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Comparative myoanatomy of Echinoderes (Kinorhyncha): a comprehensive investigation by CLSM and 3D reconstruction
© Herranz et al.; licensee BioMed Central Ltd. 2014
Received: 4 February 2014
Accepted: 28 March 2014
Published: 5 April 2014
Kinorhyncha is a clade of marine invertebrate meiofauna. Their body plan includes a retractable introvert bearing rings of cuticular spines, and a limbless trunk with distinct segmentation of nervous, muscular and epidermal organ systems. As derived members within the basal branch of Ecdysozoa, kinorhynchs may provide an important example of convergence on the evolution of segmentation within one of three bilaterian superclades. We describe the myoanatomy of Echinoderes, the most specious kinorhynch genus, and build upon historical studies of kinorhynch ultrastructure and gross morphology. This is the first multi-species comparison of a complete organ system by confocal microscopy and three-dimensional reconstruction within Kinorhyncha.
Myoanatomy of adult Echinoderes is composed of the following: Head with two mouth cone circular muscles, nine pairs of oral style muscles, ten introvert retractors, one introvert circular muscle, and fourteen introvert circular muscle retractors; Neck with one circular muscle; Trunk showing distinct pairs of ventral and dorsal muscles within segments 1–10, dorsoventral muscles within segments 3–10, diagonal muscles within segments 1–8, longitudinal fibers spanning segments 1–9, three pairs of terminal spine muscles, and one pair of male penile spine muscles; Gut showing a pharynx with ten alternating rings of radial and circular muscle fibers enclosed in a complex sheath of protractors and retractors, an orthogonal grid of longitudinal and circular fibers surrounding the intestine, and paired hindgut dilators.
Myoanatomy is highly conserved between species of Echinoderes. Interspecific variation is observed in the arrangement and number of introvert fibers and the composition of pharyngeal muscles. Segmented trunk musculature facilitates the movements of articulated cuticular plates along the anterior-posterior axis. Intersegmental muscle fibers assist with dorsoventral and lateral trunk movements. Protractors, retractors and circular muscles coordinate eversion and retraction of the introvert and mouth cone, and relocation of the pharynx during locomotion and feeding behaviors. Pairs of posterior fibers suggest independent movements of terminal spines, and male penile spines. Within Scalidophora, myoanatomy is more similar between Kinorhyncha and Loricifera, than either group is to Priapulida. Kinorhynch myoanatomy may reflect a convergent transition from vermiform to segmented body plans during the early radiation of Ecdysozoa.
Kinorhyncha is a clade of invertebrate meiofauna that inhabit marine sediments from the intertidal zone to abyssal depths in all major ocean basins . They have a distinctly segmented body plan, with a retractable introvert and a diverse array of cuticular structures along its length. Very little is known about their embryonic development , there are no larval life history stages, and only a few studies have examined growth and morphogenesis in pre-adult stages [3–6]. The origin of Kinorhyncha and the relationships within the clade are unresolved. Within Metazoa, kinorhynchs are members of the ‘moulting animals’ known as Ecdysozoa , one of two protostome superclades [8–11]. Together, kinorhynchs, priapulids, and most likely loriciferans, form a clade known as Scalidophora, which is the most basal branch in the Ecdysozoa ([12–17], but see ). In turn, the scalidophorans share several molecular and morphological similarities with two groups of soft-bodied worms (nematodes, nematomorphs), particularly in the architecture of the brain, which has been a consideration for uniting these five taxa as the more inclusive Cycloneuralia . However, monophyly has not been established for this group [10, 11, 16, 17, 19], and therefore the assignment of particular synapomorphic characters within cycloneuralian organ systems, such as digestive, muscular, and nervous tissues, must also remain tentative [15, 20, 21]. Yet, the kinorhynchs may be the most derived taxon within Scalidophora, or even among the cycloneuralians, since they are the only animals with clearly segmented internal and external structures, including the cuticle, paired and unpaired spines, gland cells, sensory spots, muscles and neurons that collectively represent developmental products of mesodermal and ectodermal tissues along the anterior-posterior axis [14, 22, 23]. Most importantly, because of their relative position within Ecdysozoa, as a separate and distinct lineage from Panarthropoda, the segmented body plan of kinorhynchs may represent a fascinating example of convergent evolution, and an independent contrast of both the development and function of segmentation not only within Ecdysozoa, but also among other metazoans where segmentation is recognized.
The trunk region of adult kinorhynchs consists of eleven well-defined segments, reflecting an anterior-posterior pattern of repeated elements in the epidermis, nervous system and musculature. Most notable are eleven sets of articulating exoskeletal plates, a ganglionated ventral nerve cord with perpendicular branching of neurites to the peripheral nervous system, and paired sets of functionally specific muscle bands along the trunk [1, 24]. Unlike most bilaterians, especially soft-bodied invertebrates, kinorhynchs do not develop the typical set of outer circular and inner longitudinal muscle groups below the epidermis, which must correlate with the production of hard cuticle in their segmented exoskeleton . The continuous circular and longitudinal muscle layers of the body wall have apparently been replaced by isolated muscles attached to the exoskeleton through an intermediate epidermal cell [1, 20, 25]. Moreover, kinorhynchs do not have limb-like appendages along the body, unlike all of the segmented taxa of Panarthropoda . Amongst others, the absence of such locomotory appendages in kinorhynchs is evidence of a convergent transition from vermiform to segmented body plans that are visible in Panarthropoda and Kinorhyncha, but are missing among all other cycloneuralians. Thus, kinorhynchs are pivotal for understanding the evolution of segmentation. Important similarities and differences in muscle organization between kinorhynchs and arthropods suggest there is still a lot of work to do . Studies of cell lineage, and at least gene expression during segmentation, at analogous sites of appendage development, and within many other organ systems along the kinorhynch body do not exist, but are certainly needed. Until then, it is not possible to infer homology of muscles, nerves or even segments between kinorhynchs and other ecdysozoans with any certainty, at least not beyond predictions based solely on cladistics [5, 11, 26–28].
Apart from segmentation, kinorhynchs share several notable characteristics with their scalidophoran relatives, including a retractable introvert with rings of chitinous scalids, and the complex myoanatomy that operates it. Within kinorhynch muscle cells, the arrangements of the myofibrils are cross-striated. The exception is an orthogonal grid-like pattern of minute smooth fibers encircling the kinorhynch intestine [5, 25, 29, 30]. Cross-striated myofibrils, although not exclusive to the clade, are thought to facilitate rapid contractions of muscle fibers. As scalidophorans live among the sand grains of marine sediments, and do not have appendages (excluding the toes of the loriciferan Higgins larvae) or locomotory cilia [20, 21, 31], they must rely on introvert musculature for locomotion and feeding [32–35]. The introvert also thought to have important sensory roles in that environment [1, 12, 33, 36–38]. Furthermore, in each taxon, there are well-developed retractors, protractors, circular muscles, pharynges, and an assortment of external chitinous spines, teeth or scalids [1, 21, 33, 36]. Variation in character states for these and other features are not subtle, and appear to correspond with size, shape, behavior and the presence versus absence of a hard exterior cuticle [1, 20, 39, 40]. Overall, similarities and differences in the function and presumed evolution of characters among kinorhynchs, within Scalidophora, and across Cycloneuralia, are not well understood. Yet, almost all of the internal anatomy, and many external structures, are thought to be directly associated with contractile cells and their fibers [1, 14, 20, 36, 41–43]. Thus, thorough descriptions of myoanatomy are essential.
Comparative difference in size, shape, and spines in five species of Echinoderes of which muscle architecture was investigated
Trunk length (μm)
Bulbous anterior end
External morphology of Echinoderes
Myoanatomy of Echinoderes
A comparison among the five species of Echinoderes in this study reveals a similar pattern of myoanatomy, regardless of detectable differences in external morphology (Table 1, Figure 1A-E). For clarity, we divide our descriptions of musculature into head, neck, trunk and gut regions of the kinorhynch body plan. When observed, species-specific differences in myoanatomy are noted for a particular region.
Musculature of the head: mouth cone
Musculature of the head: introvert
The myoanatomy of the introvert includes a set of longitudinal introvert retractors, an introvert circular muscle, and a set of longitudinal introvert circular muscle retractors. The introvert retractors are composed of one or two sets of longitudinal muscles. There are ten groups of 2–3 short, thin distal retractor muscles (idr) that probably insert into the anterior part of the introvert (Figures 2C, J, K, 4B-I and 5D-F). These (idr) muscles alternate positions with the primary spinoscalids (psp) and bend toward the bases of the spinoscalids (Additional file 1, Figure 2C-D, J). The spinoscalids themselves do not possess musculature (Additional file 1, Figure 2C-D, J, K).
The distal retractor muscles (idr) are connected with ten pairs of longitudinal proximal retractor muscles (ipr), which extend in an anterior-posterior direction between the pharynx and the trunk musculature (Additional file 1, Figures 2D, L, 4B, E, H and 5D-F). Each muscle in a pair of proximal retractor muscles (ipr) is composed of 2–3 fibers. The posterior ends of the proximal introvert retractors attach dorsolaterally or ventrolaterally, most likely at the segmental pachycycli (cuticular thickening situated at the anterior margin of a segment) from trunk segment 3 to segment 5 (Figures 4B, E, D, G and 5D-F).
In E. dujardinii, there is no distinction between proximal and distal retractor muscles. Instead, there are ten pairs of long continuous introvert retractors (ir) composed of four fibers each. These introvert retractors attach posteriorly in the same trunk segments as in the other Echinoderes species, and bend anteriorly in a swan-neck-shaped configuration toward the bases of the spinoscalids (Figure 5A-C). Only the two central fibers, out of four fibers, bend toward the spinoscalids. The remaining two short fibers are positioned adjacent to the longer, curved fibers.
Musculature of the neck
Musculature of the trunk
Segmentally arranged musculature is observed within trunk segments 1–10, and includes four distinct groups, in three orientations. Pairs of ventral and dorsal muscles are oriented longitudinally in each segment. There is one pair of ventral muscles (vm), and two pairs of dorsal muscles (dm) that are in subdorsal and laterodorsal positions within each segment (Figures 8C, E and 9A-B, D). In some cases, dorsal muscle fibers may span more than one segment. In segments 1–8, there are pairs of diagonal muscle bands (dim) on left and right lateral sides of the body (Figures 8A-F and 9C). The fibers in each band appear to attach along anterolateral margins of the tergal (dorsal) pachycyclus, extend in an oblique or diagonal pattern, and converge medially to reach the pachycyclus of the following segment near each tergosternal ventrolateral plate junction (Figures 4A, D, G, 8C and 9A-C). The number of diagonal fibers within each segmental muscle band is variable among segments and species, with the first and last muscle bands of the series (segments 1, 2 and 8) typically having fewer fibers than observed within the other segments (Figure 9C). There are distinct pairs of dorsoventral muscles (dvm) in segments 3–10 (Figures 8A-D, F and 9A, B, D). Each dorsoventral muscle band is composed of two fibers. The fibers from each muscle of the pair insert on their respective left and right midventral sides of a segment, and extend dorsolaterally to symmetric attachment sites on the tergal cuticular plate in the center of each segment (Figure 8A, C, D, F). Dorsoventral muscles (dvm) are oriented perpendicular to the anterior-posterior axis, and represent one of the four pairs of segmental muscle bands, along with ventral (vm), dorsal (dm), and diagonal muscles (dim).
The digestive system of Echinoderes is subregionalized into a foregut (mouth cone, pharynx, esophagus), midgut and hindgut. Distinct sets of muscles are integrated with each subregion. There is no evidence for segmentation of the musculature associated within or among different subregions of the digestive tract. The myoanatomy of the protrusible mouth cone, which contains the mouth and represents the beginning of the alimentary canal, is described above (section “Musculature of the head”).
The pharynx of Echinoderes is a highly complex muscular organ (Figures 3, 4, 5 and 9). The pharyngeal bulb (pb) is a movable cylinder-shaped structure, and is composed of circular muscles (pcm) that alternate with radial muscles (pram) along the length of the bulb (Figures 3C-D, 4C, F, I, 5A-F and 9D). Ten bands of each type are counted, with circular bands being noticeably thinner than the radial bands (Figures 3C-D and 4I). A sphincter (sph) muscle is present at both anterior and posterior ends of the pharyngeal bulb (Figures 3C and 5C). The internal diameter of each sphincter is smaller than the internal diameters of circular and radial muscle bands. The pharynx is always positioned posterior to the buccal cavity; however, its position along the anterior-posterior axis correlates with movements of the mouth cone and introvert, and is therefore observed to vary among specimens according to the position in which they were preserved. Consequently, the pharynx is located inside the trunk when the head (mouth cone plus introvert) is retracted, and it reaches the mouth cone when the head is fully extended (Additional file 1, Figures 4C, F, I and 5A-F).
Around the pharyngeal bulb of Echinoderes sp., E. hispanicus, E. horni and E. spinifurca there are eight inner longitudinal muscles (pil). Each one of these muscles (pil) contains two fibers that extend posteriorly from the pharynx to the esophagus and midgut (Figures 2I and 3C). External to the inner longitudinal muscles (pil), there is a conspicuous tulip-shaped muscular sheath (pms) that encloses the pharyngeal bulb (Additional file 1, Figures 2D, 3D and 4I). This sheath is composed of three different muscle groups: prm, psm, and pip. Eighteen pharynx retractor muscles (prm) arranged in pairs on their anterior end, which together form the nine tips of the tulip (Figures 2D, J and 3C). The eighteen, paired retractor muscles (prm) alternate positions with ten pharynx sheath muscles (psm) that do not extend posteriorly beyond the pharynx bulb (Figures 2L and 3C). Two of the ten pharynx sheath muscles occupy the middorsal position (Figure 2L). In addition, nine to ten inner protractor muscles (pip) contribute to the composition of the muscular sheath (pms) enclosing the pharynx. These inner protractor muscles (pip) alternate positions with the sheath muscles and most likely attach to the base of the mouth cone on their anterior ends, and to the base of the pharynx at their posterior ends (Figures 3C and 5D, F).
Four to six outer protractor muscles (pop) appear to attach to the posteriormost end of the pharynx at midventral, midlateral, and laterodorsal positions. These outer protractors (pop) extend from the base of the pharynx toward the head where they likely attach to the body wall area between the introvert and the mouth cone (Figure 3C). These protractors appear J-shaped when the pharynx extends toward the animal’s anterior end, surpassing their insertion point (Figures 3C and 4F, I).
In E. dujardinii there are also eight inner longitudinal muscles (pil) surrounding the pharyngeal bulb as described above, although their paired nature cannot be assessed (Figure 5C). Nine inner protractor muscles (pip) with a flame-like shape surround the pharyngeal bulb, and extend well beyond the bulb’s anterior end to attachment sites at the basal end of the mouth cone (Figure 5B-C). In some specimens, one or two of these retractors (pip) appear to be connected with the internal mouth cone ring. The muscular sheath that surrounds the pharynx (pms) of E. dujardinii is composed of the inner protractor muscles (pip) that alternate with ten or more pharynx retractors (prm), and ten sheath muscles (psm) (Figure 5B). An undetermined number (2–4) of outer protractors (pop) are present as well, which attach to the base of the mouth cone, and may connect with the external circular muscle (mce) of the mouth cone (Figure 5B asterisk). The general appearance of the sheath in E. dujardinii resembles a ‘basket’ around the pharynx. This muscular basket-like structure can be found more or less contracted depending on the position of the pharynx, as observed in a more contracted state when the pharynx is either extended to the mouth cone, or retracted away from the mouth cone.
An additional group of thin longitudinal muscle fibers are observed in all five species. These fibers extend from the middle of the pharynx to segments 3 and 4. They appear to be relaxed when the pharynx is retracted, and not readily visible when the pharynx is extended. These particular muscles have been termed pharynx suspensors (phs) due to their position, morphology and possible function (Figures 3C and 5A, D).
Posterior to the pharyngeal bulb in each species, pharynx retractors (prm) are arranged in four groups, with two oriented in lateroventral positions, and two in laterodorsal positions (Figures 3C and 5E, F). These pharynx retractors (prm) extend into the trunk toward ventromedial and laterodorsal attachment sites within segments 5–8 (Figures 4C, F, 5C, D, F and 8D).
The musculature of the midgut is composed of sixteen inner longitudinal muscles (mil), and sixteen or more thin, outer circular muscles. These filamentous muscle fibers are arranged in an orthogonal grid-like (gg) architecture encircling the midgut intestine (Figure 3D). At the level of the esophagus, the inner longitudinal muscles of the midgut (mil) bifurcate from the eight pairs of inner longitudinal muscles of the pharynx (pil), and extend posteriorly to surround the intestine and the hindgut (esm) (Figure 3D). Between segments 10 and 11, two pairs of short transverse muscle fibers extend from laterodorsal muscles and appear to tether the hindgut laterally. These fibers were designated as hindgut dilator (hd) muscles (Figures 3D, 7F and 9A-B).
Comparative myoanatomy within Echinoderes
Among the five species of Echinoderes we examined, there is notable variation in external morphology, although it is primarily limited to differences in the number, length, and presence or absence of small cuticular structures (Table 1). Variations in the external morphology of those species are reflected by relatively minor differences in the internal morphology of their musculature. Most of this variation includes species-specific differences in the head region, such as the shape, length and number of retractor muscles of the introvert and pharynx, as well as the composition of the pharyngeal sheath. Musculature within regions of the neck and trunk is basically similar among species. Overall, comparative myoanatomy within Echinoderes is remarkably conserved, and includes the following set of common characters: (Head) two circular muscles and nine pairs of oral style muscles in the mouth cone; ten longitudinal retractors, one circular muscle, and fourteen circular muscle retractors in the introvert; (Neck) one circular muscle; (Trunk) continuous intersegmental fibers among segments 1–9, and segmental pairs of ventral, diagonal, dorsoventral and dorsal muscles within segments 1–10 of the trunk; three pairs of terminal spine muscles and one pair of penile spine muscles in segment 11of male specimens; (Gut) a pharyngeal bulb with ten radial and ten circular muscle bands enclosed in a muscular sheath, including protractor and retractor muscle fibers; an orthogonal grid of midgut muscle fibers, and lateral pairs of hindgut dilator muscles.
Comparative data on the myoanatomy of Kinorhyncha from this study and available primary literature (references included)
Echinoderes sp. E. dujardinii E. hispanicus E. horni E. spinifurca
3 circular muscles
18 longitudinal, 2 circular muscles
16 longitudinal, 8 short basal and 2 circular muscles
18 longitudinal muscles
2 circular cell basal to oos, 7 circular muscle cells basal to ios
1 circular muscle cell basal to oos, 7 circular muscle cells basal to ios
16 outer retractors 12 inner retractors
10 retractors reaching S.6
10 retractors reaching S.6, Introvert circular muscle
16 outer retractors reaching S.8
10 head retractors
10 head retractors
1- 5 circular muscles
1 circular muscle
2 circular muscles: inner outer
Longitudinal: dorsal, ventral, and additional continuous fibers, Diagonal: 8 pairs Dorsoventral: S.3-11
Longitudinal: Ventromedial + Dorsolateral and additional continuous fibers, Diagonal: 8 pairs Dorsoventral: S.3-11
Longitudinal: Ventrolateral + Dorsolateral Diagonal: 9 pairs Dorsoventral: S.1-11
3 pairs LTS + 1 pair TE muscles 1pair penile spines muscles
Midterminal spine muscles triangle- shaped
Circular lumen, 10 radial + 10 circular fibers
Circular lumen, 14–15 circular fibers alternate with inhomogeneous structures, pre- and postpharyngeal sphincters 10 protractors, Pharynx sheath present
Circular lumen, 15 radial +15 circular fibers,2 prepharyngeal 1postpharyngeal sphincters
13 radial + 14 circular muscle cell
Circular and radial muscular fibers
13 radial + 14 circular muscle cell
12-16 longitudinal muscles
Muscular grid: Inner longitudinal (16) + outer circular (+16)
Muscular Grid: Inner longitudinal + outer circular
Muscular Grid: Inner longitudinal + outer circular
Muscular Grid: inner longitudinal + outer circular
Muscular Grid: inner longitudinal + outer circular
1-2 pairs short dilator muscles
1 dilator muscle
6 dilators: 2 caudal + 2 dorsal 1 frontal 1 circular
4 dilators: 2 caudal + 2dorsal; 2dorsal + 1 ventral transversal muscle cell
4 dilators: 2 caudal + 2dorsal; 2dorsal + 1 ventral transversal muscle cell
Kristensen and Higgins  described retractor muscles in the introvert of E. aquilonius that consisted of two sets, one composed of sixteen outer retractors, and the other set with twelve inner retractors. Their descriptions differ from what we have observed in the studied species of Echinoderes. In E. aquilonius, the sixteen outer retractors appear to extend from segment 9, pass through the forebrain, and attach to the anteriormost end of the introvert . We identified ten introvert retractors in each of five species from approximately one hundred specimens. These ten retractors also extend through the forebrain, however, they attach at the level of the first row of spinoscalids and alternate positions with them. Kristensen and Higgins  may have misidentified some protractors of the pharynx as introvert retractors, leading to the wrong assignment and a higher total count. Despite these differences in number and arrangement, our introvert retractors may be the “outer retractors” described by Kristensen and Higgins . We also identified 18–20 pharynx retractors, which may correspond to the “inner retractors” of E. aquilonius, although our count differs again from the twelve described . These and other differences likely stem from our application of fluorescent markers and CLSM, which enabled staining and visualization of complete sets of muscles in multiple focal planes. Additionally, we labeled cellular structures of the brain, introvert and pharynx for contextual landmarks, and the ability to discriminate between distinct muscle fibers within highly complex regions of kinorhynch myoanatomy. As a result, we reevaluated previous ambiguities, such as inner and outer retractors , in order to recount and reassign organ-specific fibers and muscle groups (e.g. introvert distal retractors, pharynx outer protractors).
The number and arrangement of mouth cone muscles reported herein appears different from what was found in E. capitatus, where three circular muscles were described, without reference to any longitudinal fibers. In contrast, we clearly identified two circular muscles, and nine pairs of short longitudinal muscles in each of the five echinoderid species. Nebelsick  may have easily overlooked these longitudinal muscles due to their small size and position within the mouth cone. Regarding the number of mouth cone circular muscles, Nebelsick  shows three individual muscles in E. capitatus (see Figure 1 therein), however we suggest that based on their positions they are actually two circular muscles which correlate with what we found in our study.
Circular muscles of the neck are commonly identified in studies of Echinoderes. Zelinka  described a single muscle in the neck region, whereas Remane  described five rings in E. dujardinii. Our results corroborate the observations of Zelinka , and suggest that Remane  could have misidentified circular muscles from the introvert and mouth cone as additional neck musculature. Kristensen and Higgins (, see Figure twenty-seven therein) presented a detail of circular muscle attachment in the neck of E. aquilonius, although it was not described. We identified a similar arrangement between the neck circular muscle and its proximity to the interplacid areas (Figure 7B). This particular attachment site, where the neck circular muscle is oriented along the anterior end of the placids, and attached to softer interplacid cuticle, was confirmed by additional evidence (R. M. Kristensen, personal communication).
The presence of continuous longitudinal fibers in the trunk of Echinoderes is also supported by TEM images of Echinoderes cantabricus, but was not discussed by Gª Ordóñez et al. . Accordingly, Remane  described a similar pattern in E. dujardinii as the splitting of longitudinal muscles in the anterior end of the trunk. This ‘splitting’ of muscles described by Remane  most likely corresponds to the longitudinal continuous fibers that fan out within the trunk of Echinoderes species investigated here. The sixteen longitudinal midgut muscles of the orthogonal gut grid observed in Echinoderes species in our study also support previous observations by Kristensen and Higgins  who described 12–16 longitudinal muscles in the trunk of E. aquilonius.
Comparative myoanatomy of Kinorhyncha
Within Kinorhyncha, there have been TEM studies of internal morphology and ultrastructure, with details of myoanatomy in several genera: Zelinkaderes floridensis, Pycnophyes dentatus, Pycnophyes flaveolatus, Pycnophyes greenlandicus, and Pycnophyes kielensis[5, 33]. Previous descriptions of musculature by confocal microscopy have also been presented, although they were limited to one cyclorhagid species, Antygomonas sp. , and one homalorhagid species, P. kielensis[5, 30]. Thus far, most of the attention has been on longitudinal and segmental musculature of the trunk, with only one description of myoanatomy in the head and neck . Unfortunately, all of the specimens in that study had their introvert fully or partially retracted, precluding detailed resolution of anterior musculature, such as important differences between the anterior radial closing system of Echinoderidae and the bilateral closing system of species within Antygomonidae. Yet, when considering all of the available information, Antygomonas sp.  is the most appropriate model for direct comparison with Echinoderes.
We found eighteen outer oral style muscles in each species of Echinoderes studied here, representing one pair of muscles for each outer oral style. Müller and Schmidt-Rhaesa  reported sixteen outer oral style muscles, which would indicate that one of the nine oral styles of Antygomonas sp. does not have a pair of muscles. Additionally, we did not find any of the eight basal mouth cone muscles described in Antygomonas sp. (; see Figure four A therein). These short, single mouth cone muscles may be exclusive to Antygomonidae, or perhaps they are attachment sites for the sixteen mouth cone muscles. We did identify 14–16 short introvert circular muscle retractors (icmr) in each species of Echinoderes, which are most likely comparable to these singular fibers that “stretch toward the first circular ring” in the neck region of Antygomonas sp. . Although they were not characterized as circular muscle retractors, we consider them as such because they appear to extend from the introvert circular muscle toward the body wall in the first segment, which is comparable to the condition of ‘icmr’ fibers in species of Echinoderes. We have clearly identified fourteen introvert circular muscle retractors in Antygomonas paulae (unpublished observations, Herranz and Boyle). The outer retractors (or) of Antygomonas sp.  should also be considered comparable to the introvert distal retractors in Echinoderes. Müller and Schmidt-Rhaesa  observed two mouth cone circular muscles, as well as the introvert and neck circular muscles within Antygomonas sp., which match our observations in Echinoderes.
Within the trunk region, intersegmental and segmental muscle bands most likely occur in all kinorhynchs. However, diagonal muscles have been described almost exclusively for cyclorhagids [44, 45], with only one report of diagonal bands in a homalorhagid species, Pycnophyes calmani. The diagonal muscles of Echinoderes show a clear segmental pattern along the trunk, while in Antygomonas sp., each of the first three diagonal muscles span two segments . These differences could arise from variation in musculature of the neck and first trunk segments associated with radial vs. bilateral closing systems. The dorsoventral muscles are the only segmental muscles of the trunk that do not attach to pachycycli, and therefore they do leave conspicuous cuticular scars [1, 29, 44, 45]. These muscles are absent in the first and second ring-like segments of Echinoderes. Other genera within Echinoderidae, and Kinorhyncha, vary as to whether segment 2 is composed of one or two sternal plates, which may correlate with changes in the arrangement and attachment of musculature in the first two segments. As previously mentioned, further detailed comparative studies of kinorhynch closing systems are needed to address such questions.
Myoanatomy of the pharyngeal bulb has been described in several genera and species [1, 29, 33]. Within the pharynx, there are notable differences in the shape of the lumen, and the number of circular and radial muscle fibers. In Cyclorhagida, including Echinoderes, the shape of the pharyngeal lumen is primarily circular, while in Homalorhagida the lumen exhibits a triradiate, or inverted Y-shaped, configuration [20, 21]. Since triradiate pharynges are most likely homologous in Ecdysozoa, this would suggest that Homalorhagids exhibit the primitive kinorhynch gut architecture . Yet we remain cautious, as the first molecular phylogeny of kinorhynchs did not recover monophyly for either Cyclorhagida or Homalorhagida , and other evidence suggests that a triradiate pharynx “cannot be ancestral in the cycloneuralians” and likely evolved in parallel multiple times . Regarding variation in the number of alternating circular and radial fibers among genera, there are fifteen in Zelinkaderes, thirteen-to-fourteen in Pycnophyes and fourteen-to-fifteen circular fibers alternating with inhomogeneous structures in Antygomonas[29, 33, 35] (Table 2). Our results show ten circular and ten radial fibers in Echinoderes. This arrangement appears highly conserved among species, and may become an important diagnostic character for the genus. It is not known whether this arrangement of pharyngeal muscle fibers is shared within Echinoderidae.
Musculature associated with terminal spines has been reported in Pycnophyes kielensis, and a strong, paired muscle was described at the base of the midterminal spine in Antygomonas sp. . Although Müller and Schmidt-Rhaesa  did not state it, their data also suggest there could be muscles in the bases of lateral terminal spines in Antygomonas sp. Additional kinorhynch genera with midterminal and lateral terminal spines include Centroderes, Zelinkaderes and Semnoderes, however spine musculature has not yet been investigated within or among these genera. The five species of Echinoderes in our study share a similar arrangement: muscles are distinctly associated with lateral terminal spines, but not with lateral terminal accessory spines, which are rigid and immobile in live animals. The presence of penile spines in male kinorhynchs is shared by Cephalorhyncha, Dracoderes, Echinoderes, Fissuroderes, Meristoderes and Pycnophyes. Of those genera Myoanatomical data are only available for species of Echinoderes and Pycnophyes, and until now, penile-spine musculature was not identified in either genus. Our results show conspicuous muscles associated with penile spines in all five Echinoderes species, and we predict that similar muscles will be identified in species from each of the genera where penile spines are present.
Interpretations of functional myoanatomy in Echinoderes
Additional file 3:Eversion, retraction and motility of Echinoderes. Video of a live specimen of E. spinifurca under brightfield illumination. Eversion and retraction of the introvert and associated spinoscalids of the head region facilitate forward movements of the animal. The segmented trunk is highly flexible and exhibits a broad range of dorsoventral and lateral articulation. The entire gut system (mouth cone, pharynx, intestine) moves within the body as the introvert is everted and retracted. The pair of red spots at the anterior and correspond to photoreceptors. (MP4 6 MB)
Here, we propose a model for retraction of the introvert by combined action of three sets of muscles in Echinoderes: introvert retractors, introvert circular muscles, and introvert circular muscle retractors (Figure 6). When the introvert is everted, introvert retractors (ir or idr + ipr, respectively), circular muscles (icm), and circular muscle retractors (icmr) are relaxed and stretched (Figure 6A). Ten introvert retractor muscles are attached at the level of the primary spinoscalids and alternate with them in a radial arrangement. During contraction, introvert retractors cause the primary spinoscalids to fold inward, followed by the remaining scalids (Figure 6B). Synchronous contraction of introvert retractors and the relaxation of dorsoventral muscles within the trunk , combine to initiate retraction of the introvert. Musculature is absent within primary and other scalids, which implies that scalids cannot move independently from each other, and thus move passively during relocation of the head. The introvert circular muscle (icm) then contracts, reducing the volume and diameter of the introvert, enabling it to pass through the neck. At the same time, the introvert circular muscle retractors (icmr) contract, which supplements the introvert retractors, leading to retraction of the introvert (Figure 6C).
Dorsoventral muscles of the trunk play an important role during extension of the introvert. The contraction of dorsoventral muscle fibers causes an increase of internal pressure within the reduced body cavity, acting as a hydrostatic skeleton to extend the introvert [20, 25]. Once the introvert is everted, the mouth cone protrudes. Internal hydrostatic pressure within the body cavity may not be enough to fully extend the mouth cone. However, the mouth cone has an intimate positional relationship with the pharynx. When the pharyngeal protractor muscles contract, the pharynx moves in an anterior direction pushing the mouth cone outward (see below). When the pharynx is retracted toward the trunk by contraction of pharyngeal retractor muscles, the mouth cone is also retracted.
Typical food items found within the gut of kinorhynchs include bacteria, diatoms, algae and detritus [35, 36, 44, 54]. The articulated outer oral styles may be used as ‘forceps’ for grasping, manipulating, and ingesting those and other food items . In order to feed this way, muscles at the base of the outer oral styles (osm) are most likely antagonistic with an external circular muscle (mce) of the mouth cone (Figure 3A-B). When the paired, longitudinal oral style muscles contract, the external circular muscle relaxes and the oral styles are straightened and extended (Figure 3A). Conversely, when the external circular muscle contracts, the paired oral style muscles stretch and the outer oral styles bend (Figure 3B). The radial distribution of oral style muscles, as well as introvert retractors, indicate a correlated function. As previously suggested, this combination of longitudinal and circular muscles may enable limited motion of the outer oral styles . Their main function could be to sense and respond to external stimuli, which is in agreement with TEM studies that show a sensory cell at the base of each outer style [1, 32, 36]. However, both sensory and grasping functions may be combined. It would seem reasonable that the animal must detect and discriminate what is ingested. The inner oral styles are not articulated, and show only a circular muscle around their base. This may function to selectively open the mouth in the presence of food particles [1, 33, 55]. Furthermore, ciliated receptor cells and terminal pores have been confirmed in each of the inner oral styles, suggesting there may also be a sensorial feeding-related function for these structures [1, 38].
The neck acts as an anterior closing apparatus of the body by synchronous movements of alternate hard (placid) and soft (interplacid) cuticular elements [44, 45]. The radial symmetry of this ‘closing system’ is shared by all genera within Echinoderidae. In Echinoderes, the neck circular muscle attaches to soft interplacid cuticle lining the distal perimeter of the neck region (R.M Kristensen personal communication). When the introvert is retracted, the placids rotate toward the center of the neck on hinge-like articulations between the placids and the first trunk segment (Figure 7A and 1H). When the introvert is everted, the neck circular muscle is relaxed to its widest diameter along interplacid attachment sites. In this relaxed position, the hard placids are ‘flipped open’ and aligned with the anterior-posterior axis (Figure 7B). Rotation of the placids is coordinated with contraction of longitudinal fibers (lcf) that are attached to interplacid sites of the neck (Figure 7B). When the introvert is completely withdrawn, the circular muscle is contracted to its smallest diameter, soft interplacid cuticle is pulled toward the center of the neck, and the placids become tightly juxtaposed to close off the anterior of the trunk (Figures 1H and 7A). Consequently, the neck and introvert are functionally linked and interdependent [1, 53]; however, while circular muscles of the mouth cone and introvert become repositioned along the anterior-posterior axis, the neck circular muscle maintains a fixed position. Both the introvert and neck circular muscles are ultimately involved in introvert retraction and closure of the anterior trunk in Echinoderes, they are most likely independent systems, where introvert retraction is dynamic and often partial without closing off the trunk body. Contrary to this, Müller and Schmidt-Rhaesa  suggested that both muscles primarily control the closing system (neck) of Antygomonas sp. However, each of their respective closing systems exhibits a distinct morphology and thus requires a more thorough investigation.
The trunk has paired sets of longitudinal, dorsoventral and diagonal muscles that enable these animals to perform a range of movements. In Echinoderes, the relaxed body plan exhibits a curvature of the dorsoventral axis along the trunk (Figure 1A-E). Segmented dorsal and ventral longitudinal muscles may act as antagonists to produce this curvature. And paired sets of continuous fibers that span several segments likely contribute to the high degree of trunk flexibility observed in living specimens (Additional file 3). Pairs of dorsoventral muscle bands join tergal (dorsal) and sternal (ventral) plates in segments 3–10. These muscles are thought to be derived from circular muscles [1, 56]. However circular muscles are reduced or absent in the trunk of kinorhynchs, and a reasonable hypothesis for the origin of dorsoventral musculature is lacking. Yet, as with other muscle types, dorsoventral muscle bands are integral to kinorhynch locomotion and feeding. The contractions of dorsoventral fibers pull each plate toward the center of the body, which increases the internal pressure of the trunk and contributes to eversion of the introvert. To our knowledge, contraction of dorsoventral musculature has not been characterized in Echinoderes, or Kinorhyncha. We suspect that during introvert eversion, contraction of these muscles would proceed sequentially from posterior to anterior, analogous to peristaltic movements in soft-bodied invertebrates. Synchronous contraction may not be as effective, impeding anterior movement of the pharynx and mouth cone. Diagonal muscles are only present from segments 1–8, and contribute to lateral movements of the animal within that trunk region [44, 45]. Because they are not present in segments 9–11, the posterior trunk is less flexible, which may confer an unrecognized functional stability associated with sexual reproduction.
We did not detect musculature within dorsal and lateroventral spines. Müller and Schmidt-Rhaesa  described small, triangular paradorsal muscles at the base of middorsal spines in Antygomonas sp. that could be responsible for the movements of those spines. However, subsequent studies revealed that actin filaments in circumciliary microvilli of paradorsal sensory spots were misinterpreted as muscles [20, 35]. Among species of Echinoderes, we observe a similar pattern of ‘triangular’ labeling in trunk positions corresponding to sensory spots, which appears to support the alternative explanation for the presence of actin filaments in microvilli. Musculature associated with lateral terminal spines, tergal extensions and penile spines appear to be specializations of the ventral and dorsal longitudinal musculature . It is not known whether segmented ventral or dorsal muscles act simultaneously or independently with spine movements. Lateral terminal spines are directly controlled by antagonistic pairs of short muscles. Lateral terminal accessory spines do not have musculature and thus any observed movement of those spines is passive. Interestingly, penile spines are connected to long, thin muscle fibers that trifurcate distally, with individual fibers attaching to each of three spines on left and right sides of segment 11. Due to size and location, it is not yet clear whether each penile spine is capable of independent movements. Although the function of a penile spine has been questioned [1, 14, 35] detection of penile-spine-specific muscle fibers indicates a potential for distinct movements of each spine during the process of mating.
The pharynx is composed of a pharyngeal bulb, encircled by multiple fibers with different but integrated functions. It is the most complex muscle system in Echinoderes. Radial and circular muscle fibers of the pharynx bulb are reported in many studies ([1, 33, 44] and references therein). Contraction of radial fibers increases the bulb’s lumen diameter, while contraction of circular fibers decreases the lumen diameter. Together, antagonistic muscle coordination enables the pharynx to function as muscular sucking pump [1, 20, 25, 57]. The bulb’s anterior sphincter is likely to have a selective function as food moves into the buccal cavity. The posterior sphincter may regulate passage of mechanically digested food into the midgut, and prevent backflow from the midgut during changes in body pressure . Pharynx retractors move the bulb in a posterior direction when the head is retracted into the body. Outer pharyngeal protractors (pop) ‘pull’ the pharynx bulb out of the trunk when the introvert is everted. The inner protractors (pip) also move the pharynx in an anterior direction, further toward the mouth cone. The process of protraction may be very fast, due to a combination of pharyngeal musculature (pop + pip) and the increase of internal body pressure from dorsoventral muscles (dvm) of the trunk. The pharynx suspensor muscles (phs) could act to maintain the position of the pharynx bulb, and prevent twisting, when the pharynx is retracted within the trunk. Additional musculature surrounding the pharynx bulb may assist in the movement of gut contents, such as antagonistic contraction of longitudinal and radial fibers as suggested by Neuhaus . The orthogonal grid of longitudinal and circular muscles surrounding the midgut implies that digestion may be enhanced, in part, by peristalsis. This would enable particles to be displaced toward the hindgut where transverse dilatator muscles regulate defecation . A circular muscle acting as an antagonist to these posterior dilatators was described in Centroderes sp. and Zelinkaderes floridensis. We did not identify a hindgut circular muscle in Echinoderes.
Comparative myoanatomy between kinorhynchs and closely related groups
Based on morphological characters, Kinorhyncha, Priapulida and Loricifera are grouped together as the Scalidophora [11, 12, 33]. Molecular analyses have suggested an alternative hypothesis, where kinorhynchs and priapulids form a monophyletic group, excluding Loricifera [13, 58]. However, very few molecular characters have been sampled for Loricifera, and with improved molecular and taxonomic sampling, loriciferans may become repositioned within Scalidophora. Thus far the most consistent interpretation is that Scalidophora (kinorhynchs + priapulids ± loriciferans) is recognized as the most basal branch within Ecdysozoa [7, 15, 16, 19, 59]. Accordingly, comprehensive descriptions of myoanatomy in Echinoderes and other kinorhynch genera will broaden our understanding of how different types and patterns of musculature evolved within Scalidophora, and by extension, Ecdysozoa. Yet our results also imply that new mysteries have surfaced regarding putative ancestral patterns of musculature in the lineage of animals preceding the scalidophorans. For instance, there are undeniable contrasts in the size, symmetry and complexity of scalidophoran body plans that are reflected in their respective myoanatomy. Most notable is the obvious pattern of segmentation in Kinorhyncha that is apparently absent in Priapulida and Loricifera.
Comparatively, kinorhynchs, priapulids and loriciferans have an eversible head that facilitates locomotion, feeding, and protective behavior. In kinorhynchs, the radially symmetric mouth cone and introvert are equipped with unique arrays of oral styles and rings of scalids that likely overlay an original bilateral symmetry, as observed within the trunk of all kinorhynch species . The development of such radial symmetry at the anterior end is most likely an adaptation to their burrowing mode of life, which involves uniform contact with sediments . Although members each of these phyla ‘burrow’ in sediments, the segmented trunk of kinorhynchs also differs from the body plans of priapulids and loriciferans, which are essentially non-segmented vermiform or ovular, respectively. Thus, different numbers and arrangements of trunk muscles are not directly comparable among these three animal groups. Nevertheless, Kristensen and Higgins  suggested that, although distinctly segmented, longitudinal muscles in the trunk of kinorhynchs might be homologous to a layer of longitudinal muscles in the body of priapulids. This inference would appear to be supported by a study from Rothe and Schmidt-Rhaesa and Schmidt-Rhaesa and Rothe [5, 30], who observed continuous longitudinal muscles in the trunk of a juvenile kinorhynch prior to their segmental pattern in the adult, implying a developmental transition or the presence of a particular non-segmented muscle type in ancestral, adult kinorhynch taxa. Such homology would have to be demonstrated by developmental studies that identify a similar cellular origin and similar genetic specification mechanism for distinct muscle types in each group of animals, which is thus far not available. In our opinion, direct comparisons of myoanatomy among Kinorhyncha, Loricifera and Priapulida are only possible within their head and neck regions, at least as far as our methods have revealed.
In loriciferans, the distal part of the mouth cone is arranged in a hexaradial pattern, while it is pentaradial in priapulids and kinorhynchs . However, the internal arrangement of musculature does not reflect their respective patterns of mouth cone symmetry. In Kinorhyncha, there are 8–9 pairs of short longitudinal muscles in the mouth cone [29, 33], whereas there are eight individual muscles in Loricifera . Based on their arrangement, Neves et al.  consider these muscles to be homologous in both phyla. Comparable muscle groups have not been found in priapulids. The radial arrangement of introvert scalids is roughly pentagonal in priapulids and kinorhynchs. Priapulids show twenty-five longitudinal rows of scalids in the introvert , whereas the kinorhynch introvert typically bears individual rings of 10–20 scalids each. Loriciferans exhibit a highly variable arrangement of introvert scalids among genera and species, as well as among larval and adult stages. And, introvert scalid musculature is intrinsic in loriciferans, yet completely extrinsic in kinorhynchs and priapulids, resulting in the passive movements of rows or rings of scalids in the latter two taxa [1, 42]. Furthermore, there are several longitudinal and circular muscles within the introverts of both priapulids and loriciferans; however, the arrangement is different in each phylum, with a densely packed grid-like pattern of body wall muscles in priapulids, and a net-like pattern composed of few circular muscles and notably thin longitudinal fibers in loriciferans that appear to be associated with the anteriormost rows of scalids . Kinorhynchs lack a grid or net-like arrangement of muscles in their introvert, and instead show a single introvert circular muscle that is integrated with several retractors.
Introvert retractors are generally referred to in the literature as inner and outer retractors, attaching to the introvert wall on both sides of the brain in each of these three phyla [1, 35, 39, 40, 42]. This arrangement has been suggested as one of several apomorphic characters for grouping scalidophorans together . However, further comparative analyses of introvert musculature indicate there are several important taxon-specific differences. The so-called inner retractors of kinorhynchs are in fact part of the pharyngeal bulb musculature, and participate in retraction of the pharynx and the mouth cone, not the introvert. And the outer retractors of Echinoderes are introvert retractors, and therefore inner and outer retractors are assigned to separate organs. From a recent cytochemical study of myoanatomy in the loriciferan Nanaloricus sp., there is some evidence that dorsal and ventral longitudinal retractors of the head might correspond to the outer retractors, while the posterior part of the mouth cone retractors could correspond to the inner retractors described for Nanaloricus mysticus by TEM [42, 43]. However, there is an intricate system of mouth cone and buccal tube retractors that occupy a similar position, and therefore a definitive homologization is not yet possible without co-labeling musculature and nucleic acids or neurites of the loriciferan brain, or further comparative studies at the ultrastructural level. Regarding the unusual passage of muscle fibers through tissues of the brain, we did find a similar pattern in Echinoderes to what has been found in loriciferans, supporting previous observations [1, 39, 42]. In priapulids, inner and outer retractors were designated as short and long, and were not given positional correlations relative to brain structure . So it appears that more information is required to confirm spatial relationships between organ-specific retractors and cycloneuralian brain architecture within loriciferans and priapulids. Fibers that extend along inner and outer sides of a collar-shaped brain in different taxa, but connect with non-homologous organs, may simply represent convergent solutions to the same problem. If there is a correspondence between inner (pharynx/mouth cone) and outer (introvert) retractors confirmed by co-labeling experiments in all three phyla, it may prove to be an apomorphy of Scalidophora. Until then, designating the arrangement of ‘inner and outer retractors’ as a unifying character should be treated with caution.
Loriciferans and kinorhynchs also share a distinct neck region with a single, thick circular muscle [1, 43, 44]. In priapulids, only larvae exhibit a well-developed neck region, whereas in adults the introvert and trunk typically join each other directly . And although there is some external similarity between a priapulid larva and adult loriciferans, there is no circular muscle associated with the neck region of larval priapulids. Furthermore, larval priapulids can retract their head and neck internally within the trunk for protection, in contrast to the non-retractable neck regions of kinorhynchs and loriciferans. This could indicate that the neck regions are non-homologous in Priapulida and in Kinorhyncha.
In Loricifera, the pharynx is composed of myoepithelial cells with radial fibers [20, 39, 42]. Within Cycloneuralia, a myoepithelial pharynx is only shared by loriciferans and nematodes, with putative secondary losses in priapulids and kinorhynchs, however this type of pharynx most likely evolved independently several times [20, 21, 33]. The pharynx in priapulids and kinorhynchs includes both an epithelium and a muscle layer [1, 20, 21].
Nematomorphs typically are considered cycloneuralians and hence closely related with the scalidophorans. The adult has an extremely long and slender vermiform body plan, with a reduced digestive system and a rounded anterior end often lacking a distinct head [21, 25]. Adult nematomorph features are not readily comparable with scalidophorans, however, an endoparasitic larval form is equipped with an introvert and retractable proboscis [21, 60]. Muscle groups that operate the introvert and proboscis (mouth cone) are somewhat comparable to muscle groups in the head regions of priapulids, kinorhynchs and loriciferans, although based on a single study by CLSM for the nematomorph larva of Gordius aquaticus. Musculature within the larva’s anterior trunk include six introvert retractors, and six proboscis retractors, with none of those retractors associated with circular muscles, which appear to be entirely absent. Some similarity between loriciferans and nematomorphs is observed regarding the position and function of proboscis retractors in the Gordius larva and the buccal tube retractors of adult Nanaloricus sp. . Moreover, the oblique muscles described in the Gordius larvae can have the same function as the retractors of the introvert in kinorhynchs. Overall, the numbers and arrangements of particular muscle groups in this nematomorph larva are not shared with scalidophorans, especially when comparing introvert circular muscles that are common to priapulids, kinorhynchs and loriciferans but absent in Nematomorpha. It appears that the muscular organ systems of Scalidophora are relatively distinct from other cycloneuralian taxa, contributing to their putative monophyly.
The myoanatomy of Echinoderes is highly conserved. The following muscle groups were identified within each of five species: (i) two mouth cone circular muscles, and nine pairs of oral styles muscles in the mouth cone; (ii) ten introvert retractors, one introvert circular muscle, and fourteen introvert circular muscle retractors in the introvert; (iii) one neck circular muscle; (iv) ventral and dorsal longitudinal muscles within segments 1–10, longitudinal continuous fibers spanning subsets of segments 1–9, diagonal muscles in segments 1–8, and dorsoventral muscles in segments 3–10, all of them in the trunk; (v) a pharynx bulb composed of ten radial and ten circular muscle fibers, a sheath of pharyngeal protractors and retractors surrounding the pharynx, an orthogonal grid of longitudinal and circular fibers surrounding the intestine, and a minimum of one pair of hindgut dilators; (vi) three pairs of terminal spine muscles, and one pair of penile spine muscles in segment 11. Between species of Echinoderes, minor differences were observed among introvert retractor muscles and the composition of pharyngeal sheath musculature.
Within Kinorhyncha, there are common myoanatomical traits: introvert scalids are not supplied with muscles; the pharynx bulb is surrounded by a complex array of retractors and protractors forming a conspicuous muscular sheath. There are both segmented and unsegmented muscles within the trunk. Dorsal or lateroventral spines are not associated with musculature. All terminal spines are associated with musculature except for lateral terminal accessory spines (LTAS). Kinorhyncha, Loricifera and Priapulida have common sets of anterior retractor muscles, and should not be utilized as phylogenetic characters since they do not correspond in number, arrangement, and attachment patterns. They are most likely convergent adaptations to a shared burrowing life style. Within Scalidophora, the muscular organ system is comparatively more similar between kinorhynchs and loriciferans.
This study provides the first comprehensive investigation of myoanatomy in Kinorhyncha by CLSM and three-dimensional reconstruction, with comparative descriptions of the form and function of muscles systems in the head, neck and trunk regions of Echinoderes (Echinoderidae, Cyclorhagida). Our results build upon previous investigations by transmission electron microscopy, and have begun to address questions about the origins of complex myoanatomy in kinorhynchs, and closely related taxa. In the future, important insights must come from genomic and/or transcriptomic sequence analysis, characterization of gene expression patterns within muscle tissues and other organ systems, and a thorough study of early development in Kinorhyncha, the embryos of which remain elusive.
Materials and methods
Animal collection and fixation
Summary of sampling and collection data for five species of Echinoderes
Ramalhete Ria Formosa (Portugal)
May 3rd, 2012
37° 00.00 N 7° 58.63 W
Mud with Zostera sp.
Off shore Albufeira (Portugal)
April 28th 2012
36° 57.83 N 8° 12.63 W
Higgins meiobenthic dredge/Van Veen grab
4 miles station Fort Pierce (USA)
June 6th 2011 and Sept 26th 2012
27° 28.19 N 80° 12.76 W
5 miles station Fort Pierce (USA)
June 6th 2011 and Sept 26th 2012
27° 30.01 N 80° 12.69 W
6 miles station Fort Pierce (USA)
June 6th 2011 and Sept 26th 2012
21° 29.18 N 80° 10.98 W
3 miles station Fort Pierce (USA)
June 27th 2011 and Sept 26th 2012 June 27th 2011 and Sept 26th 2012
27° 28.33 N 80° 13.68 W
Muddy sand muddy sand
4 miles station Fort Pierce (USA)
27° 28.19 N 80° 12.76 W
5 miles station Fort Pierce (USA)
June 6th 2011 and Sept 26th 2012
27° 30.01 N 80° 12.69 W
6 miles station Fort Pierce (USA)
June 6th 2011 and Sept 26th 2012
21° 29.18 N 80° 10.98 W
Off shore Albufeira (Potugal)
April 28th 2012
36° 57.84 N 8° 12.63 W
Higgins meiobenthic dredge/Van Veen grab
Scanning electron microscopy (SEM)
Fixed specimens were dehydrated through a graded series of ethanol dilutions, and dried within a Tousimis Samdri-790 Critical Point Dryer (Tousimis Research Corp., Rockville, MD) with CO2 as an intermediate. Dried specimens were mounted on aluminum stubs, sputter coated with a gold-palladium alloy, and imaged with either a HITACHI S4800 or a JEOL JSM 6335 field emission scanning electron microscope.
Phalloidin and propidium iodide staining
Fixed specimens of E. spinifurca (n = 33), E. horni (n = 25), E. dujardinii (n = 28), E. hispanicus (n = 5) and E. sp. (n = 14) were washed and labeled in multiple species-specific experiments. For each species, specimens were washed from PBS:NaN3 solution with 3 × 15 min exchanges of 0.1 M PBS, followed by permeabilization in PBT (0.1 M PBS + 5.0% Triton X-100) for 24 hours at 4°C. Filamentous Actin (F-actin) fibers of musculature were labeled by incubating specimens at concentrations of a 1:40 or 1:100 dilution of Alexa Fluor® 488, 546, or 633-conjugated phalloidin (Molecular Probes) in PBT. Incubation was always performed in the dark while rocking at 4°C in glass spot plates. Total incubation times were typically 72 hrs with fresh staining solutions added after 24 and 48 hrs. For DNA staining, fixed specimens were rinsed from PBS:NaN3 solution with 3 × 15 min exchanges 0.1 M PBS, followed by 3 × 15 min exchanges of PBT (0.1 M PBS + 0.2% Triton X-100+ 0.5% BSA). These specimens were then treated with RNase A at 1.0 mg/ml PBT for 1.0 hr at 37°C, washed with 3 × 15 min exchanges of PBT, and incubated with propidium iodide (PI) at 5.0 μg/ml PBT in the dark while rocking for a period of 48–72 hrs at 4°C. Subsets of specimens were also co-labeled with phalloidin and propidium iodide for 48–72 hrs at 4°C. All labeling experiments were terminated with multiple exchanges of 0.1 M PBS immediately prior mounting.
Mounting and clearing
Prior to mounting, two or three layered strips of clear tape were each placed in parallel on one side of glass microscope slide, to elevate the placement of a coverslip above the specimens. A spot of double-stick tape was placed between the clear strips. Stained specimens were placed onto the double-stick tape and oriented during adhesion. To clear the specimens, slides were transferred through graded series of isopropanol dilutions, terminating with final immersion and mounting in a 2:1 mixture of benzyl benzoate and benzyl alcohol. A coverslip was placed across the strips of clear tape and sealed with clear nail polish. Alternatively, specimens were slowly moved through a glycerol series (20%, 40%, 60%, 80%) to prevent contraction of the trunk region, and then mounted in glycerol (80% glycerol, 0.1 M PBS), or Fluoromount G® (Southern Biotech) antifade mounting medium.
Confocal Laser Scanning Microscopy (CLSM) and 3D reconstruction
Confocal imaging was performed with an LSM 510 (Carl Zeiss Inc.), an LSM700 mounted on an Axio Imager upright microscope (Carl Zeiss Inc.), or a Leica DM 5000 CS with SP5 laser scanning unit. Confocal z-stack projections were compiled and analyzed with Fiji, v. 1.47 (Wayne Rasband, National Institutes of Health), and edited with Adobe Photoshop CS4 (Adobe Systems Incorporated, San Jose, CA). Autofluorescence of the cuticle was detectable in each of three confocal channels. Imaging of the cuticle was routinely performed with an excitation wavelength of 488 nm, and a band pass filter (BP 505–530 nm), to eliminated fluorescent emission crosstalk between adjacent channels. The cuticle, including all cuticular structures, was imaged separately, or simultaneously with the excitation of additional fluorescent markers to distinguish autofluorescent signals from the emission of fluorophore conjugates. Cuticle imaging served to orientate and guide interpretations of the internal and external anatomy in each species. For 3D reconstructions, z-stacks were surface-rendered by using the software Imaris v. 7.5.0 (Bitplane AG, Zürich, Switzerland). Schematics and figure plates were prepared with Adobe Illustrator CS6 (Adobe Systems Incorporated, San Jose, CA). The terminology used for external morphology and position follows Pardos et al. , Neuhaus and Higgins , and Sørensen and Pardos ; accordingly, trunk segments are numbered 1 to 11, from anterior-to-posterior. Internal structures are named in accordance with previous studies based on CLSM (see [5, 29, 30]) and TEM (see [1, 33]). The use of Kinorhyncha in the laboratory does not raise any ethical issues and therefore Regional or Local Research Ethics Committee approvals are not required.
MH is grateful to Dr. Mary Rice and Dr. Jon Norenburg for sponsorship and scientific advisement, and to Dr. Valerie Paul and technical staff at the Smithsonian Marine Station at Fort Pierce (SMSFP). We acknowledge technical and field staff at CCMAR (Portugal). MH is very grateful to Dr. Heinrich Reichert, and staff at the Imaging Core Facility at Biozentrum, University of Basel (Switzerland). Dr. Reinhardt Møbjerg Kristensen generously loaned us unpublished TEM images. Part of this research was funded by Project CGL 2009–08928 (Ministerio de Ciencia y Tecnología, Government of Spain) to FP. Field collection, imaging and research in Florida (USA) was funded by a Smithsonian Institution/Link Foundation Graduate Fellowship to MH. Field collection and imaging in Faro (Portugal) was funded by ASSEMBLE Grant No. 227799 to RCN and MH. This publication is Smithsonian Marine Station contribution no. 948.
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