REPRODUCTIVE Hiroshi Tobe^ MORPHOLOGY, ANATOMY, AND RELATIONSHIPS OF ON TICODENDR Abstract Ticodendron predominantly dioecious. Both male and female inflorescences bear some cymules is (or partial on primary Male inflorescences) their axes. partial inflorescences are borne verticillately in clusters of three, each 8-10 being one- to three-flowered and subtended by a single bract. Staminate flowers have or more stamens and lack a perianth. Female partial inflorescences are solitary. Each of them always one-flowered, although subtended is it is by three (one primary and two secondary) bracts, and produces some scales in each axil of the secondary bracts. it In pistiUate flowers, concentric bundles are prevalent in the periphery of the pistil wafl; the ovary inferior, bicarpellate, is and four-locular with one ovule in each locule; the placentation axile; the ovules are apical, pendulous, hemitropous, is 20-30 unitegmic, and crassinucellate; the integument is cells thick and vascularized by about 20 longitudinally parallel vascular bimdles; and the mature seeds have a two-cell-layered endosperm and seed coats composed of thick-walled integumentary cell layers and vascular tissues. In reproductive morphology Ticodendron from any other distinct is On family but best placed in Fagales. the basis of evidence from reproductive morphology and from other sources is common it is suggested that Ticodendron appears to have diverged early from a ancestor with Betulaceae or Fagaceae. T & Ticodendron^ comprising only incognita, 1977) as described in Tobe Raven (1984). Sec- 6- which occurs from northern Nicaragua through tions cut at 10 fim thickness were stained with Panama, Costa Rica to central has long been a Heidenhain's hematoxylin, safranin, and fastgreen mystery plant because of uncertain identity (Go- FCF. its & & Gomez Hammel mez-Laurito 1989; Bur- P., The ger, 1991). present paper provides a detailed OBSERVATIONS morphology and anatomy description of of flora! Ticodendron mostly Male and dioecious. fe- Ticodendron few remarks on em- is including a its How- inflorescences both appear be "^^'^ to spikes, upon bryology, in order to shed hght the position on ever, the basis of anatomical observations dis- and of the genus. affinity cussed later, has been found that the "spike" it is composed some of one- three-flowered cymules to Materials and Methods To borne on the primary axis. facilitate discussions examined were Mon- All materials collected at comparing Ticodendron in with other related taxa, FAA; teverde, Costa Rica, and fixed with examined more a comprehensive term, "partial inflores- were mature male {Haber nearly flowers 7072), 111 cence" (instead of "cymule"), be used the li^»/ will in ^ ^ # ^^> young female buds and {Gomez-Laurit* -o fruits s.n. 164-165, following descriptions (see Abbe, 1974: Haber 1986; 6840, 6868, 7286). Voucher in terminology). fQj- MO specimens are deposited and CR. at For anatomical groups study, single flowers, of male and flowers partial inflorescences male and female flowers, and a piece of mature seed were sectioned with a rotary microtome fol- Male partial inflorescences are borne verticil- lowing standard paraffin methods. Before being sec- lately on the inflorescence axis in clusters of three tioned, the materials were softened with a mixture (Fig. Each male partial inflorescence sub- 1). is 10% of 10 parts of glycerol, 3 parts of Aerosol tended by a single primary bract, and composed is & OT, and 90 parts of water (Schmid Turner, of 1-3 staminate flowers basically arranged in a am grateful to Jorge Gomez-Laurito, Barry Hammel, and William A. Haber for collection of fixed materials, * I Grayum Gomez to Michael H. and Luis Diego for valuable information on Ticodendron and related taxa in earlier stages of the work, and Peter H. Raven support various ways. to for in ^ Department of Biology, College of Liberal Arts and Sciences, Kyoto University, Kyoto 606, Japan. 135-142. Ann. Missouri Box. Card. 78: 1991. 136 Annals of the Garden Missouri Botanical 6D-H). dichasium. Individual partial inflorescences (as well of flower (Figs. 5, This peripheral vascular as individual staminate flowers in the case of three- system supplies the perianth (and abortive stamens, Each flowered partial inflorescences) are not readily dis- if present) and the styles (Fig. 6F-I). style tinguished from each other, but their distinctness has three (occasionally four) vascular bundles (Fig. revealed by vascular bundles. Those supplying 61). is each partial inflorescence or each staminate flower The central vascular system is composed of some depart in separate groups from the vascular cyl- 20 small collateral bundles, which ascend as pla- inder of the inflorescence axis. Staminate flowers cental bundles to supply the ovules (Fig. 6E, F). 8-10 have or more stamens and lack perianth and Ovule placentation axile. is have an or rarely they abortive (see pistil, pistil OVULES arrow. Fig. 1). The stamens are tetrasporangiate, and the an- Although were flowers collected simul- pistillate Anther comprise thers dehisce longitudinally. walls mature taneously with nearly staminate ones, the a fibrous endothecium and a persistent epidermis were megaspore dyad oldest ovules in the stage. still when maturity. Pollen two-celled shed. at is Probably more than several weeks pass between and The pollination fertilization. oldest ovules avail- FEMALE PARTIAL INFLORESCENCES AND FLOWERS able indicate that the ovule apical, pendulous, is and hemitropous with the micropyle upward, and Female and partial inflorescences are solitary, somewhat grows The that twists as (Fig. 7). it it each always one-flowered, although sub- is it is By ovule megaspore dyad crassinucellate. the is tended by one primary and two opposite secondary 4-5 about above dyad stage, parietal the cells lie may These bracts. three bracts fuse basally (Fig. (Fig. 8). Obturators are lacking. At each secondary some 6B). axil of the bracts, The ovule unitegmic (Fig. with the integ- is 7), 10 small appendages or scales are produced, each 20-30 ument about thick and with cells tips its receiving a vascular bundle These distinct (Fig. 2). forming a long narrow micropyle. The integument and scales are horizontally scattered in the axil are some 20 vascularized by longitudinally parallel is somewhat attached at different levels. vascular bundles which are derived from (Fig. 9), composed Pistillate flowers are only of a single a raphe bundle via post-chalazal branching. The its inferior ovary with a small, inconspicuous perianth integument each longitudinally ribbed, con- is rib on ovary The the top of the (Fig. flowers rarely 3). taining a single vascular bundle (Figs. 9, 10). Outer have abortive stamens on the inner side of the epidermal of the integument are cells radially elon- perianth; the abortive stamens receive a distinct gate and contain cytoplasm rich (Fig, 10). The vascular bundle as do ordinary ones. ovary is two bicarpellate with (rarely three) elongate sep- MATURE SEEDS arate styles and four-locular, each locule containing Only one of the four ovules the ovary develops in one ovule Styles are stigmatic throughout (Fig. 4). into a mature seed, thus each mature one- A fruit is with elongate and papillate epidermal nar- cells. seeded. The embryo of a mature seed and oily row adaxial sulcus present on styles throughout. is is massive with two straight cotyledons. The mature Judging from the position of the two styles in re- seed has a two-cell-layered endosperm (Fig. 11). lation to the inflorescence axis (see Fig. 6C, the I), As the seed matures, only the outer tissue of two carpels are positioned tangentially, not radially. the integument, including a vascular tissue and a The anatomy vascular of a female flower floral surrounding integumentary while tissue, persist, presented Figure which diagrammatically in 6, is the inner tissue completely degenerates. Thus, the shows the vascular course in a longitudinal section 8-15 mature seed coat only about thick cells is 6A) and (Fig. in selected serial transverse sections Those xylem (Fig. 11). cells, except for cells of the 6B-I). At and above the which the (Fig. level at vascular tissue, are thick-walled and flattened with scales are supplied with vascular bundles (Fig. 6B, The tanninlike contents. outer epidermal of cells C), the vascular cylinder, which composed of is the integument, which were elongate and radially many discrete collateral bundles arranged in a ring, contained rich cytoplasm ovular stages, do not in irregularly diverges into the peripheral vascular show any mature specialization in the seed coat. system and the central vascular system (Fig. 6D, E). Discussion The peripheral vascular system about 5 or is 1 4-10 The 16 aggregates of small bundles. Included are above-described inflorescence and floral a few inverted ones throughout the whole length structures of Ticodendron within the range of fit Volume Number Tobe 137 78, 1 Ticodendron Morphology, Anatomy, 1991 and Relationships ® f ® — Anatomy Figures 1-5. of partial inflorescences and flowers of Ticodendron. Transverse section (TS) of a 1. Arrow primary male inflorescence axis showing three male, one-flowered partial inflorescences. indicates abortive — 2. TS at the base of female partial inflorescence. Note that some scales are borne at the axil of the secondary pistil. — — TS bract. 3. Longitudinal section of female partial inflorescence, which is always one-flowered. 4. of female flower — TS at level of pistil. 5. of concentric bundles prevalent in the periphery of the female flower. Abbreviations: br2, mm, secondary bract; single male flower; ov, ovule; pe, perianth; scale; sy, style. Scale bars equal 500 ^m, f. s, 1 mm, mm, and 100 ^m, respectively. 1 1 138 Annals of the Garden Missouri Botanical Figure Diagrams anatomy 6. illustrating the vascular of female partial inflorescence and flower Ticodendron. in Median B-L A. longitudinal section through the line presented in C. Transverse sections at levels marked b-i in A. Abbreviations: ax, suppressed primary inflorescence axis; brl and br2, primary and secondary bracts; ov, ovule; pe, perianth; s, scale; sy, style. Number Tobe 139 Volume 78, 1 Ticodendron Morphology, Anatomy, 1991 and Relationships ^ \ V *C* :^'>x. iu' \\ - :t : L * ^yj i: /' 'L-iV -0 » m^^ Z:^ v^.^' •» >?v^^ ^ ^ <^ 5?w; \ fv*f -^ X \S :vvF ^ I -<K .^ ?>.c^ , ^ >*>- r. r *i ^Vf em V^ vf -A . I .f-v^ 'fc, i<^? *( • /s^' V*^' • J. 1^1 1 .^ ^-^>l ^v^Tr;*»--•* ^.^^4 f y _. >-F".-- ? '' \^\ /. '^ > t. ' 5'ii; >"**:, .^%'Sv >.'i> < iK^ V - A-i -'•A • * Sr^^^y'. ^•y ,k • , 'V ' <*' -^ ^> V. rv' / ^ ^: -*•. 'A i5r /- ^. I • TV F» ^-f^ii'ii. !»S A: ;.'.'t^^-v^\ ra^S ^^^ :tv/ .V V « >.^/^* -^.'*^ '^ t. I ft'^ftj; ' /. - t? ^;.> t v^^ r fS' lifj^ •i' -^ — LS Figures 7-11. Anatomy of ovules and seeds in Ticodendron.— 7. Longitudinal section (LS) of ovule. 8. — of ovule showing a dyad of megaspores in a nucellus. 9. Transverse section (TS) of ovule showing that the integument ribbed and contains a vascular bundle in each rib.— 10. Enlargement of part of Figure 9, showing a structure of is em, embryo; endosperm; integument.— TS mature seed showing seed coat structure. Abbreviations: en, thick 11. of vascular bundle. Scale bars integument; mc, megaspore; mi, of micropyle; nu, nucellus; pr, parietal cell; vs, tip in, 100 ^m, 20 200 200 and 100 respectively. equal fim, fim, fim, fim, 140 Annals of the Garden Missouri Botanical Table 1. Comparisons of Ticodendron with related families in selected reproductive characters. Fagaceae Betulaceae Juglandaceae Myricaceae Characters Ticodendron (Fagales) (Fagales) (Juglandales) (Myricales) Cupule Absent Present Absent Absent Absent Ovary position Inferior Inferior Inferior Inferior Superior Concentric bundles in Present Present Present wall pistil Number of carpels per 2 (2)3(-12) 2(3) 2(-4) 2 ovary Number of locules in 4 (2)3(-12) 2(3) 1 1 ovary Number of ovules 4 (4)6(-many) 2-4(-6) in 1 1 ovary Ovule position Axile, pendu- Axile, pendu- Axile, pendulous Axile, erect Basal, erect lous lous Ovule curvature Hemitropous Anatropous Anatropous Orthotropous Orthotropous dumber of integu- 1 (1)2 1(2) 1 1 ments 20-30 4-5 6-10 If uniteginic, thickness 4 3-7 cells cells cells thick cells cells thick of integument thick thick thick Vascular bundles in Present Present Present Present Present integument Ribbed integument Present Absent ? Absent 9 * • Mature seed coat Cells thick- Cells thick- ? Cells thick- * walled walled walled 2-4 Thickness of endo- 2 cells thick Absent or 1 cells thick 1 cell thick 1 cell thick sperm thick cell References Vaughan are: Netolitzky (1926), (1970), and Corner (1976) for families (seed coat anatomy); ' all Langdon (1939, 1947) and Poole (1952) for Fagaceae; Woipert (1910) for Betulaceae; Karsten (1902), Langdon & (1939), Meeuse Houthuesen (1964), Verhoog (1968), and Manning (1978) Juglandaceae; and Kershaw for (1900), Kuhn Yen (1927), and (1950) Myricaceae. for shown variation for these features in Fagales, Ju- Ticodendron agrees with Myricales in having a glandales, and Myricales (see Abbe, 1974, for re- longitudinally ribbed integument. view) and suggest closer affinity of Ticodendron Thus, the reproductive morphology and anato- my with these orders than with other Hamamelididae of Ticodendron indicates a close relationship members Ham- or of different subclasses. In Table 1, to Fagales, Juglandales, and Myricales in the reproductive features of Ticodendron, Fagales, amelididae ''Hamamelidae" sensu Cronquist, (or Among Juglandales, and Myricales are presented. 1981). Fagales, Juglandales, and Myri- In general, Ticodendron agrees well with Fa- Ticodendron seems be more home cales, to at and They an gales, Juglandales, Myricales. share within Fagales, which have diverse reproductive inferior ovary (except Myricales with a superior morphology, rather than in Juglandales or Myri- ovary), concentric bundles in floral vascular system cales, both of which are characterized by certain (though uncertain in Betulaceae and Myricales), unique apomorphies. Juglandales and Myricales both bicarpellate ovaries (though frequently tricarpellate characteristically have a unilocular bicarpellate in Fagales and Juglandales), unitegmic ovules (com- ovary with a single orthotropous ovule, features all monly unknown bitegmic in Fagales), vascular bundles in the that are Ticodendron and Fagales. in integument (in the outer integument only in Fagales Closer of Ticodendron with Fagales are affinities with bitegmic ovules), a similar mature seed coat further suggested by evidence from wood anatomy, composed of numerous thick-walled cell layers and pollen morphology, and other data, as specified in vascular tissues, and a thin endosperm in mature this volume. Among may Ticodendron seed. further coincides with Fagales Betulaceae, Coryleae be the closest in having two (or more) ovules per carpel and axile allies of Ticodendron, since Coryleae, like Ticoden- placentation, rather than a uniovulate ovary with dron, lack a perianth in the male flowers but possess basal placentation as in Juglandales and Myricales. in the female flowers. Evidence from wood anat- it Volume Number Tobe 78, 141 1 1991 Ticodendron Morphology, Anatomy, and Relationships omy also suggests Coryleae for the closest affinity tinct from Ticodendron in having a basal, erect of Ticodendron (Carlquist, 1991). Yet, in Ticoden- ovule and lacking a perianth in the pistillate flower. dron the ovule hemitropous with a thicker in- Hjelmqvist (1948) suggests on the basis of com- is tegument (20-30 cells thick), whereas in Coryleae parison in the "cupule" structure that Balanops anatropous and probably with a thinner integ- probably stands nearest Juglandales and Myricales. it is ument (e.g., four cells thick in Betula; Wolpert, Carlquist (1980) notes that the wood of Balanops 1910); Ticodendron has scales at the axils of the comparable with that of Hamamelidaceae. Za- is & secondary bracts, which are unknown in Coryleae vada Dilcher (1986) indicate on the basis of Ticodendron (and in other Betulaceae); lacks similarity cluster analysis using pollen characters all the tertiary bracts that are positioned decussate to ^fagu the secondary bracts and form by their fusion a the present level of our knowledge uncertain it is characteristic involucre or hull in Coryleae (Abbe, even whether Balanops related with Fagales in is 1935, 1938, 1974); in Ticodendron stamens are general. Balanops poorly known with respect is to many not deeply divided as in Coryleae (and in other reproductive structures, and an intensive and all Betulaceae); and in Ticodendron female flowers overall investigation on the genus seems to be de- are solitary, while in Coryleae two lateral flowers sired prior to critical comparisons with putative of the dichasium usually develop (Abbe, 1935, and Ticodendron. allies 1938, 1974). These differences suggest that Tico- In considering evolutionary relationships with dendron unlikely to have direct relationships with Betulaceae and Fagaceae, the presence of the scales is Coryleae or other Betulaceae. in the secondary bract axils of female partial in- may Nothofagus the best candidate in comparing florescences of Ticodendron have a key is role. Fagaceae with Ticodendron, In fact, Nothofagus Although l-3-(or 7- or more-)flowered partial male superficially similar to Ticodendron in having and female inflorescences are prevalent in Betu- is exclusively unitegmic ovules, occasionally solitary laceae and Fagaceae (see Abbe, 1935, 1938, 1947), staminate flowers, partial inflorescences composed they are generally considered to have evolved from of 1-3 flowers, and occasionally bicar- a more complex cymose inflorescence by reduction pistillate pellate pistillate flowers (for data on Nothofagus of branches of higher orders (see Abbe, 1938, see Langdon, 1947; Poole, 1952; Abbe, 1974). 1974). Indeed, reduced outer branches are sterile & Ticodendron, however, clearly distinguished from elaborated as cupular valves in Fagaceae (Fey is Nothofagus (and general from other Faga- Endress, 1983); furthermore, of presum- in vestigials all ceae) in having hemitropous ovules with thicker ably reduced outer sterile branches appear as "su- pernumerary integument (only four or five cells thick in Noth- scales'* in male partial inflorescences ofagus; Poole, 1952) and lacking characteristic of Chrysolepis chrysophylla (Fagaceae) in cupular valves, lacking a perianth in male flowers, (Hjelmqvist, 1948) or as blinding vascular bundles and lacking the tertiary bracts in female partial in female partial inflorescences of Betula tenia Those seem inflorescences. dissimilarities to indi- (Betulaceae) (Abbe, 1935). Although uncertain it is cate that Ticodendron clearly stands out from Fa- whether the scales of Ticodendron are directly gaceae as well. relevant to the scales of the cupule of Nothofagus Balanopaceae (fia/arto/?5 only), which have been or not, their anatomical features are very similar may placed by Cronquist (1981, 1988) in Fagales, to each other in their cross sectional shape and in also require comparisons with Ticodendron. Bal- receiving a distinct vascular supply (see Langdon, anops shares with Ticodendron a female partial 1947, for cupule-scale anatomy in Nothofagus), The inflorescence comprising a single pistillate flower scales of the female partial inflorescence of may subtended by a "cupule,'' an ovary with locules, Ticodendron also represent residuals of re- an anatropous, unitegmic ovule, and drupaceous duced outer branches of cymose sterile inflores- However, Balanops com- the ''cupule" of cences. fruits. is posed of numerous, spirally arranged, deltoid bracts. Regarding nonreproductive characters, Carl- lacking an elevated axial structure characteristic quist (1991) showed that Ticodendron has primi- of Fagaceae (Hjelmqvist, 1948). Its homology with tive wood compared with other Fagales; Feuer the cupule of Fagaceae doubted (Cronquist, (1991) observed that pollen of Ticodendron had is Even 1981). the bracts of the ''cupule'' of Bal- plesiomorphic (tectate-granular) wall structure if anops are comparable with the scales of Ticoden- shared with Betulaceae, Nothofagus, Casuarinales, & t/ro«, the former encloses the whole of the pistillate and Urticales (see Zavada Dilcher, 1986); and & Hickey flower, while the latter restricted only at the axils Taylor (1991) suggested, on the basis is Balanops secondary of the bracts. clearly dis- of leaf architectural analysis, that Ticodendron is 142 Annals of the Garden Missouri Botanical took a more basal position than other Fagales (and HjELMQVIST, H. 1948. Studies on the floral morphology and phylogeny of the Amentiferae. Bot. Not., Suppl. may Brunelliaceae). Ticodendron be considered an 1-171. 2: common early derivative either from a ancestor of ^1902. Karsten, g! Ueber Entwicklung der die weibli- Fagaceae before the reduced outer branches sterile chen Bliithen bei einiger Juglandaceen. Flora 90: cymose were 316-333. of the inflorescence elaborated as the Kershaw, M. The and development cupular valves, as in modern Fagaceae, or from a E. 1900. structure Myrica Ann. (London) 23: of the ovule o{ gale. Bot. common ancestor of Betulaceae before the reduced 353-362. outer sterile branches were lost completely, as in KuHN, G. 1927. Beitrage zur Kenntnis der intrasemina- modern For more Betulaceae. critical discussion of len Leitbiindel bei den Angiospermen. Bot. Jahrb. 325-379. 61: embryological Ticoden- relationships, studies in M Langdon 1939. Ontogenetic and anatomical L. dron. Nothofagus. and Betulaceae, which are still and Fagaceae and studies of the flower fruit of the meager compared with those in other genera or 301- Juglandaceae. Bot. Gaz. (Crawfordsville) 101: are needed. families, 327. 1947. The comparative morphology of the . Fagaceae. The genus Nothofagus. Bot. Gaz. (Craw- Literature Cited 1. 350-371. 108: fordsville) Abbe, E. C. 1935. Studies in the phylogeny of the W. Manning, E. 1978. The classification within the and anatomy and Betulaceae. Floral inflorescence 1058- I. Juglandaceae. Ann. Missouri Bot. Gard. 65: 1-67. morphology. Bot. Gaz. (Crawfordsville) 97: 1087. 1938. Studies in the phylogeny of the Betu- & . Meeuse, a. D. Houthuesen. 1964. The gy- J. J. laceae. 11. Extremes in the range of variation of floral noecium of Engelhardia spicata (Juglandaceae) and and inflorescence morphology. Bot. Gaz. (Crawfords- phylogenetic significance. Acta Bot. Neerl. 13: its 431-469. 99: ville) 352-366. 1974. Flowers and inflorescences of the . 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Burger. 1991. Neither oak nor 2-20. Peking Nat. Hist. Bull. 19: alder, but nearly: the history of Ticodendraceae. Ann. & Zavada, M. S. D. L. Dilcher. 1986. Comparative 89-95. Missouri Bot. Gard. 78: morphology and phylogeny pollen relationship to its & W. Hickey, L. D. Taylor. 1991. The leaf ar- J. in the Hamamelidae. Ann. Missouri Bot. Gard. 73: Ticodendron and chitecture of the application of 348-381. foliar characters in discerning relationships. Ann. its 105-130. Missouri Bot. Gard. 78: