Formation of the pronephros and pronephric duct rudiment in the Mexican axolotl

In the Mexican axolotl (Ambystoma mexicanum), the pronephros begins to form at the four-somite stage. It is initially continuous with the posterior-lateral region of somite 2 and the lateral margin of somites 3 and 4. By the seven-somite stage, the pronephros has become compacted, and the cells are now morphologically distinct from the somitic cells. At this stage, a mass of loosely connected cells, apparently originating from the lateral mesoderm, is seen below somites 4 and 5. By the eight-somite stage, these presumptive duct cells have migrated dorsally to the duct path and are found below somites 5–7. By the nine-somite stage they have begun to migrate caudally.     

GDNF and GFRalpha-1 are components of the axolotl pronephric duct guidance system

In mammals, secretion of GDNF by the metanephrogenic mesenchyme is essential for branching morphogenesis of the ureteric bud and, thus, metanephric development. However, the expression pattern of GDNF and its receptor complex-the GPI-linked ligand-binding protein, GFRalpha-1, and the Ret tyrosine kinase signaling protein-indicates that it could operate at early steps in kidney development as well. Furthermore, the developing nephric systems of fish and amphibian embryos express components of the GDNF signaling system even though they do not make a metanephros. We provide evidence that GDNF signaling through GFRalpha-1 is sufficient to direct pathfinding of migrating pronephric duct cells in axolotl embryos by: (1) demonstrating that application of soluble GFRalpha-1 to an embryo lacking all GPI-linked proteins rescues PND migration in a dose-dependent fashion, (2) showing that application of excess soluble GFRalpha-1 to a normal embryo inhibits migration and that inhibition is dependent upon GDNF-binding activity, and (3) showing that the PND will migrate toward a GDNF-soaked bead in vivo, but will fail to migrate when GDNF is applied uniformly to the flank. These data suggest that PND pathfinding is accomplished by migration up a gradient of GDNF.     

Pancreatic duct secretion: experimental methods, ion transport mechanisms and regulation

The pancreatic ductal tree conveys enzymatic acinar products to the duodenum and secretes the fluid and ionic components of pancreatic juice. The physiology of pancreatic duct cells has been widely studied, but many questions are still unanswered concerning their mechanisms of ionic transport. Differences in the transport mechanisms operating in the ductal epithelium has been described both among different species and in the different regions of the ductal tree. In this review we summarize the methods developed to study pancreatic duct secretion both in vivo and in vitro, the different mechanisms of ionic transport that have been reported to date in the basolateral and luminal membranes of pancreatic ductal cells and the regulation of pancreatic duct secretion by nervous endocrine and paracrine influences.     

Cranial features of dendrobatid larvae (Amphibia: Anura: Dendrobatidae)

The larval neurocranium and visceral arches of seven dendrobatid species representing four genera are described, based on cleared-and-stained and serially sectioned specimens. A variety of characters is shared by all seven species. Larval features do not substantiate the assumption of close ranoid affinities of the Dendrobatidae. Instead dendrobatid larvae share features such as the special quadripartite cartilago suprarostralis, the lack of the larval processus oticus, the presence of three foramina acustica, and the lack of a foramen perilymphaticum accessorius with many bufonoid larvae. The first of these characters is unique to bufonids, hylids, dendrobatids, and some New World leptodactylids; the other characters also occur in pelobatids and are presumably plesiomorphic for the Neobatrachia. The free proximal ends of Ceratobranchialia II and III are an autapomorphy of the Dendrobatidae supporting the monophyly of the family. Some features of the cranium are paedomorphic: low cartilago orbitalis, lack of connection between cartilage orbitalis and otic capsule (most species), and vestigal taeniae tecti. New anatomical terms are introduced. © 1995 Wiley-Liss, Inc.     

Functional response of suspension feeding anuran larvae to different particle sizes at low concentrations (Amphibia)

The influence of particle size, initial particle concentration and larval stage on the ingestion rate, ‘retention efficiency’, and filtering rate of anuran larvae with varying filter apparatus anatomy and different life histories was investigated for four species. Larvae of premetamorphic Stages 28 and 32 and prometamorphic Stage 40 were selected for filtering experiments on the basis of their different growth rates. Three different sizes of silica gel particles were offered as mock food. Particle concentration was measured photometrically. The Michaelis-Menten model was used to describe the dependency of ingestion rate, filtering rate, and ‘retention efficiency’ upon initial particle concentration, and to calculate maximum ingestion rate, threshold concentration, and the half-saturation constant. (1) The highest ingestion rates, filtering rates and ‘retention efficiencies’ were achieved by Xenopus laevis larvae, followed by Bufo calamita larvae. Bufo bufo larvae lay at the opposite end of the scale. Rana temporaria larvae were placed between B. calamita and B. bufo larvae. This order is attributed to differences in life histories, especially the different breeding environments in which these larvae occur. (2) The larger the particle size and the older the stage, the greater the tendency toward saturation of the ingestion rate, filtering rate and ‘retention efficiency’. These filtration parameters are graded according to particle size. The ingestion rate (number of particles), filtration rate and ‘retention efficiency’ are greatest for PS3. Ingestion volume is greatest for PS 1. The difference between PS3 and PS2 on the one hand, and PS1 on the other, is often great; for Stage 28 X. laevis it is very great. This shows that larvae ingest large particles more effectively, and that the most effective ingestion takes place at Stages 28 and 32, owing to the growth function of these stages. The ability of larvae to ingest large particles effectively is possibly a very basic phylogenetic characteristic. (3) The threshold concentration is lowest when the particles are at their largest. In accordance with conclusions drawn by other authors, threshold feeding is attributed to regulation by buccal pumping and mucus production. Considerable importance is attributed to threshold feeding with respect to larval adaptation to oligotrophic environments.     

Structure of the dermal scales in gymnophiona (Amphibia)

Histology and cytology of dermal scales of the gymnophionans Ichthyophis kohtaoensis and Hypogeophis rostratus reveal their structure and the nature of their mineralization. Dermal scales are small flat disks set in pockets in the transverse ridges of the skin. Each pocket contains several scales of various sizes. A ring of “hypomineralization” of varying diameter may occur on scales of a particular dermal pocket but bears no relation to the diameter of these scales. Three different layers form the scales and are seen on sections perpendicular to the surface. The cells of the basal layer lie deepest. Each of the two or three more superficial fibrous layers is composed of bundles of fibres that are oriented in parallel. The orientation varies among layers. The striation of the fiber scales has a periodicity comparable to that of the surrounding dermal fibers. Squamulae form a discontinuous layer on the scale surface and are the only mineralized part of the scale. The minerals are deposited both on the collagen fibers passing from the fibrous layers into the squamulae, and in the interfibrillar spaces. Spherical concretions, either isolated or coalescent, reaching up to 1 μm, are found on the surface of the squamulae. The dermal scales of Gymnophiona present some analogies with those of evolved bony fishes. Their characteristics could make them an original model for the study of mineralization.     

The effect of pH on feeding behaviour in newt larvae (Triturus: Amphibia)

The feeding responses of three species of newt larvae were compared under circumneutral and sublethal acid conditions. Under acid conditions (pH 4.5) feeding behaviour was suppressed in palmate newts, Triturus helveticus, and smooth newts. T. vulgaris , but not in crested newts, T. cristatus. At low pH, approach and orientation towards food occurred in T. helveticus and T. vulgaris , but snapping was inhibited; T. cristatus snapped and consumed food immediately it was offered under the same conditions. These differences are not consistent with the apparent greater tolerance of T helveticus for acidified ponds. The observations suggest that the chemosensory system of T. helveticus and T. vulgaris may be impaired at low pH.     

Mechanisms and regulation of ion transport in the renal collecting duct

1. In the present paper the ion transport function of the renal mammalian collecting duct and its regulation is briefly reviewed. 2. The epithelium is characterized by different cell types: principal cells, intercalated cells, type A, and intercalated cells, type B. 3. Using microelectrodes and various microscopic techniques active Na+ absorption as well as K+ secretion has been localized to the principal cells, while Cl- absorption was found to proceed largely, though not exclusively, through the tight junctions between cells. 4. Intercalated cells of type A, which prevail in the outer medullary collecting duct, secrete H+ and intercalated cells of type B, which are most frequent in the late cortical collecting duct, secrete HCO3-. 5. This specialization of different cells in transporting individual ions provides the basis for the efficient adaptive regulation of urinary ion excretion.     

Isolation and primary culture of Necturus maculosus (Amphibia: urodela) hepatocytes

Summary In order to evaluate their suitability for physiological and ecotoxicological studies, hepatocytes were isolated from the common mudpuppy (Necturus maculosus) using a two-step collagenase perfusion. Hepatocytes in primary culture were investigated for 14 d using light and electron microscopy and biochemical analyses. A typical perfusion yielded 1.7×10⁵ viable hepatocytes per gram body weight with an average viability of 86±5%. The majority of isolated cells remained in suspension and formed aggregates. The viability of hepatocytes in primary culture was dependent on a fetal calf serum (FCS) concentration and incubation temperature. Viability was best at 8°C in Leibovitz L-15 medium supplemented with 5% FCS. The ultrastructural characteristics of freshly isolated hepatocytes resembled those of N. maculosus hepatocytes in vivo. Whereas hepatocyte viability remained relatively stable (around 80%) up to 14 d in culture, electron microscopic analyses revealed changes at ultrastructural level. The majority of hepatocytes retained similar structural characteristics to those in vivo up to 4 d. Loss of cellular polarity, fractionation of rough endoplasmic reticulum, formation of autophagosomes, and successive exhaustion of cellular glycogen deposits were observed with increased time in culture. Functional integrity, as estimated by tyrosine aminotransferase induction, decreased during the culture period. Ultrastructural and biochemical analyses indicate the need for further improvement of culture conditions. Nevertheless, isolated hepatocytes in primary culture for up to 4 d can be recommended as a model for physiological and toxicological studies in lower vertebrates.     

The characterization of ion regulation in Amazonian mosquito larvae: evidence of phenotypic plasticity,population-based disparity,and novel mechanisms of ion uptake

This study is the first step in characterizing ion uptake mechanisms of mosquito larvae from the Amazon region of Brazil. Hemolymph NaCl levels and rates of unidirectional Na(+) and Cl(-) uptake were measured in larvae of Aedes aegypti and Culex quinquefasciatus in a series of environmental manipulations that are known to challenge ion regulation in other aquatic animals. Despite being reared for numerous generations in dilute media (20 micromol L(-1) NaCl), both species were able to maintain high hemolymph NaCl concentrations, a departure from previous studies. Exposure to distilled water or high-NaCl media did not affect hemolymph ion levels, but pH 3 caused significant decreases in hemolymph Na(+) and Cl(-) levels in both species. Exposure to water from Rio Negro (pH 5.5), an organically rich but ion-poor body of water, did not disturb hemolymph Na(+) and Cl(-) levels or the uptake of these ions. Acute exposure to control media or Rio Negro water titrated to pH 3.5 caused inhibition of Na(+) uptake and stimulation of Cl(-) uptake in C. quinquefasciatus, but A. aegypti larvae experienced only a significant reduction of Na(+) uptake in Rio Negro/pH 3.5 treatment. The stimulation of Cl(-) uptake at low pH has been documented only in aquatic insects and differs from all other invertebrate and vertebrate species. A similar pattern of Na(+) uptake inhibition and Cl(-) uptake stimulation was observed in A. aegypti larvae exposed to bafilomycin A(1), a blocker of V-type H(+) ATPase. Culex quinquefasciatus larvae were unaffected by this drug. Both Na(+) and Cl(-) uptake were reduced when C. quinquefasciatus larvae were exposed to acetazolamide, indicating that H(+) and HCO(3)(-), derived from hydration of CO(2), are involved with Na(+) and Cl(-) uptake. Kinetic analysis of Na(+) and Cl(-) uptake in C. quinquefasciatus, A. aegypti, and Anopheles nuneztovari larvae indicate that these Amazonian species share similar high-capacity and high-affinity mechanisms. Comparison of the Amazonian C. quinquefasciatus with a Californian population provided evidence of both phenotypic plasticity and population disparity in Na(+) and Cl(-) uptake, respectively. When the California population of C. quinquefasciatus was reared in a medium similar to that of the Amazonian group (60 micromol L(-1) NaCl) instead of 4,000 micromol L(-1) NaCl, larvae increased both Na(+) uptake capacity (J(max)) and affinity (i.e., reduced K(m)), yet Cl(-) uptake did not change from its nonsaturating, low-capacity pattern. In the reverse experiment, Amazonian C. quinquefasciatus demonstrated plasticity in both Na(+) and Cl(-) uptake by significantly reducing rates when held in 4,000 micromol L(-1) NaCl for 3 d.     

The ontogeny of the filter apparatus of anuran larvae (Amphibia,Anura)

Summary The pharynx ofBufo calamita, Rana temporaria andBombina variegata larvae (larval Types IV and III) changes considerably during the latter part of embryonic development. The entodermal regions between the visceral pockets flatten inward to form the anlagen of the filter plates. The ectoderm thrusts forward from the area of the persistent epidermal gills overlying the anlagen of the filter plates. The esophagus pushes dorsolaterally into the pharynx to give rise to the ciliary cushions. Comparison with the development ofXenopus laevis (larval Type I) reveals shared characters: (1) the filter plates are overlapped by the sensory layer of the epiderm and (2) the ciliary grooves are, like the ciliary cushions of larval Types III and IV, anteriorly directed dorsolateral extensions of the esophagus. In all the species studied an ectodermal-esophageal filter apparatus develops. The evolutionary origin of this filter apparatus is discussed. The epidermalization of gills is suggested as a common character with the sister group of Dipnoi, and is therefore a plesiomorphic character in all amphibians. The tendency of filter plate epidermalization is considered to be the end of a process which is also indicated in the epidermalization of the first visceral pouch in lung fish. The ciliary groove is unique in anuran larvae within the Lissamphibia, and is therefore seen as an autapomorphic character within amphibians. On the basis of the different structure of the ciliary cushion inX. laevis and in the other species of this study, two alternative levels of evolutionary ciliary groove origin are discussed. Derivation from the esophagus took place: (1) in a common anuran larval ancestor, or (2) at two independent levels; the first in the Pipidae (-Rhinophrynidae) ancestor and the second in the ancestor of all the other anuran families. Several larval characters and cladistic aspects make the first alternative more probable than the second. Larval Type II anatomy and Larval Type II truncation from the Larval Type IV of Ranoidea do not contradict these considerations. There is disproportionately early commencement of ingestion activity inR. temporaria (G Stage 23),B. calamita (G Stage 23), andB. bufo (G Stage 24) compared toXenopus. Feeding in the former three species precedes the differentiation of the filter plates, their mucus production, and the exhaustion of the yolk supply in the gut tissue. By contrast, the goblet cells and the ciliary cells of the ciliary cushions are already differentiated when feeding starts. This suggests that ingestion in these early stages requires mucus production by the ciliary cushions and transport by their ciliary cells. Presumably in fully formed larvae, the ciliary cushions are the mucus donors, whereas the filter plates are the mucus depositors. By contrast,X. laevis does not begin active food intake by suspension feeding until after the yolk supply has been used up from the entoderm of the buccal cavity to deep in the esophagus.Abbreviations AAC anlage of apical cell - AC apical cell - ACE anlage of cerebrum - ACG anlage of ciliary groove - AD aorta dorsalis - ADV anlage of dorsal velum - AG anlage of glottis - AFP anlage of filter plates - AFR anlage of filter rows - AFPC anlage of epidermal fold of peribranchial chamber (anlage of operculum) - ant. anterior - AMF anlage of middle fold - AO adhesive organ - APEG anlage of persistent epidermal gills - APOP anlage of postnarial papilla - APSF anlage of primary side fold - ASC1 anlage of Type 1 secretory cell - ATE anlage of tuba Eustachii - ATEG anlage of transient epidermal gills - AVV anlage of ventral velum - B branchial arch - BI-IV branchial arches I–IV - BFA buccal floor arena - BFT branchial food trap - BL basal lamina - BRA buccal roof arena - C cilium, cilia - CA cartilage of visceral arch - CC ciliary cushion - CE cerebrum, brain - CG ciliary groove - CH choana - CHY ceratohyale - CIC ciliary cell - CL capillary vessel - CN centriole, basal body - COC cuboidal cells - CT connective tissue - CTC connective tissue cell - d dorsal - DV dorsal velum - DVI–III dorsal vela I–III - E esophagus - e early - ED edge of filter plate - EN endothelium - ENC entodermal cell - EP epiderm - EPC epidermal cell - ER endoplasmatic reticulum - ET erythrocyte - ETZ ectodermal-entodermal transition zone - EV ear vesicle - EX merocrine extrusion - EY eye - EZ zone of extrusion - FP filter plate - FPII filter plate of the 2nd branchial arch - FPIV filter plate of the 4th branchial arch - FPC epidermal fold of peribranchial chamber (operculum) - FC filter cavity - FN filter niche - FR filter row - GL glottis - GS gill slit - 1. GS first gill slit - GZ glandular zone - H heart - HP hypobranchial plate - HY hyoid arch - IC intercellular space, enlarged by fixation and dehydration - L late - LJ lower jaw - LT larval type - LV lipid vacuole - M mitochondrion - MA mandibular arch - MF middle fold - med. median - MS microvillous stubs - MZ zone of microtubes - NAC nucleus of apical cell - NCIC nucleus of ciliary cell - NCL nucleus of capillary vessel - NCOC nucleus of cuboidal cells - NCT nucleus of connective tissue - NENC nucleus of entodermal cell - NEPC nucleus of epidermal cell - NO external nares - NPEC nucleus of periderm cell - NRC nucleus of random cell - NSC1 nucleus of Type 1 secretory cell - NSC3 nucleus of Type 3 secretory cell - NSLC nucleus of sensory layer cell - NSPC nucleus of supporting cell - NSQC nucleus of squamous epithelial cell - OC oral cavity - OS mouth - P papilla - PC peribranchial chamber - PCW peribranchial chamber wall - PE periderm - PEC periderm cell - PEG persistent epidermal gill - PG pigment granule - post. posterior - PS primary side fold - PH pharynx - RC random cell - RO rootlet - SC1 Type 1 secretory cell - SC2 Type 2 secretory cell, goblet cell - SC3 Type 3 secretory cell - SC4 Type 4 secretory cell - SG secretory groove - SL sensory layer - SLC sensory layer cell - SP secretory pit - SPC supporting cell - SQC squamous epithelial cell - SR secretory ridge - SRC secretory ridge cell - SS secondary side fold - ST. stage - STD stomodeum - SU spiculum of hypobranchial plate - T tentacle - TA anlage of tongue - TEG transient epidermal gill - TZ transitional zone of branchial food trap and ventral velum - UJ upper jaw - v ventral - VA visceral arch - VC vacuole - VPI–IV visceral pockets I–IV - VP visceral pocket - VV ventral velum - YV yolk vacuoles Supported by the Deutsche Forschungsgemeinschaft (DFG)     

Morphology and cell population kinetics of primary spermatogonia in the frog (Rana esculenta) (Amphibia: Anura)

Two morphologically distinct primary spermatogonial cell types were observed in the frog testis and distinguished on the basis of nuclear characteristics. They have been designated the pale and dark types of primary spermatogonia. On the basis of a kinetic analysis, it is proposed that the pale spermatogonia possess the faculty of self-renewal as well as that of forming dark spermatogonia; they are thus bipotential stem cells comparable to the undifferentiated type of mammalian spermatogonia. The dark spermatogonia, in contrast, are committed to a single pathway, i.e. to form secondary sperrnatogonia, and can be defined as differentiated or committed elements of the primary spermatogonial population. The number of stem cell spermatogonia and differentiated spermatogonia vary according to the period of the year, as does the rate of turnover of stem cells, with nearly 60–90% of cells temporarily out of the cell cycle at any given time. It is indicated that the spermatogonial population represents a 'cell renewal system' in a steady state for appreciably long periods of time, however, changing with season in as far as the magnitude of yield of spermatogonial cells is concerned. This implies that an equality should exist between the rate at which stem cells enter cell-cycling and the rate at which daughter cells change their morphological identity.     

Morphology of the kidney in larvae of Bufo viridis (Amphibia, Anura, Bufonidae)

This study deals primarily with the morphology and ultrastructure of the pronephros in the green toad Bufo viridis during prometamorphosis when the pronephros and the developing mesonephros function simultaneously. Furthermore, the mesonephros was studied during pro- and postmetamorphosis with emphasis on the distal segments of the nephron. The paired kidneys consist of two cranial pronephroi immediately behind the gill region and two more caudal elongated mesonephroi. Each pronephros consists of a single convoluted tubule which opens into the coelom via three nephrostomes. This tubule is divided into three ciliated tubules, three proximal tubule branches, a common proximal tubule and a distal tubule, which in turn continues into the nephric duct. No intermediate segment is present. The length of the pronephric tubule is 12 mm, including the three branches of the ciliated tubules and proximal tubules. Primary urine is formed upon filtration from an external glomerulus, which is a convoluted capillary lined by podocytes, a specialization of the coelomic epithelium. From the coelom the filtrate is swept into the ciliated tubules. In the collecting duct system of the developing mesonephric nephron epithelial cells with conspicuous, apical osmiophilic granules appear in larvae of 9-10 mm. Heterocellularity of mixed intercalated (mitochondria rich) cells and principal cells is observed in the collecting duct system and nephric duct from a larval body length of 14 mm. As the proliferation of mitochondria-rich cells proceeds, the osmiophilic granules disappear and are completely absent from the adult amphibian mesonephros.     

Growth and survival rate of the larvae ofHynobius nebulosus Tokyoensis Tago (Amphibia,Hynobiidae)

Growth and population density of the larvae, Hynobius nebulosus tokyoensisTago , were estimated in a small pond within the study site settled in Habu village of Hinodemachi, a suburb of Tokyo City, during the period from 1975 to 1980. The mortality factors which influenced the survival rate of larvae were also evaluated from the ecological point of view. Laboratory experiments on the growth of larvae and predation by newts were conducted in pararell with the field survey. The results showed that growth rate of larvae under the natural condition was very slow, as compared with that under the laboratory condition with sufficient food supply, and mean body size at metamorphosis was negatively correlated with the density at that time. This suggested that food resources were in short supply in the pond, and there occurred a severe intraspecific competition for food among larvae. The mortality rate of larvae was so high, 80–99% in each year, and the density of larvae survived until metamorphosis varied so greatly from year to year that the larval stage was the most important stage throughout the life cycle to the maintenance of a population for this salamander. The most important factors which contributed to this high mortality were the predation by the newt, Triturus pyrrhogaster pyrrhogasterBoie , and cannibalism. From the laboratory experiment, it was found that predators could attack only small larvae successfully, and successful attack rate decreased sharply as larvae grew larger. This relationship resulted in the characteristic L-shaped pattern of survivorship curve of larvae; that is, heavy mortality just after hatching period.     

Isolation and characterization of the third complement component of axolotl (Ambystoma mexicanum)

1. Using a monoclonal anti-human C3 antibody and a polyclonal anti-cobra venom factor antibody as probes, a protein homologous to the mammalian third complement component (C3) was purified from axolotl plasma and found to be axolotl C3. 2. Axolotl C3 consists of two polypeptide chains (Mr = 110,000 and 73,000) linked by disulfide bonds. An internal thiolester bond in the alpha chain was identified by the incorporation of [14C]methylamine and NH2-terminal sequence from the C3d fragment of C3. 3. Digestion of C3 by trypsin resulted in the cleavage of both the alpha and beta chains, generating fragments with a cleavage pattern similar to that of human C3. 4. The amino acid composition of axolotl C3 and the amino acid sequences of the thiolester site (and the surrounding amino acids), the cleavage site for the C3-convertase, and one of the factor I cleavage sites are similar to C3 from other vertebrates. 5. In contrast to human C3, which has concanavalin A binding carbohydrates on both the alpha and beta chains, only the beta chain of axolotl C3 contains such carbohydrates.     

Chondrocranial, hyobranchial and internal oral morphology in larvae of the basal bufonid genus Melanophryniscus (Amphibia: Anura)

Melanophryniscus is a genus of small toads inhabiting the southern portion of South America. This genus is considered basal within the family Bufonidae. Data on larval chondrocranial morphology do not exist for the genus and larval internal oral anatomy has only been described for a single species. Here, we describe chondrocranial and internal oral morphology in Melanophryniscus montevidensis , M. orejasmirandai and M. sanmartini . Chondrocranial morphology is similar among the species examined. Comparisons with other bufonids and with outgroup taxa suggest that the following chondrocranial characters may represent synapomorphies for the Bufonidae: free (or absent) ceratobranchial IV, a reduced or absent larval crista parotica, the lack of a larval otic process, and late development of thin, poorly chondrified orbital cartilages. The presence of an elongated processus anterior dorsalis of the suprarostral alae and the absence of a chondrified commissura quadratoorbitalis appear to be unique in Melanophryniscus among bufonids. Internal oral anatomy is conserved in Melanophryniscus , and among bufonids in general.     

The filter apparatus of Rana temporaria and Bufo bufo larvae (Amphibia,Anura)

Summary In larvae of Rana temporaria and Bufo bufo the location of filter apparatus within the larval organization, the arrangement of the morphological parts as branchial food trap, ventral velum, and filter rows, as well as their surface anatomy, are similar to that of other species of Orton's larval type IV. The means by which mucous with its entrapped food particles is transported from the filter rows to the esophagus is finally resolved. The dorsally positioned ciliary cushion extends far ventrally between the filter plates. From their contact with the filter rows, the cilia transport the mucous to Kratochwill's caudally positioned Flimmerrinne and from there to the esophagus. The original chordate principle of mucous entrapment and ciliary transport is thus retained by these anuran larvae. The only modification specific to the latter is the division into a ventral filter apparatus, whose epithelia serve for mucus entrapment, and a dorsal ciliary area.Six different types of cell may be distinguished ultrastructurally: (1) The ubiquitous squamous epithelium with merocrine extrusions; (2) the large supporting cells of the filter rows and of the ventral velum; (3) the ciliary cells of the ciliary cushion; (4) three different types of mucous producing secretory cells: (a) A type of cell similar to the goblet cell is found in the ciliary cushion (merocrine extrusion); (b) The secretory pits of the ventral velum and the secretory ridges have similar bottle-shaped merocrine secretory cells; (c) The merocrine apical cells of the filter rows are the final kind. It is evident that the ciliary cushion epithelium resembles that of both the manicotto glandulare of anuran larvae and the trachea and bronchus of Mammalia.Supported by the Deutsche Forschungsgemeinschaft-DFG