Regional differences in the developing foreleg of Drosophila melanogaster

We transplanted imaginal disks of Drosophila melanogaster from larvae of the second half of the third larval instar into prepupae. Disks from the youngest donors differentiated bristles of only the distal segments of the leg. These disks also produced unusually large areas of cuticle that had no bristles. Disks from older donors differentiated bristles of more proximal segments and the area of cuticle with no bristles was reduced. To account for the regional variation in these results, there must be regional differences among the prospective leg cells at some time during the period from the second half of the third larval instar to the end of adult bristle differentiation. We asked whether prospective distal cells were more advanced than prospective proximal cells during bristle differentiation. We estimated when bristle precursor cells undergo their final cell divisions by heavily irradiating prepupae and pupae. We assumed that cells that were insensitive to the radiation had completed their cell divisions. The distal segments were the first to have insensitive bristles. Most leg bristles became insensitive between 12 and 18 hr after pupariation. The tarsus had a larger proportion of its bristles insensitive than the femur at 15 hr after pupariation. We also investigated when bristle-forming cells begin elongating their bristle shafts. We used the length of bristle rudiments as an indicator of when elongation is initiated. At 35 hr after pupariation, bristle rudiments of distal segments were two to three times longer than bristle rudiments of proximal segments. We discuss how these intersegmental differences observed during bristle differentiation can account for the regional variation in response of discs transplanted into older hosts. However, we do not exclude the possibility that regional differences among cells of the leg tissue exist at stages earlier than the time of bristle differentiation.     

Cell polarity during wound healing in an insect epidermis

The insect integument displays uniform posterior orientation of cuticular denticles or bristles formed by the epidermal cells. We want to understand how cell polarities become uniformly oriented in the plane of the epidermal sheet. Here we test whether directed cell migration disturbs the orientation of denticles. Burning a circular area of epidermal cells beneath the cuticle causes cells to migrate into the resulting wound and the cuticle pattern observed after the subsequent moult depends on the time interval between burning and ecdysis. After a short wound-healing period cuticular protrusions tend to point away from the wound. With increasing would healing periods they tend to point more and more towards the wound centre. These results suggest that the migrating cells tend to orient cuticular protrusions in the direction of cell movement while continued cell movement will bend nascent cuticular protrusions outwards. Cell shape may also determine denticle orientation. I propose that the asymmetric localization of cell components known to determine the orientation of cell migration may also determine denticle orientation in insect epidermal cells.     

The growth, development and reproduction of a deep sea cumacean (Crustacea: Peracarida)

A single sample of over 1000 individuals of Leuconjonesi Bishop, 1982, taken at a depth of about 1500 m on the continental slope off Surinam, was studied. The carapace length of individuals in the first postmarsupial instar was already about half that of brooding females. Growth increments at early moults were of 20–25. Males reached the final morphological form in the sixth postmarsupial instar. A prepuberty moult was recognized between the third and fourth male instars. Females reached the preparatory stage in the fourth postmarsupial instar. Brooding condition occurred for the first time after the next moult. The brooding form could then alternate at successive moults with an inter-brood form, resembling the preparatory female, with small, non-overlapping oostegites. Preparatory and inter-brood females were morphologically separable; vitellogenesis was restricted to these instars. Broods were of 6–12 young. The individuals in each brood probably completed marsupial development, and were released, one by one. The copepod parasite Sphaeronella infested 10", of brooding-form females.     

Moult cycle and morphogenesis inHyas araneus larvae (decapoda,majidae), reared in the laboratory

Moult cycle and morphogenesis in larval instars (zoea I, zoea II, megalopa) of the spider crabHyas araneus (L.) were studied in the laboratory. Changes in the epidermis and cuticle were documented photographically at daily intervals to characterize the stages of the moult cycle. Stage A (early postmoult) is a very short period during which the larva takes up water. During late postmoult (B) and intermoult (C) the endocuticle is secreted, and there is conspicuous epidermal tissue condensation and growth. The onset of early premoult (D₀) is characterized by epidermal apolysis, occurring first at the bases of the setae in the telson of zoeal instars or in the rostrum of the megalopa, respectively. Intermediate premoult (D₁) is the main period of morphogenesis, in particular of setogenesis: in the setae of the zoeal telson and carapace there is invagination or (in the zoea II) degeneration of epidermal tissues. Formation of new setae in the interior of epidermal tubules was observed in zoeal maxillipeds and in the antennae of the zoea II and megalopa instars. During late premoult (Stages D_2–4) part of the new cuticle is secreted, and the results of morphogenesis become clearly visible. For technical reasons (rigid exoskeleton) only a preliminary account of the moult cycle in the megalopa can be given. A time schedule is suggested for the stages of the moult cycle. It is estimated that postmoult (A–B) takes ca 9 to 15 % of total instar duration, intermoult (C) ca 22 to 37 %, and premoult (D) ca 48 to 69 %. There is an increasing trend of relative portions of time (% of total instar duration) from instar to instar in Stages A–C (mainly in the latter) and a decreasing trend in Stage D (mainly in D₀ and D_2–4).     

Morphology of the female Myrmecolacidae (Strepsiptera) including the apron, and an associated structure analogous to the peritrophic matrix

Development in the totally endoparasitic female Strepsiptera has been clarified by light and electron microscopy. At the end of the 4th instar the cuticle sclerotizes anteriorly to form the cephalothorax and collar, the former of which is later extruded through the host cuticle. Posteriorly, the cuticle remains unsclerotized, and this region is within the host. The moult to the neotenic adult takes place within the 4th instar cuticle, and the epicuticles of the previous instars are retained as persistent sheaths. The gut, which is present in the earlier endoparasitic stages, is lost after extrusion of the cephalothorax, and a novel structure develops on the ventral surface of the neotenic female. Due to the position of this novel structure in the neotenic female, this area is called an apron. The detailed structure of the membranes in the apron in Stichotrema dallatorreanum Hofeneder from Oro Province, and of another female myrmecolacid (which has a different host) from West New Britain in Papua New Guinea, is described. A dual function for the apron is proposed.     

Development of respiratory structures in embryos and first and second instars of the bark scorpion,Centruroides gracilis (Scorpiones: Buthidae)

The SEM was used to study the development of respiratory structures in successive stages in relation to the overall changes occurring in the scorpions. Book lung development is a slow process, starting with spiracles and a sac‐like atrium in the early embryo and continuing lamellar formation to 150 or more in the adult. In the embryo, the primordial epithelial cells become aligned in a planar pattern as they secrete granules of material that aggregate spontaneously to form the cuticular walls of the lamellae. A blade‐like structure is formed consisting of cells sandwiched within the two cuticle walls they secreted. These cells are in the primordial air channel. The adjacent hemolymph channel is nearly devoid of cells, but cross‐bridges develop and help stabilize the cuticle walls and maintain the width of the channel. The cells in the primordial air channel undergo cytolysis, leaving it open for air except for cuticular cross‐bridges. Development continues in the newborn (first instars); the air channels of some lamellae still contain cells and are not yet functional for gas exchange. The first instars are weak and relatively inactive. They climb up on the mother's dorsum until the first molt (about 8 days). With the cuticular walls of the lamellae in place, cells adhering to the wall in the hemolymph channel produce a thin, new tissue layer (epithelium) on the lamellar wall facing the hemolymph channel. This layer has many discontinuities as though it is slowly developing. Formation of the tissue layer and cytolysis of the cells in the air channels continue through the first molt in which little book lung cuticle is shed as exuvium. The air channels of the second instars (foraging nymphs) are now cell free and open for air passage except for the cross‐bridges. The tissue layer is still incomplete and continues to be formed. It may provide the hypodermal primordium for cuticle replacement in later molts, but development was not studied beyond the second instar except for comparison with book lungs in the adult. The blade‐like lamellae in the adult are larger and more numerous than in the second instar, but in the anterior book lung the shape of the cuticle wall and cross‐bridges and the widths of the air and hemolymph channels are about the same as in the second instar. The air channels in the posterior part of the lamellae have distinctive, vein‐like space‐holders. The similarity of the adult anterior lamellae with those in the second instar suggests retention of this part through the 4–5 molts to maturation, and/or cell processes like those in the embryo are repeated, but this needs to be examined in further studies of cell and cuticle changes before and during the molts. J. Morphol., 2008. © 2008 Wiley‐Liss, Inc.     

The ontogeny of soldiers in Prorhinotermes simplex (Isoptera, Rhinotermitidae)

The ontogeny of the soldier caste in Prorhinotermes simplex is studied with emphasis on the instar origin of soldiers, the duration of the presoldier stage, and changes in external anatomy during the soldier morphogenesis. The soldiers of different instar origin are compared morphometrically and by analysis of the soldier defensive secretion. The soldiers were found to develop from larvae of the second up to the eighth instar, via a short (13–17 days) presoldier stage. The early soldier instars were found exclusively in incipient colonies while the mature colony contains late instar soldiers only. The abrupt change in the external anatomy occurs in two steps. During the larva-presoldier moult, the head increases in length but only slightly in width. During the presoldier-soldier moult, both the length and width of the head increase markedly and the typical cordate shape is attained; the relative size of the pronotum increases considerably. The long falcate mandibles develop mainly during the larva-presoldier moult. One antennal segment is added during these two moults. With increasing instar age of soldiers a relative increase of the pronotum and the head size in its posterior region was observed. No functional differences in external anatomy were found among the six soldier instars. The composition of the frontal gland secretion is similar in the six soldier instars, an extraordinarily high amount of a defensive substance, (E)-1-nitropentadecene, was detected together with (Z,E)-α-farnesene, presumably an alarm substance. The strategy of soldier production is discussed. We conclude that the observed patterns of soldier production in P. simplex correspond well to its ecological strategy of an advanced single-site nester able to migrate and form foraging groups. Received 16 August 2005; revised 21 November and 6 February 2006; accepted 16 February 2006.     

The levels of ecdysteroids in uninjured and leg-autotomized nymphs of Blattella germanica (L.)

The levels of ecdysteroids in control and leg-autotomized first-instar nymphs of Blattella germanica were determined by radioimmunoassay from hatching to the time of the first ecdysis. Uninjured nymphs showed a distinct release of ecdysteroids half-way through the stadium, and this resulted in the commencement of the moult cycle which formed the cuticle of the second instar. Cockroaches which had legs autotomized at 48 h after hatching (i.e. before the control ecydsteroid release) had their instar duration increased by that time period. Releases of ecdysteroids and events of the moulting cycle were also postponed by the 48 h period. The titre of ecdysteroids in injured animals was double that of controls. Nymphs were also autotomized at 96 h (i.e. after the normal release of ecdysteroids) but no changes in instar duration, ecdysteroid releases, or events of the moult cycle were recorded. The effects of injury, prothoracicotropic hormone activity and ecdysteroid release are discussed.     

蓖麻蚕个体发育中蜕皮甾类滴度的变化

用放射免疫分析法(RIA)测定了蓖麻蚕(Philosamia cynthia rieini)从卵期到成虫个体发育整个过程的蜕皮甾类(MH)水平.卵期在6天时有一个MH峰.一龄到四龄各龄均有一个MH峰,出现在停食前一天,导致幼虫蜕皮.五龄期有两个MF峰.第一个小峰出现在第三天,使进食的幼虫向预蛹转化;第二个高峰在上簇两天后,导致蛹表皮的形成.与其它鳞翅目昆虫一样,蛹期只有一个MH峰,发生在蛹期的前半段.成虫期血淋巴内MH含量很低.     

Isolation of third, fourth, and fifth instar larval midgut epithelia of the moth, Trichoplusia ni

A new tissue isolation technique was used to create intact midgut epithelial wholemounts from three Trichoplusia ni (Lepidoptera: Noctuidae) larval instars. The protease, dispase, removed the basal lamina and associated connective tissue and allowed for high resolution light microscopy of entire epithelia. Columnar, goblet, differentiating, and stem cells were characterized by double fluorescent labelling of f-actin and nuclei. A comparison of cell populations by digital image analysis revealed significant regional and temporal changes in the density and number of differentiating and stem cells. Growth of the midgut epithelium from third to fourth instar, and from fourth to fifth instar, was accomplished by both cell differentiation and cell division. Cell division however, was greatly reduced from fourth to fifth instar with a concomitant sharp decrease in the stem cell population.     

Postembryonic development of the complex tibial organ in the foreleg of the bushcricket Ephippiger ephippiger (Orthoptera,Tettigoniidae)

Summary The postembryonic development of the morphology and anatomy of the complex tibial organ in the foreleg of the bushcricket Ephippiger ephippiger is described. All the receptor cells are present in the subgenual organ, the intermediate organ and the crista acustica in the 1st larval instar. Generally, even in the 1st instar, the arrangement of the scolopidia in the three organs resembles the adult structure. The acoustic trachea, the tympana, the tympanal covers and the acoustic spiracle develop step by step in subsequent instars. The acoustic trachea resembles the adult structure for the first time in the 4th instar, although its volume is still small. The auditory threshold curves recorded from the tympanal nerve in instars 4, 5 and 6 show the same frequency maxima as those in the adult. The overall sensitivity significantly increases after the final moult. The dimensions of structures that lie within the crista acustica and that are probably involved in stimulus transduction and in frequency tuning have been analysed. The dorsal wall of the anterior trachea, the tectorial membrane and the cap cells have similar dimensions, especially in the last three instars and in adults.     

Neuroendocrine regulation of corpus allatum activity in Manduca sexta: The endocrine basis for starvation-induced supernumerary larval moult

When newly-ecdysed 5th instar larvae of Manduca sexta were starved for 3 days and thereafter fed on standard diet the majority (90%) of the surviving larvae moulted into 6th instars. Allatectomy prior to starvation abolished the supernumerary moult, while denervation of the corpora allata (CA) had no effect.Cautery of medial neurosecretory cells, but not of the lateral cells, prevented supernumerary moulting and pupation ensued. Transplantation of brains from young 5th instar donors into larvae, whose medial neurosecretory cells were cauterized prior to starvation, restored the extra larval moult. Neither CA nor corpora cardiaca (CC) could be substituted for the medial neurosecretory cells.For induction of the supernumerary moult the medial neurosecretory cells are required only until day 1 after refeeding whereas the CA are required until day 3 after refeeding. Allatectomy on day 3 after refeeding resulted in the production of black 6th instar larvae.We conclude that starvation-induced supernumerary moulting is due to activation of the CA by allatotropin produced by medial neurosecretory cells in the brain. The anteromedial cells (group II) appear to be the source of allatotropin.     

Further evidence for the protective role of sub-parietal cell membranous secretory product on the cuticle of a pentastomid arthropod parasite developing in its rodent intermediate host

The pentastomid parasite Porocephalus crotali, develops to an infective stage within a granulomatous lesion in the tissues of rodent intermediate hosts. A conspicuous layer of sub-parietal cell (SPC) secretory product, which coats the intermoult cuticle up to a depth of 12 microns, is described. Around the first five nymphal instars this material consists of an amorphous matrix with distinctive electron-lucid lacunae, but that around later instars (six and seven), while retaining much of the original morphology, possesses a significant membranous component. Host effector cells, most notably eosinophils and macrophage/epithelioid cells, are frequently completely enveloped by SPC secretion but invariably appear unreactive to it. Host cells may penetrate to the outermost layer of the epicuticle but again but again cytotoxic activity is absent. During ecdysis, effector cells are recruited to the intercuticular space where widespread degranulation is evident. Some of this is specifically directed against the underside of the cast cuticle, but not against the newly exposed cuticle. Protracted degranulation eventually reduces the cast cuticle to fragments which are endocytosed by giant cells. 1 cm long infective (seventh-stage) nymphs, which retain the sixth stage cuticle as a protective sheath, are largely devoid of membranous secretion and these were dissected from cysts, washed, and surgically transplanted into the body cavities of naive and infected mice. Pronounced differences in the onset and intensity of the subsequent inflammatory response in the two categories of host indicate some form of specific recognition. In both groups of mice though, the cuticle is an eventual target for attack by effector cells, and parasites are killed. The protective function of SPC secretion is discussed.     

Mode of action of the venom of the ectoparasitic wasp,Euplectrus comstockii, in causing developmental arrest in the European corn borer,Ostrinia nubilalis

Euplectrus comstockii Howard (Hymenoptera: Eulophidae), is an ectoparasitic, gregarious wasp which parasitizes the larval stage of several important lepidopteran pests. Parasitization of both natural and unnatural hosts prevents molting in the parasitized instar. Here we report the effect of wasp venom on the European corn borer (unnatural host), an important pest of corn and other vegetables. Venom collected from venom glands of adultE. comstockii, when injected intoO. nubilalis 5th instars, inhibited the growth rate, development and molting of the injected larvae. The observed effect on molting was dose and age dependent. When 3rd, 4th and 5th instarO. nubilalis were envenomated by adult wasps, the larvae also were developmentally arrested and failed to undergo a molt. However, 3rd and 4th instars underwent apolysis (separation of the epidermis from the old cuticle) and produced new cuticle. Fifth instars did not. A premolt hemolymph ecdysteroid peak was not observed in these experimental 5th instars, but injections of 20-hydroxy-ecdysone induced apolysis and new cuticle formation. Envenomated 4th instars (on becoming pharate 5th instars) exhibited a premolt hemolymph ecdysteroid peak. HPLC/RIA revealed that 20-hydroxyecdysone was present in the hemolymph of these pharate 5th instars. Thus, in the European corn borer, the mode of action of the venom depended upon the instar parasitized. Our results support the presence of a venom component(s) that, in 4th instar hosts, inhibited ecdysis, but did not prevent hemolymph ecdysteroid levels from increasing sufficiently to stimulate apolysis. In 5th instars, the same, or perhaps, a different component(s) ofE. comstockii venom prevented the synthesis/release of ecdysteroid by inhibiting a previously unknown molt-regulating physiological event that occurs between days 3 and 4 of the instar. Deceased     

Influence of thyroid hormones on neuronal death and differentiation in larval Rana pipiens.

The sphingid moth, Manduca sexta, typically passes through five larval instars, a pupal, and an adult stage. The larval labial glands secrete silk in the first instar and a viscous lubricant in the fifth. During metamorphosis the glands develop into salivary organs which produce an invertase-rich secretion. In normal development, the uniform population of cells in the duct of the larval gland transforms into the four sequentially arranged regions of secretory and conductive cells of the adult gland. In order to determine when competence to form the adult gland is established, fragments of labial gland ducts from first through fifth instar larvae were implanted into pupae. These gland fragments underwent metamorphosis with their hosts, passing through the same developmental phases. Glands from as early as the first instar were competent to form histologically and functionally normal adult regions. In later instars, transplants of measured fragments demonstrated that larval cells were programmed in situ to develop into the four adult cell types.     

Ultrastructural Effects of a Non-Steroidal Ecdysone Agonist,RH-5992, on the Sixth Instar Larva of the Spruce Budworm,Choristoneura fumiferana

Force feeding of RH-5992 (Tebufenozide), a non-steroidal ecdysone agonist to newly moulted sixth instar larvae of the spruce budworm, Choristoneura fumiferana, (Lepidoptera: Tortricidae) initiates a precocious, incomplete moult. Within 6h post treatment (pt) the larva stops feeding and remains quiescent. Around 12hpt, the head capsule slips partially revealing an untanned new head capsule that appears wrinkled and poorly formed. By 24hrpt, the head capsule slippage is pronounced and there is a mid-dorsal split of the old cuticle in the thoracic region but there is no ecdysis. The larva remains moribund in this state and ultimately dies of starvation and desiccation. The temporal sequence of the external and internal changes of the integument were studied using both scanning and transmission electron microscopy. Within 3hpt, there is hypertrophy of the Golgi complex indicating synthetic activity and soon after, large, putative ecdysial droplets are seen. Within 24h, a new cuticle that lacks the endocuticular lamellae is formed. The formation of the various cuticular components, the degradation of the old cuticle and changes in the organelles of the epidermal cells of the mesothoracic tergite are described. The difference between the natural moult and the one induced by RH-5992 are explained on the basis of molecular events that take place during the moulting cycle. The persistence of this ecdysone agonist in the tissues permits the expression of all the genes that are up-regulated by the presence of the natural hormone but those that are turned on in the absence of the hormone are not expressed.     

Developmental changes in dopamine levels in larvae of the fly Chymomyza costata: comparison between wild-type and mutant-nondiapause strains

Dopamine and two related catecholamines, L-3,4-dihydroxyphenylalanine (DOPA) and N-acetyl dopamine (NADA), were analyzed in whole body and tissue samples taken throughout late larval development of the drosophilid fly Chymomyza costata, which enters facultative diapause as a mature 3rd instar larva in response to short photophase. Wild-type (W) and mutant-nondiapause (M) strains reared under diapause inducing (d) and preventing (nd) photophases were compared. Developmental changes in the whole body of dopamine levels showed some general features irrespective of fly strain and rearing conditions: sharp major peaks during moult from second to third instar larva and during pupariation; lower minor peaks around the middle of both 2nd and 3rd instars. Significant differences between the strains and conditions were also found: dopamine levels were lower throughout the 2nd instar and during the 2nd to 3rd instar moult of mutant strain larvae (M/d) as compared to wild-type larvae (W/nd and W/d); while the late 2nd and late 3rd instar larvae destined to diapause (W/d) maintained relatively high dopamine concentrations, their counterparts destined to continuous development (W/nd and M/d) significantly decreased dopamine levels prior to the 2nd to 3rd instar moult or pupariation. Possible relationship between the dopamine levels and diapause induction/onset in C. costata larvae is discussed. Integument contained more than 90% of the dopamine found in the whole body. The gut and central nervous tissues showed relatively low pools of dopamine, only trace amounts were detected in haemolymph and no dopamine was found in fat body. DOPA levels were low and stable throughout larval development of both W and M strains and under both conditions. NADA levels peaked during second halves of 2nd and 3rd instars of both strains, then dropped to trace levels and were elevated again during 2nd to 3rd instar moult as well as in tanned prepupae. No elevation of NADA levels was recorded in 3rd instar W/d larvae which entered diapause.     

Design of an insect cuticle associated with osmoregulation: the porous plates of chloride cells in a mayfly nymph

In mayfly nymphs of the genus Coloburiscoides, cell complexes with an osmoregulatory function (so-called chloride cells) are found in the integuments of the oral gills, the abdominal gills and gill filaments, the coxae and the thoracic sternites. The cuticle overlying each cell complex is a rigid circular plate which is known to be porous to colloidal lanthanum suspensions. The present study shows that the plate is composed only of the cuticulin and dense layers of the epicuticle. Both layers have substructures built of subunits on almost perfect hexagonal lattices. The lattice spacings are 53 and 9.5 nm for the dense layer and the cuticulin layer respectively. During moulting the apical plasma membrane of the chloride cell remains adpressed to the old porous plate. The new porous plate is formed from a new chloride cell which intrudes from the base of the integument. Throughout the moult small pores persist in the new and otherwise continuous cuticle to allow continuity of the cytoplasm of the apical and basal portions of the old chloride cell. It is thought that this phenomenon allows osmoregulatory function of the chloride cell complex to be maintained during the moult.     

Studies on Pogonophora. 4. Fine structure of the cuticle and epidermis

The fine structure of the integument in several species of Pogonophora has been examined by electron microscopy. The cuticle over the main body is composed of several layers of orthogonally arranged fibres embedded in an amorphous matrix. It is regularly traversed by microvilli from underlying epidermal cells. Toothed bristles of the annuli and setae of the anchor are composed of closely packed fibrous cylinders wrapped in a cortical material. In fine structure the cuticle, setae, toothed bristles (or setae) and setal sacs forming the setae closely resemble the corresponding structures in annelids. The cuticle is maximally thick over the forepart (protosome + mesosome) ; it is very thin and non-fibrous over the surface of the metameric papillae and over extensive areas of post-metameric trunk. The possibilities of a collagenous nature of the cuticle fibres and their mode of secretion by the epidermal cells are discussed. The organization of various cell-types forming the epidermis over the entire animal is examined. Possible functions of these cell-types are discussed. Notable amongst these are 'possible zymogen cells' and some absorptive cells. The intriguing question of nutrition in these gut-less tubiculous animals is re-examined in the light of present observations.     

The embryonic moult in diplogastrids (Nematoda) - homology of developmental stages and heterochrony as a prerequisite for morphological diversity

Video analysis of developing eggs showed that diplogastrids, in contrast to the majority of nematodes, moult from J1 to J2 before they hatch from the egg. This embryonic moult leads to a conflict between the terminology for the J1-J4 postembryonic stages and the definition for the embryonic period that ranges from fertilization to hatching. The nature of developmental stages is discussed on the occasion of this terminological problem. Stages as “embryo”, J1, J2,… are defined as periods of time between certain developmental events and are called instars, whereas other stages as “tadpole stage” refer to characters. Character-defined stages refer to the temporal aspect of developmental characters. Only character-defined stages can be homologized between species. It is proposed to ignore the conflict of the J1-J4 terminology with the embryonic-postembryonic dichotomy as an embryonic stage cannot be satisfyingly defined. The biological relevance of the heterochronic shift of the first moult into the egg period is the possibility to omit secretion of the J1 stoma and pharynx cuticle as the diplogastrid J1 does not feed. Thereby the time slot for stoma morphogenesis that must be finished before cuticle deposition is prolonged. Within Diplogastridae this time slot facilitated the evolution of a tremendous diversity of complex stoma morphologies that is unique within “Rhabditida”.