A two-barrier compartment model for volume flow across amphibian skin

The amphibian skin has long been used as a model tissue for the study of ion transport and osmotic water movement across tight epithelia. To understand the mechanism of water uptake across amphibian skin, we model the skin as a well-stirred compartment bounded by an apical barrier and a tissue barrier. The compartment represents the lateral intercellular space between cells in the stratum granulosum. The apical barrier represents the stratum corneum, the principal/mitochondria-rich cells, and the junctional area between cells. This barrier is hypothesized to have the ability to actively transport solutes through Na+-K+-ATPase. The actively transported solute flux is assumed to satisfy the Michaelis-Menten relationship. The tissue barrier represents a composite barrier comprising the stratum spinosum, the stratum germinativum, the basal lamina, and the dermis. Our model shows that 1) the predicted rehydration rates from apical bathing solutions are in good agreement with the experiment results in Hillyard and Larsen (J Comp Physiol 171: 283-292, 2001); 2) under their experimental conditions, there is a substantial volume flux coupled to the active solute flux and this coupled volume flux is nearly constant when the osmolality of the apical bathing solution is >100 mosmol/kgH2O; 3) the molar ratio of the actively transported solute flux to the coupled water flux is about 1:160, which is the same as that reported in Nielsen (J Membr Biol 159: 61-69, 1997).     

The route of passive chloride movement across amphibian skin: localization and regulatory mechanisms

Transepithelial Cl(-) conductance (G(Cl)) in amphibian skin can be activated in several species by serosa positive potentials. Mitochondria-rich cells (MRC) or tight junctions (TJ) between the epithelial cells are possible sites for this pathway. The properties and the techniques used to investigate this pathway are reviewed in the present paper. In situ techniques are preferable, since specific properties of the MRC are apparently not maintained in isolated cells. Volume measurements and electronprobe microanalysis of intracellular ions suggest the localization of voltage-activated G(Cl) to MRC. G(Cl) correlates poorly with the density of MRC. The vibrating voltage probe allows quantitative correlation of the local Cl(-) current through morphologically identified structures and the transepithelial Cl(-) current. Our analysis shows that 80% of the voltage-activated Cl(-) current is accounted for by current through MRC or their immediate vicinity. The activation patterns of this current and the inhibition by the alpha(1)-adrenergic agonist, epinephrine, conform to those of the transepithelial current. However, less than 20% of the MRC are active at a certain moment and the activity is spontaneously variable with time. The molecular nature of this pathway, physiological control mechanisms and their relation to the temporal activity of MRC remain to be studied.     

Conductive chloride flux across amphibian skin: inhibition by indacrinone and cobalt ion.

When amphibian skin was incubated under conditions in which transepithelial sodium transport was abolished, a conductive transepithelial Cl- flux arose when Cl- was removed from one of the compartments. This flux was matched by short-circuit current and it accounted entirely for transepithelial conductance. Cl- influx was larger than efflux; it was linearly related to the magnitude of transepithelial Cl- concentration difference. When applied to the epithelial surface of the tissue, divalent metal cations such as Co2+, and the ethacrynic acid derivative, indacrinone, reduced rapidly and reversibly both transepithelial Cl- (in)flux and short-circuit current. Frog skin proved to be more sensitive to these inhibitors than toad skin. Further characterization of transepithelial Cl- pathway(s) should benefit from the fact that Cl- across amphibian skin can easily be monitored by the short-circuit current method, and from the availability of agents which inhibit this passive flux rapidly and reversibly.     

Pulsatile blood flow and gas exchange across a cylindrical fiber array

The pulsatile blood flow and gas transport of oxygen and carbon dioxide through a cylindrical array of microfibers are numerically simulated. Blood is modeled as a homogeneous Casson fluid, and hemoglobin molecules in blood are assumed to be in local equilibrium with oxygen and carbon dioxide. It is shown that flow pulsatility enhances gas transport and the amount of gas exchange is sensitive to the blood flow field across the fibers. The steady Sherwood number dependence on Reynolds number was shown to have a linear relation consistent with experimental findings. For most cases, an enhancement in gas transport is accompanied with an increase in flow resistance. Maximum local shear stress is provided as a possible indicator of thrombosis, and the computed shear stress is shown to be below the threshold value for thrombosis formation for all cases evaluated.     

Antimicrobial Peptide defenses in amphibian skin

One of the most urgent problems in conservation biology todayis the continuing loss of amphibian populations on a globalscale. Recent amphibian population declines in Australia, CentralAmerica, the western United States, Europe, and Africa havebeen linked to a pathogenic chytrid fungus, Batrachochytriumdendrobatidis, which infects the skin. The skin of amphibiansis critical for fluid balance, respiration, and transport ofessential ions; and the immune defense of the skin must be integratedwith these physiological responses. One of the natural defensesof the skin is production of antimicrobial peptides in granularglands. Discharge of the granular glands is initiated by stimulationof sympathetic nerves. To determine whether antimicrobial skinpeptides play a role in protection from invasive pathogens,purified antimicrobial peptides and natural peptide mixturesrecovered from the skin secretions of a number of species havebeen assayed for growth inhibition of the chytrid fungus. Thegeneral findings are that most species tested have one or moreantimicrobial peptides with potent activity against the chytridfungus, and natural mixtures of peptides are also effectiveinhibitors of chytrid growth. This supports the hypothesis thatantimicrobial peptides produced in the skin are an importantdefense against skin pathogens and may affect survival of populations.We also report on initial studies of peptide depletion usingnorepinephrine and the kinetics of peptide recovery followinginduction. Approximately 80 nmoles/g of norepinephrine is requiredto deplete peptides, and peptide stores are not fully recoveredat three weeks following this treatment. Because many specieshave defensive peptides and yet suffer chytrid-associated populationdeclines, it is likely that other factors (temperature, conditionsof hydration, "stress," or pesticides) may alter normal defensesand allow for uncontrolled infection.     

Aldosterone and chloride conductance of amphibian skin

Chloride influx (JCl) across the skin of toads maintained in dilute MgCl2 or Na2SO4 was determined after overnight incubation with(out) aldosterone, and related to mitochondria-rich cell (MRC) density of the preparations. Adaptation to MgCl2 vs. Na2SO4 was reflected by higher plasma aldosterone in the former group (17 vs. 3 nmol/l, respectively) while JCl was lower, even after overnight incubation (172 vs. 318 pmol cm-2 s-1). Incubation with aldosterone induced a more pronounced increase in JCl in the case of Na2SO4- vs. MgCl2-adapted toads (delta JCl: 242 vs. 25 pmol cm-2 s-1, respectively), which could be related to difference in MRC density between these two groups (1078 vs. 615 cells/mm2, respectively). On the other hand, the in vitro effect of aldosterone on Na+ transport (assessed by Isc) was equally pronounced in both groups, and thus independent of MRC density. These data suggest that aldosterone, rather than being involved in MRC proliferation, stimulates Cl- conductance by influencing the functional state of MRC.     

HV-BBI--a novel amphibian skin Bowman-Birk-like trypsin inhibitor

Here we describe the isolation of a novel C-terminally amidated octadecapeptide—SVIGCWTKSIPPRPCFVK-amide—that contains a disulphide loop between Cys⁵ and Cys¹⁵ that is consistent with a Bowman-Birk type protease inhibitor, from the skin secretion of the Chinese Bamboo odorous frog, Huia versabilis. Named HV-BBI, the peptide is encoded by a single precursor of 62 amino acid residues whose primary structure was deduced from cloned skin cDNA. The precursor exhibits the typical organization of that encoding an amphibian skin peptide with a highly-conserved signal peptide, an intervening acidic amino acid residue-rich domain and a single HV-BBI-encoding domain located towards the C-terminus. A synthetic replicate of HV-BBI, with the wild-type K (Lys-8) residue in the presumed P1 position, was found to be a potent inhibitor of trypsin with a K_i just slightly less than 19 nM. Substitution at this site with R (Arg) resulted in a significant reduction in potency (K_i 57 nM), whereas replacement of K with F (Phe) resulted in the complete abolition of trypsin inhibitory activity. Thus, HV-BBI is a potent inhibitor of trypsin and the lysyl (K) residue that occupies the P1 position appears to be optimal for potency of action against this protease.     

Growth and leaf gas exchange in Populus euphratica across soil water and salinity gradients

Soil water and salinity conditions of the riparian zones along the Tarim River, northwest China, have been undergoing alterations due to water use by human or climate change, which is expected to influence the riparian forest dominated by an old poplar, Populus euphratica. To evaluate the effects of such habitat alterations, we examined photosynthetic and growth performances of P. euphratica seedlings across experimental soil water and salinity gradients. Results indicated that seedlings were limited in their physiological performance, as evidenced by decreases in their height and biomass, and the maximal quantum yield of photosystem II (PSII) photochemistry (F_v/F_m), the effective quantum-use efficiency of PSII (F_v′/F_m′), and photochemical quenching (q_P) under mild (18% soil water content, SWC; 18.3 g kg^?1 soil salt content, SSC) and moderate (13% SWC, 22.5 g kg^?1 SSC) water or salinity stress. However, seedlings had higher root/shoot ratio (R/S), increased nonphotochemical quenching (NPQ), and water-use efficiency (WUE) relative to control under such conditions. Under severe (8% SWC, 27.9 g kg^?1 SSC) water or salinity stress, P. euphratica seedlings had only a fifth of biomass of those under control conditions. It was also associated with damaged PSII and decreases in WUE, the maximal net photosynthetic rate (P _Nmax), light-saturation point (LSP), and apparent quantum yield (_α). Our results suggested that the soil conditions, where P.euphratica seedlings could grow normally, were higher than ～ 13% for SWC, and lower than ～22.5 g kg^?1 for SSC, the values, within the seedlings could acclimate to water or salinity stress by adjusting their R/S ratio, improving WUE to limit water loss, and rising NPQ to dissipate excessive excitation energy. Once SWC was lower than 8% or SCC higher than ～28 g kg^?1, the seedlings suffered from the severe stress.     

Quantitative measurement of Batrachochytrium dendrobatidis in amphibian skin

The ability to quantify infections provides a tool with which to perform comparative pathological research. The need exists for a simplistic standard method to compare infection levels of Batrachochytrium dendrobatidis, a major cause of global amphibian declines. Through examination of skin sloughs of the Cape river frog Afrana fuscigula, we present an accessible method that not only provides quantitative measurements of B. dendrobatidis, but also provides information that increases the confidence of detection through histological surveys. The method relies on the availability of live animals that are actively shedding skin. By employing a direct microscopic count of sporangia, it is possible to express infection in terms of density. Micro-spatial infection in the skin of A. fuscigula is characterised by significant differences in sporangium density among the different components of the foot, and by similar differences in site infection frequency. Notably, toe tips and tubercles contain higher infection densities and are more often infected than webbing or the base of the foot. This pattern of infection might facilitate disease transmission due to the increased exposure of these components to abrasion. Density data can be used with the Poisson frequency function to approximate binomial probabilities of detecting B. dendrobatidis through histology. The probability matrix produced for A. fuscigula indicated that foot-site selection for histology markedly influenced the number of sections required to detect B. dendrobatidis at a specific level of probability. Thus, examination of a test sample of skin tissue with direct-count quantification can help in planning the sampling of tissues for histological surveys.     

Competition during innervation of embryonic amphibian head skin

We have examined the initial innervation of the head skin in Xenopus laevis embryos which is by two classes of trigeminal mechanoreceptor with beaded 'free' nerve-endings. By recording receptive areas electrophysiologically and staining peripheral sensory neurites with horseradish peroxidase, we have shown that 'movement detector' neurites from one trigeminal ganglion do not normally cross the dorsal midline of the head to innervate areas of skin on the opposite side. However, if one trigeminal ganglion is removed before peripheral innervation starts, movement detector neurites from the intact side will now cross the midline to innervate contralateral skin. These observations suggest a specific competitive interaction between movement detector neurites during their innervation of head skin. The second class of receptor, 'rapid transient' detectors, have a different pattern of innervation, crossing the midline in both normal and operated animals.     

Active proton and urea transport by amphibian skin

Proton secretion in frog skin is mediated by an electrogenic H+ pump. Pharmacological and immunocytological approaches have identified this pump as belonging to the V-ATPase class. The key role of this V-ATPase in proton secretion (acid-base balance) and as a membrane energizer of other solute transport from very dilute solutions is outlined. It is shown that the frog skin constitutes a model of a V-ATPase-dependent Na+ transport mechanism applicable to other freshwater animals. On the other hand, attempts to implicate the V-ATPase in the active urea transport that develops through the skin of salt-adapted frogs have failed; the nature of the different urea transporters located on apical and basal epithelial cell membranes and those responsible for active urea reabsorption remain to be identified.     

Breath-by-breath alveolar gas exchange

A method is described for breath-by-breath measurement of alveolar gas exchange corrected for changes of lung gas stores. In practice, the subject inspires from a spirometer, and each expired tidal volume is collected into a rubber bag placed inside a rigid box connected to the same spirometer. During the inspiration following any given expiration the bag is emptied by a vacuum pump. A computer monitors inspiratory and expiratory tidal volumes, drives four solenoid valves allowing appropriate operation of the system, and memorizes end-tidal gas fractions as well as mixed expired gas composition analyzed by mass spectrometer. Thus all variables for calculating alveolar gas exchange, based on the theory developed by Auchincloss et al. (J. Appl. Physiol. 21: 810-818, 1966), are obtained on a single-breath basis. Mean resting and steady-state exercise gas exchange data are equal to those obtained by conventional open-circuit measurements. Breathing rates up to 30 X min-1 can be followed. The breath-to-breath variability of O2 uptake at the alveolar level is less (25-35%) than that measured at the mouth as the difference between the inspired and expired volumes, both at rest and during exercise up to 0.7 of maximum O2 consumption.     

Antimicrobial peptides from amphibian skin: an expanding scenario

Many organisms employ antimicrobial peptides to fend off microbial pathogens. Amphibian skin is one of the most generous sources of these peptides. In the past couple of years, intriguing additional insights on various aspects of frog skin peptides have been reported. Several novel molecules, often with unprecedented structural features, have been discovered. Studies focusing on the factors that regulate the in vivo synthesis of skin peptides in response to infection have gained in prominence. Moreover, recent results indicate new possibilities for the development of effective human therapeutics based on antimicrobial peptides and partially disclosed the biotechnological potential of these molecules.     

Aldosterone upregulates purinergic responses in larval amphibian skin epithelium

Bullfrog tadpoles respond to apical application of 100 microM amiloride, acetylcholine (ACh) or ATP with a sharp transient inward (apical to basolateral) cation current. In adult skin, amiloride blockable transepithelial Na+ transport is upregulated by the hormone aldosterone. Tadpoles were treated in vivo with aldosterone and changes in short circuit current (Isc) in response to apical application of ATP were determined. Bullfrog tadpoles were exposed to aldosterone (10(-6) M) for periods ranging from 3 h to 60 h. Skins from 60-h aldosterone-treated animals showed a two- to three-fold increase in apical ATP-activated short circuit current when compared to animals treated with vehicle alone. Sodium replacement with a large, nonpermeable cation resulted in no measurable increase in Isc after exposure to ligand, consistent with ATP activation of an inward cation current and not chloride efflux. Activation/desensitization time courses and treatment with blockers revealed no measurable differences between aldosterone-treated and non-treated skins. Activation by amiloride and ACh gave essentially identical results. Studies with RT/PCR showed significant increases over controls of levels of mRNA associated with P2X channels. Given these data, our working hypothesis is that all three ligands activate the same process that exhibits both purinergic and cholinergic characteristics. These data are consistent with aldosterone upregulation of ATP gated channels expressed in the apical membrane of larval frog skin.     

Respiratory and cuticular water loss in insects with continuous gas exchange: comparison across five ant species

Respiratory water loss (RWL) in insects showing continuous emission of CO(2) is poorly studied because few methodologies can measure it. Comparisons of RWL between insects showing continuous and discontinuous gas exchange cycles (DGC) are therefore difficult. We used two recently developed methodologies (the hyperoxic switch and correlation between water-loss and CO(2) emission rates) to compare cuticular permeabilities and rates of RWL in five species of ants, the Argentine ant (Linepithema humile) and four common native ant competitors. Our results showed that RWL in groups of ants with moderate levels of activity and continuous gas exchange were similar across the two measurement methods, and were similar to published values on insects showing the DGC. Furthermore, ants exposed to anoxia increased their total water loss rates by 50-150%. These results suggest that spiracular control under continuous gas exchange can be as effective as the DGC in reducing RWL. Finally, the mesic-adapted Argentine ant showed significantly higher rates of water loss and cuticular permeability compared to four ant species native to dry environments. Physiological limitations may therefore be responsible for restricting the distribution of this invasive species in seasonally dry environments.