Isophya
publication ID |
https://doi.org/ 10.11646/zootaxa.3658.1.1 |
publication LSID |
lsid:zoobank.org:pub:C02D1C74-25C0-41DD-B098-62098EB7B62A |
DOI |
https://doi.org/10.5281/zenodo.5617309 |
persistent identifier |
https://treatment.plazi.org/id/F26F3128-390C-FF95-B1B0-0B6CFC2A9981 |
treatment provided by |
Plazi |
scientific name |
Isophya |
status |
|
Systematics of Isophya
There are few attempts to classify the species of Isophya in groups according to their morphology, bioacoustics,
karyology and/or molecular genetics (Heller 1988; Sevgili et al. 2006; Warchałowska-Śliwa et al. 2008; Chobanov
2009a, 2009 b; Grzywacz-Gibała et al. 2010; Ünal 2010). Yet, some of these attempts are controversial. Moreover,
the mentioned studies do not include all described taxa and more or less deal with regional fauna. The present study
has not the aim to reconstruct the relationships within this genus; instead it aims to classify the Balkan
representatives of Isophya using some basic phylogenetic information. For this purpose we used the earlier
published data (see the above citations), together with newly collected information to get idea on the species
grouping.
Morphology (general morphology shown in Figs 1–30 View FIGURES 1 – 18 View FIGURES 19 – 30 ). Various characters were used to outline and
characterise species relationships (e.g. Bey-Bienko 1954; Heller 1988; Sevgili et al. 2006; Warchałowska-Śliwa et
al. 2008; Chobanov 2009a). Some examples follow:
1. Tegmen (reduced fore wing transformed into a sound-producing organ) ( Figs 31–79). According to the specialisations for sound-production the form and venation of tegmina vary between species and may reflect either synapomorphies or convergencies. Males: (1) relative length of tegmina (compared to the stridulatory area and body length); (2) position of veins in relation to one another (see Fig. 32 and compare Figs 31–55)—the level of compression of tegmina through reduction the apical part of the Costo-Medial area of the wing and approximation of veins in the sound producing Medio-Anal area, which may result in changes in the form of tegmina becoming bulged and membranous; (3) development of the “stridulatory” vein CuP (Cubitus Posterior or the hind Cubital vein) and structure of the stridulatory file (pars stridens). Females: (1) position of veins in relation to one anotherparallel or reticulate; (2) structure of the secondary stridulatory apparatus—with one to three–four basal rows of teeth. The plesiomorphic character states in males include long, flat, coriaceous tegmina with relatively small stridulatory area and widely separated veins in the Medio-Anal area, while apomorphies express in different levels of compactization. Usually the compactization of male tegmen corresponds to the development of a net-like venation and a lower number of stridulatory filerows in females.
2. Colouration (compare Figs 1–30 View FIGURES 1 – 18 View FIGURES 19 – 30 ). The ancestral colouration is usually more or less uniform green with light lateral and ventral body surface and sometimes dark-green or brownish dorsal pattern. In some advanced groups a variegated colouration may occur, reaching development of melanism (typical for the relatives of I. speciosa and rare in other groups).
3. Other characteristics like morphology of the pronotum ( Figs 31–79), male cerci ( Figs 80–104 View FIGURES 80 – 104 ), ovipositor ( Figs 105–129 View FIGURES 105 – 129 ), horizontal and vertical distribution etc. may help in identifying species relationships or characterizing taxa.
Bioacoustics. Male calling song is amongst the most important species-specific features of the bioacoustically
active orthopterans and is frequently used for evaluating phylogenetic relationships including within
Phaneropteridae (e.g. Heller 1984, 1990; Chobanov and Heller 2010). Heller (1990) assumed that the ancestral
song in Barbitistini (Barbitistinae) consists of a sequence of single and relatively drawn-out syllables that are
loosely arranged and gradually increase in amplitude (crescending syllables) and points “ Type A” song as ancestral
in Isophya , consisting of single crescending syllables. However, this type of song is not very common in this genus
and is characteristic mostly for not closely related, morphologically specialised species occurring outside the centre
of diversity and (probably) origin of the genus ( Anatolia). The morphological (Warchałowska-Śliwa et al. 2008;
present paper) and molecular data (partly Grzywacz-Gibała et al. 2010; own unpublished data) support the most
primitive species in the genus are the relatives of I. straubei (Fieber, 1853) (e.g. I. hospodar ) evolutionary followed
by the I. rectipennis group and possibly also some other groups in Anatolia. Their songs usually contain small groups or phrases of short syllables that may be obscurely crescending or decrescending and this type of song is here considered ancestral. Specialisations resulting from this type may include complication of the syllable groups by developing different types of syllables or simplifying the song to single syllables. After developing song of single syllables it may be further changed by elaborating the syllables through modulating the sound producing wing movement and/or arranging the syllables in long sequences.
Karyology. A recent review of the karyology of Isophya involving 25 taxa (Warchałowska-Śliwa et al. 2008) showed the significant correspondence of the chromosomal characters with the morphological grouping proposed.
All but one species have a karyotype of 2n=31 (male) / 32 (female) acro- to submetacentric chromosomes with an X0/XX mechanism of sex determination. This karyotype was suggested being ancestral for most species of tettigoniids (e.g. White 1973; Warchałowska-Śliwa 1998). Only one species, I. hemiptera , from the northern Caucasus shows a neo-X/neo-Y sex determination system (Warchałowska-Śliwa and Bugrov 1998).
Morphotypes of the X-chromosome of species with X0/XX sex determination have been divided into three main categories (type 1—acrocentric; type 2—subacrocentric and type 3—submetacentric) that characterise different groups of morphologically similar taxa (Warchałowska-Śliwa et al. 2008). The few examples of controversy between morphological and cytotaxonomic grouping (in the I. pyrenaea group as defined by Warchałowska-Śliwa et al. 2008) are herewith resolved by further splitting the group into two complexes according to new morphological and acoustic data taken into consideration (see below).
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |
Kingdom |
|
Phylum |
|
Class |
|
Order |
|
Family |
|
Genus |