Review Article Journal of Orthoptera Research 2024, 33(1): 103-112 Egg shape and size in Phaneropierinae and other Tettigonioidea (Orthopiera, Ensifera): A global review with new data KLAUS-GERHARD HELLeR!, CLAUDIA HEmpP23 1 Triesdorf Bahnhof 8, 91732 Merkendorf, Germany. 2 University of Bayreuth, Department Plant Systematics, Bayreuth, Germany. 3 Senckenberg Biodiversity and Climate Research Centre, Frankfurt, Germany. Corresponding author: Klaus-Gerhard Heller (heller.volleth @t-online.de) Academic editor: Fernando Montealegre-Z | Received 23 November 2023 | Accepted 12 January 2024 | Published 1 April 2024 https://zoobank. org/04D76225-AE66-4891 -8ED2-7A2CC5DD2577 Citation: Heller K-G, Hemp C (2024) Egg shape and size in Phaneropterinae and other Tettigonioidea (Orthoptera, Ensifera): A global review with new data. Journal of Orthoptera Research 33(1): 103-112. https://doi.org/10.3897/jor.33.116173 Abstract Tettigonioids typically deposit their eggs within the substrate, whether in the soil or in plants. Consequently, these eggs often exhibit a rounded shape with a relatively smooth surface. Despite this, various studies have consistently demonstrated that egg shape is a stable characteristic within species, differing between distinct groups. However, to date, no compre- hensive comparative analysis has been conducted, even though regional studies have suggested that the eggs of Phaneropterinae differ from all oth- ers. In this study, we present data on the length, width, and height of 352 species and subspecies, including measurements for 158 species that were newly assessed. Our findings substantiate the claim that the eggs of the Phaneropterinae subfamily can be distinguished by their flattened shape. Based on this important and diagnostic characteristic, we advocate for the re-transfer of the genus Brinckiella into Meconematinae. We propose a hy- pothesis suggesting that the evolution of the flattened egg shape in Phan- eropterinae may have conferred advantages during the adhesive process of attaching eggs to plants—an assumed ancestral method of oviposition in this subfamily. Subsequently, these flat eggs found their way onto leaves or into the ground. While some other subfamilies exhibit eggs conforming to the basic tettigonioid shape, they showcase distinct features (e.g., Pseu- dophyllinae, Mecopodinae). We anticipate that future investigations into the lesser-explored Meconematinae, focusing on the small eggs and the oviposition behavior within this subfamily, will yield intriguing insights. Keywords oviposition, Phaneropteridae, tettigoniid subfamilies Introduction A significant proportion of animals engage in oviparity, or the laying of eggs. During the egg stage, individuals are typically most immobile and least capable of defending themselves. None of the species-specific adult morphological characteristics are discern- ible during this phase. Nevertheless, substantial variation exists in the eggs of different species, as demonstrated convincingly by Church et al. (2019a), who also explored the reasons for this di- versity. Perhaps not surprisingly, they argue that oviposition sites and styles play a crucial role in explaining egg diversity. While the variability in egg size spans ten magnitudes when comparing all insects, it gradually diminishes when examining selected groups. In Polyneoptera, for example, egg volume varies by more than six magnitudes (Church et al. 2019a, fig. S3), whereas in Orthoptera, the range is less than three magnitudes, from 0.1 mm} to about 40 mm3. Similarly, in Tettigonioidea, the range is from 1.3 to 17 mm? (Church et al. 2019b). The situation for egg shape ap- pears to be analogous, with related taxa exhibiting relatively small differences. However, despite studying more than 6700 species, Church et al. (2019b) only provided data sets for 30 tettigonioid species from seven papers. In contrast, early comparative studies of tettigonioid eggs by Cappe de Baillon (1920) depicted diverse eggs from taxonomically different groups. Over 30 years later, Bei-Bienko (1954) proposed a distinctive flattened egg shape as a diagnostic characteristic of the subfamily Phaneropterinae (“The markedly flat form of the egg is highly typical of the subfam- ily Phaneropterinae, in contrast to other Palearctic Tettigoniidae” p. 18, Bei-Bienko 1954). These interesting observations, however, were possibly over- looked, and eggs have not received much attention in either gen- eral biology or taxonomy, except for a few studies in selected tet- tigonioid species from European countries (Hartley 1964, Hartley and Warne 1972, Mazzini 1976). It was only in 1993, within the second volume of his Monograph of the Tettigoniidae of Australia, that Rentz initiated the comparative description and illustration of eggs from various species, continuing this project in subsequent papers (see Suppl. material 2). Later, Rentz et al. (2007) utilized the characteristic shape of eggs to place the newly described ge- nus Alinjarria Rentz, Su & Ueshima, 2007 in Listroscelidini, align- ing with karyological data. For most areas outside Australia, such Copyright Klaus-Gerhard Heller & Claudia Hemp. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) 104 discussions and decisions often lack comprehensive knowledge. In the description of Lipotactinae eggs, Ingrisch (1995) briefly touches on egg shape and color in some other subfamilies but without providing fundamental data on the studied genera and species. Mazzini (1987) and Ingrisch (1995) corroborate Bei- Bienko’s (1954) observations regarding the peculiar egg shape of phaneropterines, yet data for all three spatial dimensions are nearly always absent for this subfamily. This paper aims to document the morphology and size of ap- proximately 150 previously unstudied species’ eggs and to com- pare them with published data from a similar number of species. It is crucial to bear in mind that, despite their well-defined shape, eggs are evidently not as stable as other chitinous structures, such as the pronotum or hind femora. In 1909, Vosseler described and figured changes in egg shape and an increase in volume dur- ing embryonic development in a species of Eurycorypha. Similar changes were observed by Eluwa (1970), supported by quantita- tive data. Ingrisch (1988) noted a 50-150% increase in egg mass during development. This change is based on resorption of con- tact water, with the percentage differing between species (Ingrisch 1988). Of course, this increase changes the dimensions of an egg considerably, as evidenced by Vosseler’s (1909; p. 163) figures and Unal and Beccaloni’s (2017; fig. 119) photos showing new- ly laid and old eggs. The issues associated with increasing mass may be less significant when comparing only newly laid or ripe eggs taken from females. However, the effects of water uptake and loss can manifest in various ways, including the potential for eggs preserved dry to lose water and size without visible collapsing. Conversely, immersing eggs in distilled water for 24 hours before study, as done by Mazzini (1976), may artificially inflate them. Fortunately, in most cases, the basic shape of the egg seems unaf- fected, making the relationships of dimensions more reliable than one-dimensional measurements, although the numerous poten- tial sources of inaccuracies should not be overlooked. Materials and methods For this study, 458 eggs from 158 species and subspecies were examined. The locality data of the females the eggs came from are given in Suppl. material 1. Species names are used as proposed in OSF (Cigliano et al. 2023). In addition, all literature data we could localize were included, increasing the number of species/ subspecies to 352. A complete list of species including data and references is presented in Suppl. material 2. Phaneropterinae @ Mecopodinae + Phyllophorinae 4 Pseudophyllinae 7 v genus Brinckiella Height Width Fig. 1. Dimensions of eggs in different tettigonioid groups. A. Height versus width; B. Aspect ratio versus length. K.-G. HELLER AND C. HEMP The eggs were obtained in various ways. (1) Mated and un- mated females, kept in captivity, laid eggs (relatively few spe- cies). (2) For the majority of species, ripe eggs were taken from females immediately after preparation (e.g. for chromosome stud- ies). (3) In other cases, eggs were received from specimens pre- served in ethanol. The eggs were preserved in 70% ethanol or as dried specimens. The eggs were photographed (OLYMPUS SZ Binocular Stereo Zoom Microscope equipped with a digital camera SONY Cyber- shot DSC-P120), all at the same magnification, placing them horizontally and vertically using plasticine. In the photos, the eggs were measured, the largest dimension defined as length, the second largest as width, and the smallest as height (= thickness). Following Church et al. (2019a), the ratio of length to width is called aspect ratio. Relative thickness is defined as (length x width) / height. Egg volume is estimated as 1/6 *length*width*height [volume of an ellipsoid V=(4/3)x *(length/2)*(width/2)* (height/2)|, with height being replaced by width in approximately cylindrical eggs. Results The majority of Tettigonioidea exhibit ovoid-cylindrical eggs where the width is approximately equal to the height (Fig. 1A) and both ends are rounded. These eggs can be either straight or slightly curved, characterized as “generally rather sausage-shaped” by Preston-Mafham (1990). However, the subfamily Phanerop- terinae deviates from this norm; their eggs consistently exhibit a flattened shape, varying in degree (Fig. 1), with only rare in- stances approaching a cylindrical form. Consequently, the aspect ratio (length/width) is notably low in all phaneropterines, rarely exceeding three and never reaching four (Fig. 1B; for Brinckiella, see below). In terms of egg size, within our sample of 339 tettigonioid species, the length of eggs ranged from 1.6 mm (Amyttosa insec- tivora Naskrecki, 2008) to 12.6 mm (Saga ephippigera Fischer von Waldheim, 1846). The volume (n=291) ranged from 0.1 [Indiamba malkini (Jin, 1993) in Kevan and Jin 1993] to 46 mm (Philoscir- tus cordipennis Karsch, 1896) (refer to Suppl. material 2 for de- tailed information). Table 1 provides an overview of the subfamilies and tribes along with the number of species for which data on egg morphol- ogy are available (see Suppl. material 2 for details). Subsequent sections will address each of these groups separately. vy Tettigoniinae A other subfamilies | Conocephalinae © Meconematinae io, “12 ea Length JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) K.-G. HELLER AND C. HEMP Table 1. Number of species with detailed egg data in families, subfamilies, and tribes of Tettigonioidea (for full data, see Suppl. material 2). Family Subfamily Tribe / species group Number of species Phaneropteridae Mecopodinae 16 Phaneropterinae Acrometopini 5 Amblycoryphini 18 Barbitistini 49 Ducetiini 3 Elimaeini 4 Ephippithytae 7 Holochlorini 14 Insarini 3 Letanini 2 Microcentrini 2 Odonturini 7 Phaneropterini 18 Steirodontini 3 ungrouped 9 groups with single 9 representatives Phyllophorinae 3. Pseudophyllinae 16 Tettigoniidae Tettigoniinae Arytropteridini 2 Decticini 2: Nedubiini 6 Platycleidini 44 Tettigoniini 3 groups with single 2 representatives Bradyporinae Bradyporini 1 Ephippigerini 12 Zichyini 1 Austrosaginae 6 Hetrodinae / -ini 4 Listroscelidinae Requenini 8 Terpandrini 6 ungrouped 4 [Conocephalinae gr.]|_ Conocephalinae Agraeciini 10 Conocephalini 5 Copiphorini 6 Euconchophorini 2, Hexacentrinae Hexacentrini 3 Lipotactinae 1 [Meconematinae gr.| | Meconematinae Meconematini 5 Phisidini 6 Phlugidini 4 Meconematinae ? Brinckiella 3 [unknown gr.] Phasmodinae 1 Saginae 5 Tympanophorinae 3 Zaprochilinae 5 Phaneropteridae Phaneropterinae (153 species studied) Fig. 2 illustrates examples of phaneropterine eggs. Based on the still-limited sample, the most prevalent shape is depicted by Fig. 2A [Elimaea subcarinata (Stal, 1861)], characterized by a very flat pro- file with a height of approximately 0.5 mm. This particular shape is observed in Phaneropterini, Amblycoryphini (mainly the genus Eurycorypha), and Elimaeini (Fig. 3). Notably, these eggs are not al- ways elliptical and occasionally exhibit asymmetrical shapes (e.g., 105 Paraplangia Heller et al., 2018). Among the larger Holochlorini, there is a tendency for slightly thicker eggs. In the case of Barbitistini, a flightless tribe with abundant species, most members have relatively thick eggs. A few even approach the cylindrical egg shape of other subfamilies (e.g., Fig. 2B; Poecilimon pergamicus Brunner von Wat- tenwyl, 1891), while others have larger eggs without a proportion- ate increase in absolute height (e.g., Fig. 2C; Polysarcus denticauda (Charpentier, 1825)). However, the eggs of the genus Brinckiella Chopard, 1955, previously transferred from Meconematinae to Phaneropterinae by Naskrecki (1996), significantly differ from all other known Phaneropterinae. The figured eggs (Naskrecki and Bazelet 2009) are elongated and cylindrical (Fig. 1, red triangles). We propose a provisional re-transfer of Brinckiella to Meconemati- nae due to the unique mix of characters in this genus (Naskrecki and Bazelet 2009). In Phaneropterinae, egg length varies between 2.8 mm (Caedi- cia flexuosa Bolivar, 1902) and 8.8 mm (Zeuneria biramosa Sjostedt, 1929). The size of these eggs, like tettigonioid eggs in general, cor- relates strongly with the body size of the respective species (com- pare, e.g., the eggs of the small Poecilimon pergamicus with those of the large Zeuneria biramosa Sjostedt, 1929; Fig. 2B vs. 2D). How- ever, quantifying this correlation is challenging due to the absence of mass data, and morphological characteristics, such as the length of the pronotum or hind legs, may be influenced by genus-specific differences. To address this issue, we used data from the genus Poecilimon sensu lato (Borissov et al. 2023), where male body mass data were available and utilized as a proxy for female body mass. Egg volume was then calculated from size measurements and compared with the mass data (Fig. 4). The regression line (f(x) = 0.005371x + 1.375; r*= 0.80) indicates that an increase in (male) body mass by one gram results in a slight increase of more than five mm3 per egg. These volume changes can be directly correlated with changes in egg mass, as evidenced by the close relationship between volume and mass in the two studied species. Among the extensive collection of phaneropterid eggs (>150 species), some exhibit unique characteristics. Notably, the eggs of Debrona cervina Walker, 1870 (Fig. 2E) are particularly unusual, with the female laying “eggs individually on the upper surface of leaves, with each egg placed on a short vertical stalk” (Naskrecki and Guta 2019; fig. 37G; Hemp 2021, fig. Debr 8, p. 301). Three African species, still ungrouped systematically, share another dis- tinctive feature. The very thin eggs of Tropidonotacris grandis Ragge, 1957 (Fig. 2F) and two species of Ectomoptera (Fig. 2G; E. spec.) possess a flat lateral extension on one side. A similar extension is found in three Asian Holochlorini. The eggs in these species [Fig. 2I-K; Arnobia ocellata (Ingrisch, 1994), Arnobia spec, Stictophaula armata Ingrisch, 1994] are also very thin, but the extension runs around the egg, with varying widths between species. Ingrisch (1994) provides photos of living eggs of Arnobia ocellata just be- fore nymphal eclosion. It is possible that Leucopodoptera eumundii Rentz & Webber, 2003, exhibits a similar modification (Webber et al. 2003, fig. 11). Another uncommon egg shape is found in Phlau- rocentrum mecopodoides Karsch, 1892, where the egg is flattened but has a peak on the upper and lower sides (Fig. 2H; Massa 2013). Mecopodinae (16 species studied) and Phyllophorinae (3 species studied) Examples of eggs from both subfamilies are represented in Fig. 5A-E. Characteristic of most mecopodine eggs are an “elongate shape, the furrow [groove in Rentz et al. 2006], and the hook at one of the poles,” as concluded by Hemp (2021) based on observations JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) 106 K.-G. HELLER AND C. HEMP Fig. 2. Eggs of Phaneropterinae (above dorsal view, below lateral view). A-D. ‘Typical’ eggs: A. Elimaea subcarinata; B. Poecilimon pergamicus; C. Polysarcus denticauda; D. Zeuneria biramosa; E-H Peculiarly shaped eggs: E. Debrona cervina; F. Tropidonotacris grandis; G. Ectomoptera sp.; H. Phlaurocentrum mecopodoides [from Massa 2013; length 3.2 mm (Massa, per email) |; I. Arnobia ocellata; J. Arnobia sp.; K. Stictophaula armata. Scale bar: 5 mm. Amblycoryphini Barbitistini Elimaeini Holochlorini Phaneropterini other tribes / ungrouped d40¢ > @ Egg volume ssew 665 Male Body Mass Fig. 4. Relationship of egg volume and egg mass to body size (proxy male body mass) in the genus Poecilimon s.1. (data of male body mass from Vahed and Gilbert 1996, Borissov et al. 2023; data of egg mass from Hartley and Warne 1972, Reinhold and Heller 1993). of six East African species (fig. Mepo 41, p.179). In some species, ei- ther the longitudinal groove or the hook may be absent. However, the eggs of Griffiniana duplessisae Naskrecki & Bazelet, 2012 [and likely those of Macroscirtus acutipennis (Karsch, 1886) as per Eluwa 1970 and Corycoides kraussi Kirby, 1906 as per Eluwa 1971] lack both of these characteristics, described as rounded spindle-shaped (see Naskrecki and Bazelet 2012, fig. 2K). In certain species, such as those in the genus Philoscirtus, the choria (egg coverings) exhibit unusually strong sculpturing (see fig. Mepo 41 in Hemp 2021). The egg shape in the few studied Phyllophorinae closely re- sembles that of Mecopodinae. In Phyllophorella queenslandica Rentz, Su & Ueshima, 2009, both a groove (referred to as sulcus by Rentz et al. 2009) and a hook are visible. In Siliquofera grandis (Blanchard, 1853), only the groove is recognizable, distinguished by a different chorion coloration (Korsunovskaya et al. 2020, fig. 2F). The eggs of Phyllophorina kotoshoensis Shiraki, 1930 exhibit a similar shape but lack both a groove and a hook (Fig. 5E). Pseudophyllinae (16 species studied) Examples of pseudophylline eggs are depicted in Fig. 5F—J. His- torically, Pseudophyllinae eggs have been documented in six studies, with five dealing with a single species each (Cappe de Baillon 1920, Leroy 1969, Eluwa 1975, Vera 2010, Rentz et al. 2010), and one cov- ering two species (Rentz et al. 2015). Most of these papers do not mention others, except for Rentz et al. (2015), which refers to Rentz et al. (2010), and Leroy (1969), which cites Cappe de Baillon (1920). In contrast to other subfamilies, the eggs of nearly all pseu- dophylline species exhibit distinct structural differences between both poles and the surrounding regions (up to half of the egg’s length). Eluwa (1975) observed the oviposition (in wood), and his description may also be valid for most other species: “The an- terior one-fifth of the egg is covered by a parchment-like spongy JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) K.-G. HELLER AND C. HEMP 107 Fig. 5. Eggs of Mecopodinae (A-D), Phyllophorinae (E) and Pseudophyllinae (F-J) (above dorsal view, below lateral view). A. Mecop- oda elongata; B. Afromecopoda preussiana; C. Leproscirtus granulosus; D. Apteroscirtus densissimus; E. Phyllophorina kotoshoensis; F. Zabalius apicalis; G. Pseudotomias usambaricus; H. Gnathoclita vorax; 1. Onomarchus cretaceus; J. Onomarchus uninotatus. Scale bar: 5 mm. process which during oviposition is moulded into a flat strip of tissue along the plane corresponding to the broad sides of the egs.” The eggs laid by a female of Onomarchus cretaceus (Serville, 1838) align well with this description (Fig. 6), although the strip is much longer than that illustrated by Eluwa (1975) for Zaba- lius apicalis (Bolivar, 1886). On the other hand, in Acauloplacella hasenpuschae Rentz, Su & Ueshima, 2010 (Rentz et al. 2010) and Mastighaphoides tuberculatus Rentz, Su & Ueshima, 2015 (Rentz et al. 2015), the strips are smaller and assume different shapes. Eggs of Sathrophyllia rugosa (Linnaeus. 1758) (Cappe de Baillon 1920) and Aphractus acuminatus Brunner von Wattenwyl, 1895 (Vera 2010) exhibit essentially similar shapes, although eggs taken from deceased females may not fully display their natural form. While the eggs of most species in this subfamily are cylin- drical, they are exceptionally flat in Cocconotus insularis (Bruner, 1906) (as Bliastes insularis in Leroy 1969). Even in this species, “the egg has a well-marked polarity, with one end lined with a very characteristic fishnet extending over one of the keels of the egg in its anterior third” (Leroy 1969). Surprisingly, the eggs of Chloracantha garradunga Rentz, Su & Ueshima, 2015—originally described under Mecopodinae (Hebard 1922)—lack a strip or grooves and are flattened, similar to typical phaneropterine eggs (Rentz et al. 2015). Tettigoniidae Tettigoniinae (59 species studied), Bradyporinae (14 species studied), Listroscelidinae (18 species studied), Hetrodinae (4 species studied), and Hexacentrinae (3 species studied) Examples of eggs from these five subfamilies are represented in Fig. 7A-H. To the best of our knowledge, nearly all species within these subfamilies exhibit typical ovoid-cylindrical or sausage- shaped “tettigoniid” eggs, with only very few being slightly wider than high. Conocephalinae (23 species studied) Examples of conocephaline eggs are depicted in Fig. 7I-J. As highlighted by Ingrisch (1995), eggs in this subfamily are fre- quently characterized by a thin-elongate shape featuring a high aspect ratio (refer to Fig. 1B) and a semi-transparent appearance. It is worth noting that the aspect ratio values for both Euconcho- phorini species studied are the lowest within the subfamily. Meconematinae (15 species studied) Examples of meconematine eggs are presented in Fig. 7K—M. The eggs within this subfamily, while small as expected for the body size of the species, exhibit unusual diversity. This diversity may be partly attributed to the possibility that the tribe Phlugidini does not belong to Meconematinae; in the phylogenetic tree of Mugleston et al. (2018), it is positioned distant from the other Meconematinae. The eggs of this tribe differ from those of all other tettigoniid sub- families and bear a slight resemblance to those of the phanerop- terid Pseudophyllinae. In all four examined species (from Africa, Australia, and South America), one pole of the egg terminates in a ‘cap’ (Rentz 2001) or ‘egg cover plate’ (Eichler 1938). Following oviposition, this plate lies flat on the plant surface (see, e.g., Leroy 1969) and is opened by the hatching nymph (Eichler 1938). However, even the eggs of the remaining and possibly closely related Meconematinae (Meconematini and Phisidini, according to Mugleston et al. 2018) display significant diversity. Notably, the eges of Amyttosa insectivora (Fig. 7N; from Naskrecki 2008) stand out, differing from all other Tettigonioidea and resembling those of many Phasmatodea. These insects drop their eggs to the ground, where ants find, bury, and securely store them underground (see Hughes and Westoby 1992; Naskrecki 2008). Favorable precon- ditions for the evolution of such behavior may have been eggs like in Amytta (Fig. 7K) with deep indentations in the shell, although the function of these indentations remains unknown. JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) 108 K.-G. HELLER AND C. HEMP Fig. 6. Eggs of Onomarchus cretaceus. A. Oviposition site with only the strips of the eggs visible; B. Wood opened with eggs completely visible (eggs damaged - dried out). A Fig. 7. Eggs of Tettigoniidae (above dorsal view, below lateral view). A. Glyphonotus sinensis (Tettigoniinae); B. Parnassiana fusca (Tettigoniinae); C. Uromenus idomenaeus (Bradyporinae); D. Deracantha onos (Bradyporinae); E. Neobarretia imperfecta (Listroscelid- inae); F. Spalacomimus verruciferus (Hetrodinae); G. Hexacentrus unicolor (Hexacentrinae); H. Aerotegmina kilimanjarica (Hexacentri- nae; egg damaged - dried out); I. Afroagraecia sp. (Conocephalinae); J. Amblylakis nigrolimbata (Conocephalinae); K. Amytta mramba (Meconematinae); L. Neophisis siamensis (Meconematinae); M. Phlugidia kisarawe (Meconematinae); N. Amyttosa insectivora (Mecone- matinae; from Naskrecki 2008); O. Saga natoliae (Saginae; dorsal = lateral view). Scale bar: 5 mm. JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) K.-G. HELLER AND C. HEMP In terms of general shape, the other Meconematini exhibit typical tettigoniid eggs, but in African species, their two poles are more distinct (Fig. 7K; Naskrecki 2008). Finally, eggs of Phisidini mostly feature high aspect ratio values, meaning they are long and slender (see Fig. 7L). Saginae (5 species studied) and other subfamilies (Austrosaginae, Lipotactinae, Phasmodinae, Tympanophorinae, Zaprochilinae; 16 species studied) An example of a sagine egg is shown in Fig. 7N. Saginae stands out among Tettigonioidea species, featuring some of the largest eggs (refer to Suppl. material 2). In terms of shape, the eggs of Sa- ginae, as well as those from other subfamilies with available data (though not illustrated here), exhibit the typical ovoid-cylindrical or sausage-shaped morphology characteristic of ‘tettigoniid’ eggs. Discussion The eggs of most Tettigonioidea exhibit a relatively simple shape, lacking the diversity observed, for instance, in Phasmato- dea. This apparent uniformity may stem from the prevalent prac- tice of depositing eggs within the substrate, whether in various types of plant material or in the ground (see Gwynne 2001). In such environments, ovoid-cylindrical eggs, resembling cylinders with rounded ends, appear to be the most advantageous. Only a few groups deviate from this general pattern, with the subfamily Phaneropterinae being the most notable exception. As evident from the presented data and highlighted by various authors, the eggs of Phaneropterinae consistently exhibit a flattened shape, albeit to varying degrees. The thinnest eggs, as seen in Phan- eroptera, Eurycorypha, and Elimaea, are typically inserted between the upper and lower epidermis of leaves (first described by Riley 1874; see figures, e.g., in Hemp 2021, fig. Eury 82, Naskrecki and Guta 2019, fig. 44). The females of this subfamily display remarkable skill in egg placement (see figures in Massa and Rizzo 1998), capable of depos- iting eggs even within sheets of paper (Grasse and de Vichet 1924, own observations of Letana inflata (Brunner von Wattenwyl 1878) laying into blotting paper). The short, sickle-shaped ovipositors of many Phaneropterinae species are well-suited for this behavior. However, oviposition in phaneropterines exhibits considerable diversity (see e.g., Rentz 2010; Hemp 2021) and is not always con- fined to the substrate. Even species with thin and flat eggs can use places other than leaf edges. While most Eurycorypha species insert their eggs into leaves, some (e.g., E. pseudomeruensis Hemp, 2017) adhere the eggs to the surface of leaves or in crevices (Hemp. 2021), and others (e.g., E. curviflava Hemp, 2017) prefer foamy material (Hemp. 2021). The use of fluids to adhere eggs to plants appears to be crucial for phaneropterines. Many species directly attach eggs, uncovered, to leaves or twigs, as first described by Riley (1874; Fig. 8). Even species depositing their eggs in leaves often employ glue, as noted by Riley (1874) and Vosseler (1909). The use of fluids is also observed in ground-laying barbitistines (Reinhold 1999; also in Po- ecilimon affinis (Frivaldszky, 1868), Fig. 8). Some species even attach additional material to the eggs, possibly to conceal them or prevent desiccation (Polichne: Rentz 1996; Arantia, Terpnistria: Naskrecki and Guta 2019). Little is known about the nature of these fluids or their origin, which could be from glands in the oral cavity (as the mouth- parts are highly active during oviposition), the abdomen, or both. The adhesive function of these fluids may be central to understand- ing the evolution of egg shape; flattened eggs provide a larger sur- face area for adhesion, ensuring better stickiness and reduced risk of falling. This holds true even for eggs too thick to be inserted into 109 plants. Following this line of reasoning, thin eggs placed in leaves might have evolved as a secondary adaptation. The flatness of eggs in Phaneropterinae exhibits a notable degree of flexibility but is almost never entirely lost, even when genera “re- turn” to ground oviposition. The tribe Barbitistini is a flightless and speciose group in the western Palearctic, well supported by molecular data (Ullrich 2010, Grzywacz et al. 2018, Borissov et al. 2023). Some species within the genus Leptophyes, a member of this tribe, produce eggs ranging from flat to very flat (see Suppl. material 2). These eggs are often laid in bark or old galls, deviating from the typical leaf depo- sition (Deura and Hartley 1990; Cerasa and Massa 2016). Some other genera oviposit in bark and soil [species of Barbitistes, see Gottwald et al. 2002; Metaplastes ornatus (Ramme, 1931), own unpublished data] but have thicker eggs. The largest genera of the Barbitistini tribe, Iso- phya and Poecilimon s.1., predominantly lay eggs in the ground (Fig. 8G-H,; see also Heller 2021). Despite their thickness, these eggs main- tain a flattened shape (wider than high), with Poecilimon pergamicus (Fig. 2B) coming closest to a cylindrical form (see Suppl. material 2). Even in species with peculiar egg shapes (Fig. 2E-H), the flattened form persists. In some of these species, the eggs exhibit flat lateral extensions. Given the thinness of these eggs, one may hypothesize that these flat parts serve to stabilize the egg, particularly during ovi- position. The distinct shapes of these extensions (see Fig. 2F-G, I-K) suggest a separate origin in at least two groups. While gluing appears to be infrequent in other subfamilies, re- lated traits are known. Ingrisch (1998) reported a secreted envelope around each egg in Pseudosubria, deemed “unique in tettigoniids.” For Acanthopus discoidalis (Walker, 1869), Power (1958) described nests of egg packets, each consisting “of a hard roughly rectangu- lar pellet of clay in which the eggs are firmly cemented.” Although more instances may emerge with increased research, gluing and the distinct egg shape remain characteristic of Phaneropterinae. Egg color does not appear strictly correlated with oviposition. Eggs laid in leaves may be bright, as seen in Elimaea (Fig. 2A) and Eulioptera, or dark brown, as in Eurycorypha. Most species in the subfamilies Mecopodinae and Pseudophyl- linae feature cylindrical eggs. These eggs are distinguished by varia- tions in the structure of both egg poles. While many mecopodines have a stalk-like process on one pole (Fig. 5A, C, D), in Pseudophyl- linae, nearly half of the egg is typically modified. Both structures were described by Cappe de Baillon (1920) and are thought to be crucial for air regulation, a conclusion based on egg anatomy. Rentz et al. (2015) suggested that one “end protrudes slightly above the substrate, presumably to capture moisture to prevent the egg from desiccating.” However, water uptake for development is also necessary (Vosseler 1909, Ingrisch 1988). In Onomarchus cretaceus, one end even catries a large soft elongation (strip; Fig. 6), possibly serving the same function. Such modifications, potentially produced by glands, may be more widespread in the subfamily but not easy to detect in dead specimens. Many other subfamilies exhibit simple ovoid-cylindrical eggs, including Conocephalinae with high aspect ratios (Fig. 1B). The di- verse egg shapes within Meconematinae are described above, and it remains to be seen if other intriguing egg shapes, akin to that of Amyttosa insectivora (Naskrecki 2008), will be discovered. For exam- ple, what does the eggs of the minute Phlugiolopsis look like? The lack of information on egg characteristics for certain subfamilies and tribes, such as Microtettigoniinae and Pterochrozinae, under- scores the importance of further research, particularly when con- sidering egg size. In our dataset of approximately 350 tettigonioid species, egg volume ranged from 0.1 to 46 mm, already exceeding the scale presented in Church et al. (2019b) by more than one order of magnitude. However, data for very small species are still absent. JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1) 110 K.-G. HELLER AND C. HEMP Fig. 8. Phaneropterine eggs in situ and oviposition. A-F. Eggs on and in plants after oviposition. A, B. Eggs glued on leaves: A. Catop- tropteryx aurita; B. Gonatoxia maculata; C-E. Eggs inserted into leaves: C. Gonatoxia immaculata; D. Eurycorypha resonans; E. Plangia multi- maculata; F. Eggs inserted into twigs: Dioncomena tanneri; G, H. Oviposition into the ground: Poecilimon affinis, G. Female ovipositing; H. Immediately after oviposition. Note the moist sand around the oviposition site. Conclusions It appears that the evolution of egg shape in Tettigoniidae, particularly in the subfamily Phaneropterinae, might have been influenced by oviposition behavior and method of attaching eggs to plants. The flattened shape of the eggs in Phaneropterinae is suggested to be advantageous for gluing them to surfaces. Flat eggs might provide better stability and adhesion, thereby reducing the risk of eggs falling down. The flattened shape is even maintained when some genera within the subfamily return to ovipositing in the ground. 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Copyright notice: This dataset is made available under the Open Database License _ (http://opendatacommons.org/licenses/ odbl/1.0/). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this Dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited. Link: https://doi.org/10.3897/jor.33.116173.suppl1 Supplementary material 2 Author: Klaus-Gerhard Heller, Claudia Hemp Data type: xls Explanation note: Species list including measurements and refer- ences. Copyright notice: This dataset is made available under the Open Database License _ (http://opendatacommons.org/licenses/ odbl/1.0/). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this Dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited. Link: https://doi.org/10.3897/jor.33.116173.suppl2 JOURNAL OF ORTHOPTERA RESEARCH 2024, 33(1)