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Acta Bot. Croat. 70 (1), 109–114, 2011 CODEN: ABCRA 25
ISSN 0365–0588

Achene slime content in some taxa of

Matricaria L. (Asteraceae)

HUSEYIN INCEER*

Karadeniz Technical University, Faculty of Science, Department of Biology, 61080
Trabzon, Turkey

Abstract – The achenes of Matricaria aurea and two varieties of M. chamomilla (var.
chamomilla and var. recutita) have slime cells on the surface and they are characterized by
slime envelope formation during hydration. The slime in these taxa is composed of
pectins and cellulose. The slime could play important role in the distribution and colonis-
ation of new habitats in Matricaria taxa.

Key words: achene, slime, cellulose, pectin, Matricaria

Introduction

Matricaria L. is a small genus of the tribe Anthemideae with 6 species and mostly dis-
tributed in Europe, northern Africa, Macaronesia, western, south-western and central Asia,
western North America (OBERPRIELER et al. 2007). The wide range of geographical distri-
butions and the diversity of habitats such as disturbed meadows, vacant lots, areas along
roads and railroads, waste and dry areas in which Matricaria occurs may result in different
adaptations to diverse environments.

The taxonomy of Matricaria is controversial and very confused. Depending on the au-
thors, several species are classified in either Matricaria or Tripleurospermum. Therefore,
they have been confused with each other, both taxonomically and nomenclaturally (JEFFREY
1979, XIFREDA 1985, KERGUÉLEN et al. 1987, POBEDIMOVA 1995, APPLEQUIST 2002).

Achene morphology has been demonstrated to be paramount importance for the taxon-
omy of these genera (KYNO^LOVA 1970). Matricaria is characterized by achenes that are
obovoid-oblong, circular to sligthly dorsiventrally flattened in the cross-section, with 3–5
adaxially arranged thin ribs that are sometimes furnished with longitudinal resin canals and
are covered with myxogenic (slime, mucilage producing) cells mainly on their abaxial sur-

ACTA BOT. CROAT. 70 (1), 2011 109

* Corresponding address, e-mail: inceer@ktu.edu.tr
Copyright

®
2011 by Acta Botanica Croatica, the Faculty of Science, University of Zagreb. All rights reserved.

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face and on the adaxial ribs (OBERPRIELER et al. 2007). However, the slime content of the
achenes in the genus has not been studied so far. The aim of this study has been to examine
the slime characteristics of the achenes.

Materials and methods

Plant material

The mature achenes of Matricaria aurea, M. chamomilla var. chamomilla and M.
chamomilla var. recutita were collected from a native environment (Tab. 1). Plant vouchers
have been deposited in the herbarium of Karedeniz Technical University Biology (KTUB)
or H. Inceer collections.

Slime identification by chemical reactions

The behaviour of the fruit after wetting was observed and tests on the ability of its coat to
hydrate were performed. Wetting experiments, with tap water, were performed at room tem-
perature for 1–5 min, which was sufficient for the achenes to hydrate (KREITSCHITZ et al.
2009). Methylene blue and safranine staining were carried out to identify the slime type. The
images were taken using Leica DM 4000 microscope and a Leica DFC 490 digital camera.

Results

The wetting experiments show that slime cells on the surface of the pericarp produce
mucilage after which the achenes are surrounded by a slime envelope. The slime is a dis-
tinct gel-like envelope. It belongs to a cellulosic type representing a heterogenous system.
Staining with methylene blue and safranine dyes demonstrate that the Matricaria slime
consists of a pectinous matrix and a cellulosic skeleton (Fig. 1).

Methylene blue and safranine staining showed a characteristic pattern. Methylene blue
revealed a very faint blue envelope around the achene while an orange-red coloration of the
slime was obtained with safranine (Fig. 1). Staining produced almost the same colour in
both pectin and cellulose. Cellulosic threads or fibrils forming a characteristic radical skel-
eton around the achene were clearly visible, whereas the pectin color was spread homo-
genously within the envelope.

110 ACTA BOT. CROAT. 70 (1), 2011

INCEER H.

Tab. 1. The origin of the materials studied

Taxon Locality Voucher

Matricaria aurea

(Loefl.) Sch. Bip.
C6 Gaziantep/Sanlýurfa: Between Nizip and Birecik, Dutlu,
roadsides, near cultivated area, 440 m a.s.l., 08.v. 2007.

Inceer 322

M. chamomilla L.var.
chamomilla

C1 Muðla: Marmaris, between Marmaris and Köyceðiz,
roadsides, 20 m a.s.l., 18. iv. 2007.

Inceer 305

M. chamomilla L. var.
recutita (L.) Fiori

C1 Muðla: Marmaris, between Kizilkaya and Fethiye,
roadsides, 24 m a.s.l., 18. iv. 2007.

Inceer 307

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Discussion

The results obtained from micro-staining reactions demonstrated that the Matricaria
slime is of the cellulosic type, consisting of two components i.e., pectin and cellulose. This
is the first report on the slime structure of Matricaria. The staining results correspond to al-
ready published data in Artemisia and Eragrostis (BRODA 1971, GERLACH 1972, BRAUNE et
al. 1975, O' BRIEN and MCCULLY 1981, KREITSCHITZ and VALLÈS 2007, KREITSCHITZ et. al.
2009, Tab. 2). In the literature, the presence of slime has been reported for many other an-
giosperm genera, e.g. in Brassica, Salvia, Plantago, Linum, Anthemis, Artemisia and
Matricaria (MUHLETHALER 1950, YOUNG and EVANS 1973, GRUBERT 1974, GRUBERT 1982,
KREITSCHITZ and VALLÈS 2007). The cells producing slime could be arranged in isolated
rows on the fruit surface, as in Anthemis, Artemisia and Matricaria (GRUBERT 1974). In ad-
dition, GRUBERT (1982) emphasized that proper epidermal cells of the pericarp have pro-
duced the slime in M. chamomilla. The present results confirm that slime cells on the sur-
face of the pericarp produce the slime.

ACTA BOT. CROAT. 70 (1), 2011 111

ACHENE SLIME CONTENT IN MATRICARIA

Fig. 1. Slime envelope in the achenes of Matricaria. A-B – M. aurea (methylene blue). C – M. aurea
(safranine). D-F – M. chamomilla var. chamomilla (disc, methylene blue). G – M. chamomilla
var. chamomilla (disc, safranine). H – M. chamomilla var. chamomilla (ray, methylene blue).
I-K – M. chamomilla var. recutita (methylene blue). L – M. chamomilla var. recutita (safranine).
Arrow with a line indicates slime cell, arrow with two lines indicates pappus, arrow with three
lines indicates cellulose threads.

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The relative amount of slime is different in the studied taxa (Fig. 1). Differences in slime
production can result from habitat diversity of the taxa. Such a relationship was reported in
Lamiaceae (MOSQUERO et al. 2004). The achene of M. aurea growing in particularly dry hab-
itats has higher amounts of slime in the envelope than the other taxa. High slime production
in the achene may be an advantageous adaptive feature faciliating germination.

The functional significance of the slime in seeds and/or fruits has been reported in many
works. It plays an important role in the control of germination, mostly in plants that grow in
conditions of water deficiency in arid and semiarid environments, thus facilitating intake
and maintenance of the water (KREITSCHITZ and VALLÈS 2007). Furthermore, it can delay
germination due to impeded penetration by oxygen. Slime helps in fruit or seed dispersal
and in the defence against pathogens (FAHN and WERKER 1972, KOROBKOV 1973, YOUNG
and EVANS 1973, YOUNG and MARTENS 1991, HUANG and GUTTERMAN 1999, HUANG et al.
2000). Matricaria chamomilla var. chamomilla and var. recutita, which are the most wide-
spread taxa of the genus, occur in diverse habitats such as dry and wet environments,
roadsides, field margins and ruderal places as a weed. Matricaria aurea also grows on
limestone deposits, sand, saline land, flood-plain meadows with stony soil, sometimes as a
weed. It is assumed that the presence of slime cells on the surface of the achenes could play
an important role in the dispersal and competitive ability of these taxa.

In some particular cases, production of slime on the fruit and or seed surface may also
be an adaptation to ruderal, disturbed environments (YOUNG and EVANS 1973, KREITSCHITZ
and VALLÈS 2007). The presence of a slime envelope is associated with a short life cycle
and facilitates the quick colonization of such places (KREITSCHITZ and VALLÈS 2007). This
study confirmed this kind of adaptation in Matricaria, which is an annual. Similar adaptive
mechanisms are present in many common annual weeds colonizing ruderal habitats, e.g.
Lepidium flavum, L. nitidum, Plantago lanceolata, Cardaria draba (YOUNG and EVANS
1973) Arabidopsis thaliana (WESTERN et al. 2000) and Artemisia annua, A. biennis and
Neopallasia pectinata (KREITSCHITZ and VALLÈS 2007).

Acknowledgements

The author thanks Dr. Faik Ahmet Ayaz, Dr. Melahat Ozcan and Murat Bal for collecting
plant materials, Nursen Aksu for technical assistance, the Scientific and Technical Research

112 ACTA BOT. CROAT. 70 (1), 2011

INCEER H.

Tab. 2. Slime staining in Artemisia and Eragrostis species

Staining Target Obtained color Literature data References

Methylene
blue

Pectin
Cellulose

Blue
Violet-blue

Blue
Violet, blue

GERLACH (1972)
BRODA (1971 in KREITSCHITZ and
VALLÈS 2007)

Safranine Cellulose
Pectin

Orange
Orange-red

Orange-red
Red,
orange-red
Orange

BRAUNE et al. (1975), O’BRIEN and
MCCULLY (1981), KREITSCHITZ et al. (2009)
KREITSCHITZ and VALLÈS (2007)
KREITSCHITZ et al. (2009)

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Council of Turkey (TUBITAK, TBAG Project No. 106T162) for financial support. We thank
the two anonymous referees for providing helpful suggestions to improve the manuscript.

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