Metamorphosis of cranial design in tiger salamanders (Ambystoma tigrinum): A morphometric analysis of ontogenetic change

While ontogenetic analyses of skull development have contributed to our understanding of phylogenetic patterns in vertebrates, there are few studies of taxa that undergo a relatively discrete and rapid change in morphology during development (metamorphosis). Morphological changes occurring in the head at metamorphosis in tiger salamanders (Ambystoma tigrinum) were quantified by a morphometric analysis of cranial osteology and myology to document patterns of change during metamorphosis. We employed a cross-sectional analysis using a sample of larvae just prior to metamorphosis and a sample of transformed individuals just after metamorphosis, as well as larvae undergoing metamorphosis. There were no differences in external size of the head among the larval and transformed samples. The hyobranchial apparatus showed many dramatic changes at metamorphosis, including shortening of ceratobranchial 1 and the basibranchial. The subarcualis rectus muscle increased greatly in length at metamorphosis, as did hypobranchial length and internasal distance. A truss analysis of dorsal skull shape showed that at metamorphosis the snout becomes wider, the maxillary and squamosal triangles rotate posteromedially, and the neurocranium shortens (while maintaining its width), resulting in an overall decrease in skull length at metamorphosis. These morphometric differences are interpreted in light of recent data on the functional morphology of feeding in salamanders. Morphological reorganization of the hyobranchial apparatus and shape changes in the skull are related to the acquisition of a novel terrestrial feeding mode (tongue projection) at metamorphosis. Metamorphic changes (both internal and external) that can be used to judge metamorphic condition are discussed.     

Instrumentally conditioned avoidance by tiger salamanders (Ambystoma tigrinum) to reagent grade odorants

Tiger salamanders (Ambystoma tigrinum) were given pairings ofair dilutions of either n-amyl acetate or d-camphor and intenselight in a stainless steel and glass chamber using a simpleflow dilution olfactometer. Avoidance responses were conditionedto presentations of amyl acetate but avoidance responses didnot condition to presentations of camphor     

Growth rates and size at metamorphosis of high elevation populations of Ambystoma tigrinum

Summary The role of temperature in determining the alternative life history sequences in high elevation populations of Ambystoma tigrinum is given a physiological base. Growth rates of larval populations increase with increased average pond temperatures whereas sizes of the larvae at metamorphosis decrease with increased average pond temperatures. This results in a negative correlation between growth rate and size at metamorphosis for these populations. Data collected from naturally occurring populations and presented here are compatible with laboratory studies. The impact of temperature on the physiological processes of growth and metamorphosis substantiates the claim that temperature, rather than food abundance, determines the alternative life history sequences followed by high elevation populations of A. tigrinum.     

The occurrence of biochemical metamorphic events without anatomical metamorphosis in the axolotl

Although the axolotl Ambystoma mexicanum is anatomically a larval amphibian, it does produce a small amount of endogenous thyroxine. According to the theory that different tissues have different thresholds of response to thyroxine, the axolotl may undergo certain biochemical metamorphic events without anatomical metamorphosis.Gel electrophoresis demonstrated that the hemoglobin and serum protein composition of the blood changed at approximately 125 and 210 days of normal development, respectively. Both events were prematurely inducible by thyroxine; metamorphosed animals had neotenous adult hemoglobin and serum protein electrophoretic patterns.On sodium dodecyl sulfate-polyacrylamide gels, denatured neotenous adult hemoglobin fractionated into components of 15,000 and 19,000, and 24,500 molecular weight (relative to that of bovine hemoglobin monomer, 15,500). Larval hemoglobin possessed components of 13,800 and 19,500 molecular weight.It was concluded that (1) at 100–150 days of normal development, the production of new hemoglobin polypeptide subunits was stimulated whereas the synthesis of larval subunits was inhibited, (2) the axolotl is not biochemically neotenous for at least two normally metamorphic events, and (3) the tissues responsible for certain biochemical metamorphic events probably have a lower threshold of response to thyroxine than the tissues responsible for anatomical metamorphosis.     

Stimulation of terrestrial-substrate preferences and locomotor activity in newly transformed tiger salamanders (Ambystoma tigrinum) by exogenous or endogenous thyroxine

Recently transformed adult tiger salamanders (Ambystoma tigrinum) that had never resided on land were treated with increasing, alternate-day injections of thyroxine (experiment 1) or single injections of particular dosages of this hormone (experiment 2). In all cases control salamanders received equivalent volumes of saline on a similar schedule. In both experiments, subjects treated with thyroxine displayed significant levels of terrestrial-substrate preference in a moisture-gradient apparatus. Salinetreated controls never emerged from the water. In experiment 2, animals that received single thyroxine treatments also displayed heightened levels of land-directed locomotor activity. In experiment 3, blood plasma was collected from salamanders displaying spontaneous land preference and others displaying water preference. Radioimmunoassay for thyroxine indicated that salamanders that had moved to, and resided upon, a terrestrial substrate some time subsequent to metamorphosis had significantly higher plasma levels of this hormone than did animals preferring to remain submerged. These results indicate (1) that thyroxine stimulates, and possibly maintains, emergence from water and terrestrial preference in newly transformed tiger salamanders and (2) that this hormone stimulates a locomotor activity component associated with the movement of formerly aquatic adults to the terrestrial habitat.     

Cutaneous Exchange of Ions in Lower Vertebrates

SYNOPSIS. Cutaneous ion transport has long been studied forits role in osmotic and ionic regulation in amphibians. In additionto this role, it is becoming clear that cutaneous ion exchangeinfluences, and is influenced by, a number of other physiologicaland morphological factors. The exchange of Na^$ and Cl^–across the skin of larval Ambystoma tigrinum is clearly involvedin acid-base balance. The animals require NaCl in their bathingmedia in order to compensate for a respiratory acidosis or torecover normally from a metabolic acidosis. Conversely, Na^$influx is stimulated and Cl^– influx is inhibited duringhypercapnia. Cutaneous ion transport in larval A. tigrinum appearsto be at least partially influenced by cutaneous circulationas immersion in isosmotic media to reduce skin blood flow alsoslows Na^$ influx. Allometric analysis of Na^$ influx yieldeda slope of 0.52, which is significantly less than the slopepredicted for surface area. The lower slope for ion transportmay reflect changes in capillary recruitment, skin thicknessor distribution of ion transporters over the skin. In additionto the well known cutaneous ion transport of amphibians, a numberof fish and reptilian species have also been discovered to exchangeions across skin in ways which may have homeostatic consequences.     

Is Lamprey Metamorphosis Regulated by Thyroid Hormones?

Lampreys are one of just a few fishes which have a true (firstor first type) of metamorphosis in their life cycle. In thesea lamprey (Petromyzon marinus), spontaneous metamorphosisis initiated when the size (length and weight), condition factor,and lipid stores reach appropriate levels and coincide withthe postwinter rise in water temperature. The serum levels ofthe thyroid hormones, thyroxine (T₄) and triiodothyronine (T₃),drop dramatically at the onset of metamorphosis and metamorphosiscan be induced with treatment of animals with the goitrogen,KCIO₄, which also results in a decline in serum levels of thyroidhormones. The fact that thyroid hormone treatment can blockspontaneous and induced metamorphosis is support for the viewthat thyroid hormones, particularly T₃, operates like a juvenilehormone in lamprey metamorphosis; this view is counter to therole of thyroid hormones in metamorphosis of other vertebrates.The monodeiodinase pathways, whereby T₄ is converted to T₃ orto the biologically inactive reverse T₃, and even further degradationof T₃, may be a significant mechanism directing metamorphicchange. Lamprey metamorphosis is facultative in that it is initiatedor inhibited depending upon the coordination of a complex integrationof environmental, metabolic and hormonal cues. Thyroid hormonesdo not regulate lamprey metamorphosis in the sense observedin other vertebrate metamorphoses but they are important tothe developmental process. Some of the features of the involvementof thyroid hormones in lamprey metamorphosis may be relatedto the presence of the endostyle in larvae which in turn reflectsthe ancient origins of this vertebrate and perhaps the conservationof an ancient method of induction of metamorphosis. Some cluefor other factors which initiate lamprey metamorphosis may comethrough the examination of inducers of metamorphosis in lowerchordates     

THE ANTAGONISM BETWEEN THYROID AND PARATHYROID GLANDS

From the facts stated in this paper it is evident that the thymus gland of mammals contains a substance which is capable of producing tetany when fed to the larvæ of certain species of salamanders (Ambystoma opacum and Ambystoma maculatum). As long as the larvæ have not developed their own thymus glands, they are able, by means of some mechanism, to counterbalance the tetanic action of the thymus substance introduced in their food. When, however, the secretion from their own thymus glands is added to the thymus material introduced with the food, this mechanism of preventing tetany becomes inadequate and tetany ensues. In the larva of a third species of salamander, Ambystoma tigrinum, this mechanism will prevent tetany even when the larvæ are fed on thymus. In mammals the parathyroids are known to prevent tetany and are supposed either to absorb the tetany-producing substance and thus prevent its action or to change it into another non-toxic substance. It is at least probable that in the amphibians the parathyroids play the same rôle. Larvæ of anuran amphibians, which develop their parathyroids soon after hatching, never show tetanic convulsions if they are fed on thymus, but in certain species of salamanders, whose parathyroids develop only during metamorphosis, the larvæ invariably have tetanic convulsions upon thymus feeding, while the metamorphosed animals never show tetany. But in addition to the parathyroids the salamanders must possess still another mechanism which during the larval period inhibits the production of tetany by the animal''s own thymus glands. In the larvæ of Ambystoma opacum and Ambystoma maculatum this mechanism is sufficient only to prevent tetany from the animal''s own thymus, while in the larvæ of Ambystoma tigrinum it is capable of preventing tetany even when the larvæ are fed with thymus. If the thymus is the organ by whose action tetany is produced, we can understand why tetany in human beings occurs far more frequently in children than in adults, since in the latter the thymus gland is replaced, at least to a great extent, by connective tissue. The relation of thymus to tetany may also possibly explain the occurrence of tetany during pregnancy; while the parathyroids of the mother may be sufficient to prevent tetany from her largely atrophied thymus, they may not be sufficient to prevent tetany from the excess of thymus substance furnished by the fetus to the blood of the mother.     

Regulation by thyroid hormones of terminal differentiation in the skeletal dorsal muscle. II. Urodelan amphibians

In the urodelan amphibian Pleurodeles waltlii, spontaneous anatomical metamorphosis was correlated with an increase in the serum level of thyroxine (T4). It was also accompanied by a change in the myofibrillar ATPase profile of the dorsal skeletal muscle; fibers of larval type were gradually replaced by the adult fiber types I, II A, and II B. Likewise, a myosin isoenzymic transition was observed in dorsal muscle, larval isomyosins were replaced by adult isoforms. In a related species, Ambystoma mexicanum, in which no spontaneous external metamorphosis occurs under standard conditions, the serum T4 level was shown to remain low. During further development, the myofibrillar ATPase profile acquired the adult fiber types, but a high percentage of immature fibers of type II C persisted. Myosin isoenzymic transition was also incomplete; larval isoforms were still distinguished in the neotenic adults. In experimental hypothyroidian P. waltlii, no external metamorphosis occurred; the myofibrillar ATPase profile was of the immature type, and the larval isomyosins persisted. Triiodothyronine induced experimental anatomical metamorphosis in A. mexicanum; only limited changes in the myofibrillar ATPase profile resulted from the treatment, but a complete myosin isoenzymic transition was observed. These results tend to indicate that a moderate increase in the level of thyroid hormone is sufficient to induce the differentiation of adult fiber types, together with the production of adult myosin isoforms in the skeletal dorsal muscle of amphibians, while a pronounced increase would be necessary for repressing the initial larval features.     

Taste Disks are Induced in the Lingual Epithelium of Salamanders during Metamorphosis

Morphological changes of oral cavity during metamorphosis withspecial reference to the taste organ were examined in Ezo salamanders(Hynobius retardatus) and axolotls (Ambystoma mexicanum), andcompared with those in bullfrogs (Rana catesbeiana). The non-distensibletongue of salamanders changed the structure progressively duringmetamorphosis: a small area of the rostrum protruded and developedcaudally with recession of the flat area of the tongue. Theprotrusion that developed on the tongue had numerous papillae,as seen in the frog tongue. The apical region of the papillaeoccasionally had a cell mass similar to the taste disk of frogs(termed a taste disk-like cell mass). On the flat area of thetongue, the barrel-shaped taste buds of larval salamanders weretransformed into taste buds with a wider receptor area. Thebarrel-shaped taste buds decreased progressively during metamorphosis,while taste disk-like cell masses increased. Neuronal labelingwith an antibody to neuron-specific enolase and fluorescentcarbocyanine dye showed that the taste disk-like cell massesin metamorphosed salamanders were innervated by the glossopharyngealnerve (nerve IX). Nerve IX responded to taste stimulation aswell as mechanical stimulation applied to the rostral tongue.During metamorphosis the salamanders undergo transformationand rearrangement of taste organs on the tongue possibly asan adaptation to the terrestrial environment. Chem. Senses 22:535–545, 1997.     

The origin of tiger salamander (Ambystoma tigrinum) populations in California, Oregon, and Nevada: introductions or relicts?

Whether intentionally or accidentally introduced, exotic species have the capacity to dramatically disrupt native communities. In central California, tiger salamanders (Ambystoma tigrinum) have been introduced as a by-product of the sport fishing bait industry. Some of these introductions are relatively well known and have resulted in the formation of hybrids with the imperiled native California tiger salamander (A. californiense). Other populations of A. tigrinum, particularly in the northern and eastern parts of the state, remain poorly characterized and are present in regions where relictual amphibian populations of other species have persisted, suggesting that these might be relictual, native A. tigrinum. We used genetic sequence data to determine the provenance of all known extralimital A. tigrinum populations in California and adjacent Oregon and Nevada through comparison with reference samples from the native range of A. tigrinum. Our results suggest that A. tigrinum have been introduced in Northern California, Southern California and the Sierra Nevada, originating from multiple sources across the Great Plains of the US. Furthermore, two populations near the California-Oregon border are most closely related to A. tigrinum populations from Washington and Oregon and may represent native tiger salamander lineages.     

Behavioral determinations of thresholds for n-butyl acetate and nbutyl alcohol in the tiger salamander (Ambystoma tigrinum)

Two groups of tiger salamanders (Ambystoma tigrinum) were conditionedto respond to odorant-air mixtures of n-butyl acetate (8.9 x10^–5M) or n-butyl alcohol (6.7 x l0^–5M). They werethen given tests with various concentrations of the trainingodorants presented using a temporal forced-choice method ofascending limits. Results showed that reliable responses toodorant-air presentations were obtained with concentrationsof n-butyl acetate above 2.4 x l0^–7M and with concentrationsof n-butyl alcohol above 8.5 x 10^–8M. These results arein substantial agreement with previous dectrophysiological findings.     

Experimental analysis of character coupling across a complex life cycle: Pigment pattern metamorphosis in the tiger salamander,Ambystoma tigrinum tigrinum

Developmental relationships among characters are expected to bias patterns of morphological variation at the population level. Studies of character development thus can provide insights into processes of adaptation and the evolutionary diversification of morphologies. Here I use experimental manipulations to test whether larval and adult pigment patterns are coupled across metamorphosis in the tiger salamander, Ambystoma tigrinum tigrinum (Ambystomatidae). Previous investigations showed that the early larval pigment pattern depends on interactions between pigment cells and the lateral line sensory system. In contrast, the results of this study demonstrate that the major features of the adult pigment pattern develop largely independently of both the early larval pattern and the lateral lines. These results suggest that ontogenetic changes that occur across metamorphosis decouple larval and adult pigment patterns and could thereby facilitate independent evolutionary modifications to the patterns during different stages of the life cycle. J. Morphol. 237:53–67, 1998. © 1998 Wiley-Liss, Inc.     

Respiration and acid-base balance in the salamander,Ambystoma tigrinum: Influence of temperature acclimation and metamorphosis

Summary Effects of temperature acclimation (5 or 25 °C for 2–4 weeks) and metamorphosis on oxygen uptake, acid-base balance and blood-O₂ affinity have been investigated inAmbystoma tigrinum. The results differ from previous studies in three ways. (1) The transition from gilled to gill-less adults had no effect on the O₂ affinity of blood. (2) Cold acclimation increased blood O₂ affinity in neotenes and had no effect in adults. (3) O₂ uptake increased, rather than decreased, after acclimation to a higher temperature. The results resemble previous studies also in three ways. (1) O₂ uptake increased with the transition from gilled-neotenes to gill-less adults as did the dependence on air-breathing. (2) Metamorphosis resulted in CO₂ retention and a fall in arterial pH. (3) The temperature coefficient of blood pH was about –0.014dpH/dT in vivo and in vitro. The physiological significance of the results is discussed with respect to the natural history, modes of breathing, and dependance on aerial respiration ofAmbystoma tigrinum.     

Testing a key assumption of host‐pathogen theory: density and disease transmission

Conventional disease theory suggests that extinction with density‐dependent transmission is unlikely as the threshold host density (KT) is greater than zero. Extinction may result if transmission is frequency dependent or the pathogen has an environmental reservoir. Given the importance of understanding how pathogens affect species richness and diversity there are few empirical tests of these conclusions. We used an Ambystoma tigrinum–Ambystoma tigrinum virus (ATV) model system in the laboratory to examine disease transmission dynamics. Susceptible A. tigrinum larvae were exposed to three different densities and proportions of infected larvae for 24 h. We then housed susceptible hosts individually for 28 days and monitored them for infection. The density of infected hosts to which susceptible hosts were exposed was the best predictor of infection (p=0.037). There was no effect of host clutch on the probability of becoming infected (p=0.67). Larvae in the highest density treatments died sooner than larvae in lower density treatments (p<0.001). Asymptomatic but infected hosts shed sufficient virus into the water in a 24‐h period to infect susceptible hosts without any direct contact between individuals. ATV transmission was best described by a power function, leading to the prediction that extinction of A. tigrinum as a result of this pathogen is unlikely. Indeed, field observations show that larval salamander populations that experience ATV‐driven epidemics may decrease, but not to extinction, and then recover. Disease is proposed as a possible explanation for the global decline of amphibians. Ranaviruses infect many amphibian populations, but based on our results may not be a general cause of declines to extinction. In contrast, frequency dependent transmission, environmental reservoirs and alternative hosts may be the most likely explanation for the enigmatic decline, at times to extinction, of some amphibian populations as a result of emerging infectious diseases, like the chytrid fungus Batrachochytrium dendrobatidis.     

EXPERIMENTAL PRODUCTION OF GIGANTISM BY FEEDING THE ANTERIOR LOBE OF THE HYPOPHYSIS

1. Metamorphosed salamanders of the species Ambystoma opacum and Ambystoma tigrinum were fed on a pure diet of the anterior lobe of the hypophysis of cattle; the controls were fed on an abundant diet of earthworms. 2. The rate of growth of the animals fed on the anterior lobe of the hypophysis was greatly increased over the rate of growth of normal animals. 3. Growth of the animals fed on anterior lobe did not cease after they had reached the normal "maximum" size of the species, and experimental giants were produced. 4. The largest animal of the species Ambystoma opacum fed on anterior lobe of the hypophysis was 19 mm. larger than the largest normal animal of this species known to the writer; the largest animal of the species Ambystoma tigrinum fed on anterior lobe is at present about 28 mm. larger than the largest normal animal of the eastern race of this species known to the writer.     

Geographically variable selection in Ambystoma tigrinum virus (Iridoviridae) throughout the western USA

We investigated spatially variable selection in Ambystoma tigrinum virus (ATV) which causes frequent and geographically widespread epizootics of the tiger salamander, Ambystoma tigrinum. To test for evidence of selection, we sequenced several coding and noncoding regions from virus strains isolated from epizootics throughout western North America. Three of the sequenced regions contained homologues for genes putatively involved in host immune evasion and virulence: eIF‐2α, caspase activation and recruitment domain (CARD) and β‐OH‐steroid oxidoreductase. Selection analysis showed evidence of very strong purifying selection on eIF‐2α, purifying selection within certain viral clades on CARD and positive selection on β‐OH‐steroid oxidoreductase within certain clades. Analysis using multidivtime and Tajima’s relative rate tests indicate accelerated rates of evolution within clades associated with anthropogenic movement. These clades also demonstrate greater spatial variability in selection, suggesting a lack of local adaptation (i.e. locally adapted populations should exhibit little to no selection because of absent or reduced variation in fitness once a fitness optimum is reached). Increased transfer of non‐native viral strains to naïve salamander populations, in conjunction with local maladaptation as a result of local selection pressures, may explain the spread and emergence of ATV epizootics in A. tigrinum in western North America.     

Thyroid Hormone Receptor Genes of Neotenic Amphibians

Since thyroid hormones play a pivotal role in amphibian metamorphosis we used PCR to amplify DNA fragments corresponding to a portion of the ligand-binding domain of the thyroid hormone receptor (TR) genes in several neotenic amphibians: the obligatory neotenic members of the family Proteidea the mudpuppy Necturus maculosus and Proteus anguinus as well as two members of the facultative neotenic Ambystoma genus: the axolotl Ambystoma mexicanum and the tiger salamander Ambystoma tigrinum. In addition, we looked for TR genes in the genome of an apode Typhlonectes compressicaudus. TR genes were found in all these species including the obligatory neotenic ones. The PCR fragments obtained encompass both the C and E domains and correspond to α and β genes. Their sequences appear to be normal, suggesting that there is no acceleration of evolutionary rates in the TR genes of neotenic amphibians. This result is not surprising for Ambystomatidae, which are known to respond to T3 (3,3′,5-triiodothyronine) but is not in agreement with biochemical and biological data showing that Proteidea cannot respond to thyroid hormones. Interestingly, by RT-PCR analysis we observed a high expression levels of TRα in gills, intestine, and muscles of Necturus as well as in the liver of Ambystoma mexicanum, whereas TRβ expression was only detected in Ambystoma mexicanum but not in Necturus. Such a differential expression pattern of TRα and TRβ may explain the neoteny in Proteidea. The cloning of thyroid-hormone-receptor gene fragments from these species will allow the molecular study of their failure to undergo metamorphosis. Received: 23 April 1996 / Accepted: 20 January 1997     

On natural metamorphosis inducers of the cnidarians Hydractinia echinata (Hydrozoa) and Aurelia aurita (Scyphozoa)

 Hydractinia echinata and Aurelia aurita produce motile larvae which undergo metamorphosis to sessile polyps when induced by external cues. The polyps are found at restricted sites, A. aurita predominantly on rocks close to the shore, H. echinata on shells inhabited by hermit crabs. It has been argued that the differential distribution of the polyps in their natural environment largely reflects the distribution of the natural metamorphosis-inducing cues. In the case of H. echinata, bacteria of the genus Alteromonas were argued to meet these conditions. We found that almost all substrates collected in the littoral to induce metamorphosis in H. echinata, and several bacterial strains isolated from the sea, including the common E. coli, induce metamorphosis efficiently. In A. aurita metamorphosis may be induced by the water–air interface, whereby metamorphosis precedes (final) settlement. Received: 7 December 1998 / Accepted: 8 July 1999