Ultrastructure of the intercellular protuberances in leaves of Paepalanthus
superbus Ruhl. (Eriocaulaceae)

SILVIA RODRIGUES MACHADO1,4, MARIA EMÍLIA M. ESTELITA2

and ELISA APARECIDA GREGÓRIO3

(received: March 10, 2000; accepted: September 13, 2000)

ABSTRACT - (Ultrastructure of the intercellular protuberances in leaves of Paepalanthus superbus Ruhl. (Eriocaulaceae)). Mature
leaves of Paepalanthus superbus exhibit intercellular protuberances between the inner periclinal walls of the epidermal and the
parenchyma cells surface, as well as on the surface of the parenchyma mesophyll cells. These structures are mostly prominent around
the parenchyma cells, forming a gel capsule-like structure. Histochemical tests with ruthenium red indicate the pectic nature of the
intercellular deposits, with scattered lipidic inclusions as revealed by sudan IV and sudan black B. Ultrastructural analyses show a
fibrillar matrix with scattered fimbriate and tubular structures, and a distinct margin delimited by a dense membrane-like structure. Our
results suggest that the protuberances are derived from secretory activity, and are formed after the development of the intercellular
spaces. For P. superbus this structure may represent an important cell wall specialisation, related with the adhesion and transport
mechanisms between cells.

RESUMO - (Ultra-estrutura de protuberâncias intercelulares em folhas de Paepalanthus superbus Ruhl. (Eriocaulaceae)). Folhas
adultas de Paepalanthus superbus mostram protuberâncias intercelulares, entre a parede periclinal interna das células epidérmicas e
superfície de células parenquimáticas; depósitos semelhantes ocorrem na superfície das células parenquimáticas do mesofilo. Estas
protuberâncias são mais proeminentes ao redor de células parenquimáticas, formando uma estrutura que lembra uma cápsula gelatinosa.
Testes histoquímicos com vermelho de rutênio evidenciam sua natureza péctica, com inclusões lipídicas dispersas, detectadas por sudan
IV e sudan black B. Ultra-estruturalmente as protuberâncias mostram matriz fibrilar permeadas por estruturas fimbriadas e tubulares,
com margem distinta formada por estrutura membranosa. Nossos resultados sugerem que estas protuberâncias são derivadas de atividade
secretora, sendo formadas após o desenvolvimento dos espaços intercelulares. Em P. superbus esta estrutura pode representar uma
especialização da parede celular, relacionada com adesão e mecanismos de transporte entre células.

Key words - Paepalanthus superbus, ultrastructure, intercellular protuberance, leaf, Eriocaulaceae

Introduction

Intercellular pectin protuberances of varying
morphological patterns are of widespread occur-
rence in different taxa and plant tissues (Carlquist
1956, Carr & Carr 1975, Parameswaran 1976,
Heide-Jrgensen 1978, Potgieter & van Wyk 1992,
Machado & Sajo 1996). Although certain morpho-
logical aspects of the intercellular projections on
mesophyll cell walls are relatively well documented
(Potgieter & van Wyk 1992), there are controversies
over the cell wall protuberances concerning their

origin, chemical composition, and biological func-
tions. Some authors believe that these structures are
produced only as a mechanical consequence of inter-
cellular space development, with no obvious func-
tion (Parameswaran 1976, Carr & Carr 1975,
Heide-Jrgensen 1978). Others believe that they are
formed by secretion through submicroscopic “wall
pores” after the formation of the intercellular spaces
(Carr & Carr 1975). Progress have been made on the
ultrastructural and chemical aspects of the protuber-
ances that develop on the surfaces of the callus cells
(Davies & Lewis 1981) and on embryoid cell sur-
faces (Dubois et al. 1991, 1992, Verdus et al. 1993).
Ultrastructural and histochemical studies have
shown extracellular accumulations of oil drops in the
projections developed on the surface of wound callus
cells of Daucus carota (Davies & Lewis 1981) and
extracellular secretion of lipo-glyco-protein with tu-
bular structure on the cell surfaces of the Cichorium
mesophyll proembryoides (Verdus et al 1993).

Paepalanthus superbus is a herbaceous plant
that grows on rocky soils of the Brazilian vegetation
called “campos rupestres”, which literally means

Revta brasil. Bot., São Paulo, V.23, n.4, p.451-457, dez. 2000

1. Departamento de Botânica, Instituto de Biociências, Uni-
versidade Estadual Paulista, Câmpus de Botucatu, Caixa
Postal 510, 18618-000 Botucatu, SP, Brazil.

2. Departamento de Botânica, Instituto de Biociências, Uni-
versidade de São Paulo, Caixa Postal 11461, 05422-970
São Paulo, SP, Brazil.

3. Centro de Microscopia Eletrônica, Instituto de Biociências,
Universidade Estadual Paulista, Campus de Botucatu, SP,
Caixa Postal 510, 18618-000 Botucatu, SP, Brazil.

4. Corresponding author: botanica@ibb.unesp.br



stone fields. Plants from “campos rupestres” are
adapted to high light intensities, temporary damp
substrate, periods of water deficit, and low nutri-
tional and pH levels (Giulietti & Pirani 1988).

In this paper, the occurrence and ultrastructural
aspects of the intercellular protuberances in P.
superbus leaves are described.

Material and methods

Mature leaves were obtained from plants of P. superbus
growing in the greenhouse of the Departamento de Botânica,
Instituto de Biociências, Universidade de São Paulo, Brazil.

Samples from the median region of these leaves were fixed
in 2.5% glutaraldehyde, post-fixed in 1% osmium tetroxide, and
embedded in Araldite resin. Ultra-thin sections were double
stained with uranyl acetate and lead citrate, and examined with a
transmission electron microscope (TEM). For the histochemical
tests, freehand sections of fresh material were treated with ruthe-
nium red for pectic material and sudan black B and sudan IV for
the detection of lipids (Jensen 1962) and examined under a light
microscope.

Results

In P. superbus the epidermis is uniseriate and
the mesophyll is composed of irregularly spaced
parenchyma cells. Pronounced protuberances are ob-
served both on the surface of the inner periclinal
walls of the epidermal cell and on the parenchyma
mesophyll cell surfaces (figure 1). In both tissues,
these structures project into the intercellular spaces
and fill the space between adjacent cells (figures
1-3). So, the apparent fusion of the deposits forms
bridges across the intercellular space (figures 2 and
3). The histochemical test with ruthenium was posi-
tive, indicating the pectic nature of the deposited
material.

The surface of many parenchyma cells seems to
be frequently covered with masses of electron-lucent
material forming a gel capsule-like structure (figure
4). There is a margin outlining the protuberances,
with distinct organisation and electron-density (fig-
ures 2, 4). At higher magnifications, the protuber-
ance is seen to be composed of a finely
electron-dense fibrillar network matrix (figure 7)
with scattered short tubular and fimbriate structures
(figure 6). Both the tubular and the fimbriate struc-
tures seem to be attached to the outside of the cell

wall (figure 5) and to the protuberance margin (fi-
gure 6).

There are regions along the margin of the pro-
tuberances with a narrow electron-lucent line at the
interface of the adjoining protuberances (figures 8
and 9). The deposits connecting adjacent cells show
a convoluted margin of electron-dense material out-
lined by a trilamelate membrane-like structure (fi-
gure 9).

Frequently, the cells with conspicuous intercel-
lular deposits show a large spherical nucleus, dense
ribosomal content, plastids with starch and lipidic
globules, numerous peroxisomes with a paracris-
talline zone, mitochondria with prominent cristae,
and electron-dense inclusions (figure 10).

Drops or clumps of strongly electron-dense ma-
terial are seen adjacent to the outer side of the cell
wall (figures 2-4, 11 and 12), scattered in the fibrillar
matrix (figure 4) or accumulated on the margin of the
intercellular protuberance (figure 3). Histochemical
tests revealed the lipophilic nature of these materials,
as shown by sudan IV and sudan black B reactions.

Parenchyma cells bearing large protuberances
show numerous plasmodesmata with prominent
pore channel on the outside of the cell wall, as seen
in tangential sections (figure 12). These plasmode-
mata are intact and show plasma membrane, des-
motubule, and well-preserved central rod (figure
13).

Discussion

The ultrastructural features of the intercellular
protuberances in P. suberbus leaves are similar to
those described on the surface cells of proembryoids
by Verdus et al. (1993). Histochemical tests detected
pectic and lipophilic components in the protuber-
ances. The pectic substances are the major constitu-
ents of the intercellular protuberances, as detected by
ruthenium red. These substances, which are of con-
siderable importance both for their biological func-
tions and technological exploitation, form gels under
conditions of extensive hydration (Morris et al.
1982).

Mesophyll parenchyma cells bearing conspicu-
ous deposits usually showed ultrastructural features
indicative of secretory activity. Our observations
suggest that the occurrence of secretory activity is

452 S.R. Machado et al.: Intercellular protuberances in P. superbus leaves



Revta brasil. Bot., São Paulo, V.23, n.4, p.451-457, dez.. 2000 453

Figures 1-4. TEM of Paepalanthus superbus leaf. 1. Transversal section. Epidermal cell (e); parenchyma cells (pc). The arrowheads
indicate the extracellular deposits. Bar = 4 µm. 2. Protuberances connecting adjacent parenchyma cells with structured electron-dense
margins (arrow) and clumps of dense material (arrowhead) near the cell wall (W). Bar = 1 µm. 3. Clumps of electron-dense material
(arrowheads) adjacent to the margin protuberance. Bar = 1 µm. 4. Pronounced intercellular protuberance showing a finely electron-dense
fibrillar matrix and distinct structured margins (arrow). Note clumps of dense material attached to the outer side of the cell wall (W)
surface or scattered throughout the fibrillar matrix (arrowhead). Bar = 0.5 µm.



associated with the production and excretion of some
components of the intercellular deposits, as de-
scribed by Davies & Lewis (1981). Extracellular
accumulation of oil droplets in the projections was
observed by Davies & Lewis (1981) on the surface

of wound callus cells of Daucus carota. According
to these authors, the oil deposits may play a role in
cell adhesion, suberization, or plant defence against
pathogen infection.

454 S.R. Machado et al.: Intercellular protuberances in P. superbus leaves

Figures 5-9. TEM of Paepalanthus superbus leaf. 5. Tubular structures (arrows) into the dense material attached to the outer side of the
cell wall (W). Bar = 1.0 µm. 6. Protuberance lateral margin showing tubular and fimbriate structures (arrows). Bar = 0.1 µm. 7. Detail
of the deposit with scattered short tubular and fimbriate structures. Bar = 0.2 µm. 8. Electron-dense margins of adjacent cells.
Bar = 0.2 µm. 9. Convoluted protuberance margin with an electron-lucent line (arrow) connecting adjacent cells. Bar = 0.2 µm.



A membrane-like structure outlining the inter-
cellular protuberance was also observed by Davies
& Lewis (1981). This membrane may be similar to
the internal cuticle observed by Heide-Jrgensen
(1978), outlining the intercellular pectic strands of
the xeromorphic mesophyll leaves of Hakea
suaveolens. Internal cuticles have been seen in sev-

eral species with large exposed surface area of
chlorenchyma cells, being related with lower tran-
spiration rates (Cutler 1966).

The presence of intact plasmodesmata in the
parenchyma cells connected by the protuberances
can be related to the symplastic movement of ions
between adjacent cells (Carr et al. 1980), the secre-

Figures 10-13. TEM of Paepalanthus superbus leaf. 10. Parenchyma cell with intercellular protuberance (arrow); plastid (p),
mitochondria (m), peroxisomes (pe). Bar = 0.2 µm. 11. Clumps of electron-dense material adjacent to the cell wall surface. Bar = 0.2
µm. 12. Tangential section of the parenchyma cell wall showing plasmodesmata (arrowheads). The arrow indicates a clump of
electron-dense material scattered throughout the fibrillar matrix of the protuberance. Bar = 0.2 µm. 13. Detail of the parenchyma cell
wall showing plasmodesmata with prominent pore channels. The arrowhead indicates a desmotubule. Bar = 0.1 µm.

Revta brasil. Bot., São Paulo, V.23, n.4, p.451-457, dez. 2000 455



tion of extracellular materials, and the transcellular
distribution of cytoskeleton, as observed by Zhang
et al. (1998) in endosperm cells of Triticum aestivum.
Prominent plasmodesmata were also observed by
Konar et al. (1972) in the thick-walled embryogenic
cells of Ranunculus sceleratus. Remains of stretched
plasmodesmata were observed on the anticlinal
walls of palisade cells by Heide-Jørgensen (1978).
These broken plasmodesmata were interpreted by
the author as a result of the middle lamella separation
during the projection development. Our observa-
tions indicate that intercellular protuberances in P.
superbus are formed by secretion of materials
through plasmodesmata after the development of
intercellular spaces, according to Schenck hypothe-
sis (see Carr & Carr 1975).

Although protein histochemical tests have not
been performed in P. superbus, ultrastructural analy-
sis of the intercellular deposits revealed fibrillar and
tubular structures similar to those described by Ver-
dus et al. (1993). Histochemical reactions performed
by these authors revealed a lipo-glyco-protein of
tubular structure.

The occurrence of glycoproteins and other re-
lated proteins in cell walls and extracellular fluids
are widely documented in several plant species.
These proteins have been related with cell adhesion
and recognition, wound healing, and plant defence
(Showalter 1993). In addition, some structural pro-
teins are located in the middle lamella and intercel-
lular spaces of the cortex, and may act as a cement
to these cells (Keller 1993). According to Ruoslahti
& Pierschbacher (1987), this intercellular deposits
may show similarity to animal cells, where surface
glycoproteins of the extracellular matrix play a role
in adhesion and recognition, being linked to the
cytoskeleton.

Possible biological functions of the intercellular
protuberances in P. superbus leaves may be sug-
gested. So, the apparent fusion of the protuberances
to form bridges across the intercellular space sug-
gests an involvement of these structures in cell to cell
adhesion (Davis & Lewis 1981). Also, if the projec-
tions connect adjacent cells, they may facilitate the
lateral water transport in the mesophyll (Heide-
Jrgensen 1978) and/or provide a pathway of ionic
movement, particularly that of potassium ions, from
cell to cell (Carr et al. 1980). The hydrophilic prop-

erties of pectic substances and their gelation behav-
iour (Morris et al. 1982) also suggest that the protu-
berances may play a role in the hydration of cell
walls (Machado & Sajo 1996) and in the mainte-
nance of the structural tissue integrity (Morris et al.
1982). The lipophilic components of the protuber-
ances may have a role in cell adhesion, suberization,
and plant defence (Cutler 1966, Davis & Lewis
1981).

In conclusion, the presence of these intercellular
protuberances around the parenchyma cells of P.
superbus leaves could be an important cell speciali-
sation for the survival in adverse environments.
However, further studies on a larger number of
plants of this environment are necessary to deter-
mine if this structure occurs in other species.

Acknowledgements - We thank the Centro de Microscopia Ele-
trônica, IBB, UNESP, Campus de Botucatu for the technical
assistance, and to Dr. Ana Maria Benko Iseppon for the species
identification.

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