Identification of a novel dehydration responsive gene, drp10, from the African clawed frog, Xenopus laevis

Regulation of the unfolded protein response during dehydration stress in African clawed frogs, Xenopus laevis

The unfolded protein response (UPR) is a wide-ranging cellular response to accumulation of malfolded proteins in the endoplasmic reticulum (ER) and acts as a quality control mechanism to halt protein processing and repair/destroy malfolded proteins under stress conditions of many kinds. Among vertebrate species, amphibians experience the greatest challenges in maintaining water and osmotic balance, the high permeability of their skin making them very susceptible to dehydration and challenging their ability to maintain cellular homeostasis. The present study evaluates the involvement of the UPR in dealing with dehydration-mediated disruption of protein processing in the tissues of African clawed frogs, Xenopus laevis. This primarily aquatic frog must deal with seasonal drought conditions in its native southern Africa environment. Key markers of cellular stress that impact protein processing were identified in six tissues of frogs that had lost 28% of total body water, as compared with fully hydrated controls. This included upregulation of glucose-regulated proteins (GRPs) that are resident chaperones in the ER, particularly 2-ninefold increases in GRP58, GRP75, and/or GRP94 in the lung and skin. Activating transcription factors (ATF3, ATF4, ATF6) that mediate UPR responses also responded to dehydration stress, particularly in skeletal muscle where both ATF3 and ATF4 rose strongly in the nucleus. Other protein markers of the UPR including GADD34, GADD153, EDEM, and XBP-1 also showed selective upregulation in frog tissues in response to dehydration and nuclear levels of the transcription factors XBP-1 and P-CREB rose indicating up-regulation of genes under their control.

Insights from a vertebrate model organism on the molecular mechanisms of whole-body dehydration tolerance

Studies on the molecular mechanisms of dehydration tolerance have been largely limited to plants and invertebrates. Currently, research in whole body dehydration of complex animals is limited to cognitive and behavioral effects in humans, leaving the molecular mechanisms of vertebrate dehydration relatively unexplored. The present review summarizes studies to date on the African clawed frog (Xenopus laevis) and examines whole-body dehydration on physiological, cellular and molecular levels. This aquatic frog is exposed to seasonal droughts in its native habitat and can endure a loss of over 30% of its total body water. When coping with dehydration, osmoregulatory processes prioritize water retention in skeletal tissues and vital organs over plasma volume. Although systemic blood circulation is maintained in the vital organs and even elevated in the brain during dehydration, it is done so at the expense of reduced circulation to the skeletal muscles. Increased hemoglobin affinity for oxygen helps to counteract impaired blood circulation and metabolic enzymes show altered kinetic and regulatory parameters that support the use of anaerobic glycolysis. Recent studies with X. laevis also show that pro-survival pathways such as antioxidant defenses and heat shock proteins are activated in an organ-specific manner during dehydration. These pathways are tightly coordinated at the post-transcriptional level by non-coding RNAs, and at the post-translational level by reversible protein phosphorylation. Paired with ongoing research on the X. laevis genome, the African clawed frog is poised to be an ideal animal model with which to investigate the molecular adaptations for dehydration tolerance much more deeply.

Response of Anatolian mountain frogs (Rana macrocnemis and Rana holtzi) to freezing, anoxia, and dehydration: Glucose as a cryoprotectant

Cryoprotectants play an essential role in the survival of some amphibians in response to different stress conditions such as freezing, anoxia, and dehydration. Glucose is one of the cryoprotectants important for freeze-tolerant frogs. The aim of the present study was to investigate the survival strategies of Anatolian mountain frogs (Rana macrocnemis and Rana holtzi), which are terrestrial hibernators, by examining the changes in glucose and water content in some tissues at subzero temperatures. In the current study, animals were exposed to freezing (-2.5 °C), anoxia, and dehydration treatments. During these treatments, all frogs survived. The glucose levels in the plasma, liver, and skeletal muscle and the water content of the tissues were measured during the freezing, anoxia, and dehydration. Changes in body weight were also recorded in both species. During the freezing, a 3.3-fold increase was seen in the blood glucose level of R. macrocnemis (1.35 ± 0.25 to 4.45 ± 0.51 μmol mL^-1), whereas the blood glucose level of R. holtzi exhibited a 4.5-fold increase (1.90 ± 0.25 to 8.67 ± 2.22 μmol mL^-1). In the liver, a 6.7-fold increase was seen in the glucose level of R. macrocnemis (5.66 ± 0.15 to 38.27 ± 8.53 μmol g^-1) and the increase in R. holtzi was approximately 6.0-fold (2.25 ± 0.46 to 13.36 ± 1.32 μmol g^-1) during freezing. The liver glucose levels of both species also increased significantly in response to the anoxia and dehydration. In both species, the glucose levels of the skeletal muscle were found to be higher in dehydration than with freezing and anoxia. In conclusion, our results suggest that glucose may be identified as an important cryoprotectant that plays an important role in the survival of Anatolian mountain frogs during extreme conditions.

Molecular Physiology of Freeze Tolerance in Vertebrates

Freeze tolerance is an amazing winter survival strategy used by various amphibians and reptiles living in seasonally cold environments. These animals may spend weeks or months with up to ∼65% of their total body water frozen as extracellular ice and no physiological vital signs, and yet after thawing they return to normal life within a few hours. Two main principles of animal freeze tolerance have received much attention: the production of high concentrations of organic osmolytes (glucose, glycerol, urea among amphibians) that protect the intracellular environment, and the control of ice within the body (the first putative ice-binding protein in a frog was recently identified), but many other strategies of biochemical adaptation also contribute to freezing survival. Discussed herein are recent advances in our understanding of amphibian and reptile freeze tolerance with a focus on cell preservation strategies (chaperones, antioxidants, damage defense mechanisms), membrane transporters for water and cryoprotectants, energy metabolism, gene/protein adaptations, and the regulatory control of freeze-responsive hypometabolism at multiple levels (epigenetic regulation of DNA, microRNA action, cell signaling and transcription factor regulation, cell cycle control, and anti-apoptosis). All are providing a much more complete picture of life in the frozen state.