Microcystin-leucine arginine exposure induced intestinal lipid accumulation and MC-LR efflux disorder in Lithobates catesbeianus tadpoles.

Few studies exist on the toxic effects of chronic exposure to microcystins (MCs) on amphibian intestines, and the toxicity mechanisms are unclear. Here, we evaluated the impact of subchronic exposure (30 days) to environmentally realistic microcystin-leucine arginine (MC-LR) concentrations (0 µg/L, 0.5 µg/L and 2 µg/L) on tadpole (Lithobates catesbeianus) intestines by analyzing the histopathological and subcellular microstructural damage, the antioxidative and oxidative enzyme activities, and the transcriptome levels. Histopathological results showed severe damage accompanied by inflammation to the intestinal tissues as the MC-LR exposure concentration increased from 0.5 µg/L to 2 µg/L. RNA-sequencing analysis identified 634 and 1,147 differentially expressed genes (DEGs) after exposure to 0.5 µg/L and 2 µg/L MC-LR, respectively, compared with those of the control group (0 µg/L). Biosynthesis of unsaturated fatty acids and the peroxisome proliferator-activated receptor (PPAR) signaling pathway were upregulated in the intestinal tissues of the exposed groups, with many lipid droplets being observed on transmission electron microscopy, implying that MC-LR may induce lipid accumulation in frog intestines. Moreover, 2 µg/L of MC-LR exposure inhibited the xenobiotic and toxicant biodegradation related to detoxification, implying that the tadpoles' intestinal detoxification ability was weakened after exposure to 2 µg/L MC-LR, which may aggravate intestinal toxicity. Lipid accumulation and toxin efflux disorder may be caused by MC-LR-induced endoplasmic reticular stress. This study presents new evidence that MC-LR harms amphibians by impairing intestinal lipid metabolism and toxin efflux, providing a theoretical basis for evaluating the health risks of MC-LR to amphibians.

Harmful Algal Bloom Toxicity in Lithobates catesbeiana Tadpoles.

Harmful algal blooms (HAB) have become a major health concern worldwide, not just to humans that consume and recreate on contaminated waters, but also to the fauna that inhabit the environments surrounding affected areas. HABs contain heterotrophic bacteria, cyanobacterial lipopolysaccharide, and cyanobacterial toxins such as microcystins, that can cause severe toxicity in many aquatic species as well as bioaccumulation within various organs. Thus, the possibility of trophic transference of this toxin through the food chain has potentially important health implications for other organisms in the related food web. While some species have developed adaptions to attenuate the toxic effects of HAB toxins, there are still numerous species that remain vulnerable, including Lithobates catesbeiana (American bullfrog) tadpoles. In the current study we demonstrate that acute, short-term exposure of tadpoles to HAB toxins containing 1 µg/L (1 nmol/L) of total microcystins for only 7 days results in significant liver and intestinal toxicity within tadpoles. Exposed tadpoles had increased intestinal diameter, decreased intestinal fold heights, and a constant number of intestinal folds, indicating pathological intestinal distension, similar to what is seen in various disease processes, such as toxic megacolon. HAB-toxin-exposed tadpoles also demonstrated hepatocyte hypertrophy with increased hepatocyte binucleation consistent with carcinogenic and oxidative processes within the liver. Both livers and intestines of HAB-toxin-exposed tadpoles demonstrated significant increases in protein carbonylation consistent with oxidative stress and damage. These findings demonstrate that short-term exposure to HAB toxins, including microcystins, can have significant adverse effects in amphibian populations. This acute, short-term toxicity highlights the need to evaluate the influence HAB toxins may have on other vulnerable species within the food web and how those may ultimately also impact human health.

Estudio morfológico, morfométrico e histoquímico de los epitelios de revestimiento y glandular de la lengua de la rana toro, rana catesbeiana / Morphological, morphometrical and histochemical study of the lining and glandular epithelia of the tongue of the tullfrog rana catesbeiana

La superficie dorsal de la lengua de la rana toro, Rana catesbeiana, presenta un epitelio simple cilíndrico, constituido por células caliciformes y raras células ciliadas. El dorso de la lengua posee numerosas papilas filiformes y algunas fungiformes. Las primeras poseen un epitelio simple cilíndrico, con células secretoras, mientras que las segundas poseen en la región apical, un disco sensorial con epitelio estratificado cilíndrico, con células basales, periféricas, glandulares y receptoras. A lo largo del dorso de la lengua existen numerosas glándulas tubulares, que penetran en profundidad, entremezclándose con las fibras musculares. El epitelio glandular es simple cilíndrico, con células secretoras y de sostén. Las primeras son las únicas en la base de la glándula y las segundas solo se encuentran en número escaso en el tercio superior. La superficie ventral de la lengua posee un epitelio estratificado, con células caliciformes y, entre éstas, células ciliadas. La morfometría de las glándulas mostró que son más cortas en la región anterior de la lengua (330 um) que en la región posterior (450 um). Las células secretoras de las glándulas linguales anteriores son menores (1457,7 um3) que en las posteriores (2645,9 um3). Lo mismo ocurre con los núcleos celulares: 130,0 um3 en las glándulas anteriores y 202,3 um3 en las posteriores. Las células secretoras de las glándulas linguales sintetizan producto rico en proteínas y mucopolisacáridos neutros, pudiendo caracterizarse como seromucoso. Las células caliciformes de las superficies dorsal y ventral secretan proteínas y mucopolisacáridos neutros, clasificándose como del tipo G1, mientras que las células de sostén de las glándulas superficiales de las papilas fungiformes secretan moco rico en mucopolisacáridos neutros, sulfomucinas y sialomucinas.

The dorsal surface of the tongue of the bullfrog, Rana catesbeiana, has simple columnar epithelium with a few ciliated cells and goblet cells. The entire surface is covered with numerous filiform papillae and few fungiform. Filiform papillae have a simple columnar epithelium with secretory cells, while the fungiform have a sensory disc on their upper surface the lined by a stratified columnar epithelium with basal, peripheral, glandular and receptor cells. Over the dorsal lingual surface there are numerous winding tubular glands, which penetrate deeply into the muscle of the tongue, mingling with the fibers. The gland epithelium is cylindrical with secretory and supporting cells. The first are absolute on the basis of the gland and the latter are rare in the upper third. The ventral surface of the tongue is lined by a stratified epithelium, with the presence of goblet cells, with ciliated cells among them. Morphometrically, lingual glands varies in length, according to their location: shorter in the anterior region of the tongue (330 um) than in the posterior region (450 um). Secretory cells of the anterior lingual glands are smaller (1457.7 mm3) than the posterior ones (2645.9 um3). The same can be said of the cell nuclei, 130.0 um3 for the anterior glands and 202.3 um3 for the posterior ones. Secretory cells of the lingual glands contain substances rich in protein and neutral mucopolysaccharides, which characterize the seromucous type. Goblet cells of the dorsal and ventral surface epithelia secrete neutral mucopolysaccharides and proteins, and can be characterized as type G1 cells, and the supporting cells of the superficial glands of the fungiform papillae secrete a mucus rich in neutral mucopolysaccharides, sulfomucins and sialomucins.

C-fin: a cultured frog tadpole tail fin biopsy approach for detection of thyroid hormone-disrupting chemicals.

There is a need for the development of a rapid method for identifying chemicals that disrupt thyroid hormone (TH) action while maintaining complex tissue structure and biological variation. Moreover, no assay to date allows a simultaneous screen of an individual's response to multiple chemicals. A cultured tail fin biopsy or C-fin assay was developed using Rana catesbeiana tadpoles. Multiple tail fin biopsies were taken per tadpole, cultured in serum-free medium, and then each biopsy was exposed to a different treatment condition. The effects of known disruptors of TH action were evaluated in the C-fin assay. Chemical exposure was performed +/- 10 nM 3,3',5-triiodothyronine and real-time quantitative polymerase chain reaction (QPCR) of two TH-responsive transcripts, TH receptor beta (TRbeta) and the Rana larval keratin type I (RLKI), was performed. Within 48 h of exposure to Triac (1-100 nM), roscovitine (0.6-60 microM), or genistein (1-100 microM), perturbations in TH signaling were detected. Tetrabromobisphenol A (TBBPA) (10-1,000 nM) showed no effect. Acetochlor (1-100 nM) elicited a modest effect on the TH-dependent induction of TRbeta transcript. These data reveal that a direct tissue effect may not be critical for TBBPA and acetochlor to disrupt TH action previously observed in intact tadpoles.

Cloning of a thyroid hormone-responsive Rana catesbeiana c-erbA-beta gene.

Two types of thyroid hormone receptor (c-erbA) gene have been identified in mammals and in lower species including chickens and the amphibian Xenopus laevis. The two genes are located on different chromosomes and have been named TR alpha and TR beta. We have described previously the cloning of a TR alpha cDNA from Rana catesbeiana (RC) tissues (RC15) and we now report the cloning of a TR beta cDNA from this species. The cloning strategy employed utilized the polymerase chain reaction (PCR), with primers based on the sequences of the X. laevis TR beta cDNA (XenTR beta) and an RCTR beta genomic clone, which, by analogy with XenTR beta, contains some of the 3' end of the open reading frame together with 3'-untranslated sequences. At the nucleotide and amino acid levels, respectively, the cloned RCTR beta cDNA is 90% and 98% homologous with XenTR beta, and 72% and 76% homologous with RC15. Following in vitro transcription and translation, the cDNA was shown to encode a 48 kilodalton protein which binds 3,5,3'-triiodothyronine (T3) with high affinity (mean Kd: 0.032 nM). Samples of total or poly(A) +RNA from tadpoles at different stages of metamorphosis and from adult frogs were analyzed for the presence of TR beta-specific transcripts by slot blot analysis using as probe a 258 bp section of the RCTR beta cDNA. This section of the cDNA does not hybridize to the corresponding section of RC15. In confirmation of previous findings, beta-specific transcripts were not detected in RNA from tadpole red blood cells (RBCs) and none was found in RBCs from adult frogs.(ABSTRACT TRUNCATED AT 250 WORDS)