Abstract
Previous myological studies show inconsistencies with regard to the identification and naming of the shoulder joint muscles in frogs and toads (Amphibia: Anura). Those inconsistencies were revealed and resolved by assessing the ontogenetic development, innervation, and adult morphology of selected anuran species representing ancient lineages and two major neobatrachian groups. To do so, digital dissections of volumes acquired by histological serial sectioning, episcopic microtomy, and contrast-enhanced micro-computed tomography scanning were performed and three-dimensional reconstructions were derived. Muscle units crossing the shoulder joint were defined, their ontogenetic development was described, their homology across species was established, and a consistent nomenclature was suggested. The mm. anconaeus, dorsalis scapulae, latissimus dorsi, and the group of scapulohumeralis muscles were ontogenetically derived from the dorsal pre-muscle mass present in all tetrapods. The ventral pre-muscle mass gave rise to the mm. cleidohumeralis, episternohumeralis, supracoracoideus, coracoradialis, subcoracoscapularis, coracobrachialis, and pectoralis. The results indicate that the mm. anconaeus, dorsalis scapulae, latissimus dorsi, coracoradialis, and the portionis sternalis and abdominalis of the m. pectoralis have consistently been recognized and denoted in previous studies, whereas the names for the muscle units commonly denoted as m. coraco-brachialis longus and as parts of the m. deltoideus are misleading with regard to the ontogenetic origin of these muscles. The mm. scapulohumeralis profundus anterior and posterior, although present, have been overlooked in some studies. The mm. cleidohumeralis, supracoracoideus, and coracobrachialis are present with two parts or portions in some species, these portions have previously not always been recognized and assigned correctly.
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Introduction
The morphologies of the pectoral fins of fishes and of the forelimbs of tetrapods, as well as of the pectoral girdle that connects them to the axial skeleton, have long received attention to establish the homology of the anatomical elements across vertebrates and to understand the evolutionary transformations of fins into limbs and of limbs within tetrapods (e.g., Gegenbaur 1865; Rolleston 1869; Romer 1924; Diogo et al. 2016; Molnar et al. 2018). The evolution and resulting homologies of the skeletal elements of the pectoral girdle and forelimbs are comparably well known and supported by the fossil record (e.g., McGonnell 2001; Coates et al. 2002; Shubin et al. 2006, 2009; Ponomartsev et al. 2017), whereas the related soft tissues have rarely been considered (Soliz et al. 2018; but see, e.g., Rolleston 1869, Romer 1922, and Abdala and Diogo 2010 for attempts to assess forelimb muscle homologies across tetrapods and Diogo et al. 2016 and Molnar et al. 2018 for the reconstruction of muscle evolution across the fin-to-limb transition).
It is striking that extant amphibians are represented by a caudate species in most of the studies investigating the evolution and homology of anatomical elements of the forelimb and pectoral girdle within vertebrates (e.g., Romer 1922; Diogo and Abdala 2007; Molnar et al. 2018; but see Abdala and Diogo 2010 for the inclusion of an anuran species). It should be kept in mind, however, that the independent evolutionary history of the Caudata is as long as the one of the Anura, because both taxa are considered to be sister groups (e.g., Jetz and Pyron 2018; also see the discussion on “basal” or “ancestral” species in, e.g., Krell et al. 2004, Omland et al. 2008, and Zachos 2016). Consequently, it is likely that derived (i.e., apomorphic) character states have evolved within the Caudata if compared to the last common ancestor of the Anura and Caudata. The reconstruction of the evolution of the forelimbs could therefore benefit from the inclusion of the Anura by contributing to the assessment of muscle character states in the last common ancestor of Anura and Caudata.
Having reassessed existing descriptions of the shoulder joint muscles in different anuran species, we observed inconsistencies in the identification of muscle units and in the use of muscle names. Ritland (1955), for example, synonymized his ‘supracoracoideus superficialis’ with the term ‘pectoralis portio epicoracoidea’ utilized by Gaupp (1896) and thereby implied the homology of the corresponding muscle units. Diogo and Ziermann (2014), in contrast, reported the presence of both, a pars epicoracoidea of the m. pectoralis and a separate m. supracoracoideus, which contradicts the homology assumption by Ritland (1955). Jones (1933) observed the presence of a m. supracoracoideus profundus in, among others, two bufonid species, whereas Bigalke (1927) reported no such muscle in Bufo bufo (then B. vulgaris) but a pars superficialis of the m. coraco-brachialis brevis that remarkably resembled the m. supracoracoideus profundus in Jones (1933). The m. scapulohumeralis profundus anterior was observed in various anuran species, including representatives of the Ranidae (Tyson 1987). In a different study (Gaupp 1896), however, no such muscle was reported in species of the genus Rana. Likewise, the m. scapulohumeralis profundus posterior was observed in various species, including representatives of the Hyloidae and Ranidae (Tyson 1987), but in other studies, this muscle was neither included in a list of pectoral girdle muscles in hylid anurans, nor described in Rana (Soliz et al. 2018; Gaupp 1896, respectively).
The inconsistencies noted above make the homologization of shoulder joint muscles across anuran species challenging and obstruct the reconstruction of the character states in the last common ancestor of the Anura. The latter, however, would help to establish muscle homologies between the Anura and the Caudata, and to fit both taxa within the larger picture of the evolution of limbs.
The primary aim of the present study was to identify the muscle units occurring in the shoulder joint of anurans and to establish their interspecific homologies. To do so, the ontogenetic development and innervation of the shoulder joint muscles were assessed in three anuran species representing one ancient lineage (Bombinatoridae: Bombina orientalis (Boulenger, 1890)) and the two major neobatrachian groups (Ranoidea: Ranidae: Rana temporaria Linnaeus, 1758; Hyloidea: Bufonidae: Rhinella marina (Linnaeus, 1758)). In addition, previously published descriptions of the shoulder joint muscles in selected species (various species of Rana in Gaupp 1896; Bufo bufo (Linnaeus, 1758) in Bigalke 1927; Ascaphus truei Stejneger, 1899 in Ritland 1955) were reassessed to identify inconsistencies in the use of muscle names and to suggest a consistent nomenclature. The descriptions by Gaupp (1896) were included, because they seem to be the most frequently referenced for anuran muscle anatomy; the nomenclature introduced by him, and modified versions of it, presumably are the most widely used (compare, e.g., Bigalke 1927; Jones 1933; Mahendra 1936; Ritland 1955; Burton 1983; Duellman and Trueb 1994; Manzano et al. 2008; Baleeva 2009). The works of Ritland (1955) and Bigalke (1927) were used for comparison as they provide thorough descriptions of the muscles in species belonging to an ancient anuran linage and the Hyloidea, respectively, and because both refer to the nomenclature of Gaupp (1896).
Materials and methods
Specimens and usages
A total of 11 larvae (Table 1) ranging from Stage 32 to Stage 41 (staging after Gosner 1960) of Bombina orientalis, Rana temporaria, and Rhinella marina were used to investigate the ontogenetic development and innervation of the shoulder joint muscles by histological serial sectioning and three-dimensional (3d) reconstruction. A pre-existing dataset of Alytes obstetricans (Laurenti, 1768) (ZMH A12442) acquired by episcopic microtomy (Engelkes et al. 2018) served as source of data for that species, but was also modified and transformed into a hypothetical, schematic anatomical 3d model that illustrates all identified muscle units, their spatial relationships, and their innervations. Contrast-enhanced micro-computed tomography (µCT) volumes of adult specimens of Bufo bufo (ZMH A04660), Rhinella marina (ZMH A15443), and Ascaphus truei (UF H 80664; downloaded from MorphoSource, Duke University) were examined. Furthermore, histological serial sections from the ZMH museum collection of a late metamorphic stage of A. truei (ZMH A09807, Stage 42) were included. The latest larval stages examined and, if available, adult specimens of each exemplar species were used to reassess previously published anatomical descriptions (Gaupp 1896; Bigalke 1927; Ritland 1955) of those or closely related (Pyron and Wiens 2011) species. Specimens that were sectioned for this study were deposited at the ZMH collection (Table 1).
Histology
Larval specimens selected for histological serial sectioning were decalcified and embedded in either Paraplast Plus® (Leica Biosystems) or Roti®-Plast with DMSO (Carl Roth GmbH + Co. KG). The resulting blocks were sectioned on a rotatory microtome (Microm™ HM 340 E; Microm International GmbH) with slice thicknesses between 6 and 10 µm. Sections were mounted on glass slides and stained according to an Azan staining protocol (modified from Zbären 1966; 2–3 min staining in Kernechtrubin, 5–7 min differentiation in 5% phosphotungstic acid, 6–15 min staining in aniline blue-orange G, 4–5 min differentiation in 96% ethanol; staining durations were dynamically adjusted as needed).
The histological sections of the pectoral girdle region were digitized with a digital microscope (Leica DM6000 B; Leica Microsystems GmbH) and edited (adjustment of brightness and contrast, sharpness, and canvas size) in Fiji (based on ImageJ version 1.51n; Schindelin et al. 2012; Schneider et al. 2012). Depending on the quality of the original series of histological sections, the digital image stacks were either rigidly aligned in Amira® (version 6.0.1; Konrad-Zuse-Zentrum Berlin, FEI Visualization Sciences Group) or aligned in the Fiji plugin TrakEM2 allowing for affine or elastic transformations (Cardona et al. 2012). The resulting aligned volumes were converted to 8-bit grayscale images.
Episcopic microtomy
The generation of the previously published dataset of episcopic images of Alytes obstetricans (ZMH A12442) was described in detail in Engelkes et al. (2018); in short, the procedure was as follows: The specimen was decalcified and impregnated with lead ions followed by Paraplast Plus® embedding. Fiducial points were induced into the block to improve the image alignment quality in consecutive processing steps. Sections of 10 µm thickness were cut of the block surface using a rotatory microtome (Microm™ HM 340 E). Every 30 µm, an image of the original block surface was taken (camera: Nikon D7200®; macro lens: Nikon AF-S VR Micro-Nikkor® 105 mm 1:2,8G IF-ED; Nikon Corporation). Then, the surface was stained with a sodium sulfide solution (7%) and a second picture was taken. Images were digitally processed in IrfanView® (version 4.41; Irfan Skiljan, http://www.irfanview.com; conversion NEF to TIF) and Fiji (subtraction of corresponding unstained and stained images, and adjustment of brightness and contrast). One fiducial point per corner was used to align the stack of digital images in Amira®. The obtained volume was converted to 8-bit grayscale in Fiji. In defined distance intervals, sections of the specimen were mounted on glass slides, stained using a modified Azan staining protocol, and digitized as above. The digitized sections were rigidly aligned in Amira®.
MicroCT scanning
A µCT scan of the untreated adult Bufo bufo specimen (ZMH A04660) was performed using a YXLON FF35 CT (YXLON International GmbH). Subsequently, the specimen was contrast-stained with Lugol’s solution (modified from Metscher 2009; concentration: 1%, staining duration: 7 days, changed twice) and scanned in a YXLON FF20 CT. The unstained and stained scans were registered in Amira®. The adult specimen of Rhinella marina (ZMH A15443) was contrast-stained with Lugol’s solution (concentration: 1%, staining duration: 8 days, changed twice) and µCT scanned in a Phoenix v|tome|x L 450 (GE Sensing and Inspection Technologies GmbH). All µCT scans were performed in an ethanol-saturated atmosphere. The volumes were reconstructed from X-ray projections using the software delivered with the respective scanner.
Segmentation, 3d reconstruction, and visualization
All volumes were imported into Amira® and the shoulder joint muscles and contextual skeletal elements (in larvae: only chondrified or ossified parts, no condensations of mesenchymal cells or perichondrium/periosteum) of the right side were digitally dissected (i.e., segmented; Segmentation Editor with Brush tool). Bone and cartilage were not distinguished in most specimens. The left instead of the right side was segmented in Bombina orientalis ZMH A12427, Bufo bufo ZMH A04660, and Rhinella marina ZMH A15443 due to tissue visibility/damage on the right side. Bombina orientalis ZMH A12427 was mirrored to obtain consistent illustrations. In addition, nerves innervating the shoulder joint muscles were also segmented in the Stage 41 and 42 larvae and in the adult specimen of Alytes obstetricans. The original aligned digitized histological sections were used for comparison if possible and necessary. Polygon surfaces of the segmented anatomical elements were created and simplified by iterative reduction of polygon count and smoothing in Amira® and the surfaces were exported in obj format; surface generation and export were accelerated using a custom macro (MultiExport; see Engelkes et al. (2018) for details).
The simplified polymesh surfaces of the R. marina larvae and A. obstetricans were imported into MODO® (version 10.1v2; The Foundry) and manually edited (filling of holes, correction of artifacts, smoothing). The surfaces of some nerves showed considerable artifacts (i.e., discontinuity or holes) and needed major manual editing; care was taken to maintain the important properties (i.e., relative position to other anatomical elements and connections to muscles), but the form and thickness may not represent the actual conditions. The surfaces produced from A. obstetricans (ZMH A12442) were used to generate a schematic, generalized anuran model of all muscle portions and respective nerves observed across species by manually modifying the surfaces of the anatomical structures present and adding elements not present in that specimen. All surfaces were given descriptive colors (bone: beige; cartilage: blue; skeletal elements without distinguishing bone and cartilage: gray; muscles: various shades of red, such that adjacent muscles had different colors; nerves: yellow) prior to image rendering.
The muscle configurations in the adult specimens of B. bufo (ZMH A04660) and R. marina (ZMH A15443) were illustrated by combining polygon surfaces (skeleton) and volume renders (muscles) in Amira®; this approach allowed for the visualization of the fiber orientation in some muscles. Final figures were arranged and labeled in Adobe® Illustrator® CS6 (version 16.0.3; Adobe® Systems Software).
Muscle homology and nomenclature
We define shoulder joint muscles pragmatically as the set of all muscles that cross the shoulder joint from their respective origin to their point of insertion. Hypotheses on the interspecific homology (in terms of primary homology; de Pinna 1991) of muscle units were derived by following the criteria for homology introduced by Remane (1952). Two or more muscle units were considered to be homologous if they showed a similar relation to other (homologous) anatomical structures (first criterion of Remane 1952) and could be connected by similar (intermediate) stages during the ontogenetic development (third criterion of Remane 1952; also see Kerr 1955). The first criterion was mainly applied for the relative locations of the muscle attachment sites and the position of the muscle units to one another. The innervation was also considered as it has been proven useful for the identification and homologization of muscles (e.g., Romer 1924; Holliday and Witmer 2007) and because the branching pattern of the major nerves supplying the forelimb muscles seems to be rather conserved across tetrapods (Hirasawa and Kuratani 2018); yet, it should be noted that some studies (e.g., Cunningham 1890; Romer 1922; Haines 1935; Minkoff 1974) questioned the value of nerve supply for determining muscle homologies. Considering these previous reports on the usefulness of nerves for the determination of muscle homologies, we believed that the position of muscle units relative to major nerves is a reliable criterion to identify homologous muscle units if a common branching pattern was observed across species. In contrast, we assumed that nerve supplies might be misleading if there was no common branching pattern or if there were differences regarding minor nerves.
We suggest a nomenclature for the observed shoulder joint muscles and justify the selection of muscle names in the discussion section. To avoid confusing the reader with previous muscle terms, for consistency, we already apply those muscle names in the results section that we eventually suggest on the basis of the evidence presented in this work. In general, the muscle names established by Gaupp (1896), Bigalke (1927), or Ritland (1955) were kept if they were consistently applied in the literature and seemed appropriate to reflect the ontogenetic, and thereby possibly also the evolutionary development. Table 2 provides nomenclatural comparison with the mentioned references. Nerve terminology follows Gaupp (1899).
Results
In the Bombina, Rana, and Rhinella specimens examined (Table 1), the skeleton of the pectoral girdle and forelimbs and the muscles of the shoulder joint developed in parallel and accomplished most of their development while the limb was still inside the branchial cavity. Although there were species-specific differences in the timing of the developmental events, the general pattern of skeletogenesis was as follows: The skeletal elements (except for the dermal bones) arose from various centers of chondrification in pre-cartilaginous condensations of mesenchymal cells. The cartilaginous anlagen grew and, where appropriate, fused with one another to form a cartilaginous skeletal precursor element. Eventually, the cartilaginous precursors ossified.
Combining the observations of all larval and adult specimens, we discerned 18 distinct muscle units crossing the shoulder joint (Table 3). Some of these units, however, were species-specifically fused or did not separate during ontogeny. The following general pattern of myogenesis was found in the ontogenetic series examined: The shoulder joint muscles differentiated from condensations of pre-muscle cells. In the earliest developmental stages, Stages 32–33, the anlage of the m. anconaeus and three pre-muscle masses were present; one of the pre-muscle masses was located dorsal, the other two ventral to the humerus. In subsequent stages, the condensations of the pre-muscle cells split into smaller units that differentiated into the distinct shoulder joint muscles. The pre-muscle mass located dorsal to the humerus differentiated into the mm. dorsalis scapulae, latissimus dorsi, scapulohumeralis superficialis, scapulohumeralis profundus anterior, and scapulohumeralis profundus posterior. The anterior mass of the two pre-muscle masses located ventral to the humerus split into the mm. cleidohumeralis, episternohumeralis, coracoradialis, and supracoracoideus, whereas the posteroventral pre-muscle mass differentiated into the mm. pectoralis, coracobrachialis, and subcoracoscapularis; this posteroventral pre-muscle mass also gave rise to the m. cutaneus pectoris in Rana temporaria. The two pre-muscle masses ventral to the developing humerus were barely separable in the earliest developmental stage of R. temporaria (ZMH A14736). Nerves were present and in contact with the pre-muscle masses or muscle units in all stages examined, even the earliest ones.
Species-specific muscle variations
Eighteen distinct muscle units crossing the shoulder joint were observed in the species examined (Figs. 1–3, Table 3), but not all these units were present in all specimens. The muscles and their respective origins and insertions are described in Table 3; in the following, only interspecific differences are reported.
In Ascaphus truei, the mm. scapulohumeralis superficialis, cleidohumeralis, and episternohumeralis formed one continuous muscle complex. The anteromedial part of the m. supracoracoideus was continuous with this muscle complex, but distinct from it at the insertion. A large part of the m. supracoracoideus was covered by the anteriorly expanded portio sternalis of the m. pectoralis. The m. coracobrachialis was split into a pars dorsalis and a pars ventralis; the pars dorsalis was continuous with the portio coracoidea of the m. pectoralis. The m. coracobrachialis and the portio coracoidea of the m. pectoralis were continuous at their insertions in Alytes obstetricans; the insertions of these two muscles were adjacent in the latest larval stage considered (Stage 41) of Bombina orientalis.
Rhinella marina and Bufo bufo were very similar with respect to the configuration of their shoulder joint muscles (Electronic Supplementary Material Figs S1–S3). The major difference between these species concerned the m. episternohumeralis: in R. marina, this muscle was continuous with the m. supracoracoideus at its origin and along most of its length (muscles artificially separated for illustrational purpose), whereas in B. bufo, these muscles were clearly separated at their origins and along most of their lengths. In B. bufo, there was a tendency toward the formation of a pars ventralis and a pars dorsalis within the m. coracobrachialis, but these parts were mostly continuous and may not be considered to be distinct muscle units. In both species, the m. supracoracoideus was present with an anterior and a posterior muscle unit; these two parts together claimed approximately the same space on the ventral part of the girdle as the undivided m. supracoracoideus in the other species.
In the latest developmental stage of Rana temporaria considered herein (Stage 41), the m. scapulohumeralis superficialis originated from the medial surface of the pars glenoidalis of the scapula, the adjacent cartilage, and the lateral part of the coracoid; the origin of this muscle was not continuous with the origin of the m. scapulohumeralis profundus anterior. The mm. cleidohumeralis and coracobrachialis were each present with two parts that were continuous at their insertions. In addition, the pars superficialis of the m. cleidohumeralis was barely separable form the m. scapulohumeralis superficialis at its origin. Both parts of the m. coracobrachialis together claimed about the same space as the undivided m. coracobrachialis in the other species. The m. subcoracoscapularis was closely associated and mostly continuous with the pars dorsalis of the m. coracobrachialis; the former inserted more proximal on the humerus than observed in the other species. A m. cutaneus pectoris was present and originated from the ventral surface of m. rectus abdominis and inserted onto the skin.
Species-specific innervation of the shoulder joint muscles
The shoulder joint muscles were innervated by various branches of the plexus brachialis that was formed by fibers of the nn. spinalis II-IV (Fig. 4). The rr. dorsalis scapulae anterior and posterior arose from about the lateral aspect of the plexus brachialis. The r. dorsalis scapulae anterior innervated the m. dorsalis scapulae and the group of scapulohumeralis muscles. It either passed through the m. scapulohumeralis profundus anterior before it ended in the m. scapulohumeralis superficialis (Alytes obstetricans, Rana temporaria; Fig. 1c) or entered between these two muscles (Ascaphus truei, Bombina orientalis, Rhinella marina; Fig. 5a, b). The r. dorsalis scapulae posterior innervated the posterior part of the m. dorsalis scapulae and the m. latissimus dorsi.
The r. coraco-clavicularis arose from the anterior aspect of the plexus brachialis, passed through the opening between the procoracoid and coracoid, and innervated the mm. coracoradialis, supracoracoideus (only anterior part or portion), episternohumeralis, and cleidohumeralis (both portions if two were present). In all species examined, the ramus innervating the m. coracoradialis was the first to separate from the r. coraco-clavicularis. In Ascaphus truei, B. orientalis, and Alytes obstetricans, there was a separate branch arising from the r. coraco-clavicularis that formed an anastomosis with the r. coraco-brachialis of the r. pectoralis communis of the n. brachialis longus inferior; the anastomosis and the respective rami were located dorsal (profound) to the mm. coracoradialis, supracoracoideus, and the portions of the m. pectoralis, whereas they (anastomosis and rami) laid ventral (superficial) to the m. coracobrachialis (Fig. 2). No such anastomosis was present in R. marina (Fig. 6) or Rana temporaria.
The n. brachialis longus inferior separated from the posterior aspect of the plexus brachialis and gave rise to, among others, the r. pectoralis communis, which in turn split into the rr. coraco-brachialis and pectoralis proprius. The r. pectoralis communis and its derivatives laid profound to the caput scapulare of the m. anconaeus. In Ascaphus truei, B. orientalis, and Alytes obstetricans, the r. pectoralis communis passed between the mm. subcoracoscapularis and coracobrachialis (Fig. 3a, b), whereas the rr. coraco-brachialis and pectoralis proprius separated before they entered the space between the mm. subcoracoscapularis and coracobrachialis in Rhinella marina and Rana temporaria (Fig. 5d, e). In the latter two species, only the r. coraco-brachialis passed between the two muscles, the r. pectoralis proprius laid superficial to them. In all species examined, the r. coraco-brachialis innervated the mm. subcoracoscapularis, coracobrachialis, and the posterior part or portion of the m. supracoracoideus. In A. obstetricans (Fig. 4a, b) and R. temporaria, the r. coraco-brachialis also innervated the portio coracoidea of the m. pectoralis, whereas this portion was innervated by the r. pectoralis proprius in B. orientalis and Rhinella marina (Figs. 4d, f, 5d, e). No distinct portio coracoidea was observed in Ascaphus truei, but the muscle fibers most likely representing the portio coracoidea (as inferred from the relative position to the rr. coraco-brachialis and pectoralis proprius) received nerve supply from both, the rr. coraco-brachialis and pectoralis proprius. The r. pectoralis proprius of the r. pectoralis communis innervated the portionis sternalis and abdominalis of the m. pectoralis in all species examined and, as described above, in B. orientalis, R. marina, and A. truei also the portio coracoidea. In Rana temporaria, the r. pectoralis proprius also supplied the m. cutaneus pectoris.
The n. brachialis longus superior separated from the posterior aspect of the plexus brachialis in close proximity to the n. brachialis longus inferior. It innervated, among others, the heads of the m. anconaeus with one exception: in Rhinella marina, the caput scapulare received nerve supply from two rami that arose from the plexus brachialis in close proximity to the base of the n. brachialis longus superior.
Development of the skeleton
Precursors of the pectoral girdle skeleton and long bones of the forelimbs were present and developed throughout all larval stages considered herein. Despite species-specific differences, the following general pattern was observed: in the earliest of the considered stages, the pectoral girdle skeleton was present by cartilaginous precursors of the elements (scapula and coracoid) that form the glenoid fossa and, case-specifically, by the ventral parts of the suprascapula or condensations of cells preceding the suprascapula. There case-specifically also was a separate precursor of the procoracoid cartilage. During the course of development, the coracoid and procoracoid extended ventrally and, in later stages, grew toward one another (formation of epicoracoid) with cartilaginous tissue.
With about the onset of metamorphic climax, the orientation of the skeletal complex formed by the coracoid, procoracoid, and epicoracoid stated to shift from a more vertical toward a rather horizontal orientation. In addition, these ventral elements grew toward their counterparts of the other girdle half. The scapula and suprascapula extended dorsally. Humerus, radius, and ulna lengthened throughout all developmental stages and approached their adult form (i.e., development of crests, fusion of radius and ulna). The ossification of the endochondral bones, as well as the development of the dermal bones (clavicula and cleithrum), began in bone- and species-specific stages. More detailed descriptions of the chondrogenesis and ossification during larval development and metamorphosis have been published elsewhere (e.g., Púgener and Maglia 1997; Maglia and Púgener 1998; Baleeva 2001, 2009; Shearman 2005, 2008; Havelková and Roček 2006) and are beyond the scope of this study.
Development of the shoulder joint muscles in Rhinella marina
In the earliest larval stage of Rhinella marina considered herein (Stage 32–33; ZMH A14928; Fig. 7a, b), the muscles dorsal to the shoulder joint were present by a distinct caput scapulare of the m. anconaeus (distally continuous with other heads of m. anconaeus), a common precursor of the mm. dorsalis scapulae and latissimus dorsi, one pre-muscle mass representing the mm. scapulohumeralis profundus anterior and superficialis, as well as a distinct mass representing the m. scapulohumeralis profundus posterior. Both precursors of the scapulohumeralis muscles were connected by a loose accumulation of undifferentiated cells. Ventrally, one pre-muscle mass preceded the mm. supracoracoideus (portionis anterior and posterior), episternohumeralis, and cleidohumeralis. This mass was located superficial to and was medioventrally continuous with the precursor of m. coracoradialis. Posteroventrally, the mm. subcoracoscapularis, coracobrachialis, and all portions of m. pectoralis were present by one common pre-muscle mass; the cells representing the future m. pectoralis seemed less differentiated than the cells preceding the other muscles, so the m. pectoralis could artificially be separated from the others.
In Stage 34 (ZMH A14930; Fig. 7c, d), the undifferentiated cells connecting the m. scapulohumeralis profundus posterior to the mm. scapulohumeralis profundus anterior and superficialis disappeared and the m. latissimus dorsi became distinguishable from the m. dorsalis scapulae. Anteroventrally, the m. cleidohumeralis as well as the portio posterior of the m. supracoracoideus split from the remaining pre-muscle mass representing the future portio anterior of the m. supracoracoideus and the m. episternohumeralis; the separations were most obvious at the origins, whereas the muscles were almost continuous at their insertions. The posteroventral muscle precursor split into several (pre-)muscle masses: The m. pectoralis portio abdominalis became entirely distinct, while the portionis sternalis and coracoidea were separated at their insertions (the insertion of the portio coracoidea shifted to a more distal position), but remained continuous at the origin. The mm. coracobrachialis and subcoracoscapularis formed one separate muscle mass.
The specimens of Stages 37 (ZMH A14933; Fig. 7e–h) and 41 (ZMH A14937; Figs. 5, 6) showed all muscle units also present in the adult specimen (ZMH A15443; Electronic Supplementary Material Figs S1–S3): The mm. scapulohumeralis superficialis and profundus anterior were continuous at their origins, but clearly separated at their insertions. The same was observed for the m. episternohumeralis and the portio anterior of the supracoracoideus, as well as for mm. coracobrachialis and subcoracoscapularis. At their origins, the muscles of these complexes could only artificially be separated in the adult specimen by tracing the muscles fibers from the insertion to the origin. The portionis sternalis and coracoidea of the m. pectoralis were entirely separated.
Development of the shoulder joint muscles in Bombina orientalis
The overall pattern of the development of the shoulder joint muscles in Bombina orientalis was similar to the one observed in Rhinella marina, but there were some differences. Most strikingly, most developmental events occurred in earlier larval stages than in R. marina. Other than in R. marina (m. episternohumeralis continuous with m. supracoracoideus in Stage 32–33), the mm. episternohumeralis and cleidohumeralis formed one independent pre-muscle mass in the earliest considered developmental stage of B. orientalis (Stage 32, ZMH A12427); two portions were recognizable within this pre-muscle mass based on the cell orientation (Fig. 8a). As in later developmental stages of R. marina, the mm. scapulohumeralis superficialis and profundus anterior in B. orientalis (ZMH A12427) were continuous at their origins, but clearly separated at their insertions (Fig. 8b). Both these muscles had no connection to the m. scapulohumeralis profundus posterior. The mm. dorsalis scapulae and latissimus dorsi were distinct from each other as well. The caput scapulare of the m. anconaeus was distinct at its origin and distally continuous with the other heads of the m. anconaeus. Posteriorly, the precursors of the portionis abdominalis and sternalis of the m. pectoralis were mostly continuous, but distinct at their insertions; the portio coracoidea was entirely separated from the former two portions. The mm. subcoracoscapularis and coracobrachialis were continuous at their origins and separated at the insertions (Fig. 8c).
In the B. orientalis specimen of Stage 35 (ZMH A12429), the mm. episternohumeralis and cleidohumeralis remained mostly continuous at their insertions, but were clearly separated at the origins (Fig. 8d). Within the m. supracoracoideus, there was a tendency toward forming an anterior and a posterior portion (Fig. 8e), but the portions were closely associated and could not be considered distinct. The portionis abdominalis and sternalis of the m. pectoralis were distinct from one another (Fig. 8f).
The muscle configuration in Stage 41 (ZMH A12435) resembled the one observed in Stage 35 with the exceptions that the mm. episternohumeralis and cleidohumeralis, although laterally in close proximity to each other, were separated at their origins and insertions (Fig. 8g–i). The m. supracporacoideus formed one muscle mass with no tendency toward the formation of two portions.
Development of the shoulder joint muscles in Rana temporaria
The developmental pattern of the shoulder joint muscles in Rana temporaria was similar to the patterns observed in the other two species, but the condensations of pre-muscle cells were less differentiated in the earliest developmental stage considered herein (Stage 32–33, ZMH A14736). Dorsal to the humerus, the precursor of the m. anconaeus was present as a condensation of pre-muscle cells, but the different heads of this muscle were inseparable. The mm. scapulohumeralis superficialis, profundus anterior and profundus posterior, dorsalis scapulae, and latissimus dorsi were present as a continuous pre-muscle mass (Fig. 9a–c); only the future common tendon of the mm. dorsalis scapulae and latissimus dorsi was recognizable as a region of comparably densely packed cells (Fig. 9c). Ventral to the humerus, there were two pre-muscle masses that were mostly continuous and only separated by the already recognizable posterior part of the future m. coracoradialis (Fig. 9b); anteriorly, the m. coracoradialis formed one pre-muscle mass with the future mm. cleidohumeralis, episternohumeralis, and supracoracoideus (Fig. 9a). The pre-muscle mass posterior to the m. coracoradialis represented the future mm. pectoralis, cutaneus pectoris, coracobrachialis, and subcoracoscapularis (Fig. 9b, c).
In the R. temporaria specimen of Stage 34 (ZMH A14739), the pre-muscle masses were somewhat more differentiated. Dorsally, the caput scapulare of the m. anconaeus was distinct at the origin and distally continuous with other heads of m. anconaeus. The mm. dorsalis scapulae and latissimus dorsi formed one pre-muscle mass that was clearly distinct from the group of scapulohumeralis muscles. The future mm. scapulohumeralis superficialis and profundus anterior were continuous (Fig. 9d, e), but separated from the m. scapulohumeralis posterior. The anterior of the two ventral pre-muscle masses observed in Stage 32–33 (ZMH A14736) was clearly separable from the posterior one and the m. coracoradialis became more distinct, but was still largely continuous with the common precursor of the future mm. cleidohumeralis, episternohumeralis, and supracoracoideus (Fig. 9e). Concerning the posteroventral pre-muscle mass, the portio abdominalis of the m. pectoralis was separated from the remaining pre-muscle mass at its origin (Fig. 9f). An anteriorly directed expansion of the pre-muscle mass represented the future m. cutaneaus pectoris (Fig. 9e); the cell condensation preceding the m. cutaneaus pectoris was posteriorly continuous with the future portionis abdominalis and sternalis of the m. pectoralis. The remaining continuous posteroventral pre-muscle mass represented the portionis sternalis and coracoidea of the m. pectoralis and the mm. coracobrachialis and subcoracoscapularis.
In Stage 35 (ZMH A14740), the future mm. scapulohumeralis superficialis and profundus anterior were mostly continuous, but formed two distinct heads at their insertions (Fig. 9g) and the m. latissimus dorsi was separated from the m. dorsalis scapulae. Anteroventrally, the mm. episternohumeralis and cleidohumeralis were separated from one another (Fig. 9g) and from the m. supracoracoideus; the latter muscle was more distinct from the m. coracoradialis (Fig. 9h). Posteroventrally, the portio abdominalis of m. pectoralis was entirely distinct from the other portions of this muscle, while the portionis sternalis and coracoidea were separated at their origins, but remained continuous at their insertion (Fig. 9i). The future m. cutaneus pectoris was expanded anteriorly, but, posteriorly, remained continuous with the portionis abdominalis and sternalis of the m. pectoralis (Fig. 9h, i). The mm. coracobrachialis and subcoracoscapularis formed one continuous pre-muscle mass.
In the specimen of Stage 41 (ZMH A12870), the origin of the m. scapulohumeralis superficialis was shifted to the medial surface of the scapula and the anterodorsal part of the lateral coracoid. Thereby, the mm. scapulohumeralis superficialis and profundus anterior were separated at their origins (Fig. 10a, b). The m. cleidohumeralis was divided into two parts that were separated at their origins but continuous at their insertion; the pars profunda originated from the lateral part of the clavicula and the pars superficialis from the acromion (most anteroventral part of the scapula and the ventrally adjacent cartilage; Fig. 10a, b). The pars superficialis of the m. cleidohumeralis was closely associated with the mm. scapulohumeralis superficialis and profundus anterior at its origin (Fig. 10a). Posteriorly, all portions of the m. pectoralis were separated from one another and from the m. cutaneus pectoris (Fig. 10d). The m. coracobrachialis was split into a ventral and a dorsal portion (Fig. 10c), and the portio dorsalis of this muscle was closely associated and mostly continuous with the m. subcoracoscapularis (Fig. 10c, d).
Discussion
Muscle nomenclature and comparison to literature accounts
The muscles of the forelimbs in tetrapods are ontogenetically derived from two (ventral and dorsal) pre-muscle masses that form within the developing limb bud (summarized in Hirasawa and Kuratani 2018). These two pre-muscle masses split into the individual limb muscles during morphogenesis (Hirasawa and Kuratani 2018). Although none of the specimens examined herein showed only two undifferentiated pre-muscle masses, the observations presented herein are in accordance with the general pattern of limb muscle development in tetrapods: The various shoulder joint muscle entities present in late developmental stages or adult specimens ontogenetically originated from condensations of pre-muscle cells and formed by subdivisions of the latter. Extrapolating the observed pattern to earlier developmental stages, it seems likely that the mm. anconaeus, dorsalis scapulae, latissimus dorsi, and the group of scapulohumeralis muscles are derived from a single dorsal pre-muscle mass hypothesized to be present in all tetrapods. Likewise, a single ventral pre-muscle mass presumably gives rise to the mm. cleidohumeralis, episternohumeralis, supracoracoideus, coracoradialis, subcoracoscapularis, coracobrachialis, and pectoralis (Fig. 11).
Regarding the muscles derived from the dorsal pre-muscle mass, our observations on the mm. anconaeus (all heads), dorsalis scapulae, and latissimus dorsi are in line with previous anatomical descriptions of Ascaphus truei, Rana, and Bufo bufo (Ritland 1955; Gaupp 1896; Bigalke 1927, respectively; Table 2). The m. scapulohumeralis superficialis usually is considered to be a part (pars scapularis sensu Bigalke 1927) of the m. deltoideus. The mm. episternohumeralis (pars cleido-humeralis longus sensu Bigalke 1927; pars episternalis sensu Gaupp 1896) and cleidohumeralis (pars clavicularis sensu Bigalke 1927) represent the other parts of the m. deltoideus in other studies; our results, however, indicate that the different muscle units that constitute the m. deltoideus in other studies, in fact, have different ontogenetic origins, namely either the ventral or the dorsal pre-muscle mass. Because of these different ontogenetic origins of the different parts, denoting them as parts of one muscle (m. deltoideus) might be misleading. Given that the muscle mass called m. scapulohumeralis superficialis herein is closely associated (ontogenetic development, innervation, and, in most species, continuity at origin) with the m. scapulohumeralis profundus anterior, it seems expedient and justified to discard its old name ‘m. deltoideus pars scapularis’. This also applies to the other muscles commonly considered to be a part of the m. deltoideus (suggested names summarized in Table 2).
Gaupp (1896) neither observed the m. scapulohumeralis profundus anterior, nor the m. scapulohumeralis profundus posterior in different species of Rana. Our analyses, however, confirmed the presence of both muscles in R. temporaria and support the notion of Bigalke (1927) that the m. deltoideus pars scapularis described by Gaupp (1896) also comprised the m. scapulohumeralis profundus anterior. Further support for this hypothesis can be found in Gaupp’s (1896) descriptions: he reported two separate origins and insertions for the pars scapularis and those origins correspond to the origins and insertions of the mm. scapulohumeralis superficialis and profundus anterior observed herein. In addition, Gaupp (1896) observed that some fibers of his m. deltoideus pars scapularis were innervated by the r. coraco-clavicularis, which contradicts our observations that this ramus only supplies muscles derived from the ventral pre-muscle mass. It seems likely that those fibers of Gaupp’s (1896) pars scapularis that are supplied by the r. coraco-clavicularis correspond to the pars superficialis of the m. cleidohumeralis due to the pattern of innervation and the observed close association of the pars superficialis with the m. scapulohumeralis superficialis in R. temporaria. If this was true, the pars scapularis of the m. deltoideus in Gaupp (1896) would comprise the mm. scapulohumeralis superficialis, scapulohumeralis profundus anterior, and the pars superficialis of the m. cleidohumeralis recognized herein. The pars clavicularis in Gaupp (1896) would be homologous to the pars profunda of the m. cleidohumeralis herein (Table 2), which would be consistent with the position and innervation of these muscles.
The single, undivided muscle mass (called m. deltoideus by Ritland 1955) observed in Ascaphus truei is formed by the mm. episternohumeralis, cleidohumeralis, and scapulohumeralis superficialis. The contribution of these latter three muscles to the formation of the former one muscle mass is supported by its absolute and relative position and by the muscle mass being supplied by the nerve branches that usually innervate these three muscles (rr. coraco-clavicularis and dorsalis scapulae anterior; own observations; Ritland 1955). Given that the m. scapulohumeralis superficialis is ontogenetically derived from the dorsal, whereas the mm. episternohumeralis and cleidohumeralis are derived from the ventral pre-muscle mass, the most parsimonious explanation for the condition observed in A. truei is that the mm. episternohumeralis and cleidohumeralis did not separate during ontogenesis and are secondarily fused to the m. scapulohumeralis superficialis. This is supported by a previous observation that the corresponding muscle mass in Leiopelma, phylogenetically a close relative of Ascaphus, consisted of somewhat more distinct portions (Ritland 1955),
The muscle superficial (ventral) to the m. coracoradialis has previously been denoted as the pars epicoracoidea of the m. pectoralis (Gaupp 1896; Bigalke 1927) and as the m. supracoracoideus (Ritland 1955). We observed that the pre-muscle mass (anteroventral) that gave rise to this muscle separated from the pre-muscle mass (posteroventral) that gave rise to the other portions of the m. pectoralis early in ontogeny (Fig. 11). We suggest the use of the term ‘m. supracoracoideus’ instead of denoting this muscle as a portion of the m. pectoralis to highlight the split from the pectoralis group early in ontogeny (Table 2).
We further observed that the m. supracoracoideus split into an anterior and a posterior portion during the ontogenesis in Rhinella marina; there was no connection or association of this muscle to the m. coracobrachialis. The posterior portion of the m. supracoracoideus resembles the pars superficialis of the m. coraco-brachialis brevis in the descriptions and illustrations of Bufo bufo by Bigalke (1927) with regard to the locations of the origin and the insertion on the skeletal elements and relative to other muscles. Therefore, we hypothesize that they are homologous. If so, the m. coracobrachialis would be present with only one portion in R. marina and B. bufo. In contrast, the ontogenetic pattern observed in Rana temporaria indicated that the m. coracobrachialis is present with two parts in that species: the separation of the two parts (dorsal and ventral) of the m. coracobrachialis occurred in a later developmental stage than the separation of their common precursor from the precursor of the m. supracoracoideus (Fig. 11). In the light of the evidence, we consider it most parsimonious to assume that the partis dorsalis and ventralis, thus, truly are derivatives of the m. coracobrachialis in R. temporaria and neither of them is homologous to the muscle denoted m. coraco-brachialis brevis pars superficialis by Bigalke (1927) in B. bufo.
Ritland (1955) reported the presence of a superficial and a profound supracoracoideus muscle in A. truei. Our observations revealed that the muscle unit called m. supracoracoideus profundus by Ritland (1955) was located dorsal (profound) to the anastomosis formed by branches of the rr. coraco-clavicularis and coraco-brachialis. Given that a similar anastomosis was observed in Alytes obstetricans (Fig. 2) and Bombina orientalis, and that only the m. coracobrachialis was located dorsal to the nerve branch in those two species, we suggest that the m. supracoracoideus profundus observed by Ritland (1955) in fact represents a part (pars ventralis) of the m. coracobrachialis. This interpretation is also consistent with the position of the insertion of mm. supracoracoideus and coracobrachialis relative to the m. coracoradialis: the fibers of the m. supracoracoideus were located ventral (superficial) to the m. coracoradialis and inserted onto the connective tissue covering the tendon of the latter, whereas the fibers of the m. coracobrachialis laid dorsal (profound) to the m. coracoradialis and inserted onto the posterior surface of the crista ventralis and the humerus (observed in A. obstetricnas, B. orientalis, Rhinella marina, and Rana temporaria; Figs. 2, 6, Supporting Information Fig. S2). The insertions of the mm. supracoracoideus and coracobrachialis are, thus, separated by (the tendon of) the m. coracoradialis. If the muscle called m. supracoracoideus profundus by Ritland (1955) would be considered as a part of the m. coracobrachialis, the positions of the insertions of the mm. coracobrachialis and supracoracoideus relative to the m. coracoradialis would be identical to the conditions observed in the other species. If not, the insertion of the m. supracoracoideus profundus (sensu Ritland 1955) would have shifted compared to the other species.
We observed that the muscle unit, which has commonly been denoted as m. coraco-brachialis longus (Gaupp 1896; Bigalke 1927), was ontogenetically derived from the muscle precursor that also gave rise to the portionis sternalis and abdominalis of the m. pectoralis in Rhinella marina and likely also in Rana temporaria. We therefore consider this muscle to be a portion of the m. pectoralis and suggest reflecting this relation by denoting it as the portio coracoidea of the m. pectoralis (Table 2). There were, however, some observations that render the suggested assignment to the m. pectoralis ambiguous: In some species (Alytes obstetricans and Rana temporaria), the portio coracoidea received nerve supply from the r. coraco-brachialis, and in Ascalphusi truei form the rr. coraco-brachialis and pectoralis proprius, which could imply a close association of the portio coracoidea of the m. pectoralis with the m. coraco-brachialis. Some ambiguity remains that requires more research, but at the moment, we consider the relationship to the m. pectoralis more plausible because of layer, position, and ontogenetic origin.
The m. cutaneous pectoris was only present in R. temporaria and was ontogenetically derived from a shared anlage with the portionis sternalis and abdominalis of the m. pectoralis. This raises the question, if these portions of the pectoralis are homologous across the considered species or if such a homologization should include the m. cutaneous pectoris as some kind of de novo portion of the m. pectoralis.
Ritland (1955) described a m. subcoracoscapularis in A. truei. Neither Gaupp (1896), nor Bigalke (1927) described a muscle of this name in Rana and Bufo bufo, respectively. Gaupp (1896), however, observed that a similar muscle, that he denoted the pars profunda of m. corcaco-brachialis, was pierced by the r. coraco-brachialis, and Bigalke (1927) reported two insertions (humeral spina tuberculi medialis and crista ventralis humeri) for the same muscle. Our results revealed the presence of the m. subcoracoscapularis in these species. Given that we observed the mm. subcoracoscapularis and coracobrachialis to always be continuous at their origins, that these two muscles were mostly continuous in R. temporaria, and that the r. coraco-brachialis passed between these two muscles, we assume that the pars profunda of m. coraco-brachialis described by Gaupp (1896) and Bigalke (1927) comprises the m. subcoracoscapularis (Table 2). If so, the pars profunda of m. coraco-brachialis described by Gaupp (1896) and Bigalke (1927) would not be homologous to the m. coracobrachialis herein. To avoid confusion, we suggest referring to the parts of the m. coracobrachialis as pars dorsalis and pars ventralis, respectively.
Limitations
Our sampling of developmental stages was sparse and each of the developmental stages was represented by only one specimen per species. The observed differences in the timing of the developmental events (splitting of muscle units) may be subject to individual (within-species) variations and might not represent interspecific variation. Yet, interspecific differences in the timing of the development of the pectoral girdle skeleton (Baleeva 2001) and its muscles (Soliz et al. 2018) have previously been reported for other anuran species.
The innervation patterns of the shoulder joint muscles were described using one specimen per species only and the observed differences between species might be caused by individual variations rather than species-specific peculiarities. The presence of sexual dimorphism has been observed for the humerus (Lee 2001; Padhye et al. 2015; Petrović et al. 2017) and certain muscles attached to the pectoral girdle (Oka et al. 1984; Emerson 1990; Lee 2001) in some anuran species. Sexual dimorphism and how the observed patterns are modified in a gender-specific fashion need further investigation.
Although we are aware of these limitations, we believe that our sample was large enough to reach our primary aim, namely to identify the different shoulder joint muscles and to assess their interspecific homologies by considering the ontogeny and innervation. We do believe so, because our observations were consistent across developmental stages within a given species and between closely related species, and allowed for assessing the ontogenetic splitting pattern of (pre-)muscle masses. Having reached our primary aim, we hesitated to add more specimens to our sample, because we expected limited additional insights but relatively high costs in terms of time investment. The addition of younger developmental stages, in particular, appeared unnecessary to us as the included specimens were sufficient to identify homologous (pre-)muscle masses across species and because the (pre-)muscle configurations in early stages can be complemented from literature accounts.
Summary and conclusion
The anuran mm. anconaeus, dorsalis scapulae, latissimus dorsi, coracoradialis, and the portionis sternalis and abdominalis of the m. pectoralis have consistently been recognized and denoted in the previous studies (Gaupp 1896; Bigalke 1927; Ritland 1955) and are reassessed herein. The muscle unit called m. coraco-brachialis longus in previous studies has also been consistently recognized, but the name for this muscle is misleading as it suggests a close relation to the m. coracobrachialis (as used herein), whereas it is ontogenetically closely associated with the portionis sternalis and abdominalis of the m. pectoralis. The name ‘pectoralis portio coracoidea’ seems more appropriate. The muscle entities that were previously considered as parts of a m. deltoideus ontogenetically arise from different pre-muscle masses (ventral and dorsal) observed in the early development of the tetrapod limb bud (Hirasawa and Kuratani 2018). This composite nature of the ‘m. deltoideus’, in our opinion, warrants alternative terms (i.e., mm. scapulohumeralis superficialis, cleidohumeralis, and episternohumeralis) that better clarify the independent nature of the muscle entities. The m. scapulohumeralis superficialis is closely associated with the m. supracoracoideus profundus anterior and both these muscles have occasionally been described as one muscle; the m. supracoracoideus profundus posterior likely has been overlooked by some authors. The m. subcoracoscaplualris, although mostly inseparable from the m. coracobrachialis in Rana temporaria, is present in all species examined and is characterized by being superficial to the m. coracobrachialis and the r. coraco-brachialis. The mm. cleidohumeralis, supracoracoideus, and coracobrachialis are present with two parts or portions in some species, these portions have not always been recognized and assigned correctly in the previous studies.
In our study, we applied homology criteria to sort and clarify the inconsistencies in the literature. Bearing the same term is not a prerequisite per se to establish a homology statement for two entities. It is our experience, however, that the previously applied terms and contradictions in the literature obstructed the understanding of the evolution of the shoulder joint muscles. The terminology which we propose mostly recruits from existing terms and tries to limit changes to the necessary. It clarifies, in our opinion, many discrepancies, and offers more parsimonious explanations of the observed patterns than previous systems. This case study highlights the importance of critically questioning published anatomical descriptions before they are used for comparisons in other studies. For example, the observation that the muscles commonly considered to be parts of the m. deltoideus are ontogenetically derived from different pre-muscle masses renders the overall homologization of ‘the m. deltoideus’ with single muscles or muscle complexes in other vertebrate taxa questionable. In our opinion, only well-supported homologization and primary homology statements of muscle units across taxa allow for the reliable reconstruction of ancestral character states and should be scrutinized before they were used to derive evolutionary hypotheses or conclusions.
Data availability
The volume data generated for the study are accessible at https://www.fdr.uni-hamburg.de; DOIs are provided in Table 1.
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Acknowledgements
We are grateful to Katharina Ruthsatz for providing larvae of Rana temporaria, André Beerlink and YXLON International GmbH for performing the µCT scans of Bufo bufo, and Thomas Kleinteich and the TPW Prüfzentrum GmbH for performing the µCT scan of Rhinella marina. In addition, we thank Frank Friedrich for fruitful discussions, and Carla Viola Reinbold and Dilara Leptin for their help with digitizing the histological serial sections. We also thank Lennart Olsson for the time invested in the review and the very helpful comments that greatly improved the manuscript. This study was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) – 387723284.
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Open Access funding enabled and organized by Projekt DEAL. This study was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)—387723284.
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KE conceived the study, curated and analyzed the data, performed the 3d reconstructions, and drafted the manuscript. KE and SP generated the volume data. KE, SP, and AH discussed the results. AH provided resources, edited an early version of the manuscript, and acquired funding. All authors critically revised the manuscript and approved the final version.
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Supplementary file1 (PDF 54546 KB) Electronic Supplementary Material: Figures S1-3 showing the shoulder joint muscles of adult specimens of Bufo bufo (ZMH A04664) and Rhinella marina (ZMH A15443) in different views
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Engelkes, K., Panpeng, S. & Haas, A. Ontogenetic development of the shoulder joint muscles in frogs (Amphibia: Anura) assessed by digital dissection with implications for interspecific muscle homologies and nomenclature. Zoomorphology 140, 119–142 (2021). https://doi.org/10.1007/s00435-020-00510-4
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DOI: https://doi.org/10.1007/s00435-020-00510-4