Immunohistochemical localization of thyrotropin-releasing hormone (TRH) in skin of Rana pipiens

Summary Using immunofluorescent techniques thyrotropin releasing hormone (TRH) is demonstrated in skin of Rana pipiens and R. catesbeiana. The immunofluorescent-TRH is localized in all cell layers of the epidermis and in the epithelium lining the various cutaneous glands, but not in the dermal layer.We wish to thank Dr. Ronald DeLellis and Ms. Mary Blount for their expert advice and guidance in the immunohistochemical techniques.This investigation was supported by NIH National Research Service Award # 1F32 AMO6018-01 from the NIAMDD to Janice L. Bolaffi and NIH Grant AM 21863 to Ivor M.D. Jackson.     

Evolution of behavior and neural control of the fast-start escape response

The fast-start startle behavior is the primary mechanism of rapid escape in fishes and is a model system for examining neural circuit design and musculoskeletal function. To develop a dataset for evolutionary analysis of the startle response, the kinematics and muscle activity patterns of the fast-start were analyzed for four fish species at key branches in the phylogeny of vertebrates. Three of these species (Polypterus palmas, Lepisosteus osseus, and Amia calva) represent the base of the actinopterygian radiation. A fourth species (Oncorhynchus mykiss) provided data for a species in the central region of the teleost phylogeny. Using these data, we explored the evolution of this behavior within the phylogeny of vertebrates. To test the hypothesis that startle features are evolutionarily conservative, the variability of motor patterns and kinematics in fast-starts was described. Results show that the evolution of the startle behavior in fishes, and more broadly among vertebrates, is not conservative. The fast-start has undergone substantial change in suites of kinematics and electromyogram features, including the presence of either a one- or a two-stage kinematic response and change in the extent of bilateral muscle activity. Comparative methods were used to test the evolutionary hypothesis that changes in motor control are correlated with key differences in the kinematics and behavior of the fast-start. Significant evolutionary correlations were found between several motor pattern and behavioral characters. These results suggest that the startle neural circuit itself is not conservative. By tracing the evolution of motor pattern and kinematics on a phylogeny, it is shown that major changes in the neural circuit of the startle behavior occur at several levels in the phylogeny of vertebrates.     

幼年斑马鱼的视觉系统与捕食行为

神经环路的研究是揭示动物行为神经机制的关键。斑马鱼作为一种低等脊椎动物, 在神经环路的研究中有着独特优势。文章描述了斑马鱼视觉系统及其下游的神经环路, 重点讨论了它们在捕食行为中的可能作用。斑马鱼捕食行为主要依赖于视觉功能, 该过程涉及到视觉-运动通路各个层次的神经环路, 包括下游的网状脊髓命令神经元、脊髓内部的运动控制环路以及一些亟待研究的功能单元。随着在体记录和操纵神经元活动技术的成熟, 以及行为学范式的完善, 对斑马鱼捕食行为相关神经环路的研究将在未来数年内迅速发展, 同时也将推动神经科学相关研究的进步。     

Afferent and efferent components of the facial nerve in a frog,Rana pipiens

Summary The seventh cranial nerve in Rana pipiens is a slender nerve with limited peripheral distribution. We investigated the afferent and efferent components of this nerve by labeling its major branch, the hyomandibular, with horseradish peroxidase. The efferent portion of the seventh nerve originates from a small cell group in the upper medulla which contains two subdivisions. Afferent fibers carried in nerve VII travel in the solitary tract and the dorsolateral funiculus. The solitary component consists of a small number of ascending fibers that reach the level of the trigeminal nucleus and a large descending component that terminates slightly caudal to the obex in the commissural nuclei of the solitary complex. Afferent fibers also descend in the dorsolateral funiculus; many of these fibers cross dorsal to the central canal in the lower medulla. Most of the fibers in the dorsolateral funiculus terminate in the ipsilateral and contralateral dorsal horns and in nuclei of the dorsal column. A few ipsilateral fibers reach lower thoracic levels of the spinal cord.     

Assessment of rates of deformity in wild frog populations using in situ cages: a case study of Leopard Frogs (Rana pipiens) in Ontario, Canada

High rates of deformity in wild amphibian populations from north-eastern North America have been increasingly reported since 1995. In the St Lawrence River basin (Canada) elevated frequencies of limb and eye deformities in mudpuppies (Necturus maculosus) and leopard frogs (Rana pipiens) were recorded in the early 1990s. A caging study was conducted during 1998 to verify the rates recorded in leopard frogs and pursue the potential causes of deformities seen in juveniles and adults. Week-old leopard frog tadpoles were collected from a reference wetland and maintained through to metamorphosis in cages in previously identified high risk wetlands. Deformity frequencies were measured and compared with frequencies measured in wild populations of leopard frogs inhabiting the same wetlands. The results of caging studies and sampling of wild populations were also compared with corresponding data collected from a reference wetland. No deformities were observed in caged or wild reference animals. Very low deformity frequencies (up to 2.2%) were observed in frogs caged in high risk wetlands, but greater frequencies (3.4-10%) were observed in wild young-of-the-year frogs captured at the same sites. The types of deformities were similar among groups; they included fused, missing or extra digits and disproportionate hindlimb length or eye pupil size. In addition, mortality rates were elevated in two cages in high risk wetlands. In general, the caging procedure was effective in establishing the potential for production of deformities in the waters of a given wetland, but tended to underestimate the rates calculated for samples of wild populations. The ramifications of the first-year findings for similar assessments of amphibian deformity rates and establishment of cause-effect linkages are discussed.     

The origin of somatostatin fibers in the median eminence and neural lobe of Rana temporaria

Summary A light microscopic immunocytochemical study of the brain of frogs with hypothalamic lesions was performed in order to obtain evidence concerning the origin of somatostatin fibers in the median eminence and neural lobe of the hypophysis. The results indicate that the somatostatin fibers of the neural lobe originate from somatostatin perikarya located in the prechiasmatic part of the hypothalamus and possibly also in the telencephalon. The somatostatin neurons of the pars ventralis tuberis cinerei do not send axons to the neural lobe. The frog median eminence contains axon terminals of somatostatin neurons located in the pars ventralis of the tuber cinereum. Many other somatostatin fibers of the frog median eminence originate from somatostatin neurons located outside the tuber cinereum. Most of these neurons probably lie in the preoptic hypothalamic region.This investigation was supported by a grant from the Belgian Nationaal Fonds voor Geneeskundig Wetenschappelijk Onderzoek     

Chloride conductance in amphibian skin: regulatory control in the skin of Rana pipiens

Chloride conductance across the isolated skin of Rana pipiens shows a voltage-activated component (G(Cl)(V)) which requires the presence of mucosal Cl. G(Cl)(V) is normally low or dormant. It is stimulated by elevated intracellular cAMP, irrespective whether originating from application of ss-adrenergic agonists (isoproterenol), stimulators of the adenylyl-cyclase (forskolin), inhibitors of the phosphodiesterases (isobutyl-methyl-xanthine) or membrane-permeable cAMP analogues (CPT-cAMP). Baseline G(Cl) under inactivating conditions increases also with cAMP dose-dependently. The data indicate that cAMP is a central regulator of the passive, conductive chloride transport across amphibian skin.     

The integration of locomotion and prey capture in vertebrates: Morphology, behavior, and performance

For most vertebrates, locomotion is a fundamental componentof prey capture. Despite this ubiquitous link, few studies havequantified the integration of these complex systems. Severalvariables related to locomotor performance, including maximumspeed, acceleration, deceleration, maneuverability, accuracy,and approach stability, likely influence feeding performancein vertebrates. The relative importance of these measures ofperformance, however, depends on the ecology of the predator.While factors such as morphology and physiology likely definethe limits of these variables, other factors such as motivationof the predator, prey type, and habitat structure can also influenceperformance. Understanding how these variables relate to feedingunder a given suite of ecological conditions is central to understandingpredator–prey interactions, and ultimately how locomotionand feeding have co-evolved. The goals of this article are todiscuss several variables of locomotor performance related toprey capture, present new data on the relationship between locomotorand feeding morphology in fishes, discuss the evolution of preycapture in cichlid fishes, and outline some future directionsfor research. While suction feeding is a primary mechanism ofprey capture in fishes, swimming is vital for accurately positioningthe mouth relative to the prey item. Many fishes decelerateduring prey capture using their body and fins, but the pectoralfins have a dominant role in maintaining approach stability.This suggests that fishes employing high-performance suctionfeeding (relatively small mouth) will have larger pectoral finsto facilitate accurate and stable feeding. I provide new dataon the relationship between pectoral fin morphology and maximumgape in centrarchid fishes. For seven species, pectoral finarea was significantly, and negatively, correlated with maximumgape. This example illustrates that the demands from one complexsystem (feeding) can influence another complex system (locomotion).Future studies that examine the morphological, physiological,and functional evolution of locomotion involved in prey captureby aquatic and terrestrial vertebrates will provide insightinto the origin and consequences of diversity.     

Characterization of γ-glutamyltranspeptidase in the liver of the frog: 2. Response to season,temperature and thyroid hormone in Rana pipiens

The impact of season and temperature on frog liver γ-glutamyltranspeptidase was assessed by measuring the activity of this enzyme in plasma membranes isolated from the livers of Rana pipiens obtained as summer and winter frogs; subjected to short-term (3 weeks) temperature acclimation; and subjected to multiple-temperature shifts. Plasma levels of T₃ were determined. γ-Glutamyltranspeptidase was found to be 2·2-fold higher in the summer frog relative to the winter frog; decreased by 44 percent in the summer frog by cold acclimation and increased by 1·7-fold in the winter frog by warm acclimation; and increased by 1·9-fold in the summer frog and 2·8-fold in the winter frog subjected to multiple-temperature shifts. Plasma T₃ levels were found to be 42-fold higher in the summer frog relative to the winter frog; decreased by 42 percent by cold acclimation and increased by 2·9-fold by warm acclimation; and decreased by 39 percent and 38 percent in the summer and winter frogs subjected to multiple temperature shifts. T₃ replacement during the last phase of the multiple-temperature shift protocol, restored the plasma T₃ levels to 75 percent of the control levels and prevented the increase evoked by the multiple-temperature shifts in γ-glutamyl-transpeptidase activity. Indeed, enzyme activity in the T₃ replaced state was 19 percent lower than in the control state. The involvement of thyroid hormone as a negative regulator of enzyme activity is discussed.     

Spontaneous oocyte maturation in Rana pipiens: Estrogen and follicle wall involvement

Immature (germinal vesicle stage) Rana pipiens oocytes typically remain arrested in prophase I of meiosis even after extended periods of in-vitro culture, if not stimulated with hormones. We have, however, sporadically observed “spontaneous” occurrences of oocyte maturation in vitro without the addition of hormones. This study documents some of our observations on this phenomenon and presents experimental results concerning the effects and possible involvement of estrogen and follicle wall components in regulating spontaneous oocyte maturation. Estrogen was found to inhibit spontaneous oocyte maturation (GVBD) in a dose-dependent fashion. Follicles in which spontaneous maturation was inhibited by estrogen retained their responsiveness (GVBD) to both frog pituitary homogenate (FPH) and progesterone stimulation. Inhibitory effects of estrogen on spontaneous maturation, however, were not reversed following incubation of washed follicles in plain culture medium without added hormones. Possible involvement of progesterone synthesis in spontaneous oocyte maturation was ascertained by simultaneously monitoring endogenous progesterone synthesis and the occurrence of spontaneous GVBD over the course of the maturation process. In spontaneous maturing follicle there was a gradual increase in basal levels of progesterone synthesis that preceded GVBD. Significantly, addition of estrogen abolished both the spontaneous progesterone production and spontaneous oocyte maturation. When FPH was added to follicles exhibiting spontaneous oocyte maturation, progesterone production was augmented and the time course of oocyte maturation was greatly accelerated. Involvement of ovarian components in the maturation process was investigated by selective removal of various follicle layers by microdissection. Removal of follicle epithelium and theca layer (defolliculation) markedly decreased spontaneous and FPH-induced maturation, whereas removal of the entire follicle wall (denudation) completely blocked it. Our results suggest that both spontaneous and FPH-induced maturation involve an estrogen sensitive process in the follicle wall. Thus, somatic follicle cells appear to serve as a common mediator for both types of maturation, which are linked by some intrafollicular mechanism involving steroidogenesis. Hence, estrogen may play an important role as an endogenous intrafollicular regulator of oocyte meiotic maturation.     

中国林蛙蝌蚪和大蟾蜍蝌蚪的最适温度、逃避温度及致死温度

报道了中国林蛙蝌蚪 (Ranachensinensis)和大蟾蜍蝌蚪 (Bufogargarizans)在不同驯化温度下的最适温度、逃避温度和致死温度的研究结果。将中国林蛙蝌蚪和大蟾蜍蝌蚪分别在 5、1 5和 2 5℃ 3个不同温度下驯养 3周 ,利用温度梯度装置观察记录 2种蝌蚪的最适温度、逃避温度和最高致死温度。结果表明 ,经过在 5、1 5和 2 5℃ 3个温度下的驯化 ,中国林蛙蝌蚪的最适温度范围分别为 1 3 . 5～ 1 8℃、2 0. 5～2 5℃和 2 3～ 2 7. 5℃ ;大蟾蜍蝌蚪的最适温度范围分别为 1 2～ 1 6 .5℃、2 1～ 2 5. 5℃和 2 2～ 2 6. 5℃。中国林蛙蝌蚪和大蟾蜍蝌蚪的最高致死温均在 3 7～ 3 8℃之间 ,最低致死温均为 0℃。驯化温度对最适温度影响显著 (P <0 .0 1 ) ,对致死温度则没有显著影响。驯化温度对中国林蛙蝌蚪和大蟾蜍蝌蚪的逃避温度产生的影响比最适温度的大。     

Predator versus prey: on aerial hunting and escape strategies in birds

Predator and prey attack-escape performance is likely to bethe outcome of an evolutionary arms race. Predatory birds aretypically larger than their prey, suggesting different flightperformances. We analyze three idealized attack-escape situationsbetween predatory and prey birds: climbing flight escape, horizontalspeeding, and turning and escape by diving. Generally a smallerbird will outclimb a larger predator and hence outclimbing shouldbe a common escape strategy. However, some predators such asthe Eleonora's falcon (Falco elenorae) has a very high rateof climb for its size. Prey species with an equal or highercapacity to climb fast, such as the swift Apus apus, usuallyadopt climbing escape when attacked by Eleonora's falcons.To analyze the outcome of the turning gambit between predatorand prey we use a Howland diagram, where the relative lineartop speeds and minimum turning radii of prey and predator definethe escape and danger zones. Applied to the Eleonora's falconand some potential prey species, this analysis indicates thatthe falcon usually wins against the example prey species; thatis, the prey will be captured. Level maneuvering hunting isthe most common strategy seen in Eleonora's falcons. To avoidcapture via use of this strategy by a predator, the prey shouldbe able to initiate tight turns at high linear speed, whichis facilitated by a low wing loading (weight per unit of wingarea). High diving speed is favored by large size. If close enough to safe cover, a prey might still opt for a verticaldive to escape in spite of lower terminal diving speed thanthat of the predator. On the basis of aerodynamic considerationswe discuss escape flight strategies in birds in relation tomorphological adaptations.     

Vulnerability of marine forage fishes to piscivory: effects of prey behavior on susceptibility to attack and capture

We conducted a series of size-structured laboratory experiments to quantify and compare the susceptibility of several estuarine and marine forage fishes to attack and capture by piscivorous predators. Size-dependent estimates of capture success, handling time, and prey profitability were generated from single-species experiments offering bay anchovy, Atlantic menhaden, Atlantic silverside, and age-0 striped bass to piscivores. Bay anchovy and Atlantic menhaden were most susceptible to capture and yielded high profitability compared to Atlantic silverside and age-0 striped bass prey. Variation in capture success among forage species was particularly influential in generating disparate profitability functions. Although morphological differences among forage species contributed to variation in susceptibility to predation, behavioral analyses indicated that variable reaction distances to approaching predators and activity levels of prey may explain a large fraction of the observed differences in susceptibility. When several forage species were offered to predators simultaneously in larger enclosures, mortality was highest and occurred earlier for bay anchovy and Atlantic menhaden compared to other prey, which points to the strong influence of predator capture success on overall forage fish vulnerability. Our results demonstrate species-specific differences among forage fishes in the ability to avoid attack and capture by piscivores, and we conclude that the expression of antipredator behaviors contributes significantly to variation in forage species vulnerability.     

Temperature and prey capture: opposite relationships in two predator taxa

Abstract 1. All other things equal, predator capture rates are expected to depend on encounter rate with prey, prey escape capability (including prey defences), and on predator agility. Ectotherm predators and their prey both respond to increasing temperature by increased activity, i.e. predators increase their search area and prey may enhance their escape capability. This means that, as temperature changes, the ability of a predator to catch prey will decrease, increase, or remain unchanged depending on the relative effect of temperature on predator and prey. Their responses may further be differentially moulded by light conditions depending on whether the predator is diurnally or nocturnally active. It was hypothesised that flying Diptera are vulnerable to carabid beetles only at low temperatures and over the full temperature range for spiders because carabids, in contrast to spiders, are not built to catch swiftly moving prey. 2. The first experiment examined the spontaneous locomotor activity of the predators and of fruit flies at different temperatures (5, 10, 15, 20, 25, and 30 °C) and light conditions (light, dark). A second experiment examined the effect of temperature and light on the predation rate of two carabid beetles (Pterostichus versicolor and Calathus fuscipes) and two spiders (Clubiona phragmitis and Pardosa prativaga) using fruit flies (Drosophila melanogaster) as prey. 3. All four predators and the fruit fly increased their locomotory activity at higher temperatures. Activity of the carabid beetles peaked at intermediate temperatures; spiders and fruit flies were most active at the highest temperatures. Predation rate of the spiders increased with temperature whereas the beetles caught flies only at low temperatures (5 and 10 °C). 4. Diurnal variation in temperature may bring different prey groups within the set of potential prey at different times of the day or at different seasons. The ability of many carabid beetles to forage at low temperatures may have nutritional benefits and increases the diversity of interactions in terrestrial food webs.     

Prey location,biomechanical constraints,and motor program choice during prey capture in the tomato frog, <Emphasis Type="Italic">Dyscophus guineti</Emphasis>

This study investigated how visual information about prey location and biomechanical constraints of the feeding apparatus influence the feeding behavior of the tomato frog, Dyscophus guineti. When feeding on prey at small azimuths (less than ± 40°), frogs aimed their heads toward the prey but did not aim their tongues relative to their heads. Frogs projected their tongues rapidly by transferring momentum from the lower jaw to the tongue. Storage and recovery of elastic energy by the mouth opening muscles amplified the velocities of mouth opening and tongue projection. This behavior can only occur when the lower jaw and tongue are aligned (i.e., within the range of motion of the neck). When feeding on prey at large azimuths (greater than ± 40°), frogs aimed both the head and tongue toward the prey and used a muscular hydrostatic mechanism to project the tongue. Hydrostatic elongation allows for frogs to capture prey at greater azimuthal locations. Because the tongue moves independently of the lower jaw, frogs can no longer take advantage of momentum transfer to amplify the speed of tongue projection. To feed on prey at different azimuthal locations, tomato frogs switch between alternative strategies to circumvent these biomechanical constraints.     

Acoustic startle/escape reactions in tethered flying locusts: motor patterns and wing kinematics underlying intentional steering

We simultaneously recorded flight muscle activity and wing kinematics in tethered, flying locusts to determine the relationship between asymmetric depressor muscle activation and the kinematics of the stroke reversal at the onset of wing depression during attempted intentional steering manoeuvres. High-frequency, pulsed sounds produced bilateral asymmetries in forewing direct depressor muscles (M97, 98, 99) that were positively correlated with asymmetric forewing depression and asymmetries in stroke reversal timing. Bilateral asymmetries in hindwing depressor muscles (M127 and M128 but not M129) were positively correlated with asymmetric hindwing depression and asymmetries in the timing of the hindwing stroke reversal; M129 was negatively correlated with these shifts. Hindwing depressor asymmetries and wing kinematic changes were smaller and shifted in opposite direction than corresponding measurements of the forewings. These findings suggest that intentional steering manoeuvres employ bulk shifts in depressor muscle timing that affect the timing of the stroke reversals thereby establishing asymmetric wing depression. Finally, we found indications that locusts may actively control the timing of forewing rotation and speculate this may be a mechanism for generating steering torques. These effects would act in concert with forces generated by asymmetric wing depression and angle of attack to establish rapid changes in direction.Abbreviations ASR acoustic startle response - dB SPL decibel sound pressure level (re: 20 Pa RMS) - EMG electromyogram - FWA forewing asymmetry - HWA hindwing asymmetry