candollea
Journal international de botanique systématique
Helictochloa Romero Zarco (Poaceae),
a new genus of oat grass
Carlos Romero-Zarco
12 juillet 2011
66
(1)
1
Helictochloa Romero Zarco (Poaceae),
a new genus of oat grass
Carlos Romero-Zarco
Abstract
Résumé
ROMERO-ZARCO, C. (2011). Helictochloa Romero Zarco (Poaceae), a new
genus of oat grass. Candollea 66: 87-103. In English, English and French
abstracts.
ROMERO-ZARCO, C. (2011). Helictochloa Romero Zarco (Poaceae), un
nouveau genre d’avoine. Candollea 66: 87-103. En anglais, résumés anglais
et français.
Morphological and anatomical characters used to separate the
genera related to Avena L. (Poaceae: Aveneae) are analyzed.
The taxonomic importance of these characters is discussed
with regard to recent molecular studies. Six genera of perennial oats are recognized: Arrhenatherum P. Beauv., Pseudarrhenatherum Rouy, Helictotrichon Besser, Avenula (Dumort.)
Dumort., Tricholemma (Röser) Röser and Helictochloa Romero
Zarco (described here) is accepted. New combinations for the
species included in Helictochloa are proposed. A key to Avena
related genera from the Mediterranean region is given.
Les principaux caractères morphologiques et anatomiques
sont présentés ici et utilisés pour servir à la délimitation des
taxons les plus proches du genre Avena L. (Poaceae: Aveneae).
L’importance taxonomique de ces caractères est discutée selon
des études moléculaires récentes. Six genres d’avoines vivaces
sont ainsi distingués: Arrhenatherum P. Beauv., Pseudarrhenatherum Rouy, Helictotrichon Besser, Avenula (Dumort.)
Dumort., Tricholemma (Röser) Röser et Helictochloa Romero
Zarco (décrit ici). Plusieurs nouvelles combinaisons pour les
espèces incluses dans Helictochloa sont établies. Une clé de
détermination est aussi donnée pour séparer les genres proches
d’Avena pour la région méditerranéenne.
Key-words
POACEAE – Avena – Arrhenatherum – Pseudarrhenatherum
– Avenula – Helictochloa – Tricholemma – Helictotrichon –
Oat grasses – Taxonomy
Address of the author: Departamento de Biología Vegetal y Ecología, apdo 1095, 41080-Sevilla, Spain.
Email: zarco@us.es
Submitted on April 20, 2009. Accepted on February 17, 2011.
ISSN : 0373-2967
Candollea 66(1) : 87-103 (2011)
Edited by P. Bungener
© CONSERVATOIRE ET JARDIN BOTANIQUES DE GENÈVE 2011
88 – Candollea 66, 2011
Introduction
This article is especially focused on the so called “perennial
oats” (GERVAIS, 1973), that is, Avenula (Dumort.) Dumort. plus
Helictotrichon Besser (Poaceae: Aveneae), a group that has been
circumscribed as a single genus (HOLUB, 1958; RÖSER, 1989,
among others) or two (HOLUB, 1962; GERVAIS, 1973; KERGUÉLEN,
1975; ROMERO-ZARCO, 1984a, 1984b) or four genera (RÖSER
& al., 2009). Nevertheless, it is also necessary to discuss
their phylogenetic relationships with Avena L., Arrhenatherum
P. Beauv. and Pseudarrhenatherum Rouy at the light of recent
molecular studies (RÖSER & al., 2001; GREBENSTEIN & al., 1995,
1998; RODIONOV & al., 2005; QUINTANAR & al., 2007; SORENG
& al., 2007; WINTERFELD & RÖSER, 2007; SCHNEIDER & al.,
2009; WINTERFELD & al., 2009).
“Oats grasses” is used here as the appropriate common
name for species belonging to Avena, Helictotrichon, Avenula,
Arrhenatherum and Pseudarrhenatherum. Other genera with
nomenclatural relations with Avena or Helictotrichon, such
as Amphibromus Nees, Danthoniastrum (Holub) Holub,
Gaudinia P. Beauv., Ventenata Koeler, Deschampsia P. Beauv.,
Avenella Parl., and Trisetum Pers., etc. are not considered here,
as they do not pose taxonomic problems in relation to the limits of the genus Avena. The aim of this article is to ascertain
relationships among oat grasses. For this purpose anatomical
and morphological characters are summarized and discussed.
Consequently, a taxonomic scheme for oat grasses is here
established, accepting in general the monophyletic lineages
suggested by molecular studies and supported by anatomical,
morphological and biogeographical evidence.
GREBENSTEIN & al. (1995), using highly repeated satellite
DNA as a molecular marker, found differences between
Helictotrichon s.s. and the remaining species investigated.
A second study (GREBENSTEIN & al., 1998) concludes that
Helictotrichon s.l. is paraphyletic, if not polyphyletic according to ITS1 and ITS2 rDNA sequence analysis. Further
evidence from physical mapping of 5S rDNA (RÖSER & al.,
2001) and from plastid ‘trnT-F’ and nuclear ITS sequences
(QUINTANAR & al., 2007) strongly suggest that the large genus
Helictotrichon is paraphyletic or polyphyletic.
The anatomical characteristics of leaf blade in transverse
section have been intensely investigated and used in the
taxonomy of the group (D UVAL -J OUVE , 1863 ; P OTZTAL ,
1951). It has been of special importance for the separation
of Avenula with respect to Helictotrichon (H OLUB , 1962 ;
GERVAIS, 1973; KERGUÉLEN, 1975; ROMERO-ZARCO, 1984b).
Nevertheless, molecular studies suggest that Avenula is polyphyletic (G REBENSTEIN & al., 1998 ; R ÖSER & al., 2001 ;
QUINTANAR & al., 2007). A taxonomic consequence is the
description of the monospecific genus Homalotrichon
Banfi, Galasso & Bracchi (CONTI & al., 2005) including
H. pubescens (Hudson) Banfi, Galasso & Bracchi ( Avenula
pubescens (Hudson) Dumort. Avena pubescens Hudson,
see below). This implies that the conduplicated leaf blades
structure, a diagnostic character for the genus, could have
evolved independently in three lineages. In order to investigate this possibility, the anatomical structure of blades were
re-examined in more detail in A. pubescens (placed by recent
molecular analyses in an isolated position near Arctagrostis
Griseb. or Milium L.; see Q UINTANAR & al., 2007), and
Avenula pratensis (L.) Dumort., with strong affinity with the
rest of European Avenula species, both clearly separated with
respect to Helictotrichon and other Aveneae genera (GREBENSTEIN & al., 1998; RÖSER & al., 2001).
Material and methods
Approximately 2600 sheets (herbarium specimens) were
examined for this study. Leaf blade cross-sections from
sterile innovations were obtained from nearly 260 samples,
following methods in S AINT-Y VES (1931) and anatomical
techniques described in previous papers (ROMERO-ZARCO,
1984b, 1985b). Several root samples of different diameters
were removed for study from one year old plants grown in
pots. For each species lodicules were observed in 10 or more
florets from at least three populations when possible. Two
or three dried mature caryopses samples were studied in
selected species. The caryopses were softened in fresh water
during six hours and then embryos were dissected using an
entomological needle and placed in 50% lactic acid. Most
of the studied specimens belong to the main collection of
the Servicio General de Herbarios de la Universidad de
Sevilla (SEV). Vouchers cited in the figures are listed in table
1. Nomenclature used in the next section follows ROMEROZARCO (1984a, 1984b, 1985a, 1985c, 1993).
Results and discussion
Root anatomy (Fig. 1)
The presence of a ring of sclerenchyma around endodermis in several European species of Helictotrichon and in
Pseudarrhenatherum longifolium (Thore) Rouy was shown by
GERVAIS (1968). This periendodermic ring does not appear in
Avena species, Arrhenatherum elatius (L.) J. Presl & C. Presl,
nor in Avenula species. A similar ring was described later in
the roots of Pseudarrhenatherum pallens (Link) Holub by
ROMERO-ZARCO (1985c). In order to complete the data, this
character was investigated in Arrhenatherum album (Vahl)
W. D. Clayton and, for comparison, in Pseudarrhenatherum
pallens and Avenula hackelii (Henriq.) Holub. The results
obtained here are in agreement with those contributed by
GERVAIS (1968, 1973) and by RÖSER (1989). The studied
species of Arrhenatherum and Avenula lack a sclerenchymatic
ring, whereas this ring is present in Pseudarrhenatherum.
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 89
Table 1. – Material cited in the figures. Nomenclature according to ROMERO-ZARCO (1984a, 1984b, 1985a, 1985c, 1993).
Taxa
Arrhenatherum album var. erianthum (Boiss.) Romero Zarco
Arrhenatherum elatius (L.) J. Presl & C. Presl subsp. elatius
Arrhenatherum elatius subsp. baeticum Romero Zarco
Avenula hackelii (Enriq.) Holub
Avenula bromoides (Gouan) H. Scholz subsp. bromoides
Avenula bromoides subsp. pauneroi Romero Zarco
Avenula gervaisii Holub subsp. gervaisii
Avenula marginata (Lowe) Holub var. marginata
Avenula pratensis subsp. iberica (St.-Yves) O. Bolòs & Vigo
Avenula pubescens (Hudson) Dumort.
Helictotrichon cantabricum (Lag.) Gervais
Helictotrichon sarracenorum (Gand.) Holub
Helictotrichon sedenense (DC.) Holub subsp. sedenense
Pseudarrhenatherum longifolium (Thore) Holub
Pseudarrhenatherum pallens (Link) Holub
A
Locations
Spain. Córdoba, entre Torrecampo y Santa
Eufemia, 8.VI.1978
Spain. Ávila, Circo de Gredos, 27.VII.1978
Spain. Jaén, Valdepeñas de Jaén, 18.VI.1979
Portugal. Bajo Alentejo, Vila Nova de Milfontes
[pinares de P. pinaster junto al camping], 17.IV.1981
Spain. Burgos, entre Pancorvo y Bujedo, 16.VII.1980
Spain. Jaén, Sierra de Cazorla, Nava de San Pedro,
23.VI.1980
Spain. Málaga, entre Archidona y Salinas, 17.VI.1980
Spain. Asturias, Puerto de Tarnas, 12.VII.1980
Spain. Jaén, Sierra del Pozo, pico Cabañas, 24.VI.1980
Spain. Huesca, entre Aínsa y Campó, 21.VII.1980
Spain. Burgos, entre Soncillos y Cubillos del Rojo, 16.VII.1980
Spain. Palencia, San Martín de Valdeiglesias, 10.VIII.1982
Spain. Huesca, Puente la Reina de Jaca, 25.VIII.1981
Spain. Granada, Sierra Nevada, Fuente de San Jerónimo,
26.VI.1980
Spain. León, Valverde de la Sierra, Pico Espiguete,
14.VIII.1975
Spain. Huesca, Sallent de Gállego, El Respumoso,
9.VIII.1980
Spain. Cádiz, Algeciras, Sierra de Ojén, 4.VII.1981
Portugal. Estremadura, Setúbal, Sierra de Arrábida,
28.IV.1981
Vouchers
E. F. Galiano & A. Ramos
(SEV 78472)
J. A. Devesa & al. (SEV 78612)
M. J. Díez & al. (SEV 78626)
C. Romero-Zarco (SEV 86752)
J. A. Devesa & al. (SEV 77484)
J. A. Devesa & al. (SEV 77506)
J. A. Devesa & al. (SEV 86683)
J. A. Devesa & al. (SEV 79499)
J. A. Devesa & al. (SEV 77590)
J. A. Devesa & al. (SEV 77573)
J. A. Devesa & al. (SEV 86747)
P. Montserrat (SEV 86748)
J. A. Devesa & al. (SEV 77605)
J. A. Devesa & al. (SEV 86651)
P. Montserrat & L. Villar (SEV 77616)
P. Montserrat & L. Villar (SEV 77613)
J. Arroyo & al. (SEV 66721)
J. A. Devesa & C. Romero-Zarco
(SEV 86754)
B
Fig. 1. – Root anatomy in cross-sections stained with safranin. A. Avenula hackelii (Henriq.) Holub (SEV [86752]) ; B. Pseudarrhenatherum pallens (Link) Holub (SEV [86754]).
[en = endodermis ; sc = periendodermic sclerenchyma].
[Bar = 0.2 mm]
90 – Candollea 66, 2011
In Arrhenatherum album and Avenula hackelii (Fig. 1A)
the endodermis is composed of approximately square cells,
almost totally plugged by deposits of suberin, with a small
lumen next to the outer wall. The sclerification of cortex cells
was not observed. On the contrary in Pseudarrhenatherum
pallens (Fig. 1B) the endodermis is formed by cells extended
radially, with an inner ‘V’-shaped suberin deposit leaving a
lumen half as large as the cutting surface. A two to three row
layer of sclerenchyma cells are observed around the endodermis. As asserted in GERVAIS (1973) the endodermis of Pseudarrhenatherum is different from those of Arrhenatherum, Avenula
and Helictotrichon.
Leaf blade anatomy (Fig. 2)
Details of sclerenchyma girders and the arrangement of the
chlorenchyma are shown in figure 2 for Avenula pratensis
subsp. iberica (St.-Yves) O. Bolòs & Vigo and A. pubescens.
In Avenula pratensis subsp. iberica, the subepidermal strands
of sclerenchyma are substantially thinner than the marginal
ones, and some of them are connected to the vascular strand
forming thin, ‘I’-shaped girders. In A. pubescens the marginal
strands are less developed and the subepidermal strands of sclerenchyma are very robust, even more than the marginal ones,
forming rounded girders with main lateral vascular strands.
The differentiation of a palisade chlorenchyma is observed in
Avenula pratensis subsp. iberica, whereas in A. pubescens all
chlorenchyma cells are nearly isodiametric. Other Avenula taxa
have palisade chlorenchyma (LÓPEZ & DEVESA, 1991) and
girders, when present, are ‘I’-shaped (GERVAIS, 1973; ROMEROZARCO, 1984b; RÖSER, 1989).
Morphology of lodicules (Fig. 3)
The morphological characteristics of lodicules in Arrhenatherum elatius subsp. baeticum Romero Zarco, Pseudarrhenatherum pallens, Helictotrichon sarracenorum (Gand.) Holub,
H. sedenense (DC.) Holub subsp. sedenense, Avenula bromoides
subsp. pauneroi Romero Zarco and A. pubescens are summarized in figure 3. Avenula pubescens differs remarkably from the
others by having shorter (< 1 mm) and irregularly lobed lodicules (see also ROMERO-ZARCO, 1984b: Fig. 5; RÖSER, 1989:
Fig. 8). The remaining species have longer lodicules (> 1 mm),
with a lanceolate membranous portion, with or without a
Fig. 2. – Leaf blade cross-sections from sterile innovations, stained with safranin. A-B. Avenula pratensis subsp. iberica (St.-Yves) O. Bolòs & Vigo (SEV [77590]) ; C-D. Avenula
pubescens (Hudson) Dumort. (SEV [86747]). [bc = bulliform cells, ms = marginal sclerenchyma, nr = nerve region, sg = sclerenchyma girders, vb = vascular bundle].
[Bars = 0.2 mm]
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 91
Fig. 3. – Morphology of the lodicules in perennial oat grasses. A. Arrhenatherum elatius subsp. baeticum Romero Zarco (SEV [78626]) ; B. Pseudarrhenatherum pallens (Link)
Holub (SEV [86754]) ; C. Helictotrichon sarracenorum (Gand.) Holub (SEV [86651]) ; D. Helictotrichon sedenense (DC.) Holub subsp. sedenense (SEV [77616]) ; E. Avenula
bromoides subsp. pauneroi Romero Zarco (SEV [77506]) ; F. Avenula pubescens (Hudson) Dumort. (SEV [86747]).
[Bar = 0.5 mm]
lateral lobe or tooth. In all Arrhenatherum taxa investigated,
the presence of a lateral lobe or tooth is a variable character,
even between the basal and apical floret within the same
spikelet (ROMERO-ZARCO, 1985a). This character is less variable in species of Pseudarrhenatherum, Helictotrichon s.s. and
Avenula. A lobe is always observed in most Eurasian Avenula
species (A. pubescens excluded); the lobe is located at or below
the middle on the lateral margin facing the palea, and its size
is variable. Pseudarrhenatherum and most Eurasian Helictotrichon taxa investigated have entire lodicules, with the
exception of H. sedenense subsp. sedenense, that has a small
lateral tooth in some cases (ROMERO-ZARCO, 1984a; RÖSER,
1989). Lodicules in Avena s.s. (BAUM, 1977; ROMERO-ZARCO,
1996) are similar to Helictotrichon, containing a lanceolate
membranous portion, and with or without a small (sometimes
tiny) lateral tooth.
Morphology of the embryos (Fig. 4)
Some differences between species were observed in
the morphology of epiblast. Several types of epiblasts have
been described in Avena, some with rounded apical margins
and others with more or less truncated margins (BAUM, 1977).
Figure 4 shows the morphology of embryos extracted from
mature caryopses of the following perennial oats: Arrhenatherum album var. erianthum (Boiss. & Reut.) Romero Zarco,
A. elatius subsp. elatius, Pseudarrhenatherum longifolium,
Helictotrichon sedenense subsp. sedenense, H. cantabricum
(Lag.) Gervais, Avenula pubescens, A. pratensis subsp. iberica, A. gervaisii Holub subsp. gervaisii, A. bromoides (Gouan)
H. Scholz subsp. bromoides and A. marginata (Lowe) Holub
var. marginata. Aside from the differences in size (probably
attributable to the size of the caryopsis itself), variations in two
characters are observed: the form of the epiblast and the apex
of the scutellum.
The combination of both characters allows us to define
three types of embryos in perennial oat grasses:
1. “Arrhenatherum” type, characteristic of this genus,
with rounded epiblast and scutellum.
2. “Helictotrichon” type, with truncated or somewhat
emarginated epiblast, and subobtuse or rounded scutellum, present in Helictotrichon, Pseudarrhenatherum
and Avenula pubescens.
3. “Avenula” type, with epiblast similar to the “Helictotrichon” type and scutellum with nipple-shaped
apex, present in most Avenula species (A. pubescens
excluded).
According to NEGBI & SARGENT (1986: 252, Fig. 7), the
scutellum of Avena fatua L. resembles the subobtuse one of
Helictotrichon sedenense subsp. sedenense (Fig. 4D).
92 – Candollea 66, 2011
A
F
B
C
G
D
H
E
I
J
Fig. 4. – Morphology of the embryos in perennial oat-grasses (frontal view). A. Arrhenatherum album var. erianthum (Boiss.) Romero Zarco (SEV [78472]) ; B. A. elatius (L.) J. Presl
& C. Presl subsp. elatius (SEV [78612]); C. Pseudarrhenatherum longifolium (Thore) Holub (SEV [66721]); D. Helictotrichon sedenense (DC.) Holub subsp. sedenense (SEV [77613]);
E. Helictotrichon cantabricum (Lag.) Gervais (SEV [77605]) ; F. Avenula pubescens (Hudson) Dumort. (SEV [86748]) ; G. Avenula pratensis subsp. iberica (St.-Yves) O. Bolòs &
Vigo (SEV [77573]) ; H. Avenula gervaisii Holub subsp. gervaisii (SEV [86683]) ; I. Avenula bromoides (Gouan) H. Scholz subsp. bromoides (SEV [77484]) ; J. Avenula marginata
(Lowe) Holub var. marginata (SEV [79499]). [sc = scutelum ; ep = epiblast].
[Drawn by author] [bar = 1mm]
Taxonomic treatment
1. Avena s.s.
Since the formal description of Avena by Linnaeus in
1753, many genera have been attributed to the tribe Aveneae.
In the last 100 years the main subject of discussion in the
taxonomy of Avena has focused on the separation of annual
species (Avena s.s.) with respect to perennial ones [Helictotrichon s.l., that is : including Avenula (H OLUB , 1958 ;
RÖSER, 1989), Arrhenatherum (POTZTAL, 1951), and Pseu -
darrhenatherum (RÖSER & al., 2009)]. The main stumbling
block has been the existence of Avena macrostachya Coss.
& Durieu, a perennial species, endemic to northwestern
Africa, that has spikelets similar to other annuals in the
genus. In the analysis of RÖSER & al. (2001), A. macrostachya appears as an isolated lineage, occupying a basal position with respect to Helictotrichon s.s. and not clustered with
A. sativa L. QUINTANAR & al. (2007) included eight annual
Avena species, and A. macrostachya is placed between two
Avena s.s. clades.
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 93
These two clades are well defined based on morphological features of the spikelets:
1. the species near A. ventricosa Coss. (see Avena sect.
Ventricosa Coss., ROMERO-ZARCO, 1996);
2. the remaining species (A. sativa, A. barbata Link, etc.).
Avena macrostachya is found in a similar position in
another phylogenetic tree (RODIONOV & al., 2005), although
sister to A. ventricosa group, and distantly related to A. sativa.
According to WINTERFELD & al. (2009) karyotype features
suggest that A. macrostachya is close to the C-genome species
of Avena (i.e. A. eriantha Durieu). These results support retaining A. macrostachya in Avena s.s., as proposed by BAUM (1968)
who based his conclusion on morphological and anatomical
characters (large glumes and sclerenchyma not present surrounding the endodermis in the root).
Avena L., Sp. Pl.: 79. 1753.
Lectotypus designated by BRITTON & BROWN, 1913):
Avena sativa L.
Diagnosis. – Annuals (with the exception of A. macrostachya); roots without sclerenchyma surrounding endodermis; culms with (2-)3-6 visible nodes; leaves convolute,
relatively soft and flexible; cross-section with numerous
secondary nerves, scarcely pronounced ribs, bulliform cells
scarcely developed, forming several rows between the nerves,
‘I’-shaped girders of colourless parenchyma, and subepidermal sclerenchyma in small, scarcely developed strands.
Spikelets (12-)16-41(-48) mm long, (1-)2-4(-5) florets, completely developed, bisexual; equal or unequal glumes, almost
as long as the whole spikelet, rounded on the back, glabrous,
with (5-)7 or more nerves; lemma generally hairy towards the
base, somewhat scabrous towards the apex; awn dorsal, generally with a strongly twisted column -exceptionally flattened
or not developed in cultivated forms-; palea strongly 2-keeled,
keels minutely ciliate; lodicules longer than ovary, lanceolate,
entire or with a small lateral tooth. Caryopsis furrowed; hilum
linear; embryo with a rounded or truncated epiblast and subobtuse scutellum.
Species and distribution. – 24-31 species, some of them
cultivated derivatives; West Mediterranean and Macaronesia
is the main centre of species diversity.
2. Arrhenatherum vs Pseudarrhenatherum
The delimitation of Arrhenatherum presents two problems.
First its separation from Helictotrichon and second, the splitting of Pseudarrhenatherum as proposed by ROUY (1913,
1921). There are three traditional morpho-anatomical criteria
used to delimit these genera.
The first criterion used is the composition of spikelets.
Arrhenatherum elatius and related species are clearly separable from other perennial oats by having two unequal florets
that are joined at maturity; the lower floret masculine, with
a strong subbasal awn; the upper floret bisexual, with a
rudimentary, subapical awn, sometimes absent. It is evident
that this configuration must be understood as a specialized
polyandry syndrome in the context of the family. The majority of the remaining species of the group have spikelets with
several similar, bisexual florets, all of them articulated with
the rachilla, so that the dispersal unit (diaspora) is a single floret. Nevertheless some Avena and Helictotrichon species have
spikelets with a reduced number of florets (frequently only two
of them well developed) remaining united at maturity, since
only the lower floret is articulated with the rachilla. The result
is the configuration of a synaptospermic diaspora. In Avena
this phenomenon occurs in some species belonging to different sections (A. sterilis L., A. murphyi Ladizinsky and A. eriantha; see for example ROMERO-ZARCO, 1996: Fig 1). Among
the European Helictotrichon species, this specialized configuration of spikelets occurs in a small group of closely related,
central European species, the group of H. parlatorei (J. Woods)
Pilger (see RÖSER, 1989: 65-76). In all these cases the two florets of the spikelets are similar, both provided with a well developed, dorsal awn. However, in the two unique species included
in the genus Pseudarrhenatherum (HOLUB, 1980; ROMEROZARCO, 1985c), spikelets are formed by two different florets,
both completely developed and bisexual, the lower floret with
a well developed, dorsal awn, the upper floret without awn or
with a reduced, straight subapical one.
Four kinds of major modifications in the structure of the
spikelets occur in oats grasses:
1. reduction to two completely developed florets, rarely
only one in some cultivars;
2. synaptospermy;
3. morphological differentiation between the lower floret
and the upper one;
4. polyandry.
In synaptospermic Avena species, the spikelets have 2-4
(-5) florets (see ROMERO-ZARCO, 1996), but only cultivated
forms have two morphologically different florets. In Arrhenatherum, the spikelets reach the maximum degree of modification, with reduction, differentiation, and polyandry. Obviously, synaptospermy cannot occur in Arrhenatherum, since
the spikelets contain a unique fruit, but the atrophy of the joint
at the base of the second flower does occur. In Pseudarrhenatherum the three first phenomena occur together, but not
polyandry. In the species of Helictotrichon parlatorei group
(RÖSER, 1989), together with certain endemic atypical species
from Atlas Range (Avena Jahandiezii Litard. and A. breviaristata Barratte, included by HOLUB, 1962, 1976 in Avenula),
synaptorpermy occurs, occasionally accompanied by the reduction of spikelets to two fertile florets, but there is no clear
upward differentiation as in Pseudarrhenatherum.
94 – Candollea 66, 2011
The second critieria used to separate species of Arrhenatherum from Pseudarrhenatherum is foliar anatomy. Arrhenatherum leaves are similar to those of Avena, i.e. relatively
soft, with scarcely developed subepidermal sclerenchyma and
less protruding ribs. The leaves of Pseudarrhenatherum are
rigid, similar to those of Paleartic Helictotrichon species, with
numerous, well-marked ribs above, with abundant subepidermal sclerenchyma forming ‘T’-shaped girders and, in more
xerophilic species, a continuous layer of subepidermal
sclerenchyma beneath. The variability observed among
Pseudarrhenatherum species is parallel to that occurring in
Helictotrichon (see ROMERO-ZARCO, 1985c).
The third criterion is based on the anatomical characteristic of the root as described by GERVAIS (1968, 1973). The endodermis is surrounded by a more or less heavy layer of sclerenchyma cells in the roots of the European Helictotrichon
species, as well as in Pseudarrhenatherum. This character does
not occur in Avena species (including A. macrostachya),
Avenula, or Arrhenatherum s.s. In addition, the form of
the endodermic cells are different in Helictotrichon when
compared with Pseudarrhenatherum: in the former, the cells
are ± rounded, with a thick internal reinforcements of suberin
and a reduced lumen, whereas in the later the cells are extended
radially and have a broad lumen. This detail was observed
by GERVAIS (1973) in P. longifolium and is verified here in
P. pallens.
Two additional criteria are added here: the morphology of
the embryos and the presence of macrohairs on the back
of lemmas (excluding the callus). The embryos of Arrhenatherum differ by having rounded epiblasts, not truncated or
emarginated epiblasts, like the other genera studied (Fig. 4).
Macrohairs are present on lemmas of Pseudarrhenatherum,
Arrenatherum and some Avena and Avenula s.l. species and
not in Eurasian and American species of Helictotrichon (FINOT
& al., 2005; ROMERO-ZARCO, 1984a, 1984b, 1985a, 1985c,
1996).
Four schemes regarding the classification are:
1. to maintain a broad criterion for Helictotrichon, including Arrhenatherum and Pseudarrhenatherum;
2. to separate Arrhenatherum and Helictotrichon maintaining Pseudarrhenatherum within the first;
3. the same but including Pseudarrhenatherum in Helictotrichon;
4. to completely separate these three genera.
How have molecular studies contributed to these questions?
GREBENSTEIN & al. (1995, 1998) have demonstrated with different molecular markers, that Arrhenatherum elatius clearly
occupies a different position from Avena and from European
Helictotrichon s.s. species. However, no Pseudarrhenatherum
species where included in these studies. RÖSER & al. (2001) concluded that Pseudarrhenatherum should be included in Helic-
totrichon s.s. on the basis of its 5S rDNA sequence, but only the
most common species, P. longifolium, was studied, and no
Arrhenatherum species were included in their analysis. A study
of the whole group would have supported their conclusion in
this respect. QUINTANAR & al. (2007) in their phylogram on
nuclear ITS data, separate clearly Arrhenatherum elatius from
Helictotrichon s.s., but Pseudarrhenatherum longifolium is
nested in Helictotrichon. Similar relationships are seen in recent
studies (SCHNEIDER & al., 2009; WINTERFELD & al., 2009). One
might assume that Pseudarrhenatherum longifolium should
not be included in Arrhenatherum, but it could be included in
Helictotrichon if the phylogenetic position of Pseudarrhenatherum pallens were clarified. Meanwhile, the most coherent
position according to available data is to maintain the independence of these three genera until an analysis including all
taxa with more molecular markers is completed.
Arrhenatherum P. Beauv., Ess. Agrostogr. 55: 1812.
Lectotypus (designated by PFEIFFER, 1872: 274): Avena
elatior L. ( Arrhenatherum elatius (L.) J. Presl &
C. Presl).
Taxonomic characters and diagnosis. – See ROMEROZARCO (1985a).
Species and distribution. – Only five species, primarily
found in the Mediterranean Basin and SW Asia. The polymorphic A. elatius is the most frequent species, extending from
Macaronesia to Siberia and introduced elsewhere.
Pseudarrhenatherum Rouy in Bull. Soc. Bot. France 68: 401.
1921.
Thorea Rouy, Fl. France 14: 142. 1913 (non Thorea
Bory in Ann. Mus. Hist. Nat. 12: 127. 1808 [nom.
illeg.].
Typus: Avena longifolia Thore ( Pseudarrhenatherum
longifolium (Thore) Rouy).
Nomenclature. – See ROUY (1921) and ROMERO-ZARCO
(1985c).
Taxonomic characters and diagnosis. – See ROMEROZARCO (1985c).
Species and distribution. – Two species: the West-European, acidophilic P. longifolum, with the southernmost known
populations in South Spain and Morocco, and P. pallens,
endemic from a few localities near Lisbon, growing on calcareous substrates.
3. Avenula vs Helictotrichon
The question of recognizing Avenula as separate from Helictotrichon has been suitably discussed by several authors using
morphological and anatomical characters (GERVAIS, 1973;
HOLUB, 1962; ROMERO-ZARCO, 1984b). Most distinguishing
characteristics of the former with respect to the later are based
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 95
on leaf and root anatomy. The Eurosiberian and Mediterranean
species of Helictotrichon s.s. have a layer of sclerenchyma surrounding the endodermis that is not present in Avenula s.l. (that
is, including Tricholemma (Röser) Röser). Moreover, leaf blades
are bilaterally symmetrical in Avenula s.l., since there are no
ribs, and bulliform cells form rows along each side of the adaxial midrib. Other important characters such as palea hairiness,
lodicule shape and the form of awn columns are heterogeneous
in Avenula s.l., A. pubescens has glabrous paleas, short, ovate
or obovate lodicules and terete or square awn column in crosssection; A. jahandiezii (here included in Tricholemma together
with A. breviaristata) has similar lodicules and awn columns,
but minutely ciliate paleas found in many grasses; the remaining Avenula species have ciliate paleas, long, lanceolate lodicules, and flattened awn column with pale margins.
Therefore, RÖSER (1989) in his first treatment, maintained
a broad concept of Helictotrichon by recognizing four subgenera:
1. Helictotrichon subgen. Helictotrichon, includes species
with ribbed leaves and strongly twisted awn columns,
terete or square in cross-section, from Europe, N Africa,
Western Asia and one North American species.
2. Helictotrichon subgen. Pubavenastrum (Vierh.) Holub,
monospecific, includes only H. pubescens (Hudson)
Pilger, a species with a wide distribution but isolated
morphologically and phylogenetically, with conduplicate leaf blades as in Avenula species, awn like in Helictotrichon s.s., short Trisetum type lodicules (BAUM,
1968), and palea with smooth keels, a unique configuration in the group.
3. Helictotrichon subgen. Tricholemma Röser includes
two rare species from NW Africa, characterized by lemmas with the central nerve prominent and hairy at the
base; awn like in Helictotrichon s.s., and leaf blades
very similar to those of Avenula.
4. Helictotrichon subgen. Pratavenastrum (Vierh.) Holub
includes species with conduplicate leaf blades and
± flattened awn columns; distributed mainly in the
Mediterranean basin.
All molecular analyses published to date agree in separating Helictotrichon s.s. from most Avenula species (that is,
excluding Tricholemma). The results of QUINTANAR & al.
(2007) are compatible with the hypothesis that the four subgenera defined by RÖSER (1989) constitute separate phylogenetic clades. According to morphological and anatomical characters and molecular analyses, I think the simplest taxonomic
solution is to recognize four genera. Coming to the same conclusion RÖSER & al. (2009) established the generic category
for the four groups: Helictotrichon subgen. Tricholemma is
upgraded to generic rank as Tricholemma and Homalotrichon
is accepted for Helictotrichon subgen. Pubavenastrum as an
independent genus.
So, in the author’s opinion, the species at present classified
under Avenula must be separated into the following three genera Tricholemma, Avenula and the new Helictochloa Romero
Zarco. A nomenclature summary, diagnoses and diversity are
proposed for the following four genera formerly included in
Helictotrichon s.l. (sensu RÖSER, 1989):
1. Tricholemma, its generic rank has been well defended
by RÖSER & al. (2009);
2. Avenula, a monotypic genus including A. pubescens.
The separation of A. pubescens in a monotypic genus
(apart from the rest of species at present classified under
Avenula) is according to morphological and anatomical characters analyzed above;
3. Helictochloa Romero Zarco, a large and new genus
including the remaining Avenula species (Avenula subgen. Avenula sensu ROMERO-ZARCO, 1984b);
4. Helictotrichon s.s.
Tricholemma (Röser) Röser in Schlechtendalia 19: 34. 2009.
Helictotrichon subgen. Tricholemma Röser in Diss. Bot.
145: 46. 1989.
Typus: Avena jahandiezii Litard. ( Tricholemma jahandiezii (Litard.) Röser)
Diagnosis. – Perennials, densely caespitose; roots without
sclerenchyma surrounding endodermis; culms with 1-2 visible
nodes, sometimes subbulbous at the base. Leaf blades flat, conduplicate or junciform, not furrowed above, with or without thin
ribs beneath, very hard or relatively soft, but rigid, with several
or numerous secondary nerves; abaxial midrib and margins outstanding, without long hairs; bulliform cells forming a row each
side of the adaxial midrib; without girders and subepidermal sclerenchyma (T. jahandiezii) or with subepidermal sclerenchyma
forming ‘I’-shaped girders at the lateral nerves (T. breviaristatum (Barratte) Röser). Spikelets 13-18 mm long, with 2-3 developed bisexual florets, two upper floret not or scarcely exceeding
the upper glume, apical floret reduced; glumes slightly unequal,
keeled in the back, glabrous, 3-nerved; rachilla disarticulating
only above the glumes; lemmas with a row of hairs on the back,
along the lower part of the central nerve, the rest glabrous; awn
without pale margins, dorsally inserted and with a strongly
twisted column, or reduced and subapically inserted, with or without a slightly twisted column; palea strongly 2-keeled, keels
minutely ciliate; lodicules as long or shorter than the ovary, ovate
or obovate, with a ± truncate, usually dentate apex. Caryopsis
furrowed; hilum linear; embryo not seen.
Species and distribution. – Two endemic species in
NW Africa: T. jahandiezii from Morocco (Middle Atlas) and
T. breviaristatum, endemic from E Algeria.
Nomenclature and taxonomy. – See RÖSER & al. (2009).
96 – Candollea 66, 2011
Avenula (Dumort.) Dumort. in Bull. Soc. Bot. Belg. 7: 68.
1868.
Trisetum sect. Avenula Dumort., Observ. Gramin. Belg.:
122. 1823.
Avena sect. Avenastrum W. D. J. Koch, Syn. Fl. Germ.
Helv.: 795. 1837 [nom. illeg.].
Homalotrichon Banfi, Galasso & Bracchi in F. Conti,
G. Abbate, Aless. & C. Blasi, Annot. Cheklist Italian
Vasc. Fl.: 18. 2005 [nom. illeg.].
Lectotypus (designated by CHASE, 1939): Avena pubescens Hudson ( Avenula pubescens (Hudson) Dumort.).
Perennial, loosely caespitose; roots without sclerenchyma
surrounding endodermis; culms with 1-3 visible nodes. Leaf
blades flat or ± conduplicate, not furrowed, relatively soft but
rigid, with long hairs; bulliform cells forming a row each side
of the adaxial midrib; with abaxial midrib and margins scarcely
evident; secondary nerves few; well developed subepidermal
sclerenchyma forming ‘O’-shaped girders at lateral nerves.
Spikelets 14-20 mm long, with 3-4 developed bisexual florets,
two upper floret not or scarcely exceeding the upper glume, apical floret reduced; glumes unequal, keeled on the back, somewhat scabrid on the central nerve at the base, the lower glume
1-3-nerved, the upper glume 3-nerved; rachilla disarticulating
above the glumes and between the florets; lemmas glabrous
(except for the callus); awned dorsally, with a strongly twisted,
rounded column, without pale margins; palea scarcely 2-keeled,
with glabrous keels; lodicules as long or shorter than the ovary,
ovate or obovate, 2-3-lobed or with a irregularly dentate apex.
Caryopsis furrowed; hilum linear; embryo with a truncated epiblast and obtuse scutellum.
Nomenclature. – See ROMERO-ZARCO (1984b), RÖSER (1989:
44) and HOLUB (1976: 288).
Lectotypification. – There are two different lectotopyfications of the generic name Avenula: a) Avena pubescens Hudson, designated by CHASE (1939: 568) and ignored by most
European taxonomists (HOLUB, 1977; ROMERO-ZARCO, 1984b;
RÖSER, 1989; RÖSER & al., 2009) and b) A. pratensis L., designated by BREISTROFFER (1966). Only these two species were
cited by DUMORTIER (1824) in the original description of Trisetum sect. Avenula, the basyonim of Avenula, and both fit the protologue. According to MCNEILL & al. (2006, art. 10.5), the first
lectotypification is accepted, and the correct name for the monotypic genus including A. pubescens is Avenula. The name Homalotrichon is then illegitimate (MCNEILL & al., 2006, art. 52.1).
Species and distribution. – Only the diploid Avenula pubescens, extends from Spain to China: from submediterranean
Europe through Central Europe to continental regions of Middle Asia and Central Siberia (cf. RÖSER, 1997: 109).
Helictochloa Romero Zarco, gen. nov.
Typus: Avena bromoides Gouan ( Helictochloa bromoides (Gouan) Romero Zarco).
= Avena sect. Pratenses Rouy, Fl. France 14: 132. 1913.
Typus: A. pratensis L.
= Avena subsect. Ecostatae St.-Yves in Candollea 4: 374.
1931. Lectotypus (designated here): A. pratensis L.
= Avenastrum ser. Pratenses Roshev. in Kom. & al.,
Fl. CCCP 2: 273. 1934. Typus: Avena pratensis L.
( Avenastrum pratense (L.) Opiz).
= Avenastrum sect. Pratavenastrum Vierh. in Verh. Ges.
Deutsch. Naturf. 85: 672. 1914. Helictotrichon subgen. Pratavenastrum (Vierh.) Holub in Nemec. & al.,
Philipp Maxmillian Opiz Bedeut. Pflanzentaxon.: 125.
1958. Typus: Avena pratensis L. ( Avenastrum
pratense (L.) Opiz).
= Avenochloa Holub in Acta Horti Bot. Prag. 1962: 82.
1962 [nom. illeg]. Typus: Avena planiculmis Schrad.
( A. planiculmis (Schrad.) Holub).
= Helictotrichon sect. Scleravenastrum Holub in Nemec.
& al., Philipp Maxmillian Opiz Bedeut. Pflanzentaxon.:
126. 1958. Avenula sect. Scleravenastrum (Holub)
Holub in Folia Geobot. Phytotax. 11: 294. 1976. Typus:
Avena hackelii Henriq. ( Helictotrichon hackelii
(Henriq.) Henrard).
– Avenula mult. auct.
Ab Helictotricho sensu stricto praecipue differt foliis
conduplicatis, nervo medio dorsaliter notato, margine
incrassato. Ab Avenulae sensu stricto praecipue differt
foliis glabris vel scabridis; carinis paleae ciliolatis;
lodiculis lanceolatis. A Tricholemmate praecipue differt
lemmate nervo mediano non prominente instructo. A generibus praecedentibus atque differt columella aristae sectione transversa applanata. Gramina ob folia in sicco
saepe helica Helictochloa nominata.
Perennials, loosely or densely caespitose; roots without
sclerenchyma surrounding endodermis; culms with 1-3 visible nodes. Leaf blades flat, conduplicate or ± junciform, not
furrowed above, sometimes with thin ribs beneath, relatively
hard and rigid; bulliform cells forming a row each side of
the adaxial midrib; margins and abaxial midrib prominent,
cartilaginous; secondary nerves numerous or not; with or without ‘I’-shaped girders of sclerenchyma and/or colourless
parenchyma; subepidermal sclerenchyma in ± developed small
islands, rarely forming a continuous layer beneath. Spikelets
10-36 mm long, with (2-)3-9(-12) developed, bisexual florets,
two or more upper florets exceeding the glumes, apical floret
reduced; glumes unequal, keeled on the back, somewhat
scabrous on the nerves, the lower glume with (1-)3-5 nerves,
the upper glume with 3-5(-7) nerves; rachilla disarticulating
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 97
above the glumes and between the florets; lemmas glabrous
or sericeous towards the base, awned dorsally; awn with a
loosely twisted column, ± flattened in cross-section, with pale
margins; palea strongly 2-keeled, keels minutely ciliate; lodicules longer than the ovary, lanceolate, with a lateral, ± developed lobe. Caryopsis furrowed; hilum linear; embryo with
a truncate or somewhat emarginate epiblast, scutellum with a
nipple-shaped apex.
Etymology. – From Greek helictos, by the spirally twisted
leaves when dry, and chloe, green grass.
Nomenclature and taxonomy. – See HOLUB (1976) for
Avenochloa Holub. According to MCNEILL & al. (2006, art.
22.6) Avena pratensis is the type species of infrageneric names
derived or similar to its epithet.
According to the taxonomic criteria here defended, a number of 40 taxa (25 species) accepted by DOGAN (1985), RÖSER
(1989, 1996), SAUER (1984), SAUER & CHMELITSCHEK (1976),
ROMERO-ZARCO (1984b), ROSHEVITS & SHISHKIN (1934) or WU
& PHILLIPS (2006) must be transferred to the new genus (see
Appendix 1).
SAINT-YVES (1931) included in his Avena subsect.
Ecostatae 8 species belonging to 3 different genera:
1. Avena jahandiezii (classified here within Tricholemma)
is discarded as a possible lectotypus because he considered it an intermediate species (SAINT-YVES, 1931:
425);
2. Avena pubescens (type species of Avenula), discarded
as lectotype by the same reason;
3. A. hackelii Henriq. (genus Helictochloa); this species
was considered by SAINT-YVES (1931: 435) an atypical species in the group or even a possible hybrid
between two species belonging to different subsections;
4. Avena pratensis (genus Helictochloa), the most complex and extended species of this group in Europe;
5. A. versicolor Vill. (genus Helictochloa);
6. A. blaui Asch. & Janka [“Blavii”] (genus Helictochloa);
7. A. bromoides (genus Helictochloa), another species
complex, extended around the Mediterranean basin;
8. A. breviaristata (classified here within Tricholemma)
considered by SAINT-YVES (1931: 489) of doubtful classification due to some affinities with his subsect. Anomalae.
So, only species 4 to 7 can be properly selected as lectotype. Avena pratensis have been designated here because it
was previously selected by VIERHAPPER (1906), ROUY (1913),
and ROSHEVITS & SHISHKIN (1934) as the type species for other
infrageneric taxa including this species group.
Species and distribution. – Several polyploid species complexes and some ± isolated endemic species previously classified as Avenula or Helictotrichon. The number of species
ranges from 20 to 30 according to different taxonomic treatments. Two main centres of diversity: West Mediterranean and
Balkan-Aegean region. A secondary centre is in the European
Alpes. Some species extending north and east in Europe to
Asia. Only one species in N America.
Helictotrichon Besser in Schultes & Schultes fil., Mant. 3: “326”
[526]. 1827.
Lectotypus (designated by SCHWEICKERDT, 1937: 185):
Avena sempervirens Vill. ( Helictotrichon sempervirens
(Vill.) Pilger).
Perennials, densely or loosely caespitose, sometimes mat
forming; roots with sclerenchyma surrounding endodermis;
culms with 1-3 visible nodes. Leaf blades convolute, ± flattened, involute, junciform or setaceous, furrowed above,
with protruding ribs, very hard or relatively soft, but rigid,
with several or numerous lateral nerves; abaxial midrib and
margins not outstanding ; bulliform cells forming several
rows between the nerves, sometimes reduced or not developed between the distal nerves; sclerenchyma forming ‘T’shaped girders across the main nerves and ‘I’-shaped or
incomplete girders at the secondary nerves; subepidermical
sclerenchyma frequently forming a continuous layer beneath.
Spikelets 7.5-20 mm long, with 2-4 developed bisexual florets, apical floret reduced ; glumes unequal, keeled in the
back, somewhat scabrous on the keel near the apex, the
lower glume 1-3-nerved, the upper glume 3-5-nerved, almost
as long as the spikelet; rachilla disarticulating only above
the glumes or between the florets too ; lemmas 7-18 mm
long, generally 2-dentate, glabrous (except for the callus) or
somewhat scabrous towards the apex; awns ± equally developed, without pale margins, dorsally inserted and with a
strongly twisted column, terete or square in cross-section;
palea strongly 2-keeled, keels minutely ciliate ; lodicules
longer than the ovary, lanceolate, generally entire, rarely
with a small lateral tooth. Caryopsis furrowed; hilum linear; embryo with truncate epiblast and obtuse or subobtuse
scutellum.
Nomenclature. – See RÖSER (1989: 44) (under Helictotrichon subgen. Helictotrichon).
Species and distribution. – Approximately 42 species following different regional taxonomic treatments, some of then
recently described (COPE, 2006; ROMERO-ZARCO, 2007). A wellknow Mediterranean-Balkanic group of approximately 12 species,
some of them forming polyploid complexes (ROMERO-ZARCO,
1984a, 1985b; RÖSER, 1989). At least 20 species in Tropical and
South Africa, with two different diversity centres: E Africa and
98 – Candollea 66, 2011
Cape Region. Perhaps only nine species in Asia, but some of
them polymorphic, as H. junghuhnii (Buse) Henrard. Only one
species in N America: H. mortonianum (Hitchc.) Parodi, and the
South American H. bulbosum (Hitchc.) Parodi.
Key for Avena related genera present in the Mediterranean
region
1.
Leaf blades not furrowed above; bulliform cells forming
a row each side of the adaxial midrib .......................... 2
1a. Leaf blades furrowed above; bulliform cells forming
several rows between the nerves, sometimes reduced or
not developed between the distal nerves ..................... 4
2.
Awns with a loosely twisted column, ± flattened in crosssection, with pale margins. Spikelets with (2-)3-9(-12)
florets, two or more upper florets exceeding the glumes.
Lodicules lanceolate, generally with a subbasal lateral
lobe. Mainly Mediterranean, sub-Mediterranean or alpine
species ...................................................... Helictochloa
2a. Awns with a strongly twisted column, rounded or quadrangular in cross-section (rarely very reduced), rarely with
pale margins. Spikelets with (2-)3-4 florets, two upper
floret not or scarcely exceeding the upper glume. Lodicules ovate or obovate, 2 or 3-lobed or with a dentate
apex. Eurosiberian or Atlasic species .......................... 3
3.
Leaf blades with long hairs. Lemmas glabrous (except for
the callus). Eurosiberian species ...................... Avenula
3a. Leaf blades without long hairs. Lemmas with a row of
hairs on the back, along the lower part of the central
nerve. Endemic species from Algeria and Morocco .......
................................................................. Tricholemma
4.
Annuals, very rarely perennial. Lower glumes with (5-)7
or more nerves. Lemmas (10-)12-33(-36) mm long.
Mediterranean or Eurosiberian species ............... Avena
4a. Perennials. Lower glumes 1-3-nerved. Lemmas 5-17
(-18) mm long .............................................................. 5
5.
Lemmas glabrous (except for the callus) or somewhat
scabrous towards the apex. Spikelets 7.5-20 mm long,
with 2-4 florets; rachilla disarticulating only above the
glumes or between the florets too. Awns ± equally developed, dorsally inserted ........................... Helictotrichon
5a. Lemmas hairy. Spikelets 5-12(-14) mm long, with two
developed florets. Rachilla disarticulating only above the
glumes. Awn of the lower floret inserted near the base
or near the middle, awn of the upper floret reduced, subapically inserted ........................................................... 6
6.
Awn of the lower floret inserted near the middle of the
lemma. Leaf blades with very protruding ribs, relatively
hard and rigid. Culms without corms. Subatlantic species
..................................................... Pseudarrhenatherum
6a. Awn of the lower floret inserted near the base of the
lemma. Culms frequently with the basal internodes
swollen into globose corms. Leaf blades relatively soft
and flexible. Mediterranean, Iranoturanian and Eurosiberian species ...................................... Arrhenatherum
General discussion
According to the taxonomic scheme adopted here, the
conduplicate structure of the leaf blade, with two rows of bulliform cells flanking the central nerve, a character usually used
to the separate Avenula s.l. from Helitotrichon, does not have
a unique origin in the group. This is not surprising for
researchers of leaf anatomy. In figure 2 the anatomical characters of the leaf blade in Avenula pubescens and in A. pratensis subsp. iberica (now classified in the new genus Helictochloa) have been compared. In species here included within
Helictochloa, the strands of subepidermal sclerenchyma
are much thinner than marginal strands, and in many species
(H. pratensis (L.) Romero Zarco, H. marginata (Lowe) Romero
Zarco, and related species) these strands are united to the vascular bundles forming relatively thin, ‘I’-shaped girders. In
Avenula pubescens the marginal strands are less developed and
the subepidermal strands are very robust, forming ‘O’-shaped
girders. Beside this, differentiation of a palisade chlorenchyma
is found in Helictochloa pratensis but not in Avenula pubescens. LÓPEZ & DEVESA (1991) also found palisade chlorenchyma in Helictochloa bromoides subsp. bromoides (sub.
Avenula). The remaining species of Helictochloa all have
palisade chlorenchyma according to many figures previously
published (ROMERO-ZARCO, 1984b; RÖSER, 1998). The anatomical structure of the leaf blade in Avenula pubescens may
be the result of analogous changes also having originated in
the typical leaves of Helictochloa and Tricholemma.
In the genus Tricholemma, the two known species present
very different leaf blade structures. In T. jahandiezii, the leaves
have only sclerenchyma in front of the central nerve (beneath)
and in the margins, a unique pattern of sclerenchyma distribution in oat grasses (see RÖSER, 1989: 31, Fig. 4). However,
in T. breviaristatum the distribution of sclerenchyma in crosssection (see SAINT-YVES, 1931: Fig. 37) is similar to that of
certain xeromorphic populations of Helictochloa pruinosa
(Hackel & Trabut) Romero Zarco from Middle Atlas, originally described by SAINT-YVES (1931: 485, Fig. 36) as Avena
bromoides subvar. dolosa St.-Yves. This remarkable difference
between two closely related species, can be seen in the different development of the sclerenchymatous tissue probably in
response to habitat. In the case of T. jahandiezii, the absence
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 99
of subepidermal strands in front of lateral nerves can be
explained by an extreme reduction of the sclerenchyma,
perhaps as an adaptation to the relatively humid habitat where
it grows: “garriga” schrublands at the Middle Atlas up to
1600 m above see level in deep calcareous soils, with autumnal precipitations of 1000 mm or more and frequent fog
(RÖSER, 1996: 214). On the contrary, Tricholemma breviaristatum is an endemic xeromorphic species of the Djebel Sahari,
in NW Algeria, zone of median height mountains with
Mediterranean type vegetation, containing elements of the
Quercetea ilicis A. Bolòs & O. Bolòs 1950 (RÖSER, 1996:
214). A similar relationship between humidity and development of sclerenchyma in the leaves has been described between
mesomorphic and xeromorphic Helictochloa species (RÖSER,
1989, 1996, 1997, sub Helictotrichon subg. Pratavenastrum)
and in Pseudarrhenatherum species (ROMERO-ZARCO, 1985c).
The remarkable development of the marginal strands of
sclerenchyma is a shared characteristic between Tricholemma
and Helictochloa. A detailed phylogenetic analysis will be necessary to find out if this foliar structure has arisen independently in both genera or is the result of common descent. The
molecular analyses available do not clarify the question.
Nuclear ITS sequences studies (GRENBENSTEIN & al., 1998;
QUINTANAR & al., 2007) align T. jahandiezii closer to Helictotrichon s.s. than to Avenula or Helictochloa. Nevertheless
RÖSER & al. (2001) in his analysis of 5S rDNA sequences proposed an isolated and basal situation of this species in respect
to the group. Both results are not absolutely contradictory and
they could be resolved if T. breviaristatum were studied. Unfortunately, T. breviaristatum has not been collected since May
1882 (RÖSER & al., 2009). In conclusion, the so called “Avenastrum type” leaf structure (POTZTAL, 1951), may be the result
of convergent processes resulting in anatomical simplification.
The splitting of species showing a unique combination of
morphological characters within monotypic genera or genera
with 2-3 taxa, is frequently encountered in the Aveneae tribe
(Avenella, Danthoniastrum, Lagurus L., Mibora Adans., Ventenata, among others). Some cases, like the new Tricholemma
genera, are possibly, relics of a substratum of diversity from
which other genera, at present in the diversification process
arose, and may be a significant example of the otherwise poor
supraspecific endemism in the orophytic Mediterranean flora
of N Africa RÖSER (1996: 245). The distribution of Tricholemma species corresponds to the southern edge of the
Mediterranean vegetation in N Africa, where orophytic taxa
were isolated at the end of the Tertiary. This, together with the
great differences (possibly quantitative) in leaf anatomy and
spikelet morphology (T. breviaristatum has very reduced awns)
suggests an ancient derivation and a long history for this genus,
which would support its basal position with respect to the group
as shown in the dendrogram of RÖSER & al. (2001).
The next challenge in the taxonomy of the group would be
to investigate the phylogenetic relationship between Paleartic,
Paleotropical and South African species of Helictotrichon. The
species from south and east Africa, together with some from
SE Asia, differ from Paleartic species in several characters;
specifically in the morphology of the lemma, but also by a
greater variability in the morphology of lodicules, awns and
leaves. New data are needed for a clear delimitation of Helictotrichon outside of Europe.
Acknowledgements
This work was financially supported by the Spanish “Plan
Andaluz de Investigación” of the Junta de Andalucía (RNM
204) and Dirección General de Investigación Científica y Técnica through projects “Flora iberica” VII(2) (CGL2006-00817)
and “Flora iberica” VIII(2) (CGL2009-08178). I thank Dr
Anass Terrab for the French abstract. An anonymous reviewer
kindly improved the first manuscript.
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Appendix 1. – New combinations for Helictochloa Romero
Zarco
Helictochloa adsurgens (Simonk.) Romero Zarco, comb. nova
Avena adsurgens Simonk., Enum. Fl. Transsilv.: 574.
1887.
Helictochloa adsurgens subsp. ausserdorferi (Asch. & Graebn.)
Romero Zarco, comb. nova
Avena alpina subsp. ausserdorferi Asch. & Graebn.,
Syn. Mitteleur. Fl. 2(1): 261. 1899.
Helictochloa aetolica (Rech. fil.) Romero Zarco, comb. nova
Avenastrum aetolicum Rech. fil. in Beih. Bot. Centralbl., Abt. 2, 54: 680. 1936.
Helictochloa agropyroides (Boiss.) Romero Zarco, comb. nova
Avena agropyroides Boiss., Diagn. Pl. Orient. 13: 50.
1854.
Helictochloa albinervis (Boiss.) Romero Zarco, comb. nova
Avena albinervis Boiss., Voy. Bot. Espagne 2: 656.
1844.
Helictochloa albinervis var. gaditana (Romero Zarco) Romero
Zarco, comb. et stat. nov.
Avenula sulcata subsp. gaditana Romero Zarco in
Lagascalia 13: 124. 1984.
Helictochloa armeniaca (Schischk.) Romero Zarco, comb.
nova
Avena armeniaca Schischk. in Izv. Tomsk. Gosud.
Univ. 81: 418. 1929.
Helictochloa blaui (Asch. & Janka) Romero Zarco, comb.
nova
Avena blaui Asch. & Janka in Természetrajzi Füz. 1:
99. 1877.
Helictochloa blaui subsp. aenigmatica (D. Lange) Romero
Zarco, comb. nova
Helictotrichon blaui subsp. aenigmaticum D. Lange in
Biblioth. Bot. 144: 181. 1995.
Helictochloa bromoides (Gouan) Romero Zarco, comb. nova
Avena bromoides Gouan, Hort. Monsp.: 52. 1762.
Helictochloa bromoides subsp. pauneroi (Romero Zarco)
Romero Zarco, comb. nova
Avenula bromoides subsp. pauneroi Romero Zarco in
Lagascalia 13: 114. 1984.
Helictochloa cincinnata (Parl.) Romero Zarco, comb. nova
Bromus cincinnatus Ten., Fl. Med. Univ. 1: 52. 1823.
Helictochloa cintrana (Röser) Romero Zarco, comb. nova
Helictotrichon cintranum Röser in Taxon 41: 60. 1992.
Helictochloa compressa (Heuff.) Romero Zarco, comb. nova
Avena compressa Heuff. in Flora 18: 244. 1835.
Helictochloa crassifolia (Font Quer) Romero Zarco, comb.
nova
Avena crassifolia Font Quer in Butl. Inst. Catalana Hist.
Nat. 20: 189. 1920.
Helictochloa dahurica (Kom.) Romero Zarco, comb. nova
Avena planiculmis subsp. dahurica Kom., Fl. Kamtschatka 1: 159. 1927.
Avenastrum dahuricum (Kom.) Roshev. in Kom. & al.,
Fl. CCCP 2: 275. 1934.
Helictochloa gervaisii (Holub) Romero Zarco, comb. nova
Avenula gervaisii Holub in Preslia 49: 205. 1977.
Helictochloa gervaisii subsp. arundana (Romero Zarco)
Romero Zarco, comb. nova
Avenula gervaisii subsp. arundana Romero Zarco in
Lagascalia 13: 108. 1984.
Helictochloa hackelii (Henriq.) Romero Zarco, comb. nova
Avena hackelii Henriq. in Bol. Soc. Brot. 20: 87. 1905.
Helictochloa hackelii var. algarbiensis (Romero Zarco)
Romero Zarco, comb. nova
Avenula hackelii var. algarbiensis Romero Zarco in
Lagascalia 13: 136. 1984.
Helictochloa hookeri (Scribn.) Romero Zarco, comb. nova
Avena hookeri Scribn. in Hackel, True Grasses: 123.
1890.
Helictochloa hookeri subsp. schelliana (Hackel) Romero
Zarco, comb. nova
Avena schelliana Hackel in Trudy Imp. S.-Peterburgsk.
Bot. Sada 12: 419. 1892.
Helictotrichon hookeri subsp. schellianum (Hackel)
Tzvelev in Novosti Sist. Vyssh. Rast. 8: 68. 1971.
Helictochloa levis (Hackel) Romero Zarco, comb. nova
Avena levis Hackel in Oesterr. Bot. Z. 27: 122. 1877.
Helictochloa lusitanica (Romero Zarco) Romero Zarco, comb.
nova
Avenula pratensis subsp. lusitanica Romero Zarco in
Lagascalia 13: 95. 1984.
Helictotrichon lusitanicum (Romero Zarco) Röser in
Flora 193: 438. 1998.
Helictochloa marginata (Lowe) Romero Zarco, comb. nova
Avena marginata Lowe in Trans. Cambridge Philos.
Soc. 6: 529. 1838.
Helictochloa marginata var. font-queriana (St.-Yves) Romero
Zarco, comb. nova
Avena pratensis var. font-queriana St.-Yves in
Candollea 4: 465. 1931.
Helictochloa murcica (Holub) Romero Zarco, comb. nova
Avenula murcica Holub in Preslia 49: 206. 1977.
Helictochloa planiculmis (Schrad.) Romero Zarco, comb. nova
Avena planiculmis Schrad., Fl. Germ. 1: 381. 1806.
Helictochloa planiculmis subsp. angustior (Holub) Romero
Zarco, comb. nova
Avenula planiculmis subsp. angustior Holub in Preslia
49: 209. 1977.
Helictochloa Romero Zarco (Poaceae), a new genus of oat grass – 103
Helictochloa praeusta (Rchb.) Romero Zarco, comb. nova
Avena praeusta Rchb., Fl. Germ. Excurs.: 140(5). 1831.
Helictochloa pratensis (L.) Romero Zarco, comb. nova
Avena pratensis L., Sp. Pl.: 80. 1753.
Helictochloa pratensis subsp. amethystea (Br.-Bl.) Romero
Zarco, comb. nova
Avena pratensis subsp. amethystea Br.-Bl. in Commun.
Stat. Int. Géobot. Médit. Montpellier 87: 223. 1945.
Helictochloa pratensis subsp. gonzaloi (Sennen) Romero
Zarco, comb. nova
Avena gonzaloi Sennen, Pl. Espagne 1925: nº 5454.
1925-1926 [in sched., cum notula].
Avenula pratensis subsp. gonzaloi (Sennen) Romero
Zarco in Lagascalia 13: 86. 1984.
Helictochloa pratensis subsp. iberica (St.-Yves) Romero Zarco,
comb. nova
Avena pratensis subsp. iberica St.-Yves in Candollea
4: 435. 1931.
Helictochloa pratensis subsp. hirtifolia (Podp.) Romero Zarco,
comb. nova
Avenastrum pratense subsp. hirtifolium Podp. in Cas.
Morav. Zemsk. Mus. Brne 12: 272. 1912.
Helictochloa pruinosa (Hackel & Trabut) Romero Zarco,
comb. nova
Avena pruinosa Hackel & Trabut in Bull. Soc. Bot.
France 36: 411. 1889.
Helictochloa talaverae (Romero Zarco) Romero Zarco,
comb. nova
Avenula talaverae Romero Zarco in Lagascalia 13:
138. 1984.
Helictochloa versicolor (Vill.) Romero Zarco, comb. nova
Avena versicolor Vill., Prosp. Hist. Pl. Dauphiné: 17.
1779.
Helictochloa versicolor subsp. caucasica (Holub) Romero
Zarco, comb. nova
Helictotrichon versicolor prol. caucasicum Holub in
Preslia 31: 51. 1959.
Avenula versicolor subsp. caucasica (Holub) H. Scholz
& Valdés in Willdenowia 36: 663. 2006.
Helictochloa versicolor subsp. praetutiana (Arcang.) Romero
Zarco, comb. nova
Avena scheuchzeri subsp. praetutiana Arcang., Comp.
Fl. Ital.: 777. 1882.