Developmental morphology of ovules and seeds of Nymphaeales

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Anatomy and Morphology

Developmental morphology of ovules and seeds of Nymphaeales¹

Toshihiro Yamada²^,3, Ryoko Imaichi⁴ and Masahiro Kato²

²Department of Biological Sciences, Graduate School of Science, University of Tokyo, 7-3-1 Hongo, Tokyo 113-0033, Japan ⁴Department of Chemical and Biological Sciences, Japan Women's University, 2-8-1 Mejirodai, Tokyo 112-8681, Japan

Received for publication June 22, 2000. Accepted for publication August 31, 2000.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Ovule and seed development in six species of Nymphaeales wasexamined. In the Cabombaceae the two species studied resemblesome extant basal angiosperms by having a hood-shaped outerintegument. A micropyle–hilum complex results when theouter integument and derived testa are lacking between the micropyleand the funiculus, thus the hood-shaped appearance. In the Nymphaeaceaethe outer integument is annular at an early stage and then cup-shapedthough it is semiannular at initiation in Nupar japonicum andNymphaea alba. The micropyle and hilum are separated by an interveningtesta. Developmental data on the formation of the outer integument,from semiannular to hood-shaped vs. from annular to cup-shaped,are useful for inferring the morphology of the outer integumentfrom the relative position of the micropyle to the hilum inseed fossils. The oldest (early Cretaceous) probable nymphaealeanseeds had the micropyle–hilum complex, suggesting thatthe hood-shaped outer integument may be primitive in the Nymphaeales.This needs to be tested by examination of this feature in othergroups of basal angiosperms.

Key Words: developmental morphology • evolution • integument • micropyle–hilum complex • ovules • Nymphaeales • seeds

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Bitegmic and anatropous ovules are common in basal angiospermsand are usually considered to be primitive in flowering plantsas a whole (Stebbins, 1974 ; Bouman, 1984 ; Cronquist, 1988 ; Takhtajan,1991 ; Johri, Ambegaokar, and Srivastava, 1992). Only a few authorsregard anatropy as derivative and orthotropy as ancestral (Bocquetand Bersier, 1960 ). It has been suggested that the outer integumentsare cup shaped and asymmetrical (Bouman, 1984 ). However, recentdevelopmental and morphological studies have shown that in manybasal angiosperms the outer integument is sharply asymmetricand hood shaped, that is, it is lacking on the concave (funicular)side of the ovule (Matsui, Imaichi, and Kato, 1993 ; Umeda, Imaichi,and Kato, 1994 ; Imaichi, Kato, and Okada, 1995 ; Endress andIgersheim, 1997, 1999 ; Igersheim and Endress, 1997, 1998 ; seealso Johri, Ambegaokar, and Srivastava, 1992).

The origin of bitegmy has been variously interpreted in contrastto the agreement on the origin of the first (inner) integumentby fusion of telomes (Herr, 1995 ). Crane (1985, 1986) and Doyleand Donoghue (1986, 1987) postulated that the outer integumentis derived from the leafy lamina of a Caytonia-like ancestor,while the carpel enclosing ovules is derived by lateral expansionof its leaf axis. It is also hypothesized that the bitegmicovules have been derived from unitegmic and orthotropous ovulesof glossopterid-like gymnosperms by the enclosure of the unitegmicovules by the ovuliferous leaf to form the outer integument(Stebbins, 1974 ; Dahlgren, 1983 ; Kato, 1990 ; Stewart and Rothwell,1993; Umeda, Imaichi, and Kato, 1994 ; Imaichi, Kato, and Okada,1995 ; Doyle, 1996 ). Kato (1991) also speculates that the anatropyis an extreme modification of the hyponastic curvature of leaves(ovuliferous leaf). However, the origin of the outer integumentand the origin of anatropy are still uncertain, partly becausethe ovules of primitive or basal angiosperms are not well understoodeven on a morphological level.

Recent molecular analyses (Mathews and Donoghue, 1999 ; Qiu etal., 1999 ; Soltis, Soltis, and Chase, 1999 ) suggest Amborellaceaeare the sister group to all other angiosperms and the Nymphaealesare the next group to diverge in angiosperm phylogeny.

Nymphaeales are a monophyletic group composed of two families,Cabombaceae and Nymphaeaceae. Cabombaceae are composed of twogenera, Brasenia and Cabomba, while Nymphaeaceae are composedof three subfamilies—Nupharoideae, including a singlegenus, Nuphar; Barclayoideae, including a single genus, Barclaya;and Nymphaeoideae, including four genera, Euryale, Nymphaea,Ondinea, and Victoria (Les and Schneider, 1995 ; Takhtajan, 1997 ;Les et al., 1999 ).

Ovules of Nymphaeales are uniformly bitegmic and crassinucellatebut vary in their orientation from anatropy to orthotropy (Khanna,1965, 1967 ; Moseley, 1972; Schneider, 1976, 1978 ; Williamsonand Moseley, 1989 ; Johri, Ambegaokar, and Srivastava, 1992;Igersheim and Endress, 1998 ). Variations within a group mayprovide useful data for understanding the evolution of ovulesin basal angiosperms. Collinson (1980) described the morphologyand anatomy of the seeds of Nymphaeaceae sensu lato (s. l.)with special reference to the relative position of the micropyleto the hilum in the micropylar region, which was called a circularcap by Collinson.

Furthermore, Collinson (1980) compared seeds of living and fossiltaxa of the Nymphaeales. The significance of comparative neo-and paleobotanical studies is increasingly obvious, becauseapproaches combining fossil data with molecular data improvephylogenetic interpretations. Fossil records of delicate ovulesare scarce as compared to seed fossils due to taphonomical bias(Holyoak, 1984 ). Therefore, combined data of seed fossils andextant angiosperm ovules are useful for determining the primitivecharacteristics of ovules.

The purposes of this study were to: (1) illustrate the variationsof the outer integument in six species of Nymphaeales; (2) suggestevolutionary changes of ovule shapes relative to outer integument,and; (3) compare ovules and seeds of the order. In this study,the ovules and seeds of Cabombaceae, Nupharoideae, and Nymphaeoideaeexcept for Ondinea were examined. Those of Barclayoideae (Barclayalongifolia Wall.) and Ondinea were not examined because theyhave been well described by Schneider (1978) and Schneider andFord (1978) , respectively.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Flowers and fruits of the Cabombaceae, Nupharoideae, and Nymphaeoideae(except for Ondinea) were collected in successive developmentalstages and vouchers were prepared for the University of Tokyoherbarium (Table 1).

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Table 1. Plants used in this study

The materials were fixed in a mixture of 5% formalin, 5% aceticacid, and 50% ethyl alcohol (FAA), dehydrated in an ethyl alcoholseries, and embedded in HistoResin Plus (glycol methacrylate,Leica, Heidelberg) or dehydrated in an acetone series and embeddedin Spurr resin (TAAB, Berks, UK). They were cut into 2–3µm thick sections and stained with safranin, toluidineblue, and orange G (Jernsteadt et al., 1992).

For scanning electron microscopic (SEM) observations, freshmaterials were molded using epoxy resin (Replica SEM method:Williams, Vesk, and Mullins, 1987 ) or dehydrated in an ethylalcohol series and t-butyl alcohol and freeze-dried. They werecoated with platinum-palladium. Material was observed in a scanningelectron microscope (JEOL JSM-820S) at 10–20 kV.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Cabombaceae
The ovules are anatropous (Figs. 7, 15), bitegmic, and crassinucellatein both genera (Figs. 4, 12). The inner integument is annularor ring-like even in an early stage (Figs. 2, 3) and consequentlycup-shaped in both genera (Figs. 4–7, 12–15). Thegenera exhibit very similar patterns of ovule development.

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Figs. 1–7. Ovules of Brasenia schreberi at successive stages of development. 1. Median londitudinal section (MLS) of incurved ovular primordium. 2. MLS of young ovule with the inner and outer integuments initiating. 3. SEM micrograph of young ovule at a similar stage to that of Fig. 2 . 4. MLS of immature anatropous ovule. Note that there is no outer integument on the concave side. 5. SEM micrograph of immature ovule at a similar stage to that of Fig. 4 . 6. MLS of mature ovule, showing no outer integument on the concave side. 7. SEM micrograph of mature ovule with the operculum projecting. Scale bars = 100 µm. Figure Abbreviations: a, aril; et, exotesta; f, funiculus; h, hilum; i, inner integument; m, micropyle; m–h, micropyle–hilum complex; o, outer integument; op, operculum; mt, mesotesta.

At an early stage in Brasenia schreberi the ovular primordiacurve inward before the initiation of integuments (Fig. 1).The outer integument initiates on the convex and lateral sidesjust below the inner integument, that is, it is semiannular(Figs. 2, 3). The outer integument ends at the lateral sidesof the funiculus. After the ovule incurvation has finished,the outer integument is hood shaped and has no outgrowth onthe concave side of the funiculus in both genera (Figs. 4, 5, 12, 13).

In mature ovules of both genera the micropyle is surroundedonly by the inner integument, i.e., composed of the endostome(Figs. 7, 15). The inner integument is two cells thick exceptin the micropylar region where the epidermis divides periclinallyand thickens to form an operculum before maturity (Figs. 6, 14).In Cabomba caroliniana the operculum is very thick in contrastto the other part of the inner integument (Fig. 14). The hood-shapedouter integument is three or four cells thick in Brasenia schreberi(Fig. 6) and two cells thick in Cabomba caroliniana (Fig. 14).

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Figs. 12–17. Ovules and seeds of Cabomba caroliniana at different stages of development. 12. MLS of young ovule. Note that there is no outer integument on the concave side. 13. SEM micrograph of young ovule at a similar stage to that of Fig. 12 . 14. MLS of the micropylar region of mature ovule, showing well-developed operculum. 15. SEM micrograph of mature ovule. 16. MLS of the micropylar region of mature seed. Arrowheads indicate boundaries between the circular cap and the proximal exotesta. 17. SEM micrograph of mature seed showing the micropyle–hilum complex in the circular cap. Double-headed arrow indicates the realm of the circular cup. Scale bars = 100 µm

In postfertilized ovules of Brasenia schreberi the inner integumentappears plicated (Figs. 8, 10: which is also the case with matureseeds of Cabomba caroliniana, Fig. 16). The outer epidermalcells of the outer integument enlarge without periclinal divisionsand develop into a unilayered exotesta (Fig. 8). The exotestathickens more than the other layers of the outer integumentand the inner integument, and consequently the micropyle ofimmature seeds is apparently formed by the exostome and endostome(Figs. 8, 9). There is no testa (developed from the outer integument)between the hilum and the endostome, because no additional tissueforms between the two during seed maturation (Figs. 8, 9). Eventuallythe hilum, consisting mostly of vascular bundles in mature seeds,is adjacent to the endostome. We apply the term micropyle–hilumcomplex to this structure (Figs. 10, 11, 16, 17).

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Figs. 8–11. Seeds of Brasenia schreberi at different stages of development. 8. MLS of the micropylar part of immature seed. 9. SEM micrograph of immature seed at a similar stage to that of Fig. 8 . Note that the operculum and hilum are surrounded by the exotesta. 10. MLS of the micropylar part of mature seed. 11. SEM micrograph of mature seed showing the micropyle–hilum complex. Double-headed arrow indicates the realm of the circular cap. Scale bars = 100 µm

In mature seeds of both genera the exotesta is sclerified, sothat the seeds are exotestal (Figs. 10, 16). In Brasenia schreberithe exotestal cells in the circular cap are rectangular in contrastto lobed cells of the surrounding region (Fig. 11). In Cabombacaroliniana the exotestal cells are smaller in the circularcap than in the surrounding region (Figs. 16, 17). In Braseniaschreberi the outer cell walls of the exotesta are very thick( $~$ 150–200 µm) and as thick as, or thicker than, itslumens (Fig. 10). In Cabomba caroliniana the cell walls of theexotesta are much thinner than in Brasenia schreberi ( $~$ 20 µm;Fig. 16).

Nupharoideae (Nuphar japonicum)
The ovules are anatropous (Figs. 26, 27), bitegmic, and crassinucellate(Fig. 20). The inner integument is annular at an early stagewhen the ovules are weakly curved inward (Figs. 18, 19) andeventually cup shaped (Figs. 20–23, 26, 27). The outerintegument initiates on the convex and lateral sides of theovular primordia, and it is semiannular (Figs. 18, 19). Theouter integument ends on the concave side near the lateral sidesof the funiculus. At a little later stage the growth of theouter integument proceeds to the concave side of the funiculusbut in the center on the concave side (Figs. 20, 21). As theovules are further incurved, the development of the outer integumentextends to the center on the concave side of the funiculus (Figs. 22, 23),so that it becomes cup shaped. The submarginal partof the outer integument on the concave side of the funiculusis four cells high (Fig. 24), the median part two cells high(Fig. 22), and the submedian part three cells high (Fig. 25).Thus, the outer integument is developed to the least extentin the center on the concave side of the funiculus.

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Figs. 18–26. Ovules of Nuphar japonicum at successive stages. 18. Nearly median longitudinal section of young ovule with the inner and outer integuments just initiating. 19. SEM micrograph of ovule at a little later stage than that of Fig. 18 . Arrowheads indicate the ends of the semiannular outer integument. 20. Nearly median longitudinal section of young ovule at later stage than that of Fig. 18 . Note that the outer integument does not grow on the concave side. 21. SEM micrograph of ovule at a similar stage to that of Fig. 20 . Arrowhead indicates the place where there is no outgrowth of outer integument. 22. MLS of older ovule that has nearly finished incurvation. Note that the outer integument on the concave side is two cells high. 23. SEM micrograph of ovule at a similar stage to that of Fig. 22 . 24. Sagittal longitudinal section through the marginal part of the same ovule as that of Fig. 22 . Note the four-cell-high outer integument. 25. Submedian longitudinal section of the same ovule shown in Fig. 22 . Note that the outer integument is three cells high. 26. Nearly median longitudinal section of the micropylar region of mature ovule, showing the developed outer integument on the concave side and the operculum. Scale bars = 100 µm

In mature ovules the outer integument is five to eight cellsthick (Fig. 26). The weaker development of the outer integumentin the center on the concave side of the funiculus results ina depression of the outer integument on the concave side (Fig. 27).The micropyle is formed only by the endostome, the tipof the inner integument being exposed beyond the outer integument(Figs. 26, 27). The inner integument is two cells thick exceptin the micropylar region, which develops into an operculum (Fig. 26).

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Figs. 27–35. Ovule and seeds of Nuphar japonicum at successive stages. 27. SEM micrograph of mature ovule. Arrowhead indicates depression on the concave side. 28. MLS of immature seed. Note thin exotesta between the micropyle (operculum) and hilum. 29. SEM micrograph of immature seed at a similar stage to that of Fig. 28 . Note the micropyle (operculum) is separated from the hilum. 30. SEM micrograph of immature seed at a later stage than that of Fig. 29 . Double-headed arrow indicates the realm of circular cap with the micropyle and hilum. 31. MLS of immature seed at a similar stage to that of Fig. 30 . 32. Cross section through the micropylar region of mature seed. Note radial cell files round the operculum, separating the spongy-like hilum from the operculum. 33. SEM micrograph of mature seed. 34. MLS of mature seed. Arrowheads indicate the boundaries between the circular cap and the proximal exotesta. 35. Magnified micropylar region of Fig. 34 , showing the exotesta between the micropyle (operculum) and the hilum. Scale bars = 100 µm

In postfertilized ovules the inner integument is plicated orcrushed except for the operculum, while the outer epidermisof the outer integument develops into an exotesta (Figs. 28, 31).The micropyle is separated from the hilum by the exotesta(Figs. 29, 30). The circular cap becomes distinct in a surfaceview (Fig. 30).

In mature seeds the exotesta is sclerified, so that the seedsare exotestal (Fig. 34). The sclerified exotestal cells surroundthe endostome in a cross section, showing that the testa occursbetween the hilum and the micropyle also in this stage (Fig. 32;see also Fig. 33 for a relative position of the micropyleto the hilum from a surface view). A longitudinal section showsthat there are sclerified exotestal cells adjacent to parenchymatouscells of the hilum (Fig. 35). Thus, the hilum is adjacent tothe micropyle but separated from it by the exotesta. The exotestalcells that compose the circular cap in the periphery of themicropyle are smaller than surrounding cells (Fig. 34).

Nymphaeoideae
The ovules are anatropous or hemianatropous (Figs. 38, 48, 56),bitegmic, and crassinucellate in the species examined (Figs. 36, 46, 56;see Williamson and Moseley [1989 ] for Ondinea purpurea).The inner integument is annular (Figs. 36, 37, 44, 45), thencup shaped and two cells thick except in the micropylar regionwhere it thickens to form an operculum (Figs. 38, 46, 48, 56).

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Figs. 36–43. Ovules and seeds of Nymphaea alba at different stages. 36. MLS of young ovule with the outer integument not yet initiating on the concave side. 37. SEM micrograph of young ovule at a similar stage to that of Fig. 36 . Arrowheads indicate the ends of the semiannular outer integument. 38. MLS of mature ovule with the outer integument on the concave and convex sides. 39. SEM micrograph of mature ovule with the aril removed. 40. MLS of immature seed. 41. SEM micrograph of immature seed at a similar stage to that of Fig. 40 . 42. MLS of mature seed with the aril removed. Note the existence of testa between the micropyle and the hilum. Arrowheads indicate the boundaries between the circular cap and the proximal exotesta. 43. SEM micrograph of mature seed. Double-headed arrow indicates the realm of the circular cap including the micropyle and hilum. Scale bars = 100 µm.

At an early stage, the outer integument is semiannular in Nymphaeaalba and develops in a similar way to that of Nupharoideae (Figs. 36, 37).In Euryale ferox the outer integument is annular whenthe ovules are curved at nearly right angles to the funiculus(Figs. 44, 45). At a little later stage when the outer integumentdevelops to almost the same height as the inner integument,the outer integument becomes cup shaped (Figs. 46, 47). Theovules become bent a little more and eventually are hemianatropous(Figs. 48, 49).

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Figs. 44–51. Ovules and seeds of Euryale ferox at successive stages. 44. MLS of a little incurvating young ovule. Note the existence of the outer integument on the concave side. 45. SEM micrograph of ovule at a similar stage to that of Fig. 44 , showing the annular outer integument. 46. MLS of ovule at a later stage than that of Fig. 44 . Note the well-developed outer integument on the concave side. 47. SEM micrograph of ovule at a similar stage to that of Fig. 46 . 48. MLS of mature hemianatropous ovule. 49. SEM micrograph of mature ovule. 50. MLS of immature seed. Arrowheads indicate the boundaries between the circular cap and the proximal exotesta. 51. SEM micrograph of immature seed at a similar stage to that of Fig. 50 . Double-headed arrow indicates the realm of circular cap. Scale bars = 100 µm.

In mature ovules of all species examined the outer integumentis asymmetrically cup shaped. The micropyle is formed by theendostome and exostome, although the exostome is loose (Figs. 38, 48, 56).Williamson and Moseley (1989)

illustrated thatOndinea purpurea also has a cup-shaped outer integument. InNymphaea alba the outer integument is four or five cells thick(Fig. 38). In Euryale ferox and Victoria cruziana it is verythick ( $~$ 200–300 µm: Figs. 48, 56).

In postfertilized ovules of Nymphaea alba and Euryale feroxthe inner integument is plicated or crushed except for the operculum(Figs. 40, 52), as in the mature seed of Victoria cruziana (Fig. 58).The outer epidermis of the outer integument grows intoan exotesta (Figs. 42, 50, 52). In Nymphaea alba the parenchymatoussubdermal layer of the outer integument does not thicken wellduring the seed maturation (Fig. 40, 42). In Euryale ferox theouter epidermis of the outer integument in the micropylar regionenlarges so strongly that the circular cap becomes distinct(Figs. 50, 51). The parenchymatous cells of the outer integument(mesotesta), except in the micropylar region, divide both periclinallyand anticlinally, so that the testa thickens. By contrast, themicropylar region remains relatively thin (Fig. 52) and is recognizedmore distinctly as a circular cap (Fig. 53).

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Figs. 52–59. Seeds of Euryale ferox and ovules and seeds of Victoria cruziana at different stages. Arrowheads indicate the boundaries between the circular cap and the proximal exotesta. Double-headed arrows indicate the realm of the circular cap. Figs. 52–55. Seeds of Euryale ferox. 52. MLS of immature seed at a later stage than that of Fig. 48 , showing the existence of the exotesta between the micropyle and the hilum. 53. SEM micrograph of immature seed at a similar stage to that of Fig. 52 . 54. MLS of mature seed. Note the more sclerified mesotesta than that of Fig. 52 . 55. SEM micrograph of mature seed with a distinct circular cap. Figs. 56–59 . Ovules and seeds of Victoria cruziana. 56. MLS of mature ovule. 57. SEM micrograph of mature ovule. 58. MLS of mature seed with the micropyle and the hilum separated. 59. SEM micrograph of mature seed. Note that the circular cap is not distinct. Scale bars = 1 mm in Figs. 52–55 ; 500 µm in Figs. 56–59

In mature seeds the hilum and the micropyle are separated byan intervening testa derived from the outer integument in allspecies examined (Figs. 43, 55, 59). It is the same as in Ondineapurpurea (Schneider and Ford, 1978

). In Nymphaea alba the exotestais sclerified and the parenchymatous cells of the testa arecrushed, resulting in the exotestal seed. The exotestal cellsare less sclerified and smaller in the micropylar region thanin the surrounding region, so that the circular cap is recognizable(Fig. 42). In Euryale ferox the exotesta is sclerified and themesotesta is very thick (850–1000 µm) and also sclerified(Fig. 54). So the seeds are exomesotestal, although describedto be exotestal by Collinson (1980)

. In Victoria cruziana theseeds are exotestal with the exotestal cells composed of verysmall lumens and thick cell walls. The layer of parenchymatouscells beneath the exotesta is very thick (150–200 µm),and these cells are crushed except in the circular cap wherethey become sclerified (Fig. 58).

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The ovules of Nymphaeales are classified into two groups withrespect to outer integument morphology: one group (Cabombaceae:Brasenia schreberi [Khanna, 1965 ; Richardson, 1969 ] and Cabombacaroliniana) has the hood-shaped outer integument. The other(Nymphaeaceae: Nuphar japonicum, Nymphaea alba, Euryale ferox,and Victoria cruziana, which is illustrated by Khanna [1967] and Schneider [1976] ) has the cup-shaped outer integument. InBrasenia and Cabomba the hood-shaped outer integument developsfrom the young semiannular integument. The results of our developmentalstudies are in accord with Igersheim and Endress' (1998) descriptionsof mature ovules for these genera except for Nymphaea and Nupharin which Igersheim and Endress stressed intraspecific variationsof ovules. Such variations were not detected in this study.

The outer integument of Nuphar japonicum, which is the sistergroup to all other Nymphaeaceae (Les et al., 1999 ), is developmentallyintermediate between hood-shaped and cup-shaped forms. It issemiannular in a very early stage of development and cup shapedwith a depression on the concave side in the mature ovule. Preliminaryobservations (data not shown) show that the outer integumentis constantly cup shaped at maturity in Nymphaea tetragona,although the species was described by Igersheim and Endress(1998) to have a hood-shaped outer integument in some ovulesand the cup-shaped in the others. Our observations show thatin Nymphaea alba the mature outer integument is cup shaped thoughit is semiannular at a very early stage of development (butlater annular). In addition, many other species of Nymphaeaare illustrated to have a cup-shaped outer integument at maturity,such as N. stellata (Khanna, 1967) and N. gigantea (Batygina,Kravtsova, and Shamorov, 1980 ). This study and previous reportsindicate Nymphaea has a cup-shaped outer integument.

Collinson (1980) pointed out differences among the nymphaealeanseeds with regard to the relative position of the micropyleto hilum, but evidence for the developmental relationship betweenthese seed characters and the relevant characters of ovuleswas not available. In seeds of Cabombaceae in which the micropyle–hilumcomplex develops from ovules with a hood-shaped outer integument,the absence of the outer integument between the funiculus andthe micropyle throughout development results in the lack ofthe testa in that region. In contrast, in members of the Nymphaeoideaein which the outer integument is cup shaped, the hilum is separatedfrom the micropyle by the testa, which developed from the outerintegument intervening between the funiculus and the micropyle.In Nuphar with an intermediate type of outer integument, themicropyle and hilum are separated by a very narrow testa.

A similar manner of development from the ovules with the hood-shapedouter integument to the seeds with the micropyle–hilumcomplex is suggested here for the Annonaceae by comparing theovules (Imaichi, Kato, and Okada, 1995 ) with the seeds (Corner,1949, 1976 ). It is the case with the Hernadiaceae, Lauraceae,and Winteraceae (Corner, 1976 ; Heo and Tobe, 1995 ; Endress andIgersheim, 1997 ; Igersheim and Endress, 1997 ). These four familiesare basal to eudicots (Qiu et al., 1999 ; Soltis, Soltis, andChase, 1999 ).

The above developmental data indicate that the morphology ofthe outer integument is able to be inferred from the seeds.The oldest probable nymphaealean seeds from the Lower Cretaceous(Barremian to Aptian?) of Portugal (Friis, Pedersen, and Crane,1999 ) have the micropyle–hilum complex, suggesting thatovules with the outer integument hood-shaped already existedin early Cretaceous. Therefore it seems possible that the hood-shapedouter integument is primitive in the Nymphaeales, as has alsobeen argued for other basal angiosperms (Matsui, Imaichi, andKato, 1993 ; Umeda, Imaichi, and Kato, 1994 ; Imaichi, Kato, andOkada, 1995 ).

Considering together the fossil data and the phylogenetic relationshipof the Nymphaeales (Les et al., 1999 ), an evolutionary trendis suggested with the anatropous ovules with the hood-shapedouter integument evolving into the anatropous ovules with thecup-shaped outer integument via an intermediate type of ovule,as seen in Nuphar, and further into the orthotropous ovulesof Barclaya with the cup-shaped outer integument (Schneider,1978 ).

Seeds of Nymphaeales are characterized by the circular cap atthe micropylar end (Collinson, 1980 ). This structure is usefulto identify the fossil seeds of the Nymphaeales (Collinson,1980 ; Friis, Pedersen, and Crane, 1999 ). The spatial relationshipsbetween the circular cap and the micropyle and hilum were arguedby Collinson (1980) . The circular cap was defined from its appearance.We noted the circular cap is associated with the histology ofthe exotestal cells and in some species mesotestal cells, andboth kinds of cells are smaller and less sclerified than thosein surrounding seed coat. We also observed that in Euryale feroxthe circular cup does not include the hilum, its area beingsmaller than circumscribed by Collinson (1980) .

There is a difference in micropyle structure among the Nymphaeales.The micropyle is endostomic or composed of the inner integumentin Brasenia, Cabomba (Cabombaceae), Nuphar (Nupharoideae), andBarclaya (Barclayoideae; see Igersheim and Endress, 1998 ), whereasit is both endostomic and exostomic or composed of the innerand outer integuments in Euryale, Nymphaea, Ondinea (Williamsonand Moseley, 1989 ), and Victoria (Nymphaeoideae). A phylogenetictree (Les et al., 1999 ) suggests that the endostomic micropylesare ancestral to the double endo- and exostomic ones in theNymphaeales. Many other basal angiosperms including the basalmostAmborella also have endostomic micropyles (Johri, Ambegaokar,and Srivastava, 1992; Imaichi, Kato, and Okada, 1995 ; Endressand Igersheim, 1997 ; Igersheim and Endress, 1997, 1998 ), suggestingthe primitiveness of endostomy.

In Arabidopsis thaliana, a model plant of molecular genetics,the outer integument initiates first on the convex side of theovules and its development is repressed on the concave side,resulting in an asymmetrically cup-shaped outer integument similarto that of Nuphar and Nymphaea (Gaiser, Robinson-Beers, andGasser, 1995 ; Villanueva et al., 1999 ). This configuration isconsidered to be regulated in the way in which the expressionof INNER NO OUTER (INO) gene is repressed by SUPERMAN (SUP)gene on the concave side of the funiculus (Villanueva et al.,1999 ). Mutants obtained exhibit a variety of ovules of seedplants. For example, the sup mutant has orthotropous ovuleslike those of Barclaya, and the unitegmic orthotropous ovulesof the ino mutant apparently resemble gymnospermous ovules,implying that the INO gene is a critical component in the evolutionof the outer integument (Gasser, Broadhvest, and Hauser, 1998 ).As suggested by some workers (Gasser, Broadhvest, and Hauser,1998 ; Villanueva et al., 1999 ), analysis of patterns of expressionof such genes in primitive angiosperms will help us to understandthe process of ovule evolution. Primitive families or ordersthat have intergeneric variations of the outer integument morphologyand plenty of fossil records, like the Nymphaeales, may be suitablefor the analysis.

FOOTNOTES

¹ The authors thank Ms. Chiharu Karasaki, Kyoto University; Mr.Ryosen Yamaguchi, Honsenji Temple; and Mr. Hiromichi Takahashi,Botanical Gardens, University of Tokyo for their assistancein collecting specimens. This study was partly supported bya Grant-in-Aid for Scientific Research from Japan Society forthe Promotion of Science to M.K.

³ Author for reprint requests (e-mail: ptilo{at}mb.infoweb.ne.jp ).

LITERATURE CITED

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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