carpels plicate; embryo sac bipolar, 8 nucleate, antipodal cells persisting; endosperm triploid.
MONOCOTS [CERATOPHYLLALES + EUDICOTS]: (A opposite [2 whorls of] P).
[CERATOPHYLLALES + EUDICOTS]: ethereal oils 0.
EUDICOTS: Myricetin, delphinidin scattered, asarone 0 [unknown in some groups, + in some asterids]; root epidermis derived from root cap [?Buxaceae, etc.]; nodes 3:3; stomata anomocytic; flowers (dimerous), cyclic, K/outer P members with three traces, "C" with a single trace, few, (polyandry widespread), filaments fairly slender, anthers basifixed, pollen with endexine, tricolpate, G with complete postgenital fusion, style solid [?here]; seed coat?
[[SABIACEAE + PROTEALES] [TROCHODENDRALES [BUXALES + CORE EUDICOTS]]]: (axial/receptacular nectary +).
TROCHODENDRALES [BUXALES + CORE EUDICOTS]: benzylisoquinoline alkaloids 0; euAP3 + TM6 genes [duplication of paleoAP3 gene: B class], mitochondrial rps2 gene lost.
BUXALES + CORE EUDICOTS: ?
CORE EUDICOTS: Ellagic and gallic acids common; micropyle?; PI-dB motif +, small deletion in the 18S ribosomal DNA common.
ROSIDS ET AL. + ASTERIDS ET AL.: root apical meristem closed; (cyanogenesis also via [iso]leucine, valine and phenylalanine pathways); flowers rather stereotyped: 5-merous, parts whorled, calyx and corolla distinct, stamens = 2x K/C, developing internal to the corolla whorl, (numerous, but then often fasciculate and/or centrifugal), pollen tricolporate, (nectary disc +), [G 5], [3] also common, compitum +, placentation axile, stigma not decurrent; endosperm nuclear; fruit dry, dehiscent, loculicidal [when a capsule]; euAP1 + euFUL + AGL79 genes [duplication of AP1/FUL or FUL-like gene], PLE + euAG [duplication of AG-like gene: C class], SEP1 + FBP6 genes [duplication of AGL2/3/4 gene].
ROSIDS ET AL. = DILLENIALES [SAXIFRAGALES + VITALES + ROSIDS]: ?
SAXIFRAGALES + VITALES + ROSIDS: stipules + [inserted on the stem]; anthers articulated [often ± dorsifixed, transition to filament narrow, connective thin].
ROSIDS: embryo long; genome duplication; chloroplast infA gene defunct, mitochondrial coxII.i3 intron 0.
ROSID II = [GERANIALES + MYRTALES] [PICRAMNIALES [HUERTEALES [SAPINDALES [MALVALES + BRASSICALES]]]]: ?
[GERANIALES + MYRTALES]: ellagic acid +; K persistent in fruit[!]
MYRTALES Reichenbach Main Tree, Synapomorphies.
Flaky bark; flavonols only, myricetin, methylated ellagic acid +; cork cambium deep seated, (polyderm +); pits vestured; libriform septate fibers +; tension wood +; secondary phloem stratified in young twigs; internal phloem +; nodes 1:1; (spirally-thickened tracheoids +); cuticle waxes often 0; branching from current flush [all?]; leaves opposite, (small stipules +), colleters +; (flowers 4-merous); hypanthium +, nectariferous, K valvate, A incurved in bud, pollen with pseudocolpi, many ovules/carpel, (transseptal bundles +), micropyle bistomal and zig-zag, style +, long, minor stylar bundles +, stigma wet; (mesotesta sclerotic), endotesta crystalliferous; endosperm at most slight. - 11 families, 380 genera, 11027 species.
Myrtales contain ca 6% core eudicot diversity. Fossils assignable to Myrtales are some 65 million years old (Crepet et al. 2004). Lycaenidae caterpillars are quite commonly to be found on members of this order (esp. Lythraceae, Myrtaceae, Combretaceae - see Fielder 1991, 1995).
The position of Myrtales within the rosids is unstable in a recent rbcL analysis of all angiosperms (Hilu et al. 2003); see also the Crossosomatales page. However, there was some support for a position sister to all other rosids except Geraniales, Vitales and Saxifragales (Zhu et al. 2007). Relationships within the order have been extensively studied by Conti et al. (1996, 1998, 1999, 2002), Sytsma et al. (1998, esp. 2004), Clausing and Renner (2001: Melastomataceae), Schönenberger and Conti (2001, 2003: esp. Oliniaceae, etc.) and Wilson et al. (2005: Myrtaceae s.l.), and the tree is based on these publications. The position of Combretaceae seems still to be unclear.
There are a number of other characters that are common in Myrtales and may be apomorphies for them. Raffinose and stachyose are common oligosaccharides in phloem exudate in Myrtaceae, Onagraceae, Lythraceae and Combretaceae, at least (Zimmermann & Ziegler 1975). Polyderm (alternating endodermal and parenchymatous layers laid down by a pericyclic meristem) is known from families like Onagraceae, Lythraceae, Myrtaceae, and probably Penaeaceae and Oliniaceae, at least (Mylius 1913), while in roots of some aquatic Lythraceae, Melastomataceae. Myrtaceae and Onagraceae (and Euphorbiaceae and Fabaceae) there is a distinctive lacunate cork produced from a pericyclic cork cambium (Little & Stockey 2006). Tracheoidal sclereids with spiral wall thickenings that are associated with the vein endings are known from Vochysiaceae, Lythraceae, Combretaceae, Melastomataceae, Alzateaceae and Penaeaceae (Sajo & Rudall 2002); their more general distribution needs to be checked. Since there is internal phloem, petiole and midrib bundles are often bicollateral. Weberling (2000) notes that "true rudimentary stipules" occur in Myrtaceae and most myrtalean families; stipules, when they occur, are indeed generally small. In Myrtaceae the calyx and corolla originate at about the same time, while in Lythraceae and Onagraceae the calyx is visible considerably before the corolla (Mayr 1969); it will be interesting to know the general distribution of this feature. Many Myrtales, including some Myrtaceae, have notably narrow petal bases, i.e., they are close to being clawed; the definition and distribution of clawed petals may have to be amended. Those taxa in which the stamens are straight in bud have short filaments, and the length of the style is correlated in part with the length of the hypanthial tube. The basic chromosome number for the order may be x = 12 (Graham et al. 1993).
The cork cambium is sometimes initiated in the mid-cortical position (e.g. Myrtaceae, Melastomataceae).
For further information, see Weiss (1890: cork cambium), Lourteig (1965), Venkateswarlu and Prakash Rao (1971), Beusekom-Osinga and Beusekom (1975: morphology etc. around Crypteroniaceae), Johnson and Briggs (1985: morphological phylogeny), Van Vliet and Baas (1975, 1985: vegetative anatomy), Rye (1979), Solt and Wurdack (1980: chromosome number), Tobe and Raven (1983a, 1985a, 1985b, 1987a, 1990: embryology), Dahlgren and Thorne (1985: general, and other papers in this issue of the Ann. Missouri Bot. Gard.), Boesewinkel and Venturelli (1987: ovule and seed), Ronse Decraene & Smets (1991b: polyandry), and Almeda (1997: chromosome number).
Includes Alzateaceae, Combretaceae, Crypteroniaceae, Lythraceae, Melastomataceae, Memecylaceae, Myrtaceae, Oliniaceae, Onagraceae, Penaeaceae, Rhynchocalycaceae, Vochysiaceae.
Synonymy: Combretales Baskerville, Lythrales Caruel, Melastomatales Oliver, Oenotherales Bromhead, Onagrales Reichenbach f., Penaeales Lindley, Vochysiales Dumortier - Myrtanae Takhtajan - Myrtopsida Bartling, Oenotheropsida Brongniart
COMBRETACEAE R. Brown, nom. cons. Back to Myrtales
Lianes or trees; 5-desoxyflavonoids, flavonoid sulphates +; (cork epidermal; included phloem + - Combreteae); fibers with at most minutely bordered pits; sclereids +/0; (mucilage ducts - Terminalia); (stomata cyclo- or paracytic); petiole bundle arcuate to annular (wing bundles +); hairs often unicellular, pointed, thick-walled, and with a basal internal compartment, (lepidote); leaves spiral or opposite, conduplicate or supervolute (revolute - Laguncularia), domatia or other glands common, stipules at most small; (plant monoecious), inflorescence racemose; flowers 4-5(-8)-merous; C often small or 0, A obdiplostemonous, (= and alternate with or opposite sepals; -15), inserted below or at the hypanthial, G [2-5(-8)], inferior, alternate with K or odd member abaxial (nectary on top), unilocular, with (1-)2-7(-20) pendulous ovules, nucellar cap +, (micropyle endostomal - Guiera), funicles long, usu. with obturator, stigma punctate (capitate); fruit indehiscent, usu. dry and wind- or water-dispersed, ± flattened and/or winged, (drupaceous); seed large; endotesta tracheidal or sclerotic, ?not crystalliferous, fibrous exotegmen +; embryo often green, cotyledons convolute or plicate; n = (7, 11)12-13.
14[list]/500: Combretum (255), Terminalia (190). Largely tropical (Map: from van Steenis & van Balgooy 1966; Wickens 1976; FloraBase 2006: incomplete). [Photo - Flower, Flower, Fruit.]
Keating (1985) describes the stomata as being paracytic while Dahgren and Thorne (1985) call them anomocytic; in any event, variation in stomatal morphology is extensive (Tilney 2002). Fibers are usually non-septate; those of Lythraceae are septate. For obdiplostemony, see Eckert (1966, also Tomlinson 1986). There are hairs lining the ovary loculus walls in Combretum.
Strephonema may be sister to the rest of the family - Strephonema lacks internal phloem and has paracytic stomata: K 5, C 5, clawed, A 10, pollen lacking pseudocolpi, only semitectate, G half inferior, 2 pendulous ovules; cotyledons large, hemispherical. Lumnitzera and Laguncularia, both mangrove plants, are sister taxa, but Conocarpus, also found in similar habitats, is not immediately related (Tan et al. 2002).
Some information is taken from Graham (1964: general), Verhoeven and van der Schijff (1974: anatomy, including root cork cambium!), El Ghazali et al. (1998: pollen) and Stace (2006: general).
Synonymy: Bucidaceae Sprengel, Myrobalanaceae Martynov, Sheadendraceae G. Bertolini, Terminaliaceae Jaume Saint-Hilaire
Onagraceae + Lythraceae: tannins often not abundant, soluble oxalate accumulating; vessels in groups in the wood; fibers with at most minutely bordered pits; petiole bundle arcuate; inflorescence racemose; (flowers vertically monosymmetric), C clawed, (pollen at anthesis with starch), several megasporocytes; fibrous exotegmen +; starch grains in nucellus; n = 7.
Decodon is the only typically pentamerous genus in Lythraceae (Graham 2006); see also Ludwigia (Onagraceae) - both seem to be sister to the rest of their respective families! Working out where meristicity changes on the tree thus becomes difficult.
ONAGRACEAE Jussieu, nom. cons. Back to Myrtales
Often herbaceous; flavonoid sulphates +; raphides +; leaves ± flat to involute, (spiral, margins toothed, stipules 0); inflorescence raceme or spike (flowers axillary), bracteoles often 0, C often clawed, deciduous, A straight, anthers polythecate, pollen with viscin threads, starchy, (colpate), apertures protruding, ektexine paracrystalline, beaded, ovary inferior, alternating with K, (placentation parietal), embryo sac 4-nucleate, monosporic [Oenothera type]; fruit a capsule opening down the sides (baccate); exotesta often hairy or papillate, inner walls thickened and lignified (mesotestal cells thickened; endotegmic cells longitudinally elongated, "tanniniferous", inner walls thickened); endosperm nuclear, diploid.
22[list]/656 - two subfamilies below. World-wide (Map: based on Raven 1963, 1967; Meusel et al. 1978, P. Hoch & W. Wagner, pers. comm.).
1. Ludwigioideae W. L. Wagner & Hoch
Flowers 4-5-merous, hypanthium 0, (A 10), pollen in tetrads (monads), nectary on G, G with central vascular bundles, megasporocyte 1, style short, stigma capitate; diploid.
1/82: World-wide, esp. America. [Photo - Flower]
The stipules of Ludwigia can be quite prominent. Taxa with five and those with ten stamens form separate clades (Barber et al. 2008). The style has minor bundles, but these are absent in other members of the family.
2. Onagroideae W. L. Wagner & Hoch
Included phloem +; flowers 4-merous (2-merous - Circaea), hypanthium long, deciduous, A also (1, 2), transseptal vasular bundles +, (nucellus 10-25 cells thick), (style short), no minor stylar bundles (stigma divided; dry); K not persistent in fruit; n = 9-11, etc.
21/574: Epilobium (165), Oenothera (145: inc. Gaura, etc.), Fuchsia (105), Clarkia (42), Lopezia (22). World-wide, esp. S.W. North America. [Photo - Flower, Flower.]
Some caterpillars are found both on Vitaceae and Onagraceae (Forbes 1956) - and both contain raphides. Different rusts occur on Onagroideae and Jussiaeaoideae (Savile 1979b). fo details of floral morphology and its relation to pollination, see details throught Wagner et al. (2007).
There are some very distinctive floral morphologies in Onagroideae. Thus Circaea has only two petals and two stamens, the latter being opposite the calyx. In the monosymmetric flowers of Lopezia there is only a single extrorse anther, a petaloid staminode, while the two adaxial petals may be recurved, with pseudonectaries on their claws. Gongylocarpus has sessile flowers, as is quite common in Onagraceae, but after pollination the ovary becomes completely enveloped by stem tissue. The viscin threads vary considerably in morphology, often being annular-vermiform, but also smooth or irregularly beaded (Skvarla et al. 1976).
All the chromosomes in some species of Oenothera form a ring by a series of permanent translocations, the whole genome forming a single linkage units (Harte 1993 for its contributions to biology; Wagner et al. 2007). Hugo de Vries thought that the abrupt appearance of O. lamarckiana was an example of evolution, which for him was a process in which mutation = major change/speciation, but no natural selection. However, it turned out that it was a morphological variant that represented the breakdown of the translocation system (cf. Linnaeus and Peloria (Plantaginaceae).
Knowledge of relationships along the backbone of the Onagroideae seems to be stabilising. Hauya, [Fuchsia + Circaea], Lopezia, and Gongylocarpus are successive branches (tribes) from the clade leading to [Epilobeae + Onagreae] (Levin et al. 2003, 2004), however, Ford and Gottlieb (2007) obtained a grouping [Hauya [Fuchsia + Circaea]]. Reflecting the new, but for the most part well supported phylogeny of the family, taxon limits have had to be adjusted, so Oenothera has been expanded and Camissonia very much cut up (e.g. Levin et al. 2004); for appropriate nomenclatural changes, see Hoch and Wagner (2007).
In 1827 Robert Brown recorded the phenomenon that is now called Brownian motion when observing the pollen grains of Clarkia pulchella.
For information, see Johansen (1928: hypostase presence, and correlation with the environment), Eyde (1982: floral anatomy), Tobe and Raven (1986, 1996), Hoch et al. (1993: all variation in anther septa development, embryology), the Onagraceae website (up-to-date summary of phylogeny, classification, etc.) and Wagner et al. (2007: superb summary, all supraspecific taxa).
Synonymy: Circaeaceae Ruthe, Epilobiaceae Ventenat, Fuchsiaceae Lilja, Isnardiaceae Martynov, Jussiaeaceae Martynov, Lopeziaceae Lilja, Oenotheraceae C. C. Robin
LYTHRACEAE Jaume Saint-Hilaire, nom. cons. Back to Myrtales
Herbs to trees; quinolizidine alkaloids +; mucilage cells common; hairs uni- or bi(multi)cellular; leaves (spiral), flat to conduplicate, (margins dentate - Trapa), stipules +/0; (inflorescence determinate); flowers 3-6(-16)-merous, heterostyly common; (hypanthium spurred, or 0, but with K + C tube), hypanthium/K often strongly ribbed, with alternating appendages, C crumpled in bud, (0), A basically obdiplostemonous, (1 - = and opposite sepals - many, centrifugal), inserted just below C to near ovary, filaments of unequal length, (pollen pseudocolpi 0; disc at base of G), G [2-6(-many)], superior to inferior, orientation variable, (placentation parietal), (1-few ovules/carpel), archesporium multicellular, stigma also dry; fruit a capsule, dehiscence various, inc. circumscissile (indehiscent; berry), K persistent, often ± enclosing fruit; seeds flattened; testa multiplicative, many-layered (not Duabanga), exotesta various, (invaginated mucilage hairs +), endotestal cells often elongated and tracheidal/sclerotic, (endotegmen of crossing fibres); (cotyledons folded); n = (5-)8(-11, + polyploids), chromosomes 1-4 µm long.
31[list]/620: Cuphea (cigar flower - 250: flower monosymmetric; placenta expanded in fruit, see Graham et al. 2006 for a phylogeny), Diplusodon (75), Lagerstroemia (55 - A centrifugal), Nesaea (55 - probably to go into Ammannia - then = 80), Rotala (45). Tropical, but some temperate (Map: from van Balgooy 1975; Graham et al. 2005). [Photo - Flower]
The fossil Trapago is known from deposits 65-73 million years before present, and other fossils assignable to Myrtales are perhaps slightly older (Crepet et al. 2004, for references). Sonneratia, a mangrove genus, has a long fossil record (distinctive pollen as Florschuetzia - Muller 1978); for the evolution of the mangrove habitat, see Rhizophoraceae.
Androecial development is both centrifugal and centripetal (Weberling 1989 and references; Ronse Decraene & Smets 1991). Pollen is notably variable (Graham 2006). When G = K, the carpels may alternate with or be opposite to them, when G = 2, the carpels may be transverse or median, when G = 3, the odd carpel is adaxial (Eichler 1878; Baillon 1877; Spichiger et al. 2002). The inferior ovary of Punica granatum (pomegranate) is unique in flowering plants, appearing to have two (or three) superposed layers of carpels, the basal with axile and the others with intrusive parietal placentation; the placentation is fundamentally axile, the appearance of parietal placentation being the result of growth at the base od the ovary (Sinha & Joshi 1959 for vasculature). In the other species of the genus, P. proto-punica, there is an ordinary semi-inferior ovary.
S. Graham et al. (2005) found some support for the topology [Decodon [[Lythrum + Peplis] remainder of the family]]; these other genera were included in two large clades, inverted mucilaginous hairs in the testa possibly being a synapomorphy. However, support along the whole back-bone was weak, and in some analyses there were two major clades in the whole family, with the three genera just mentioned forming a subclade within one of them. S. Graham et al. (2005) list characters for the major clades that they found. Sonneratiaceae - Sonneratia plus Duabanga - are not monophyletic (Shi et al. 2000; see also Huang & Shi 2002: one species per genus sampled); Sonneratia itself may be sister to Trapa.
Graham and Cavalcanti (2001) suggest that x = 8 is the basic chromosome number for the family.
For general information, see Graham (2006).
Synonymy: Ammanniaceae Horaninow, Blattiaceae Niedenzu, Duabangaceae Takhtajan (n = 12), Lagerstroemiaceae J. Agardh, Lawsoniaceae J. Agardh, Punicaceae Horaninow, nom. cons. (ellagitannins in fruit; no xylem parenchyma; cuticle waxes as platelets; C clawed, crumpled in bud; G on two or three levels, transseptal bundles +, micropyle exostomal [bistomal - Corner, 1976]; exotesta columar, fleshy, tegmen undistinguished; n = 7, 8 - alkaloids like those of other Lythraceae), Sonneratiaceae Engler, nom. cons. (no axial xylem parenchyma; branched sclereids +; tegmen not persistent (check); n = 12 - [Sonneratia, embryo green - mangrove]), Trapaceae Dumortier, nom. cons. (aquatic; A 4, G 2, transverse, one pendulous ovule/carpel, massive nucellar beak +; fruit indehiscent, K persisting as horns; testa multiplicative; haustorial suspensor +, endosperm starchy, cotyledons very unequal; n = 20, 24 - Trapa [water chestnut])
Oil glands are found in the anthers of Myrtaceae and Memecylaceae, and a number of other taxa in the Melastomataceae-Crypteroniaceae clade also have a very much expanded connective. Whether some staminal features - perhaps linked with pollination - are a higher-level apomorphy in this clade awaits further study.
Vochysiaceae + Myrtaceae: hairs simple, 1-2-celled; K and C imbricate, pollen syncolporate; style depressed in apex of gynoecium; fruit a capsule.
Sytsma et al. (2004) discuss the age and biogeographic history of the group in some detail, noting i.a. that the present distribution of Vochysiaceae on either side of the Atlantic is likely to be the result of dispersal; they suggest that Psiloxylon may have been hopping about on islands in the Indian Ocean for almost 40 my.
Conti et al. (1996) found a well supported [Heteropyxidaceae + Psiloxylaceae] sister to [Myrtaceae + Vochysiaceae]; the pollen grains of the first two are similar to those of Myrtaceae (Dahlgren & Thorne 1985). Monophyly of Myrtaceae s. str. (= Myrtoideae) was not strong (Conti et al. 1996, 1998). However, Wilson et al. (2005: matK only) found Myrtaceae s. str. to have 80% jacknife support, while Myrtaceae s. str. + [Heteropyxidaceae + Psiloxylaceae] (all together = Myrtaceae here) had ³95% support; a similar set of relationships occured in Sytsma et al. (2004; matK and ndhF).
VOCHYSIACEAE A. Saint-Hilaire, nom. cons. Back to Myrtales
Trees (lianes); 5-deoxyflavonoids +; plants Al accumulators; included phloem +; leaf traces run along stem before entering petiole; pericyclic fibers at most few; sclerified bundles + (0) (secretory canals +) in pith; sclereids, mucilage cells +; cuticle waxes as ± grouped parallel platelets; stomata also paracytic; indumentum often brown, hairs T-shaped, unicellular, or stellate; leaves opposite, conduplicate, leathery, stipules cauline, as large glands or colleter-like; inflorescence terminal (axillary), with lateral cincinni, flowers strongly obliquely mono- or asymmetric, hypanthium 0, K basally connate, one adaxial-lateral larger and with nectariferous spur from floral axis (three K petaloid - Korupodendron), C 1, 5 (3), unequal, A 1, straight, more or less opposite abaxial lateral petal, (staminodes 2), G [3 (4)], odd member adaxial, many [epitropous] ovules/carpel, stigma punctate to subcapitate; fruit samaroid [by accrescent K lobes] OR seeds variously winged, testa thin, mesotesta ?not sclerotic, endotestal cells ± thickened, pectic, mesotegmic cells fibrous, thick-walled or not, or testa multiplicative, exotesta with thickened hairs, a few other layers persisting, but rest and tegmen disorganised; cotyledons folded; n = 11, 12.
7[list]/190: Vochysia (100), Qualea (60). Lowland tropical America, apart from Erismadelphus and Korupodendron from W. Africa (Map: from Stafleu 1954). [Photo - Flower]
Erismieae, containing the tropical American Erisma and the West African Erismadelphus and Korupodendron, are monophyletic. They have cortical/subepidermal phellogen, G 1, ± inferior (perhaps plesiomorphic), 1-2 lateral to apical ovules/carpel; fruit samaroid, with persistent enlarged K; testa undifferentiated, with vascular bundles. Vochysieae are probably not monophyletic (Litt 1999).
At least in Vochysia guatemalensis there are conspicuous, symmetrically-arranged mucilage canals in the pith. The stamen may be opposite either the abaxial-lateral C or the adjacent K; in the latter case, it is off the plane of symmetry (Kawasaki 1998; also Litt & Stevenson 2003b). The flowers are basically epigynous, the ovary being initiated in an inferior position; the superior position in the mature flower is secondary (Litt 1999; Litt & Stevenson 2003a). Baillon (18) suggested that the odd carpel is abaxial. Leaves of small saplings may have short petioles and swollen leaf bases.
Although anatomy and molecular data strongly suggest that Vochysiaceae are to be included in Myrtales, at first sight the flowers appear unlike those of the other members of the order. Hardly surprisingly, Vochysiaceae have often been associated with families that are no longer thought to be at all closely related. Thus Vochysiaceae, often including Euphronia (e.g. Mabberley 1997; Takhtajan 1997: see Euphroniaceae in Malpighiales here), were placed in Celastrales by Cronquist (1981), and in Vochysiales, along with families like Malpighiaceae (in Malpighiales), Tremandraceae (= Elaeocarpaceae, in Oxalidales) and Krameriaceae (in Zygophyllales), by Takhtajan (1997).
For anatomy, see Sajo and Rudall (2002), for floral development and morphology, see Litt and Stevenson (2003a, b), for a general account, see Kawasaki (2006).
MYRTACEAE Jussieu, nom. cons. Back to Myrtales
Ethereal oils [usu. terpenes] +; wood fibers with distinctly bordered pits; leaves with gland dots; connective glandular [terpene-producing].
131/4620, three groups below. Worldwide, mostly tropical-warm temperate.
1. Psiloxyloideae Schmid
Plant "tanniniferous"; leaves spiral; plant dioecious; C clawed, A erect in bud, with separate traces, staminate flowers: 4 anther thecae opening separately, pistillode +; carpellate flowers: staminodia +, G [3], embryo sac bisporic, 8-nucleate; endotesta crystalliferous, cells periclinally elongated; x = 12.
Johnson and Briggs (1984) emphasized the fully superior nature of the ovary in Psiloxyloideae (= their Psiloxylaceae), with its relatively narrow base, comparing it with the more or less inferior ovary of Myrtoideae (Myrtaceae), which always had a broad base.
2/4. Southern Africa, Mascarenes.
1A. Heteropyxideae Engler & Gilg Back to Myrtales
Trees; no axial xylem parenchyma; crystallolids as small platelets; leaves with domatia, stipules minute; (plant monoecious); staminate flowers: stamens = and opposite sepals[?] (+ 2 or 3 opposite petals); carpellate flowers: (G also [2]), ovules hemitropous, stigma capitate; seeds with 2 wings (one at micropyle), exotesta with tangentially elongated cells, walls scalariform-reticulately thickened, exotegmic cells elongated.
1/3. Central and S.E. Africa.
Heteropyxideae are perhaps most similar to Myrtoideae-Leptospermeae; both wood anatomy (e.g. bordered pits) and pollen are like those of Myrtoideae (Stern & Brizicky 1958). The plant apparently lacks terpenes. The stamens have separate traces and the androecium shows no signs of being fasciated.
Synonymy: Heteropyxidaceae Engler & Gilg, nom. cons.
1B. Psiloxyleae (Croizat) A. J. Scott Back to Myrtales
Trees; secretory canals in the young stem; vestured pits?; nodes ?; hairs 0; stipules colleter-like; (plant polygamodioecious), pedicels articulated; flowers 4-5(-6)-merous; C coriaceous, caducous, punctate, staminate flowers: A 2x C, anthers versatile; carpellate flowers: (G also [4]), ovules hemicampylotropous, style 0, stigma large, lobed; fruit baccate, punctate; exotesta cells large, exotegmen crushed.
1/1: Psiloxylum mauritianum. Mascarenes.
Synonymy: Psiloxylaceae Croizat
3. Myrtoideae Sweet Back to Myrtales
(Ectomycorrhizal) trees; (plants Al accumulators); (hairs multicellular); sieve tubes with non-dispersive protein bodies; (stomata paracytic); leaves opposite or spiral, ptyxis variable, (2ndary veins palmate), stipules 2, or several, colleter-like, or 0; flowers (3-)4-5(-8)-merous; (K or P calyptrate, circumscissile), C (0-)4-5(-12), often deciduous, A many, conspicuous (5, = or in fascicles opposite petals (K); development centripetal; 10), pollen often syncolpate, G [2(-18], at least partly inferior, alternate or opposite petals or odd member abaxial, placentae thick, transseptal bundles +, (ovules unitegmic), (1-locular; 1-4(-10) basal ovules), minor stylar bundles 0, stigma punctate to capitate (peltate), also dry; (fruit baccate); testa multiplicative, ± sclerotic, or exotesta thickened, endotesta thickened or not (sclerotic palisade cells at the micropyle), exotegmen 0; embryo (undifferentiated - Eugenia), green or white, straight or curved, cotyledons often connate, intricately folded, etc.; n = (5-)11(12).
129[list]/5330: Eugenia (1115, to include Hexaclamys), Syzygium (1045), Eucalyptus (680 - Corymbia, if separate, 115), Eugenia (1115, to include Hexaclamys), Myrcia (400: limits unclear), Melaleuca (220), Verticordia (100), Calyptranthes (100: limits unclear), Psidium (100), Campomanesia (80), Leptospermum (80), Calytrix (75), Myrcianthes (50), Metrosideros (50: limits unclear), Darwinia (45), Xanthostemon (45), Tristania (40). Tropical, also temperate, esp in Australia (Map: from Meusel et al. 1978). [Photo - Bark, Flower, Flower, Fruit.]
Tortricine moths (Epitymbiini) larvae feed on Myrtaceae leaf litter in Australia, and some other moth groups are also foliovores on this family there (Powell et al. 1999). About half the galls on Australian plants have been recorded from Myrtaceae (Mani 1964); thus galls are commonly formed from a possibly mutualistic association of a nematode Fergusobia and the dipteran Fergusonina, which the nematode parasitises for part of its life cycle (Ye et al. 2007). In many Myrtaceae the numerous stamens with their brightly coloured filaments are the part of the flower than attracts pollinators visually, and in a number of taxa such as Callistemon, the bottle-brush, the flowers are aggregated into inflorescences all flowers of which open simultaneously. Calothamnus has monosymmetric flowers, the upper lip being formed by a group of connate stamens (Westerkamp & Claßen-Bockhoff 2007). The anther glands produce oils, sometimes perhaps to attract pollinators, but also to help in the attachment of pollen to stylar hairs that are involved in the secondary pollen presentation that occurs in Verticordia, for example (Ladd et al. 1999). Dry-fruited Myrtoideae are ectomycorrhizal (e.g. Smith & Read 1997).
For polyhydroxyalkaloid distribution, see Porter et al. (2000). A number of Myrtoideae produce gums. Myrtaceae quite commonly have a more or less elaborated basal portion of the hypocotyl bearing root hairs, however, in Angophora there is a broad, disc-like structure apparently devoid of such hairs (Baranov 1957). Perianth parts of some Eucalyptus relatives are undifferentiated (Bohte & Drinnan 2005); circumscissile abscission of the hypanthium occurs in various ways. Androecial variation is extreme, even in quite closely-related taxa; even when the stamens are apparently oppositisepalous, this condition is developmentally derived from an oppositipetalous androecium (see e.g. Carrucan & Drinnan 2000; Drinnan & Carrucan 2005). There is considerable variation in ovule development (Bohte & Drinnan 2005).
When a family, this group was traditionally divided into Leptospermoideae - leaves spiral to opposite; fruit dry, dehiscent - and Myrtoideae - polyhydroxyalkaloids common; leaves opposite; terpenoid-containing glands in the apex of the connective, stigma dry; fruit fleshy, indehiscent. The latter are largely derived and monophyletic, although the large genus Syzygium (in the past sometimes even synonymised under Eugenia), along with Acmena and other segregate genera, represent an independant acquisition of the fleshy fruit from that in Eugenia itself and the bulk of Myrteae (see also Johnson & Briggs 1984). Some generic limits in these latter are problematic (Lucas et al. 2005, 2007), while Biffin et al. (2006; see also Biffin et al. 2007) suggest that Syzygium should be delimited broadly, at least pending a better understanding of the morphological variation of this clade. The capsular Leptospermoideae are paraphyletic (Sytsma et al. 1998; Wilson et al. 2001; Salywon et al. 2002). It is perhaps not surprising that testa anatomy correlates with fruit type: capsular fruits have exotestal seeds; baccate fruits have seeds with a generally sclerotic testa.
For inflorescence structure, see Briggs and Johnson (1979).
Synonymy: Chamelauciaceae Rudophi, Kaniaceae Nakai, Leptospermaceae F. Rudolphi, Melaleucaceae Vest, Myrrhiniaceae Arnott
For general information on the family, see Schmid (1980), for a matK phylogeny and classification, see Wilson et al. (2005), for general information on the very large genus Syzygium s.l., see Parnell et al. (2007), for Eucalyptus, see McKinnon et al. (2008), for fossils, see Basinger et al. (2007), and for terpenes in Australian Myrtaceae, see Keszei et al. (2008).
Melastomataceae + Crypteroniaceae + Alzataeaceae + Penaeaceae + Oliniaceae + Rhynchocalycaceae: (plants Al accumulators); (nodes swollen); branched or unbranched sclereids +/0 within same family; inflorescence cymose; connective abaxially much expanded [least in Rhynchocalycaceae], disc 0.
A number of taxa, but apparently not Melastomataceae, have more than a single branch from the leaf axil. Nodes other than simple unilacunar are quite widespread, however, a survey of nodal anatomy, particularly that of Melastomataceae, is much needed. For relationships in this area, see Conti et al. (2002).
Melastomataceae + Memecylaceae [= Melastomataceae s.l.]: included phloem +; (styloids +); 2ndary veins 2 or 4, strong, from (near) the base; C contorted, anthers with branched trace, pollen with pseudocolpi; radicle bent.
The inclusion of Memecylaceae in Melastomataceae is an option in A.P.G. II. Mouriri + Memecylon are sister to Pternandra, in turn sister to Melastomataceae s. str. in ndhF trees; Morley (1953, 1976) suggested this general relationship. However, Pternandra is probably sister to rest of Melastomataceae s. str. (Clausing & Renner 2001: moderately good support in a 3-gene analysis).
Included phloem may be homoplasious in Pternandra and Memecylaceae (Clausing & Renner 2001). For vasculature of the stamens, see Wilson (1950 - ignore the explanation!). Uninucleate tapetal cells are common, although not in Mouriri. For leaf anatomy, see Mentink and Baas (1992).
I am grateful to S. Renner for comments.
MELASTOMATACEAE Jussieu, nom. cons. Back to Myrtales
Acylated anthocyanins +; (nodes 1:3; split laterals); cortical (and medullary) bundles +; leaves conduplicate or supervolute, tertiary veins at right angles to the midrib, stipules 0; (flowers ± monosymmetric by the androecium), pollen 3-colporoidate, ovary superior to inferior, opposite sepals, often spaces between ovary wall and tube, nucellar cap +, stigma punctate to capitate; fruit a capsule (opening down inferior part); radicle in testal pocket, exotesta palisade to cuboid and lignified, sclerotic mesotesta +, tegmen crushed, small seeds with hilar operculum; cotyledons often unequal.
182[list]/4570 - 2 main groups below. Largely tropical and subtropical, esp. South America. [Photo - Flower, Fruit, Fruit.]
1. Kibessioideae
Petiole bundle arcuate; stomata anomo-cyclocytic; hairs uniseriate; endothecium in inner wall of inner sporangium only, placentation parietal [ovary divided by septae]; capsule fleshy.
1/15. Southeast Asia.
2. Melastomatoideae
Included phloem 0; petiole bundles variable; leaf veins lacking fibrous sheath; endothecium ephemeral.
2A. Astronieae
Petiole bundle complex, open; stomata mostly anomocytic; hairs peltate scales; (anthers opening by slits), placentation basal to basal-axile.
4/150: Astronidium (70), Astronia (60). Indomalesia and Pacific.
2B. REST:
Trees (lianes) herbs; petiole bundle(s) arcuate or complex; stomata variable, poly- and cyclocytic, etc.; hair types very diverse, including short-stalked glands; leaves with 2ndary veins 3 or 5 strong from (near) the base, tertiary veins at right angles to the midrib; flowers (3-)4-5(-10)-merous, (K with alternating lobes, A (= and opposite sepals, many), connective with a basal appendage or not (nectary +), G 2-15, (1-few ovules/carpel), (style hollow); (fruit dehiscence irregular; baccate); n = (8-)9(-)12(-)17 (23, 31).
177/4305: Miconia (1000), Medinilla (400), Tibouchina (245), Sonerila (?180), Leandra (175), Clidemia (120), Gravesia (105), Microlicia (100), Tococa (50). Largely tropical and subtropical, esp. South America (Map: from Quian & Ricklefs 2004; FloraBase 2007; Woodgyer 2007).
For a phylogeny of the fleshy-fruited and speciose - but paraphyletic - Miconieae, members of the one genus are also considerably intermingled, see Michelangeli et al. (2004) and Martin et al. (2008); generic limits in Merianeae are also difficult (Schulman & Hyvönen 2003).
Some species of Tococa live in close association with the ant Myrmelachista which creates mono- or oligospecific "devil's gardens" by injecting formic acid into the leaves of the surrounding vegetation, which is thus suppressed (Morawetz et al. 1992; Frederickson et al. 2005). Buzz pollination is common, however, some taxa have nectariferous anther connectives, or nectar is produced on the corolla (Medinilla) or even on the top of the ovary (some Miconia), and in these cases the contorted petals form a tube, rather than spreading widely as is common in the family and there is bird pollination (Vogel 1997; Varassin et al. 2007: for necariferous taxa, see also Renner 1989). Petiolar or laminar ant domatia are quite common in Blakeeae and Miconieae. Morley & Dick (2003) were inclined to think that the broad outlines of diversification in Melastomataceae could be linked with major tectonic (drift) events, but Renner (2004 and references) suggests that dispersal is more likely, with separate Miocene dispersal events populating Madagascar, for example.
Sonerila may look rather different vegetatively from the rest of the family, the leaf blades sometimes lacking the typical venation and having toothed margins, but it has similar anthers (although sometimes there are only three stamens), fruits, etc. (in some species the fruits open by the placenta breaking through the wall- cf. Cuphea! [Cellinese 1997]).
Vessel:ray pits are simple. The roots have anthocyanins. A survey of nodal anatomy in the family is needed; split laterals are probably quite common (see also R. A. Howard in van Vliet & Baas 1975). In Dissochaeta and Pternandra there is a prominent stipular flange below the leaves in the interpetiolar position. Ptyxis may seem to be plicate, perhaps because the secondary veins are so prominent. Monosymmetry of the flower is most evident in the androecium, and the stamens may form a serried rank on one side of the flower; I do not know the basic orientation of the flower.
For the phylogeny and morphology of Melastomataceae, see Clausing and Renner (2001). A tribal classification awaits further sampling of New World taxa in particular, but it cannot be based simply on fruit types. Capsular fruits are linked with superior ovaries and fleshy fruits with inferior ovaries; fleshy fruits have arisen more than once. A few taxa with dry, dehiscent fruits have inferior ovaries, and here the fruit wall may fall away, the fruit than functioning as a capsule (Michelangeli et al. 2008).
Synonymy: Blakeaceae Barnhart, Miconiaceae K. Koch, Rhexiaceae Dumortier
MEMECYLACEAE Candolle Back to Myrtales
Libriform septate fibers 0; intraxylary phloem +; (nodes 1:3); sclereids, inc. terminal foliar sclereids + (0); crystal styloids + (0); petiole bundle arcuate or annular; (leaf veins lacking fibrous sheath); stomata paracytic; hairs 0 (uniseriate); stem apex frequently aborting, branching (complex) from previous flush; leaves with flat [Memecylon] or revolute [Mouriri] ptyxis, (2ndary veins pinnate), stipules + [seedlings]; pedicels articulated; flowers 4-5-merous, K imbricate or quincuncial, A 2x K (straight - Votomita), connective with depressed elliptic terpenoid-producing gland, ovary inferior, carpels opposite petals, placentation basal, axile or parietal, 1-18(-many) apotropous ovules/carpel, stigma wet; fruit a berry; seeds large, cotyledons thick or curved, exotestal cells ± longitudinally elongated (some sclerotic hypodermal exotestal cells: Memecylon), exotegmen fibrous, massively sclerotic subhilum; embryo large (small), green, cotyledons crumpled [Memecylon]; n = 7; hypocotyl elongated or not in germination, cotyledons lobed.
6/435: Memecylon (300), Mouriri (85). Tropical (Map: from Morley 1976; Schatz 2001). [Photo - Flower, Fruit.]
Genera of Apidae and Anthophoridae collect material from the terpenoid-producing anther glands, also collecting pollen by buzz pollination. Flowers with these glands (overwhelmingly predominating) are blue, flowers without them are white (Buchmann 1987).
Stone (2006) provides a phylogeny of this clade (as Olisbeoideae); the six morphologically-based genera all have molecular support.
Vessel:ray pits are half bordered, and the rays are 2-5 cells wide and heterocellular, compared to 1(-4) cells wide and homocellular elsewhere. There is no anthocyanin in the root tips; cf. Melastomataceae! The leaves of Mouriri remain folded as they elongate. The floral vasculature of Mouriri is distinctive (Morley 1976).
Much information is taken from Morley (1976) and Renner (1993).
Synonymy: Mouririaceae Gardner
Crypteroniaceae + Alzataeaceae + Penaeaceae + Oliniaceae + Rhynchocalycaceae: stipules minute; stamens = and opposite petals, endothecium ephemeral; fruit a capsule; exotestal cells periclinally elongated, endotegmen not fibrous.
The stems are square, sometimes ridged, and the nodes are swollen. Laterocytic stomata are known i.a. from Alzatea, Dactylocladus, and Rhynchocalyx (Baranova 1983). Is there a sclerotic mesotesta in all taxa? - there is in Penaeaceae. Van Beusekom-Osinga and van Beusekom (1975) included Alzataeaceae and Rhynchocalycaceae in their expanded Crypteroniaceae, and this may make sense - lump the lot, other things being equal?
For pollen of much of this group, see Muller (1975), for anatomy - very variable - see van Vliet and Baas (1975: detailed comparison within Myrtales), for gross morphology, see van Beusekom-Osinga and van Beusekom (1975).
CRYPTERONIACEAE A.-L. de Candolle, nom. cons. Back to Myrtales
Tree; cork also subepidermal; septate fibers 0, fiber pits bordered; nodes 3:3 [by split laterals], cortical bundles ± developed or 0; sclereids +/0; petiole bundles annular (with medullary trace) or arcuate, wing bundles +; stomata paracytic (anomocytic - Dactylandra); hairs 0 (unicellular); leaves with 2ndary veins pinnate to palmate; plant polygamodioecious, or flowers bisexual, inflorescence with long spicate or racemose branches, flowers 4-5-merous; C 0, 4-5, (A 2x K), connective thickened apically or not, (pollen bisyncolporate), G [2-6], ± inferior, placentation parietal or basal, (transseptal bundles +), 1-3 basal-many ovules/carpel, nucellar tissue disintegrates early, (endothelium + - Axinandra), style usu. slender, stigma capitate; fruit a capsule, flattened or not, K deciduous; seeds many, endotesta crystalliferous, exotesta and endotegmen tanniniferous, other layers ± persistent; n = ?
3[list]/10. South East Asia, Malesia, Sri Lanka (Map: from van Beusekom-Osinga 1977).
Conti et al. (2002, see also Rutschmann et al. 2004 and esp. 2007) suggest that Crypteroniaceae rafted from Gondwana (Africa) to Asia via India, with an origin any time from the Early to Late Cretaceous, a later date being favoured.
Some information is taken from Tobe and Raven (1983b, 1987b) and Renner (2006b: general).
Synonymy: Henslowiaceae Lindley
Alzateaceae + Rhynchocalycaceae + Penaeaceae + Oliniaceae: style stout.
Relationships within this clade are only weakly supported (see Schönenberger & Conti 2003 for phylogeny and floral evolution of the whole group).
ALZATEACEAE S. Graham Back to Myrtales
Plants not Al accumulators, myricetin 0; septate fibers +, fiber pits barely bordered; branches tending to be several together; nodes 3:3, cortical bundles +; sclereids +; petiole bundle annular and with wing bundles; stipules 0; flowers small, 5(-6)-merous, K pointed in bud, C rudimentary even in bud, filaments short, connective wide, with backwards-directed appendage, thecae along apical margin, pollen pseudocolpi 0 [faint], G [2], placentation intrusive parietal and with an incomplete septum, transseptal bundles +, micropyle endostomal, archesporium multicellular, embryo sac bisporic, Allium-type, stigma capitate; capsule flattened, K persistent; seeds several, winged, exotestal cells low, with sinuous walls, everything else collapsed; n = 14.
1[list]/?2. Costa Rica to Peru (Map: see Silverstone-Sopkin & Graham 1986). [Photo - Flowers]
details of internal exine structure are similar to those of some Crypteroniaceae. The seeds have a hair-pin bundle.
See Graham (1985, 2006) for general information.
Rhynchocalycaceae [Penaeaceae + Oliniaceae]: leaves with glandular tips; x = 10.
RHYNCHOCALYCACEAE L. A. S. Johnson & B. G. Briggs Back to Myrtales
Myricetin 0; septate fibers +, fiber pits barely bordered; branches tending to be several together; plants Al accumulators; cork cortical; petiole bundle arcuate; sclereids + [not in stem?]; stipules colleter-like; flowers 6-merous, K pointed, C clawed, lobed, A with 4 loculi opening separately, epidermis only persisting, G [2 (3)], placentation parietal, transseptal bundles +, micropyle endostomal, archesporium multicellular, stigma ± punctate; capsule flattened; seeds several, winged; exotesta tanniniferous, outer wall lignified, all coat cells persist.
1[list]/1: Rhynchocalyx lawsonioides. South Africa, coastal Natal and Transkei.
See Schönenberger (2006) for general information.
Penaeaceae + Oliniaceae: plants not Al accumulators; non-hydrolysable tannins +; hypanthium well developed, pollen grains psilate, foot layer and tectum thick.
PENAEACEAE Guillemin, nom. cons. Back to Myrtales
Small, evergreen, ericoid shrubs; libriform septate fibers 0; mesophyll with (spirally thickened) fibers; leaves often sessile, stipules ± colleter-like; flowers axillary, 4-merous; K petaloid, C 0, (A straight in bud; connective with branched vascular bundle), G 4, opposite petals, 2-4(-many) ascending or ascending and descending ovules/carpel, embryo sac tetrasporic, 16-celled, style also filiform, stigma capitate or lobed; fruit a capsule; seeds with funicular elaiosome; exotestal cells much developed or endotestal cells much elongated, other layer crushed, endotegmen fibrous; chalazal {"basal"] endosperm haustorium +, embryo with large hypocotyl, cotyledons tiny, suspensor 0.
7[list]/23: Stylapterus (8). South Africa, S. and S.W. parts of the Cape. [Photo - Habit]
The vegetative anatomy is undistinguished, but the embryo sac is unique. Nectar is secreted from the base of the hypanthium.
For the embryo suspensor, see Ross and Sumner (2005), and for general information, see Schönenberger et al. (2006).
OLINIACEAE Arnott, nom. cons. Back to Myrtales
Cork subepidermal; stomata variable; stipules cauline-on leaf base; flowers (4-)5-merous; ?epicalyx +, small, K ± spatulate, C concave, thick, hairy, pollen heteropolar, G [(2)4-5], inferior, opposite sepals, transseptal bundles +, 2-3 pendulous apotropous campylotropous ovules/carpel, micropyle bistomal, chalaza strongly vascularized, hypostase +, stigma ± clavate (commissural); fruit drupaceous, K not persisting; seed usually single; testa 3-4 thin-walled cells across, exotegmen fibrous; cotyledons spirally twisted or irregularly folded.
1[list]/5. Africa, St. Helena. [Photo - Fruit] [Photo - Flowers.]
Crushed or broken plant parts smell of almonds (the cyanogenic glucoside prunasin).
The ovules have been reported as being apotropous and ascending (Baillon 1877). The interpretation of the perianth is a matter of some dispute; here I follow the interpretation offered by Schönenberger and Conti (2003), although the exact nature of the outer whorl of very small appendages is still unclear (described as "?epicalyx" above). n = 12, according to Takhtajan (1997).
For general information, see von Balthazar and Schönenberger (2006).
Synonymy: Plectroniaceae Hiern
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