Light and electron microscopic studies on the Y organ of the freshwater crab Travancoriana schirnerae

Characterization of the molecular, cellular, and behavioral changes caused by exposure to a saline-alkali environment in the Chinese mitten crab, Eriocheir sinensis

In the context of global warming, the accelerated evaporation of seawater will lead to a continuous expansion of saline-alkali land area. As an important economic freshwater crustacean, investigation on the mechanism of damage to Eriocheir sinensis (E. sinensis) under saline-alkali environment will provide a valuable precedent for understanding the detrimental effect of climate change on crustaceans. In this study, histopathological analysis and integrative omics analysis were employed to explore the injury mechanism on the cerebral nervous system of E. sinensis exposure to saline-alkali stress. Our findings revealed that under this stress E. sinensis exhibited behavioral disorders and damage to cerebral neurosecretory cells and key organelles. Additionally, several pathways related to detoxification metabolism, neurotransmitter synthesis, and antioxidant defense were significantly down-regulated. Collectively, these results show, for the first time, that saline-alkali stress can induce neurodegenerative disease-like symptoms in E. sinensis, and provide critical information for understanding the harmful effects of saline-alkali environments.

Alkali exposure induces autophagy through activation of the MAPKpathway by ROS and inhibition of mTOR in Eriocheir sinensis

Saline-alkali water is widely distributed around the world, and salinization of water ecosystems has occurred in some areas of the world, comprising approximately one-third of the total land area, which has drawn much attention to the conservation of water ecosystems and aquatic animals. However, due to the complex composition of saline-alkaline water, many aquatic animals are unable to survive, which greatly limits the development and utilization of saline-alkaline waters. Carbonate alkalinity is an important stress factor for aquatic animals in saline-alkaline water. Exposure to highly alkaline carbonate can induce oxidative stress. For this study, we used Eriocheir sinensis as a model organism to evaluate the effects of alkaline stress on oxidative stress and autophagy. The trial was divided into five alkali level treatment groups (control, 4.375 mmol/L, 8.75 mmol/L, 17.5 mmol/L, and 35 mmol/L, respectively), and liver tissues were assessed by antioxidant enzyme kits, real-time quantitative PCR assays and ultrastructural observations at 3 time points (24 h, 48 h, 96 h). Compared with the control group, the activities of antioxidant enzymes (superoxide dismutase (SOD), glutathione reductase (GSH), glutathione peroxidase (GSH-PX) and total antioxidant capacity (T-AOC)) in the alkali stress group increased and then decreased with increasing time, while the content of malondialdehyde (MDA) increased. At the molecular level, the expression of MAPK pathway-related genes (P38, MAPK, JNK) in the alkaline stress group showed a dose-dependent increase at 48 and 96 h and was significantly higher than that in the control group. The expression of autophagy-related genes (ATG5, ATG12, ATG7 and GABARAP) increased dose-dependently at 24, 48, and 96 h and was significantly higher than that in the control group. In contrast, mTOR expression was always in a suppressed state. These results suggest that alkaline stress induces activation of the MAPK pathway via ROS and inhibits mTOR expression, thereby inducing autophagy in the liver tissue of Eriocheir sinensis. This study investigated the stress mechanism of carbonate on Eriocheir sinensis and provided a theoretical basis for the continued exploitation of saline-alkaline water aquaculture.

De novo transcriptome assembly and functional annotation for Y-organs of the blue crab (Callinectes sapidus), and analysis of differentially expressed genes during pre-molt

Blue crabs (Callinectes sapidus) undergo incremental growth involving the shedding (molting) of the old exoskeleton, and subsequent expansion and re-calcification of the newly synthesized one. The cellular events that lead to molting are triggered by steroid hormones termed ecdysteroids released from Y-organs, paired endocrine glands located in the anterior cephalothorax. The regulatory pathways leading to increased synthesis and release of ecdysteroids are not fully understood, and no transcriptome has yet been published for blue crab Y-organs. Here we report de novo transcriptome assembly and annotation for adult blue crab Y-organs, and differential gene expression (DGE) analysis between Y-organs of intermolt and premolt crabs. After trimming and quality assessment, a total of 91,819,458 reads from four cDNA libraries were assembled using Trinity to form the reference transcriptome. Trinity produced a total of 171,530 contigs coding for 150,388 predicted genes with an average contig length of 613 and an N50 of 940. Of these, TransDecoder predicted 31,661 open reading frames (ORFs), and 10,210 produced non-redundant blastx results through Trinotate annotation. Genes involved in multiple cell signaling pathways, including Ca²⁺ signaling, cGMP signaling, cAMP signaling, and mTOR signaling were present in the annotated reference transcriptome. DGE analysis showed in premolt Y-organs up-regulated genes involved in energy production, cholesterol metabolism, and exocytosis. The results provide insights into the transcriptome of blue crab Y-organs during a natural (rather than experimentally induced) molting cycle, and constitute a step forward in understanding the cellular mechanisms that underlie stage-specific changes in the synthesis and secretion of ecdysteroids by Y-organs.

Hormonal control of the crustacean molting gland: Insights from transcriptomics and proteomics

Endocrine control of molting in decapod crustaceans involves the eyestalk neurosecretory center (X-organ/sinus gland complex), regenerating limbs, and a pair of Y-organs (YOs), as molting is induced by eyestalk ablation or multiple leg autotomy and suspended in early premolt by limb bud autotomy. Molt-inhibiting hormone (MIH) and crustacean hyperglycemic hormone (CHH), produced in the X-organ/sinus gland complex, inhibit the YO. The YO transitions through four physiological states over the molt cycle: basal in intermolt; activated in early premolt; committed in mid- and late premolt; and repressed in postmolt. We assembled the first comprehensive YO transcriptome over the molt cycle in the land crab, Gecarcinus lateralis, showing that as many as 23 signaling pathways may interact in controlling ecdysteroidogenesis. A proposed model of the MIH/cyclic nucleotide pathway, which maintains the basal YO, consists of cAMP/Ca²⁺ triggering and nitric oxide (NO)/cGMP summation phases. Mechanistic target of rapamycin (mTOR) signaling is required for YO activation in early premolt and affects the mRNA levels of thousands of genes. Transforming Growth Factor-β (TGFβ)/Activin signaling is required for YO commitment in mid-premolt and high ecdysteroid titers at the end of premolt may trigger YO repression. The G. lateralis YO expresses 99 G protein-coupled receptors, three of which are putative receptors for MIH/CHH. Proteomic analysis shows the importance of radical oxygen species scavenging, cytoskeleton, vesicular secretion, immune response, and protein homeostasis and turnover proteins associated with YO function over the molt cycle. In addition to eyestalk ganglia, MIH mRNA and protein are present in brain, optic nerve, ventral nerve cord, and thoracic ganglion, suggesting that they are secondary sources of MIH. Down-regulation of mTOR signaling genes, in particular Ras homolog enriched in brain or Rheb, compensates for the effects of elevated temperature in the YO, heart, and eyestalk ganglia in juvenile Metacarcinus magister. Rheb expression increases in the activated and committed YO. These data suggest that mTOR plays a central role in mediating molt regulation by physiological and environmental factors.

The light-oxygen effect in biological cells enhanced by highly localized surface plasmon-polaritons

Here at the first time we suggested that the surface plasmon-polariton phenomenon which it is well described in metallic nanostructures could also be used for explanation of the unexpectedly strong oxidative effects of the low-intensity laser irradiation in living matters (cells, tissues, organism). We demonstrated that the narrow-band laser emitting at 1265 nm could generate significant amount of the reactive oxygen species (ROS) in both HCT116 and CHO-K1 cell cultures. Such cellular ROS effects could be explained through the generation of highly localized plasmon-polaritons on the surface of mitochondrial crista. Our experimental conditions, the low-intensity irradiation, the narrow spectrum band (<4 nm) of the laser and comparably small size bio-structures (~10 μm) were shown to be sufficient for the plasmon-polariton generation and strong laser field confinement enabling the oxidative stress observed.