American Journal of Botany 100(9): 1757–1778. 2013.
ANDROECIAL EVOLUTION IN CARYOPHYLLALES IN LIGHT OF A
PARAPHYLETIC MOLLUGINACEAE1
SAMUEL BROCKINGTON2, PATRICIA DOS SANTOS3, BEVERLEY GLOVER2,
AND LOUIS RONSE DE CRAENE3,4
2Department
3Royal
of Plant Sciences, University of Cambridge, Cambridge, CB2 3EA, UK; and
Botanic Gardens Edinburgh, 20A Inverleith Row, Edinburgh, EH3 5LR, Scotland, UK
• Premise of the study: Caryophyllales are highly diverse in the structure of the perianth and androecium and show a mode of
floral development unique in eudicots, reflecting the continuous interplay of gynoecium and perianth and their influence on
position, number, and identity of the androecial whorls. The floral development of five species from four genera of a paraphyletic Molluginaceae (Limeum, Hypertelis, Glinus, Corbichonia), representing three distinct evolutionary lineages, was investigated to interpret the evolution of the androecium across Caryophyllales.
• Methods: Floral buds were dissected, critical-point dried and imaged with SEM. The genera studied are good representatives
of the diversity of development of stamens and staminodial petaloids in Caryophyllales.
• Key results: Sepals show evidence of petaloid differentiation via marginal hyaline expansion. Corbichonia, Glinus, and Limeum
also show perianth differentiation via sterilization of outer stamen tiers. In all four genera, stamens initiate with the carpels and
develop centrifugally, but subsequently variation is significant. With the exception of Limeum, the upper whorl is complete and
alternisepalous, while a second antesepalous whorl arises more or less sequentially, starting opposite the inner sepals. Loss or
sterilization of antesepalous stamens occurs in Glinus and Limeum and is caused by altered carpel merism and inhibition by
sepal pressures.
• Conclusions: Outer stamens of Hypertelis correspond with petaloids of Caryophyllaceae and suggest that staminodial petaloids
and outer alternisepalous stamens are interchangeable in the Caryophyllales. We emphasize a switch in the position of first
formed stamens from antesepalous to alternisepalous following the divergence of Limeum; thus stamen position is an important
synapomorphy for the globular inclusion clade.
Key words: carpels; Caryophyllales; centrifugal stamens; floral development; globular inclusion clade; raphide clade; sepals;
staminodial petaloids; stamen loss.
Spatial patterning in the angiosperm flower commonly proceeds in a proximal to distal direction, termed centripetal. However, a significant number of angiosperms deviate from this
strict centripetal progression. Some floral organs, particularly
within the gynoecium and androecium, develop in a distal-toproximal sequence, in a pattern referred to as centrifugal (Payer,
1857; Sattler, 1972; Rudall, 2010, 2011). Taxa within the core
eudicot clade Caryophyllales commonly exhibit centrifugal initiation of the androecium, which can in turn precipitate a number of further evolutionary consequences (Brockington et al.,
2009; Ronse De Craene, 2010). One such consequence is the
occurrence of pseudodiplostemony, in which the common eudicot pattern of two stamen whorls (diplostemony) is achieved,
but via a completely different developmental sequence (hence
the term “pseudo”). This can be clearly seen in the Caryophyllaceae, where initiation of antesepalous stamens is inversed and
petals arise basipetally from antepetalous stamens, generally
by division of common primordia (see Ronse De Craene and
Smets, 1993; Hofmann, 1994; Ronse De Craene et al., 1998;
1 Manuscript
received 27 February 2013; revision accepted 13 May 2013.
The authors thank Frieda Christie for assistance with the SEM, Prof.
Simon Owens (RBG Kew) for permission to use the pickled collection, and
Emma Tredwell for help with sampling the specimens. Permission by Bart
Wursten, José Quiles and Chien-Jung Lin to use their photographic material is
acknowledged. S.B. and L.R.D.C. contributed equally to this work.
4 Author for correspondence (e-mail: l.ronsedecraene@rbge.ac.uk)
doi:10.3732/ajb.1300083
Smissen and Garnock-Jones, 2002; Harris et al., 2012; Luo
et al., 2012). A second consequence of the centrifugal initiation
occurs through interaction with the perianth. Outer members of
the centrifugal androecium may become flattened and showy
and form the inner petaloid members of a differentiated perianth (e.g., Aizoaceae and Corbichonia). Furthermore, mutual
repression between the centripetally advancing perianth and
centrifugally developing androecium can cause organ loss in
outer tiers of stamens. Thus, a centrifugally initiating androecium can contribute to both variation in perianth differentiation
and to changes in merism within the androecium and perianth.
In addition to a centrifugally developing androecium, there is a
strong connection between the androecium and gynoecium in
the development of a common platform not much different
from an androgynophore. Changes in carpel merism seem to
directly influence the upper stamens, as loss of carpels seems to
be correlated with lower stamen numbers, at least in Caryophyllaceae (Ronse De Craene et al., 1998).
Given the evolutionary singularity of the androecium in the
Caryophyllales, it is important to describe the occurrence and
consequences of centrifugal androecium initiation across the
order. Recent changes to our concept of the caryophyllid phylogeny also forces reconsideration of the evolution of many
traits including androecial morphology. Here, the identification
of Molluginaceae as paraphyletic is particularly important because there is considerable androecial variation in Molluginaceae sensu lato, and the now exiled lineages of Molluginaceae
are widely scattered across the core Caryophyllales (Fig. 1). For
example, Corrigiola and Telephium, previously members of the
American Journal of Botany 100(9): 1757–1778, 2013; http://www.amjbot.org/ © 2013 Botanical Society of America
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Fig. 1. Updated phylogeny of Caryophyllales, modified from Brockington et al. (2011). Genera whose floral development is described in this study
are denoted in red. Major phylogenetic transition in androecium prior to the globular inclusion clade is annotated and marked with a red bar.
Molluginaceae have now been recognized as true members
of Caryophyllaceae (Fior et al., 2006; Harbaugh et al., 2010).
Cuénoud et al. (2002) found support for the removal of three
other genera from Molluginaceae, Corbichonia as sister (with
Lophiocarpus) to Phytolaccaceae, Nyctaginaceae, and Aizoaceae
within the raphide clade, and Limeum as sister to the globular
inclusion clade (a placement also recovered in Brockington et al.,
2009). Schäfferhoff et al. (2009) found evidence for the exclusion
of Hypertelis bowkeriana from Molluginaceae and its placement
within the raphide clade, as sister to Aizoaceae. Brockington
et al. (2011) and Christin et al. (2011) also placed Hypertelis
salsoloides within the raphide clade. However, Christin et al.
(2011) also found Hypertelis to be a potentially paraphyletic
genus with Hypertelis spergulacea still nested within Mollugo.
Brockington et al. (2011) and Christin et al. (2011) both found
Macarthuria to be placed as one of the early-diverging lineages
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toward the base of the Caryophyllales, well outside the Molluginaceae. In summary therefore, Molluginaceae sensu stricto
comprises the nine genera Adenogramma, Polpoda, Psammotropha, Coelanthum, Pharnaceum, Suessenguthiella, Glinus, Glischrothamnus, and Mollugo (Brockington et al., 2011; Christin
et al., 2011). This narrower circumscription has in turn led to
the recognition of the following lineages as distinct to the Molluginaceae: Macarthuria, Limeum, Hypertelis, Lophiocarpaceae
(Corbichonia), Corrigiola, and Telephium (see Fig. 1).
The reconsideration of a paraphyletic Molluginaceae provides an ideal opportunity to reevaluate the floral morphology of a number of former members of the family. The floral
development of Hypertelis, Corbichonia, Limeum, and Glinus
is the focus of this study. The choice of these four genera is
justified by the strategic position they occupy on the phylogenetic tree of Caryophyllales; Limeum is a member of the earlydiverging lineages; the other genera are part of the “globular”
inclusion” clade, with Glinus at the base of the “Portulaceous
alliance”, and Hypertelis and Corbichonia members of the
“raphide” clade (Fig. 1). Given this broad distribution, observations on these taxa have bearing on floral evolution across the
entire order.
Hypertelis is a small genus with 9–11 species distributed in
southern Africa, with one species extending to Madagascar and
tropical Africa and another endemic to St. Helena (Adamson,
1958a; Endress and Bittrich, 1993). The placement of Hypertelis
bowkeriana and Hypertelis salsoloides within the raphide clade
is still uncertain. Schäfferhoff et al. (2009) placed Hypertelis
bowkeriana in the raphide clade as part of a polytomy with Limeum,
Aizoaceae, Gisekia, and a Phytolaccaceae/Nyctaginaceae
clade. Brockington et al. (2011) and Christin et al. (2011)
placed Hypertelis salsaloides as sister to the remainder of the
raphide clade following the divergence of Corbichonia. Corbichonia has two species, one endemic to southwestern Africa
and the other widespread in Africa and southwestern Asia (Endress
and Bittrich, 1993). Corbichonia is placed with Lophiocarpus
in a small family Lophiocarpaceae (Cuénoud et al., 2002), and
together they are placed at the base of the raphide clade by repeated molecular analyses (Schäfferhoff et al., 2009; Christin
et al., 2011; Brockington et al., 2011). Limeum contains about
20 species, with a center of diversity in southern Africa, and is
currently placed as sister to the globular inclusion clade with relatively weak support (e.g., Cuénoud et al., 2002; Brockington
et al., 2009, Schäfferhoff et al., 2009; Christin et al., 2011).
Glinus is a variable genus containing about six species. Christin
et al. (2011) found that Glinus is monophyletic and represents a
derived clade sister to Glischrothamnus and a number of species of Mollugo.
In this study we describe petals as “petaloids” as an indication of putative function, not as homology, which is variable in
Caryophyllales. While a staminodial nature of the petals in e.g.,
Caryophyllaceae and Aizoaceae is undeniable, this is in contrast
with petals derived from a calyx as is common in the Portulacineae
(Ronse De Craene and Brockington, 2013; Ronse De Craene,
2013). The former could be described as “staminodial petaloids”, while the latter as “calycinal petaloids”. The four genera
studied here (Hypertelis, Corbichonia, Glinus, and Limeum)
are diverse in their flower morphology, especially the number
and arrangement of stamens and petaloids, and all are thought
to exhibit centrifugal androecium formation (Hofmann, 1994).
Although Hypertelis has been subject to limited morphological
studies (e.g., Friedrich, 1956; Hofmann, 1973, 1994), no detailed
floral ontogenetic analysis has been published. Batenburg et al.
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(1984) described the morphology of the mature inflorescence of
Hypertelis salsoloides. A short description of floral development in Corbichonia rubriviolacea is given by Hofmann (1994)
and the floral development of Corbichonia decumbens has
been partly investigated by Ronse De Craene (2007) to clarify
the development of petaloids as part of the androecium. However, a more detailed investigation is needed. Hofmann (1994)
shows some basic images of floral development in Glinus lotoides with the initiation of many stamens and petaloids, comparable to Corbichonia, but no detailed ontogenetic study has
been performed. Moreover, Glinus is a variable genus, especially
G. lotoides, with great variation in the number and arrangement
of stamens, ranging from five alternisepalous stamens to several
whorls with or without outer staminodes (Müller, 1908; Hofmann,
1973, 1994). Meanwhile, the floral development of Limeum
is completely unknown, aside from basic observations on
mature flowers (Hofmann, 1973). This is especially unfortunate
given the pivotal position of Limeum as sister to the globular
inclusion clade.
As part of ongoing studies of floral development in the Caryophyllales, we describe the floral ontogeny of three genera formerly placed in Molluginaceae (Hypertelis salsoloides, Limeum
africanum, and Corbichonia decumbens) and two species of
Glinus, G. lotoides, and G. dahomensis, which belong in the newly
circumscribed Molluginaceae (Fig. 1). We primarily focus on describing patterns of androecium development in these lineages in
the context of their recent phylogenetic placement, and with a
view to patterns of floral evolution across Caryophyllales.
MATERIALS AND METHODS
Hypertelis salsoloides (Burch.) Adamson was cultivated from seed by
S.F.B. in the greenhouses at the Department of Plant Sciences obtained from
Silverhill Seeds (Cape Town, South Africa). Glinus dahomensis A.Chev. (considered as a synonym of Glinus lotoides var. virens Fenzl.) was cultivated from
seed (from RBG Seed Bank, Wakehurst) by S.F.B. in the greenhouses at the
Department of Plant Sciences, Cambridge. Limeum africanum L. was collected
wild in South Africa in FAA (90 mL ethanol 70%, 5 mL acetic acid, 5 mL
formaldehyde 40%) by S.F.B. in Namaqualand, South Africa (sine numero).
Floral material was fixed in FAA. Floral buds of Corbichonia decumbens Scop.
(nr 5007 - Tanganyka, coll. Mrs H. Faulkner 1589, 16 April 1955) and Glinus
lotoides L. (nr 3282 - N. Rhodesia Petanke Distr., col. P. J. Greenway 8045,
5 Sept 1947) were sampled in the spirit collections in Kew by L.R.D.C. Floral
buds and mature flowers were transferred to 70% ethanol and prepared using a
Wild MZ8 stereomicroscope (Leica, Wetzlar, Germany). Dissected material
was dehydrated in an ethanol–acetone series and critical-point dried with a
K850 Critical Point Dryer (Emitech, Ashford, Kent, UK). The dried material
was mounted on aluminum stubs and coated with approximately 180 nm of
gold using an Emitech K575 sputter coater (Emitech) and examined with a
Supra 55VP scanning electron microscope (LEO Electron Microscopy, Cambridge, UK) at RBG Edinburgh and a FEI Philips XL30 FEGSEM electron
microscope at Cambridge.
RESULTS
Hypertelis salsoloides (Figs. 2A, B, 3–5, 16A)— Mature
flowers of Hypertelis are relatively small, approximately 1 cm
across by 1 cm high: Fig. 2A, B). While they are globular in
bud, with sepals and pedicels covered with red trichomes,
opened flowers have a reflexed perianth with distinctive outer
and inner sepals (Fig. 2A, B). Outer sepals are green with narrow, white or pink margins, while margins of inner sepals are
expanded and pink or white. Sepal three shows a combination of outer and inner sepals because one margin only is well
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Fig. 2. Mature flowers of investigated species. A, B. Hypertelis salsoloides. (A) Lateral view of three flowers at different stages of development.
(B) Apical view of mature flower; note the morphological difference between outer and inner sepals (numbered), and the intermediate shape of sepal 3. (For
photograph of flower, see http://www.flickr.com/photos/taiwanicus/2907299590/). (C) Corbichonia decumbens. Partial view of inflorescence with flowers
at different stages of development. The pink petaloids represent staminodes. For photograph of flower, see http://www.zimbabweflora.co.zw/speciesdata/
image-display.php?species_id=122960&image_id=4. D, E. Limeum africanum. (D) Apical view of flower showing small spathulate petaloids. (E) Flower
from below. Note the five sepals with white margins and larger inner sepals. (F) Glinus lotoides. Partial view of inflorescence with flowers at different developmental stages. José Quiles Hoyo, http://www.florasilvestre.es/mediterranea/index.htm. Bars: A, C–F = 10 mm; B = 5 mm.
developed (Fig. 2B). Hypertelis salsoloides always has 15 stamens arranged in three alternating whorls. The inner stamens
are longest and alternate with sepals; those of the intermediate
whorl are opposite sepals, and those in the outer whorl alternate
with sepals (Figs. 4F, 5A, 5B). The stamens are basally fused in
an inflated ring that is glandular on the inside, and the outer
whorl is attached at the bottom of this ring (Fig. 5C). The 15
stamens are erect with yellow, basifixed anthers and pink filaments. The green globular ovary bears five yellow, terminal
stigmatic extensions (Figs. 2A, 2B, 5B).
Inflorescences are thyrsoid with a variable number of flowers. Each inflorescence develops into a terminal flower after
initiating three lateral branches in the axil of pherophylls
(bracts) (Fig. 3A, B). Each lateral branch terminates in a flower
enclosed by two rapidly growing prophylls (bracteoles) (Figs.
3A–C, 4B). A smaller flower bud often develops in the axil of
the first formed prophyll (Fig. 3B). In the terminal flower, the
transition of bracts to sepals is continuous, with the first sepal
occupying the position to be expected by a pherophyll on a
normal racemose inflorescence (Figs. 3A, 3B, 4B). In lateral
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BROCKINGTON ET AL.—ANDROECIAL EVOLUTION IN CARYOPHYLLALES
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flowers, the first sepal arises on the side opposite to the first
formed prophyll (Fig. 3B, arrowhead), and the second sepal is
placed adaxially. Pherophylls and prophylls have two large basally attached stipules (Fig. 3A, B). The five sepals are always
initiated in a 2/5 phyllotaxis (Figs. 3C, 4A–F). Sepals one and
two grow rapidly (Figs. 3C, 4A, 4C, 4D, 4F); growth of the remaining sepals is slower after initiation (Figs. 3C, 4A–F). Aestivation of sepals in bud is imbricate. Inner sepals increase
considerably in size only in preanthetic buds (Fig. 5B). Glandular red trichomes are scattered over the abaxial side of sepals,
bracts and pedicels (Fig. 2A).
The androecium develops on a hemispherical floral apex
(Fig. 3C). Five upper alternisepalous stamens arise simultaneously and are followed by five stamens opposite the sepals
(Figs. 3C, 4A–C). Initiation of antesepalous stamens appears to
be in a basipetal sequence with those opposite sepals 3–5 developing more rapidly than those opposite sepals 1–2 (Fig. 4A-C).
A third whorl of stamens arises below the first whorl in a centrifugal direction in close connection with the upper stamens
alternating with the sepals (Fig. 4A–C). Stamen growth exceeds
the development of sepals in younger stages, and the ovary occupies a prominent terminal position (Fig. 4C–F). It is only at
anther and locule differentiation that the outer sepal lobes cover
the floral bud completely (Fig. 4F). Globular anther lobes develop and subsequently split into two thecae that become again
divided in two parallel symmetrical lobes; anthers are well developed with dorsal pollen sacs almost equal to ventral pollen
sacs (Figs. 4F, 5A, 5B). In preanthetic buds stamens are more
or less arranged in three whorls (Fig. 5A–C). Filaments only
elongate just before anthesis. Stamens are lifted up by a common stamen tube that develops as a bulging rim (Fig. 5C). At
anthesis, the stamens push their way through the closed perianth prior to it becoming reflexed. While the inner stamens are
inserted on top of the rim, the middle whorl occupies a position
halfway the rim, and the outer stamens are inserted just below
the outer margin of the rim. The inside of the stamen tube develops as a nectary.
The gynoecium starts development as a relatively flattopped pentagon on the floral apex at the initiation of the
third stamen whorl (Fig. 4B). While the central area bulges
slightly out, five prominent lobes are differentiated opposite
the sepals and half moon-shaped depressions become visible
in the middle of each carpel primordium (Fig. 4C–E). Five
septal branches converge in the center of the flower, while
the abaxial side of each carpel grows more extensively as to
cover the locular space (Figs. 4F, 5A, 5B). The dorsal tips
extend into five terminal stigmatic appendages before closing of the ovary is complete (Fig. 5B). The mature gynoecium grows as a globular ovary topped by five long stigmatic
branches as no style is formed (Fig. 2B). Within each carpel,
ovules develop in two rows on free-central placentae (not
shown). A floral diagram shows the position of organs in the
flower (Fig. 16A).
Fig. 3. Hypertelis salsoloides. SEM micrographs of early floral development. (A) Young lateral inflorescence showing terminal flower
surrounded by smaller flowers arising sequentially. (B) Older lateral inflorescence showing the differentiation of the terminal flower and basipetal
development of younger flowers. (C) Detail of terminal flower in B with
sequential sepal initiation and simultaneous initiation of five alternisepalous primordia (asterisks) on the androecial plug. Bars = 100 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen; Fl, lateral flower;
Ft, terminal flower; Ph, pherophyll; Pr, prophyll.
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Fig. 4. Hypertelis salsoloides. SEM micrographs of early floral development. (A) Centrifugal initiation of three stamen whorls. Arrows point to outer
alternisepalous stamen primordia. (B) Differentiation of pentagonal gynoecial dome. Note unequal size of antesepalous stamen primordia. (C) Development of carpel primordia and separation of lower alternisepalous primordia from upper stamens; sepals one and two removed. (D, E) Deepening of carpellary lobes and differentiation of stamens. (F) Development of septal branches and differentiation of anthers. Bars = 100 µm; C = 50 µm, F = 500 µm.
Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen; Pr, prophyll.
Corbichonia decumbens (Figs. 2C, 6–8, 16B)— Flowers are
initiated in condensed cymes. Most terminal flowers are generally accompanied by two smaller flowers arising sequentially in
the axil of prophylls. This process is repeated in lateral flowers
(Fig. 6A–F). The inflorescence is a mixture of dichasial and
monochasial branches, as often only one lateral flower reaches
maturity. Each flower is subtended by a large pherophyll and
two prophylls. Prophylls develop rapidly and are mucronate,
forming a cap-like protuberance (Fig. 6A, B). Initiation of sepals
is continuous in a 2/5 sequence, and the two outer sepals rapidly
cover the bud, while the inner sepals are still small (Figs. 6A–F,
7B, 7C); sepal two is strictly positioned in a median position
(Figs. 6B, 6E, 6F, 7B). Outer sepals develop a mucronate tip
similar to prophylls (Figs. 6E, 7B). The inner sepals remain
small during most of the floral development, and the extensive
pressure of the outer sepals molds the flower bud in a distinctive
disymmetric shape (Figs. 6E, 7B, 7C). The inner sepals reach
considerable size only at anther differentiation. Immediately after
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sepal initiation, the floral apex takes a flattened convex shape and
stamens are rapidly initiated on the periphery (Fig. 6B–D). The
earliest stages available show the simultaneous initiation of five
alternisepalous stamen primordia (Fig. 6B–D). Immediately after
(or at the same time as) the alternisepalous stamens, antesepalous
stamen primordia appear at a slightly lower level (Fig. 6B–D). Initiation of antesepalous stamens is sequential, with stamens opposite sepal four, five, and three arising first (Fig. 6D, F). The next
stamens arise opposite sepal one and finally sepal two, where the
space remains empty for some time (Fig. 6D–F).
While a central pentagonal area is delimited as the gynoecium,
stamen development extends centrifugally with a pair of additional stamens arising in close connection with the antesepalous
(Fig. 7B, C) or more rarely the alternisepalous (Fig. 7A) stamens.
As these three stamens are more closely connected, they appear as
complex primordia (Fig. 7A,B). The clustered arrangement becomes more clear when three additional primordia are initiated
externally, followed by two more (Figs. 7C, 8B).
The three upper tiers of stamens extend upward and develop
anther tissue starting with the alternisepalous stamens (Figs. 7C,
7D, 8A–C). Anthers are positioned at different levels in the flower,
with alternisepalous stamens at the top, an intermediate level opposite the sepals, and a third level with paired anthers next to the
antesepalous stamens (Fig. 8A–E). Anthers are slightly displaced
in bud by pressure of the closed perianth, but they retain their respective sizes (Fig. 8C, D). While the H-shaped anthers differentiate pollen sacs, filament growth lifts the stamens up, concomitant
with the growth of the styles (Fig. 8C, D, F).
While the three inner series of the androecium develop as normal stamens, the fate of the two outer series is highly different.
Primordia remain globular at first, and contrary to the fertile stamens, they become flattened by marginal growth (Fig. 8B, E). The
flattened staminodes remain small at first, but grow progressively
upward, covering each other in a haphazard way (Fig. 8F, G). Prior
to anthesis, they reach beyond the stamens and form the main attraction of the flower (Figs. 8H, 2C). In total, 45 stamen primordia
are initiated in the flower, and the number of fertile stamens and
staminodial petaloids is 20 and 25, respectively, and remains highly
constant (Fig. 16B).
Simultaneously with stamen initiation, a pentagonal gynoecial dome is delineated (Fig. 6E, F), and rounded carpellary
lobes develop on the five angles. A triangular depression becomes differentiated midway between the margin and apex, and
five carpellary lobes emerge, separated by broad septal branches
converging in the center (Fig. 7B–D). The dorsal carpellary
lobes do not initially grow much, and ovule primordia start developing in an axillary position (Fig. 7D). Later, more extensive
abaxial growth lifts the carpel wall up, while the ovary deepens
by extensive growth below the lobes (Fig. 8A, B). Finally, the
carpellary lobes converge in the center and close the ovary,
while they grow up as five stylar branches (Fig. 8C, D, F, G).
The stylar branches are covered with papillae on their adaxial
side and lie horizontally on top of the mature ovary. A floral diagram shows the position of organs in the flower (Fig. 16B).
Fig. 5. Hypertelis salsoloides. SEM micrographs of late floral development. (A) Lateral view at style differentiation; the stamens are crowded
within the calyx. (B) Nearly mature flower at closure of the carpels; the
sepals have been moved apart. (C) Detail of mature androecium. Note the
staminal ring with three tiers of stamens. Bars: A = 200 µm; B, C = 500 µm.
Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen.
Limeum africanum (Figs. 2D, E, 9–11, 16C)— Mature flowers are clustered at the end of branches in dense pseudoheads
with flowers arranged in a repetitive cymose pattern. Partial
cymes consist of a top flower accompanied by two smaller lateral flowers of different age (Figs. 9C–F). Prophylls are generally compressed toward the axis by the pressure of the pherophyll
(Fig. 9D, F). Mature flowers have sepals arranged in an imbricate
pattern enclosing small spathulate petaloids and erect stamens
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Fig. 6. Corbichonia decumbens. SEM micrographs of early floral development. (A) Lateral view of young lateral flower showing initiation of the first
sepal. (B) Apical view of older flower at initiation of the androecium. (C) Side view of young flower toward sepal four: initiation of two whorls of stamens
at different levels and first traces of carpels. (D) Lateral view of similar stage—alternisepalous stamens shown by asterisk; note the absence of a stamen
opposite sepal two. (E, F) Two different views at the differentiation of a gynoecial pentagone. Note the unequal size of antesepalous stamens; no stamen
has been formed opposite sepal two. Bars = 20 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen; Fl, lateral flower; Ft, terminal
flower; Pr, prophyll.
(Fig. 2D). The sepals develop in a 2/5 sequence, and the first
sepal is rapidly followed by sepal two situated against the axis
in median position (Fig. 9A–D). Both outer sepals develop a
distinctive mucronate apex (Figs. 9A, 9C, 9D, 10A). The three
inner sepals remain initially smaller and only expand in size at
maturity as to exceed the outer sepals in size (Fig. 2D, E). The
mature sepals develop a broad central zone of chlorophyllous
tissue around the midrib with narrow white margins. As soon as
sepals have been initiated, stamen primordia differentiate on a
hemispherical platform (Fig. 9B–E). Stamens are positioned in
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Fig. 7. Corbichonia decumbens. SEM micrographs of early floral development. (A) Lateral view showing centrifugal development of the androecium
(white numbers) linked with the alternisepalous stamens. (B) Abaxial view of flower at differentiation of the septa. (C) Detail of stamen initiation. Numbers
show centrifugal development of antesepalous stamen groups. (D) View of flower at anther differentiation and ovule development. Bars: A–C = 20 µm;
D = 100 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen; Pr, prophyll.
a single whorl. The number of stamens initiated varies between
seven (Figs. 9C–F, 10A, 10F, 11B, 11C) and six (Figs. 10B–D,
11A). Stamens are variously inserted opposite sepals and petaloids. With seven stamens, a stamen is always absent opposite the
petaloid between sepals three and five and opposite sepals one
and two (Figs. 9F, 10A, 10D, 10F, 16C). With six stamens, another
stamen is absent between sepals two and five (Fig. 10B–D).
Initiation is rapid with stamens at different levels and with a
different size (Fig. 9C–E). While the initiation sequence of the
stamens is difficult to observe, subsequent growth of stamens
demonstrates a regular sequence approximating a 3/8 pattern
that can be traced from stamen differentiation until maturity
(Figs. 9F, 10A, 10D, 10F, 11A–C). The development of stamens runs in an inversed spiral sequence starting either with the
stamens opposite sepal five and sepal four although it was difficult to discern which was the first to arise (Figs. 9F, 10A, 10C,
10D, 10F, 11B, 11C). Stamens differentiate globular anthers on
filaments of different length reflecting the sequential growth
(Figs. 10D, 10F, 11A–F). The two first-formed stamens remain
the longest in bud (Figs. 10, 10F, 11C, 11D, 11F). The base of
the filaments inflates and becomes covered with trichomes on
its margins and on the adaxial side (Fig. 11F, G). Filaments are
connected by a short tube that is covered with nectarostomata
on the adaxial side below the level of the trichomes. Primordia
of the petaloids arise immediately after (or simultaneously with)
stamen initiation (Fig. 9C–E) and are delayed in growth (Figs. 9F,
10C–F, 11C). Initiation of petaloids is independent of upper
stamens (Fig. 10C), but they appear closely connected to the
alternisepalous stamens. The petaloid alternating with sepals
three and five has no opposite stamen (Fig. 16C). A petaloid is
rarely absent (Fig. 10B, asterisk). Petaloids become dorsiventrally flattened and grow as short, strongly spathulate appendages at the base of the stamen tube (Figs. 2D, 11F, 11G). In a
few buds, petaloids develop as short erect filament-like appendages (Fig. 11D).
The ovary initiates as a globular protuberance on top of the
staminal platform (Fig. 9F). A central depression is delineated by
a low peripheral rim initially growing on one side (Fig. 10B–D).
The ovary extends toward sepal two, forming a second protuberance that will eventually develop into a second style (Fig. 10F,
11A, 11C). The second rim is delayed relative to the first, as the
ovary is pseudomonomerous. Although two ovules are initiated
(Fig. 11E), only the adaxial one reaches maturity, while both
styles are equal in size. Carpels are always oriented in a median,
though slightly oblique position as carpel one lies on the radius of
sepal one. A floral diagram shows the position of organs in the
flower (Fig. 16C).
Glinus lotoides (Figs. 2F, 12, 13, 16D)— Mature flowers
of Glinus lotoides are greenish-white with five sepals and a
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Fig. 8. Corbichonia decumbens. SEM micrographs of late floral development. (A) Apical extension of carpellary lobes. (B) Lateral view of the same.
Note the centrifugal differentiation of four whorls of antesepalous stamens. (C) Apical view showing differentiation of stigmatic lobes. (D) Apical view of
older stage. Note the crowding of the stamens in several series. (E) Lateral view of the same. Note the arrangement of staminodes in two irregular tiers.
(F, G) Successive stages in the expansion of the staminodes. (H) Adaxial view of part of the androecium in a preanthetic bud. Note the staminodial petaloids
overtopping the stamens. Bars = 100 µm; H = 200 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen.
variable number of stamens, staminodes, and petaloids. As for
Hypertelis, the inner sepals have broader white margins than
the two outer sepals, and sepal three is intermediate (Figs. 2F,
16D) Flowers arise on compound cymose inflorescences containing several lateral branches (Fig. 12A). Lateral branches are
monochasial, with a terminal flower and a smaller axillary
flower (Fig. 12A). The number of lateral branches is variable
but ranges from three to five. Each partial inflorescence is subtended by a pherophyll and two prophylls (Fig. 12A). Within
each partial inflorescence, the top flower differentiates five sepals in a 2/5 sequence with sepal one positioned toward the
bract and sepal two against the axis (Fig. 12A–C). The two
outer sepals expand above the developing flower bud and become slightly hooded (Fig. 12B, C). While the inner sepals are
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Fig. 9. Limeum africanum. SEM micrographs of early floral development. (A) Apical view of early initiation of the sepals. (B) Lateral view with early
differentiation of androecial plug. (C–E) Rapid sequential initiation of seven androecial primordia (asterisks) and first traces of petaloid primordia
(arrows). (F) Sequential differentiation of stamen primordia (white numbers) and formation of gynoecial dome. Bars = 100 µm. Abbreviations: Fl, lateral
flower; Pr, prophyll.
still small, the floral apex has become pentangular, and five alternisepalous stamen primordia are initiated almost simultaneously on its margins (Fig. 12B, C). The stamens next to sepal one
are slightly advanced compared to the other stamens (Fig. 12B).
Primordia are inserted in alternation with the sepals but tend to
converge in two pairs (opposite sepals one and two) and a single stamen between sepals three and five (Fig. 12D, E). There is
more space between the stamens in the areas opposite sepals
three, four, and five (Fig. 12E). After the differentiation of the
gynoecium, a number of extra stamens can be initiated opposite
the sepals (Figs. 12E, 12F, 13A). The extra stamens are generally sterile and develop either as small, two-lobed, petaloid appendages (Fig. 13A–C) or as small stubs (Figs. 12F, 13A, 13B);
they rarely develop as fully fertile stamens and may have half
of the anther sterile (Fig. 13C). While the spaces opposite sepals three, four, and five are generally occupied by sterile stamens, stamens are more rarely formed opposite sepals one and
two, and the extent of development of the stamens is inversely
correlated with the sequence of sepal initiation (Fig. 16D).
When fully developed, petaloid staminodes have a long bifid
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Fig. 10. Limeum africanum. SEM micrographs of early floral development. (A) Apical view showing sequence of differentiation of stamens and development of a central depression on the gynoecium. (B) Adaxial view of flower with six stamens. Note the empty position opposite sepal 2 (asterisk) and
single petaloid (arrow). (C) View of young bud from the adaxial side. Note two petaloids (arrows), single stamen opposite sepals 2, and initiation of carpellary rim. (D) Similar stage seen from the abaxial side. Note two petaloids (arrows) and unequal stamen pair opposite sepal 1. (E) Adaxial view at differentiation of the filaments; note the small petaloids (arrows). (F) Lateral view at differentiation of the anthers and carpels. Note the initiation of a second
carpellary rim and the different length of the filaments, reflecting the sequence of differentiation of the stamens (white numbers). Bars: A, C–F = 100 µm;
B = 50 µm. Abbreviations: Fl, lateral flower; Pr, prophyll.
apex (Fig. 13C). Fertile stamens differentiate as a broad rectangular organ; further development leads to H-shaped anthers containing two extrorse thecae on a narrow connective and a stout
filament (Fig.13A, C). The ovary develops as a triangular apical
primordium with the angles facing sepals one, two, and three
(Fig. 12D). Three deep slits are formed midway on the angles delimiting a central meristematic triangle (Fig. 12E). The slits deepen
progressively by the upward growth of the underlying gynoecial
tissue (Fig. 12F). As a result, the gynoecium develops as a tall
cylinder, retaining apical slits (Fig. 13A). Within each slit, a locule
develops with several ovules arranged in four rows. The areas
abaxial to the apical slits extend as overarching tissue and develop
as short styles only before anthesis (Fig. 13C). A floral diagram
shows the position of organs in the flower (Fig. 16D).
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Fig. 11. Limeum africanum. SEM micrographs of late floral development. (A) Apical view with upward growth of carpellary lobes. (B) Apical view
at anther differentiation and filament growth reflecting the sequence of initiation (white numbers). (C) Lateral view of flower at closure of the carpels. White
numbers indicate the sequence of stamen initiation. (D) Lateral view of flower at anther and petaloid differentiation. Note that two petaloids are staminodium-like (arrows). (E) Cross section of young ovary showing two ovules of different size (arrowheads); the upper ovule will eventually abort. (F) Preanthetic bud showing small spathulate petaloids and inflated filament bases with trichomes developing on the adaxial side. (G) Apical view of mature flower;
ovary removed. Note the long trichomes on the base of the filaments and nectariferous area below. Bars: A = 20 µm; B, C, E = 100 µm; D, F, G = 200 µm.
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Fig. 12. Glinus lotoides. SEM micrographs of early floral development. (A) View of young inflorescence showing initiation of younger flowers around
a terminal flower. Initiation of first sepals on lateral flower (numbers). (B) Formation of pentangular apex after sepal initiation; note that the adaxial side is
advanced with two stamens being initiated (asterisks). (C) Slightly older bud showing the differentiation of five alternisepalous stamen primordia; four are
visible (asterisks). (D) Development of three carpel primordia and expansion of the alternisepalous stamens. (E) Apical view of flower at carpel initiation.
Arrows point to spaces between stamens where further stamens initiate. (F) Lateral view of flower at differentiation of anther tissue. Arrows point to small
antesepalous primordia. Bars = 20 µm. Abbreviations: Aa, alternisepalous stamen; Pr, prophyll.
Glinus dahomensis (Figs. 14, 15)—The species shows a pattern of early floral development similar to G. lotoides with cymose
inflorescences containing several lateral branches (Fig. 14A).
Lateral flowers arise between a pherophyll and two prophylls,
and an extra flower usually develops only in the axil of the first
formed prophyll (Fig. 14B, C). Sepals are initiated in a regular
2/5 sequence, and the outer sepals rapidly cover the inner sepals
(Fig. 14A–E), although differences in size are not as strong as
in other genera. Sepals develop a mucronate apex (Fig. 14D, E).
Five alternisepalous stamens are initiated more or less on the
same level but in a rapid sequence starting with a stamen between sepals three and five and ending with a stamen between
sepals one and four (Fig. 14C, E). Antesepalous stamens initiate at a lower level and their development is also sequential
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(Fig. 14C, E, F). Stamens opposite sepals one, two, and three
are visible before those opposite sepals four and five (Fig. 14C,
D), and stamens generally differ in size (Fig. 14E, F). Alternisepalous stamens become subequal in size, and differentiated anther tissue develops extrorsely (Figs. 14F, 15A). The antesepalous
whorl is generally fertile but with shorter filaments (Fig. 15B).
Occasionally stamens are misshapen with a sterile half-anther
(Fig. 15B,E), or stamens are sterile and petaloid with a bifid
apex (Fig. 15C, F). Petaloids develop opposite the alternisepalous stamens after differentiation of the anthers (Fig. 15D). They
develop into bifid, heart-shaped appendages (Fig. 15B, E) and
eventually grow into narrow forked structures (Fig. 15C). The
gynoecium is initiated in the same way as in Glinus lotoides
(Figs. 14E, 14F, 15A–C).
DISCUSSION
The floral morphology of (core) Caryophyllales is unique
among eudicots, with a basic absence of petals, and a strong convergent evolution with other petal-bearing angiosperms through
the evolution of staminodial petaloids. In addition, the androecium development and evolution is highly divergent. These four
genera (Corbichonia, Limeum, Glinus, Hypertelis) exhibit a
number of floral developmental features indicative of evolutionary processes across the Caryophyllales. These processes include
perianth differentiation within the calyx whorl or via stamen sterilization, centrifugal stamen initiation on an androecial platform
surrounding the gynoecium, reversed initiation of antesepalous
stamens, starting opposite sepals four and five, variable merism
of the gynoecium linked with a predictable loss of antesepalous
stamens, and finally phylogenetically informative alterations in
patterns of androecium development. These processes will be explored further with reference to evolutionary patterns of floral
development across the Caryophyllales.
Essential patterns of centrifugal stamen initiation within
the androecium— As demonstrated by the four genera studied
here, centrifugal initiation of the androecium appears to be extremely common in the Caryophyllales (Payer, 1857; Hofmann,
1994; Leins and Erbar, 1994; Ronse De Craene, 2010). It is at
present unclear what regulates the centrifugal initiation of organs in flowers, as it may reflect a tendency for an increase in
organ number (as in complex polyandry: Ronse De Craene and
Smets, 1992) as frequently observed in several Caryophyllales
(e.g., Corbichonia, Aizoaceae, Portulacaceae, Cactaceae), or a
regression of organs and their loss (delayed organ initiation and
growth: Ronse De Craene et al., 1993), also found in Caryophyllales (e.g., Caryophyllaceae, Limeum, Glinus: Ronse De Craene,
2010; Ronse De Craene et al., 1998; Wagner and Harris, 2000;
Harris et al., 2012). The common underlying genetic factors for
centrifugal stamen initiation are currently unknown, but they
Fig. 13. Glinus lotoides. SEM micrographs of late floral development.
(A) Lateral view at closure of carpels and differentiation of anthers. Note
fully developed alternisepalous stamens and small antesepalous appendages. (B) Detail of A showing bilobed staminodial petaloid and small underdeveloped structure. (C) Lateral view of nearly mature flower at
differentiation of stigmatic lobes. Note bifid staminodial petaloid (right
arrow) and abnormal antesepalous stamen, with one anther half sterile (left
arrow). Bars: A = 100 µm; B = 20 µm; C = 200 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen.
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Fig. 14. Glinus dahomensis. SEM micrographs of early floral development. (A) Lateral view of young inflorescence. Note younger flowers developing
around more advanced terminal flower. (B) Lateral flower showing the initiation of five sepals. Note smaller flower in the axil of the left prophyll. (C) Apical view at early initiation of alternisepalous stamens (asterisks). Note smaller antesepalous stamen opposite sepals one and three. (D) Older bud showing
continuous growth of sepals and larger alternisepalous stamens. (E) Apical view at differentiation of three carpels. Note additional stamens opposite sepals
one-four. (F) Apical view at differentiation of septa and anther formation. Note antesepalous stamens of different size. Bars: A, B, F = 100 µm; C–E =
50 µm. Abbreviations: Fl, lateral flower; Ph, pherophyll; Pr, prophyll.
are probably diverse. Centrifugal stamen initiation may represent a synapomorphy for the order, or substantial part thereof;
however, early-diverging lineages have not yet been studied for
their androecium development. In a centrifugally initiating androecium, it is the gynoecium that dictates the phyllotaxis of the
first-formed stamen primordia, thus an understanding of gynoecium development in Caryophyllales is especially important for
understanding patterns of centrifugal androecium development
(see below). In Caryophyllales, carpels within the gynoecium
always occupy an antesepalous position when isomerous, with
very few exceptions (Ronse De Craene, 2013), and thus in an
isomerous flower, the first-formed stamens are expected to be
alternisepalous, the second centrifugal tier is then antesepalous,
where there is less pressure from the carpels, the third alternisepalous, and so on. However, as we discuss subsequently, the
first-formed stamens are not always alternisepalous, and there
are some important deviations to this pattern. Further complexity emerges in the patterns of initiation within each stamen tier.
For example, although the first alternisepalous stamen primordia arise almost simultaneously, subsequent antesepalous stamens in these four genera arise sequentially. The sequential
initiation of antesepalous stamens runs mostly in an inversed
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Fig. 15. Glinus dahomensis. SEM micrographs of late floral development. (A) Apical view of flower showing differentiation of upper extrorse anthers.
(B) Detail of equivalent developmental stage. Note longer antesepalous stamens and initiation of a petaloid (arrow). (C) Lateral view of slightly older stage
at style formation. Note the initiation of petaloids (arrows). (D) Detail of C; note petaloid differentiation opposite alternisepalous stamen. Arrow points to
undeveloped theca of antesepalous stamen. (E) Flower with variable development of petaloids (black arrows) and antesepalous staminodes (white arrows).
(F) Nearly mature flower bud at stigma differentiation. Note longer alternisepalous stamens and variable development of antesepalous staminodes (arrows).
(D) Lateral view at initiation of alternisepalous petaloid (arrow). Bars: B, D = 50 µm; A, C = 100 µm; E = 200 µm; F = 500 µm. Abbreviations: Aa, alternisepalous stamen; Ao, antesepalous stamen.
sequence relative to the sepals, and the first stamens initiate opposite sepals four and five. This pattern has been reported in a
number of families, such as Caryophyllaceae, Phytolaccaceae,
and Nyctaginaceae (Hofmann, 1994; Ronse De Craene et al.,
1997, 1998; Ronse De Craene, 2010). Inversed sequence initiation is subsequently reflected in length differences within the
antesepalous stamens, with the first-formed stamens being longer. Furthermore, as discussed in the next section, this inversed
sequence initiation is reflected in patterns of stamen loss, with
later initiating stamens opposite sepals one and two being the
most likely to be lost.
Genus-specific variation in patterns of stamen initiation
and loss— Limeum, Hypertelis, and Glinus exhibit patterns of
stamen loss. Stamen number is unstable among different species of Glinus, ranging from five to several series of stamens
including outer staminodes (Hofmann, 1973, 1994). Androecia
with higher numbers look similar to Corbichonia (see Hofmann,
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Fig. 16. Floral diagrams of investigated species. (A) Hypertelis salsoloides; (B) Corbichonia decumbens; (C) Limeum africanum; (D) Glinus lotoides.
Petaloid calyx (parts) shown in white, sepaloid calyx (parts), pherophyll and prophylls shown in black; ovals and white arcs with central dots: staminodial
petaloids; full circles: confines of androecial ring; gray ring: intrastaminal nectary. Position of stylar tissue shown by small arcs on the carpels; asterisks,
missing stamens; in B, dotted circle shows stamen group; in C, numbers show sequence of stamen initiation.
1994: fig. 17), suggesting an increase of stamens. Alternatively,
Sharma (1963) described Glinus oppositifolius as having 10–13
stamens in three whorls, suggesting a tendency for reduction
with loss of the outer stamen whorl. However, the species investigated here show mostly 10 stamens in Glinus dahomensis,
and rarely more than five in Glinus lotoides. The fluctuation in
stamen number in Glinus is not random. The five upper alternisepalous stamens are always present in all species, but the
number of antesepalous stamens fluctuates strongly, and this is
generally linked with an inversed initiation sequence. However,
in Glinus dahomensis antesepalous stamens are exceptionally
not inversed, with those opposite sepals one and two arising
before those opposite sepals three, four, and five. This sequence
may be linked with the rapid initiation of alternisepalous stamens seen in this taxon. However, in all cases, stamens opposite
sepals one and two are the first to disappear. Other Molluginaceae
also invariably have five alternisepalous stamens, probably reflecting the loss of all antesepalous stamens.
Within families of the raphide clade and even among genera,
stamen number can also fluctuate strongly, as exemplified by
Hypertelis. The androecium of Hypertelis varies between three
and many stamens (Endress and Bittrich, 1993), encompassing a
high variability. Hofmann (1973) studied mature herbarium material of Hypertelis, and her description of the androecium based
on unpublished material of Hypertelis salsoloides (Hofmann,
1994) corroborates our data. The flower of Hypertelis is distinctive in the presence of 15 stamens arranged in three alternating
whorls. Flowers with three alternating stamen whorls are rare,
if not completely absent from other core eudicots. Hypertelis
bowkeriana has only five alternisepalous stamens, probably corresponding to the first-formed stamens of H. salsoloides.
When comparing the floral development of Corbichonia with
Hypertelis, there is a concordance in development up to the
second whorl of stamens (Ronse De Craene, 2008, 2010).
Corbichonia and Hypertelis share an inversed sequence of antesepalous stamen initiation with the other genera, but the antesepalous whorl is always fully developed. Friedrich (1956)
interpreted the androecium of Corbichonia rubriviolacea (Friedr.)
as consisting of five alternisepalous stamens and five antesepalous groups of five stamens each plus outer petaloids. Hofmann
(1973) rejected this interpretation as implausible, although our
floral developmental data tend to corroborate the interpretation
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greatly limits space for the initiation of a stamen, as this is often
the last position to be filled. Consequently, stamens opposite
sepal two are frequently missing or at least delayed, as we observed in Corbichonia and Hypertelis. With five carpels, the
antesepalous stamens are naturally those undergoing the strongest pressure from carpels and perianth, leading to their reduction or loss in Aizoaceae and Phytolaccaceae. The alternisepalous
stamens have sufficient space to increase stamen numbers by
division of initially formed primordia (Fig. 17B).
of Friedrich. The sister genus of Corbichonia, Lophiocarpus,
has only four stamens: three alternating with sepals and one opposite a sepal (Eckardt, 1974; Stannard, 1988). The unusual
presence of one antesepalous stamen in Lophiocarpus could indicate that this stamen was derived from an original condition
with five alternisepalous stamens by a fusion of two stamens
under influence of a reduced tetramerous ovary, similar to a
process occurring in Mollugo (Batenburg and Moeliono, 1982).
Meanwhile, Corbichonia resembles Aizoaceae more closely in
the development of several outer whorls of staminodes. However, contrary to Aizoaceae, initiation is less clearly confined to
the alternisepalous sectors of the flower, and stamen increase
often starts in the antesepalous sector of the flower.
The inversed sequence of stamen initiation is more complex in
Limeum and includes alternisepalous stamens. Descriptions of
stamen positions in Limeum are often contradictory. Friedrich
(1956) and Hofmann (1973, 1994) concluded that flowers with
seven stamens have five shorter alternisepalous stamens and two
longer stamens opposite sepals four and five (three stamens are
assumed to be lost). However, our investigation shows a progressive decrease in stamen sizes with three stamens in antesepalous
positions and a pair of unequal size situated opposite sepals one
and two. One alternisepalous stamen position is also empty. This
pattern of initiation is comparable to Bougainvillea and some
other Nyctaginaceae (see Vanvinckenroye et al., 1993; Ronse De
Craene, 2013), where stamen position and initiation is apparently
disconnected from the perianth. Several species, including L.
africanum possess outer staminodial petaloids. Limeum corresponds to Caryophyllaceae and other members of the basal grade
of Caryophyllales in its larger upper antesepalous stamens opposite sepals four and five. In several members of Caryophyllaceae, stamens are lost in an inversed sequence to the sepals
(Thomson, 1942; Ronse De Craene et al., 1998).
Disjunct patterns of androecium development across Caryophyllales— Our analysis of these four genera emphasizes an
unusual disjunction in patterns of androecial development
across the Caryophyllales that merits further investigation. The
first-formed and upper stamens are invariably in alternisepalous
position in Glinus, Corbichonia, and Hypertelis; however, they
are in an antesepalous positions in Limeum. Limeum also differs
from the other genera in the inversed spiral sequence of stamen
initiation affecting both antesepalous and alternisepalous stamens. The globular inclusion clade containing Portulacineae,
Molluginaceae, and the raphide clade appear to share a common pattern of androecial development, while the paraphyletic
alliance of lineages, which diverge earlier than the globular inclusion clade (e.g., Caryophyllaceae, Stegnosperma, Macarthuria,
and Limeum) share a different pattern of androecial development (Fig. 1).
This phylogenetic disjunction is revealed by the following
two observations. The first observation is that the upper longer
stamens are positioned in an alternisepalous position in the
globular inclusion clade, and in an antesepalous position in the
early-diverging lineages. The alternisepalous position links
Hypertelis with both the Portulacineae and raphide clade, where
stamens are often in alternisepalous position or have been
Processes underlying stamen loss— In general, we can propose two possible causes for the stamen reduction and loss seen
in these four genera and in the Caryophyllales as a whole. In
essence, the gynoecium and centripetally advancing sepals act
as two separate forces on the intervening androecium to cause
stamen loss (Fig. 17). First, stamen loss is linked with a reduction of carpels from five to three or two (Fig. 17A). There is a
strong correlation between numbers of stamens in the upper tier
and numbers of carpels. Upper stamens always alternate with
carpels, and if carpels are increased or decreased in number,
this invariably affects the upper stamen whorl. In taxa with
lower carpel numbers, such as Limeum, the longer antesepalous
stamens alternate with the remaining carpels, while stamens
tend to be reduced or lost in the radius of the carpels lobes,
presumably because the stamens are then forced into a crammed
position between carpel and sepal that then engenders stamen
loss (Fig. 17A). Meanwhile, the best-developed antesepalous
stamens are those that alternate with carpels. However, in Glinus with three carpels, the alternisepalous stamens tend to converge in pairs against the flanks of the carpels and are thus
protected to an extent from pressure by the sepals, but they
leave less space for the initiation of the antesepalous stamens.
Second, the stamens to be lost are those that undergo the
highest pressure from sepals during development. Given the
predictable pattern of stamen loss whereby the later initiating
stamens are preferentially lost, a plausible explanation for the
inversed initiation and loss of stamens is inhibitory pressure
of the larger outer sepals against the developing flower buds.
For example, sepal two, which is in a median adaxial position,
Fig. 17. Illustrations of spatial patterning in the development of the
flower of Caryophyllales; longitudinal overviews. (A) Upper position of
antesepalous stamens with trimerous ovary and loss of stamens opposite
sepals one and two. Development of outer staminodial petaloids (e.g.,
Limeaceae, Macarthuria, Caryophyllaceae). (B) Upper position of alternisepalous stamens with loss of antesepalous stamens. Centrifugal multiplication of alternisepalous stamens (e.g., Aizoaceae, Phytolaccaceae).
Arrows highlight the pressure from the gynoecium and perianth. Gray
area: gynoecium; hatched area: calyx; white area: androecium; red dots,
alternisepalous stamens; green dots, antesepalous stamens; stars, lost stamens; half moons, staminodial petaloids.
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increased by secondary expansion of a ring primordium or by
division of primary stamens. In some Portulacineae, there is
apparently a reversal to an upper antesepalous position (some
Didiereaceae, Montiniaceae: Ronse De Craene, 2013). Also in
the variable Phytolaccaceae, upper or first-formed stamens tend
to be in alternisepalous position or are shifted in pairs opposite
sepals (e.g., Phytolacca dodecandra: Ronse De Craene et al.,
1997; Ercilla volubilis: Ronse De Craene, 2010). A second observation is the tendency for loss of some of the upper stamens
in the earlier-diverging lineages; these are always those situated
opposite sepals one and two (and sometimes three) (e.g., Macarthuria with eight stamens; Limeum sulcatum, L. pterocarpum, and L. viscosum with seven stamens: Friedrich, 1956;
Sharma, 1963; Hofmann, 1973; several Caryophyllaceae with
an incomplete antesepalous whorl, e.g., Stellaria, Scleranthus,
Spergularia: Ronse De Craene et al., 1998; Hofmann, 1994;
Smissen and Garnock-Jones, 2002). The lost stamens are incidentally those that appear latest in the sequence of antesepalous
stamen initiation, similar to the sequence observed in Hypertelis.
Alternisepalous stamens on the contrary do not suffer similar
pressures, and, especially for the raphide clade, these alternate
with five carpels. Although it is not clear how these mechanical
causes became fixed within families, they can be translated in a
phylogenetic context. All taxa with upper antesepalous stamens
branch off before the globular inclusion clade, indicating a profound change in androecium morphology.
Perianth “differentiation” within the calyx— The perianth
of the four studied genera adhere to the general concept of the
Caryophyllid perianth in the following characteristics: (1) the
perianth is pentamerous with a clear 2/5 arrangement and a
strong differentiation between outer and inner sepals; (2) the
sepal shape is rounded and often dorsally mucronate, and (3)
the sepal margins are petaloid, while the area around the vascular bundle is green (Fig. 2). In Corbichonia, the calyx is greenish; however, in Glinus, Limeum, and Hypertelis, the calyx
becomes partially petaloid. Several Caryophyllales develop a
comparable calyx, and the sepals are differentiated along the
proximal–distal axis, with a lower flattened petaloid zone and
an upper subapical pointed mucro (e.g., Sesuvium, Trianthema,
and Galenia in Aizoaceae, Paronychioideae of Caryophyllaceae: Hofmann, 1973; Brockington et al., 2012; Ronse De
Craene, 2010). Sepals correspond to transformed leaves in the
possession of these proximal and distal zones; the petaloid lateral zone represents the hyaline margin of a leaf sheath and the
upper tip representing a reduced unifacial leaf blade (Vorlaüferspitze: Kaplan, 1975). The hyaline “leaf-sheath” margin can be
co-opted in the development of petal-like tissue (Brockington
et al., 2012), as is clear by the extensive petaloid tissue developing in the inner sepals of Hypertelis. Outer sepals have a small,
lateral, colored rim, while sepal three is asymmetric with a onesided extension of a colored flap (Fig. 2B). This observation
likely indicates that petaloidy in Hypertelis is caused by extensive marginal growth of the narrow rim of tissue present in
other Caryophyllales. The differentiation of petaloid tissue on
the inner sepals is possibly related to exposure to light; the outer
sepals and half of the third sepal are chlorophyllous, while the
covered floral parts develop pink hues. This differentiation is
similar to that of sepal tissues observed in several Polygonaceae
(L. P. Ronse De Craene, unpublished data) and is reminiscent of
experimental observations of the differentiation of perianth in
Nymphaeaceae by Warner et al. (2009). While initially larger and
enclosing the inner sepals in bud, the outer sepals are narrower
[Vol. 100
and smaller at maturity in Glinus, Hypertelis, and Limeum. The
calyx of Corbichonia retains its larger outer sepals, and attraction is mainly through the whorls of staminodial petaloids. Adamson (1958b) mentions that the perianth of Corbichonia
decumbens is green outside and often colored adaxially.
Perianth differentiation by stamen sterilization—Staminodial
petaloids are variously present in the investigated species, reflecting the condition found in other Caryophyllales, where the
second perianth whorl is invariably of staminodial origin (Ronse
De Craene et al., 1998; Brockington et al., 2009; Ronse De
Craene, 2010, 2013). The petaloid organs of staminodial origin
are the latest to be initiated and lag behind in their development,
only exceeding stamen size in a few instances at later stages of
development (e.g., Corbichonia, Limeum). With the exception
of Corbichonia, where numerous outer staminodes are regularly arranged as petaloid appendages, a single-whorled corolla
tends to be infrequent and variable. In Glinus, outer petaloids
are present depending on the vigor of the flower and space for
their initiation. Petaloid number in Glinus can fluctuate enormously and can either be in antesepalous position (replacing a
fertile stamen) or in alternipetalous position as an appendage of
the upper stamen. In Limeum, spathulate petaloids are generally
present in the flower. Hypertelis is unusual as it lacks petaloids
altogether, but stamens occupy the position of petaloids in other
Caryophyllales. A similar arrangement was observed in Trichostigma and Ledenbergia of Phytolaccaceae-Rivinoideae, but
with a tetramerous merism (Ronse De Craene and Smets, 1991).
The close connection of the petaloids with the androecium,
their shape and development, and occasional replacement by
stamens points to a clear staminodial origin.
A number of Caryophyllales with comparable androecium
morphologies to Hypertelis have the outer stamens replaced by
petaloid structures (e.g., Macarthuria, Limeum, Glinus, Stegnosperma, possibly Asteropeia, and most Caryophyllaceae). In all
observed cases, a narrow petaloid appendage develops on the
outside of the staminal rim, or below it where the staminal rim
is protruding. The petaloid structure is often indistinguishable
from a staminode or is occasionally replaced by a stamen (e.g.,
Stellaria, Sagina, and Scleranthus in Caryophyllaceae: Ronse
De Craene et al., 1998). Thus, there seems little difficulty
in recognizing the outermost stamen whorl of Hypertelis as
homologous with the staminodial petaloids of other Caryophyllales on the basis of position. Other Caryophyllales with staminodial petaloids have more stamens arising centrifugally in
girdles as part of a complex multistaminate androecium. (e.g.,
Corbichonia, Mesembryanthemoideae, and Ruschoideae in the
Aizoceae).
Development of the gynoecium— Gynoecial development is
strikingly similar among a range of Caryophyllales, which in
the data presented here is best exemplified by Hypertelis. In
Hypertelis, the gynoecium develops as a central protuberance
surrounded by the androecial platform. Stamens and carpels
thus form a distinct association (Fig. 17). Development starts
with a hemispherical dome, and locules arise as half-moonshaped slits separated by prominent septa. In genera of the
raphide clade, more active growth of the dorsal carpel parts
leads to overtopping of the locules, and terminal stigmatic lobes
are formed while the ovary develops as a globular structure
with axile placentation. Corbichonia closely resembles Hypertelis in carpel development. In Glinus, growth of dorsal appendages is less prominent. The development of the ovary is generally
September 2013]
BROCKINGTON ET AL.—ANDROECIAL EVOLUTION IN CARYOPHYLLALES
more pronounced than the stigmatic lobes, leading to a cylindrical structure with apical slits resembling a salt-shaker. A comparable pattern of development is visible in members of the
Portulacineae (L. P. Ronse De Craene, personal observations).
Limeum is highly unusual for Caryophyllales in becoming
pseudomonomerous, developing from two carpels. However,
reductions to three, two, or a single carpel are not uncommon
within the different clades of Caryophyllales, while secondary increases of carpels are more limited (e.g., in Cactaceae,
Phytolaccaceae).
Conclusions— The data generated here fill some significant
phylogenetic gaps in our understanding of androecial development across Caryophyllales, most notably with the inclusion of
Limeum. We reveal two important patterns of stamen development including (1) the preferential loss of antesepalous stamens
starting opposite sepals one and two and (2) a switch in the
position of the first formed stamens from antesepalous to alternisepalous following the divergence of Limeum (Fig. 1). This
switch provides important morphological data in further support of the globular inclusion clade. The data also provide insight into the link between centrifugal development and meristic
variation in the androecium. The study emphasizes the importance of developmental morphology in providing cryptic morphological synapomorphies and in providing insight into the
developmental basis of morphological variation. Future studies
should explore the evolution of Caryophyllid floral development in early-diverging lineages and the impact of centrifugal
development on the developmental genetics of organ identity.
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