Protein stability in Artemia embryos during prolonged anoxia

Encysted embryos (cysts) of the brine shrimp, Artemia franciscana, are arguably the most stress-resistant of all animal life-history stages. One of their many adaptations is the ability to tolerate anoxia for periods of years, while fully hydrated and at physiological temperatures. Previous work indicated that the overall metabolism of anoxic embryos is brought to a reversible standstill, including the transduction of free energy and the turnover of macromolecules. But the issue of protein stability at the level of tertiary and quaternary structure was not examined. Here I provide evidence that the great majority of proteins do not irreversibly lose their native conformation during years of anoxia, despite the absence of detectable protein turnover. Although a modest degree of protein denaturation and aggregation occurs, that is quickly reversed by a brief post-anoxic aerobic incubation. I consider how such extraordinary stability is achieved and suggest that at least part of the answer involves massive amounts of a small heat shock protein (p26) that acts as a molecular chaperone, the function of which does not appear to require ribonucleoside di- or tri-phosphates.     

Long-term anoxia in encysted embryos of the crustacean, Artemia franciscana: viability, ultrastructure, and stress proteins

Cells of encysted embryos of Artemia franciscana, the brine shrimp, are among the most resistant of all animal cells to extremes of environmental stress. We focus here on their ability to survive continuous anoxia for periods of years, during which their metabolic rate is undetectable. We asked whether their impressive tolerance was reflected in changes at the ultrastructural level. The ultrastructure of encysted embryos previously experiencing 38 days and 3.3 years of anoxia was compared with those not undergoing anoxia (controls). Rough endoplasmic reticulum was abundant in anoxic embryos, in spite of the absence of protein biosynthesis in their cells. Other cytoplasmic changes had occurred in the anoxic cells, but overall their structure was remarkably intact, in view of their 3 years of continuous anoxia. A major difference was the presence of abundant electron-dense granules in the nuclei of anoxic embryos; these were present but rare in nuclei of controls. Biochemical fractionation and Western immunoblotting confirmed previous observations that substantial amounts of the small heat shock/alpha-crystallin protein (p26) translocated into nuclei of anoxic embryos. We have no evidence that the dense granules contain this protein, but that remains a possibility. In contrast, and contrary to expectation, proteins of the hsp70 and 90 families did not undergo anoxia-induced nuclear translocation, an unusual result since such translocations have been widely observed in cells from a variety of organisms.     

Dephosphorylation of cell cycle-regulated proteins correlates with anoxia-induced suspended animation in Caenorhabditis elegans

Some metazoans have evolved the capacity to survive severe oxygen deprivation. The nematode, Caenorhabditis elegans, exposed to anoxia (0 kPa, 0% O(2)) enters into a recoverable state of suspended animation during all stages of the life cycle. That is, all microscopically observable movement ceases including cell division, developmental progression, feeding, and motility. To understand suspended animation, we compared oxygen-deprived embryos to nontreated embryos in both wild-type and hif-1 mutants. We found that hif-1 mutants survive anoxia, suggesting that the mechanisms for anoxia survival are different from those required for hypoxia. Examination of wild-type embryos exposed to anoxia show that blastomeres arrest in interphase, prophase, metaphase, and telophase but not anaphase. Analysis of the energetic state of anoxic embryos indicated a reversible depression in the ATP to ADP ratio. Given that a decrease in ATP concentrations likely affects a variety of cellular processes, including signal transduction, we compared the phosphorylation state of several proteins in anoxic embryos and normoxic embryos. We found that the phosphorylation state of histone H3 and cell cycle-regulated proteins recognized by the MPM-2 antibody were not detectable in anoxic embryos. Thus, dephosphorylation of specific proteins correlate with the establishment and/or maintenance of a state of anoxia-induced suspended animation.     

Small heat shock protein p26 associates with nuclear lamins and HSP70 in nuclei and nuclear matrix fractions from stressed cells

The small heat shock/alpha-crystallin protein p26 undergoes nuclear translocation in response to stress in encysted embryos of the brine shrimp Artemia franciscana. About 50% of total p26 translocates to nuclei in embryos treated with heat shock or anoxia, and in embryo homogenates incubated at low pH. Nuclear fractionation shows that the majority of nuclear p26 and a nuclear lamin are associated with the nuclear matrix fraction. To further explore the roles of p26 and other HSPs in stabilizing nuclear matrix proteins (NMPs), nuclear matrices from control, and heat-shocked embryos were disassembled in urea and evaluated by one and two-dimensional (2-D) gel electrophoresis and Western immunoblotting after reassembling. Nuclear lamins were present only in reassembled fractions and, in the case of heat shock, p26 and HSP70 were also present. HSP90 was not detected in any nuclear fraction. Confocal microscopy on isolated nuclei and nuclear matrix preparations from control and heat-shocked embryos showed that the majority of p26 and a nuclear lamin share similar nuclear distributions. The combination of microscopy and fractionation results suggests that p26 and HSP70 play a role in the protection of nuclear lamins within the nuclear matrix.     

Nucleotide Levels Do Not Critically Determine Survival of Maize Root Tips Acclimated to a Low-Oxygen Environment

We tested the hypothesis that ATP levels and energy charge determine the resistance of maize (Zea mays) root tips to anoxia. We focused on root tips of whole maize seedlings that had been acclimated to low O2 by exposure to an atmosphere of 3% (v/v) O2 in N2. Acclimated anoxic root tips characteristically have higher ATP levels and energy charge and survive longer under anoxia than nonacclimated tips. We poisoned intact, acclimated root tips with either fluoride or mannose, causing decreases in ATP and energy charge to values similar to or, in most cases, below those found in nonacclimated anoxic tips. With the exception of the highest fluoride concentration used, the poisoned, acclimated tips remained much more tolerant of anoxia than nonacclimated root tips. We conclude that high ATP and energy charge are not components critical for the survival of acclimated root tips during anoxia. The reduced nucleotide status in poisoned, acclimated root tips had little effect on cytoplasmic pH regulation during anoxia. This result indicates that in anoxic, acclimated root tips either cytoplasmic pH regulation is not dominated by ATP-dependent processes or these processes can continue in vivo largely independently of any changes in ATP levels in the physiological range. The role of glycolytic flux in survival under anoxia is discussed.     

Cell cycle arrest associated with anoxia-induced quiescence, anoxic preconditioning, and embryonic diapause in embryos of the annual killifish Austrofundulus limnaeus

Embryos of the annual killifish Austrofundulus limnaeus can enter into dormancy associated with diapause and anoxia-induced quiescence. Dormant embryos are composed primarily of cells arrested in the G(1)/G(0) phase of the cell cycle based on flow cytometry analysis of DNA content. In fact, most cells in developing embryos contain only a diploid complement of DNA, with very few cells found in the S, G(2), or M phases of the cell cycle. Diapause II embryos appear to be in a G(0)-like state with low levels of cyclin D1 and p53. However, the active form of pAKT is high during diapause II. Exposure to anoxia causes an increase in cyclin D1 and p53 expression in diapause II embryos, suggesting a possible re-entry into the cell cycle. Post-diapause II embryos exposed to anoxia or anoxic preconditioning have stable levels of cyclin D1 and stable or reduced levels of p53. The amount of pAKT is severely reduced in 12?dpd embryos exposed to anoxia or anoxic preconditioning. This study is the first to evaluate cell cycle control in embryos of A. limnaeus during embryonic diapause and in response to anoxia and builds a foundation for future research on the role of cell cycle arrest in supporting vertebrate dormancy.     

Bioinformatic analysis of embryo development related small heat shock protein Hsp26 in Artemia species

Artemia embryos can endure extreme temperature,long-term anoxia,desiccation and other wide variety of stressful conditions.How the embryos survive these stresses is a very interesting and unsolved subj...     

Respiration of Artemia franciscana embryos after continuous anoxia over 1-year period

Encysted embryos of the brine shrimp, Artemia franciscana, exhibit extraordinary longevity when exposed to continuous anoxia. To explore the metabolic basis of this ability, the post-anoxic respiration of embryos exposed to anoxia for periods exceeding 1 year was measured. Since anoxic metabolism might result in the accumulation of metabolic end products, an O₂ debt would be expected. Contrary to that expectation, post-anoxic embryos exhibited a marked depression in respiration rate whether embryos were hydrated under anoxic conditions or were exposed to a previous aerobic incubation and then placed under anoxia. These results, and those of previous studies, suggest that extended anoxia may bring the metabolism of these embryos to a reversible standstill.     

A small heat shock/alpha-crystallin protein from encysted Artemia embryos suppresses tubulin denaturation

Small heat shock/alpha-crystallin proteins function as molecular chaperones, protecting other proteins from irreversible denaturation by an energy-independent process. The brine shrimp, Artemia franciscana, produces a small heat shock/alpha-crystallin protein termed p26, found in embryos undergoing encystment, diapause, and metabolic arrest. These embryos withstand long-term anoxia and other stresses normally expected to cause death, a property likely dependent on molecular chaperone activity. The association of p26 with tubulin in unfractionated cell-free extracts of Artemia embryos was established by affinity chromatography, suggesting that p26 chaperones tubulin during encystment. To test this possibility, both proteins were purified by modifying published protocols, thereby simplifying the procedures, enhancing p26 yield about 2-fold, and recovering less tubulin than before. The denaturation of purified tubulin as it "aged" and exposed hydrophobic sites during incubation at 35 degrees C was greatly reduced when p26 was present; however, tubulin polymerization into microtubules was reduced. On incubation at 35 degrees C, centrifugation in sucrose density gradients demonstrated the association of purified p26 with tubulin. This is the first study where the relationship between a small heat shock/alpha-crystallin protein and tubulin from the same physiologically stressed organism was examined. The results support the proposal that p26 binds tubulin and prevents its denaturation, thereby increasing the resistance of encysted Artemia embryos to stress. Additional factors are apparently required for release of tubulin from p26 and restoration of efficient assembly, events that would occur as embryos resume development and the need for microtubules is established.     

Functional coupling of glycolysis and phosphocreatine utilization in anoxic fish muscle. An in vivo 31P NMR study

Three fish species with different strategies for anoxic survival (goldfish, tilapia, and common carp) were exposed to environmental anoxia (4, 3, and 1 h, respectively). The concentrations of high energy phosphate compounds and inorganic phosphate, besides the intracellular pH in the epaxial muscle were measured during anoxia and recovery by in vivo 31P NMR spectroscopy. The concentration of free ADP was calculated from the equilibrium constant of creatine kinase. During anoxia the patterns of phosphocreatine utilization and tissue acidification are remarkedly similar. Free ADP rises rapidly during the initial period of oxygen deficiency and reaches a plateau in goldfish and tilapia, while it keeps rising in the common carp. At elevated levels of free ADP, the creatine kinase reaction and anaerobic glycolysis are functionally coupled by H+ as a common intermediate. The coupling between both processes disappears upon reoxygenation, when mitochondrial respiration induces a rapid drop of [free ADP]. The removal of ADP shifts the creatine kinase equilibrium toward phosphocreatine synthesis despite the low pH.     

Ontogeny of low molecular weight stress protein p26 during early development of the brine shrimp, Artemia franciscana

Embryogenesis in the brine shrimp, Artemia sp., occurs by one of two pathways: (i) the direct, uninterrupted development of nauplius larvae within the female or (ii) the production of embryos that arrest development at the gastrula stage and enter diapause. Diapause embryos are released from females into the aqueous environment where they remain in diapause until activated by appropriate environmental cues and resume development. These encysted embryos possess at least one low molecular weight stress protein, which we refer to as p26 and which has been implicated previously in the stress response of activated embryos. We investigated the appearance of p26 in developing diapause embryos in utero and looked for its presence in embryos developing directly into nauplii. We found p26 to be specific to diapause-destined embryos; it was not detected in direct-developing embryos. We conclude that p26 is not required for the basic developmental program that produces the nauplius. In diapause-destined embryos, p26 was first detectable after 3 days of development, at which time the embryos were late gastrulae. This protein continues to increase in amount until the encysted embryos are released, approximately 5 days after fertilization. At the time of release almost all p26 is located in the low speed supernatant fraction, but as released embryos continue diapause, p26 transfers to the pelleted nuclear fraction in increasing amounts. Our working hypothesis views p26 as a molecular chaperone preventing protein denaturation and aggregation under conditions associated with metabolic arrest and other stressful states, which these encysted embryos encounter.     

The Role of Sugars,Hexokinase, and Sucrose Synthase in the Determination of Hypoxically Induced Tolerance to Anoxia in Tomato Roots

Hypoxic pretreatment of tomato (Lycopersicon esculentum M.) roots induced an acclimation to anoxia. Survival in the absence of oxygen was improved from 10 h to more than 36 h if external sucrose was present. The energy charge value of anoxic tissues increased during the course of hypoxic acclimation, indicating an improvement of energy metabolism. In acclimated roots ethanol was produced immediately after transfer to anoxia and little lactic acid accumulated in the tissues. In nonacclimated roots significant ethanol synthesis occurred after a 1-h lag period, during which time large amounts of lactic acid accumulated in the tissues. Several enzyme activities, including that of alcohol dehydrogenase, lactate dehydrogenase, pyruvate decarboxylase, and sucrose synthase, increased during the hypoxic pretreatment. In contrast to maize, hexokinase activities did not increase and phosphorylation of hexoses was strongly inhibited during anoxia in both kinds of tomato roots. Sucrose, but not glucose or fructose, was able to sustain glycolytic flux via the sucrose synthase pathway and allowed anoxic tolerance of acclimated roots. These results are discussed in relation to cytosolic acidosis and the ability of tomato roots to survive anoxia.     

Functional analysis of a small heat shock/alpha-crystallin protein from Artemia franciscana. Oligomerization and thermotolerance.

Oviparously developing embryos of the brine shrimp, Artemia franciscana, synthesize abundant quantities of a small heat shock/alpha-crystallin protein, termed p26. Wild-type p26 functions as a molecular chaperone in vitro and is thought to help encysted Artemia embryos survive severe physiological stress encountered during diapause and anoxia. Full-length and truncated p26 cDNA derivatives were generated by PCR amplification of p26-3-6-3, then cloned in either pET21(+) or pRSETC and expressed in Escherichia coli BL21(DE3). All constructs gave a polypeptide detectable on Western blots with either p26 specific antibody, or with antibody to the His(6) epitope tag encoded by pRSETC. Full-length p26 in cell-free extracts of E. coli was about equal in mass to that found in Artemia embryos, but p26 lacking N- and C-terminal residues remained either as monomers or small multimers. All p26 constructs conferred thermotolerance on transformed E. coli, although not all formed oligomers, and cells expressing N-terminal truncated derivatives of p26 were more heat resistant than bacteria expressing p26 with C-terminal deletions. The C-terminal extension of p26 is seemingly more important for thermotolerance than is the N-terminus, and p26 protects E. coli against heat shock when oligomer size and protein concentration are low. The findings have important implications for understanding the functional mechanisms of small heat shock/alpha-crystallin proteins.     

Studies of ribonucleotide reductase in crucian carp-an oxygen dependent enzyme in an anoxia tolerant vertebrate

The enzyme ribonucleotide reductase (RNR) catalyzes the conversion of ribonucleotides to deoxyribonucleotides, the precursors for DNA. RNR requires a thiyl radical to activate the substrate. In RNR of eukaryotes (class Ia RNR), this radical originates from a tyrosyl radical formed in reaction with oxygen (O(2)) and a ferrous di-iron center in RNR. The crucian carp (Carassius carassius) is one of very few vertebrates that can tolerate several months completely without oxygen (anoxia), a trait that enables this fish to survive under the ice in small ponds that become anoxic during the winter. Previous studies have found indications of cell division in this fish after 7 days of anoxia. This appears nearly impossible, as DNA synthesis requires the production of new deoxyribonucleotides and therefore active RNR. We have here characterized RNR in crucian carp, to search for adaptations to anoxia. We report the full-length sequences of two paralogs of each of the RNR subunits (R1i, R1ii, R2i, R2ii, p53R2i and p53R2ii), obtained by cloning and sequencing. The mRNA levels of these subunits were measured with quantitative PCR and were generally well maintained in hypoxia and anoxia in heart and brain. We also report maintained or increased mRNA levels of the cell division markers proliferating cell nuclear antigen (PCNA), brain derived neurotrophic factor (BDNF) and Ki67 in anoxic hearts and brains. Electron paramagnetic resonance (EPR) measurements on in vitro expressed crucian carp R2 and p53R2 proteins gave spectra similar to mammalian RNRs, including previously unpublished human and mouse p53R2 EPR spectra. However, the radicals in crucian carp RNR small subunits, especially in the p53R2ii subunit, were very stable at 0°C. A long half-life of the tyrosyl radical during wintertime anoxia could allow for continued cell division in crucian carp.     

Nitrite reduces cytoplasmic acidosis under anoxia

The ameliorating effect of nitrate on the acidification of the cytoplasm during short-term anoxia was investigated in maize (Zea mays) root segments. Seedlings were grown in the presence or absence of nitrate, and changes in the cytoplasmic and vacuolar pH in response to the imposition of anoxia were measured by in vivo (31)P nuclear magnetic resonance spectroscopy. Soluble ions and metabolites released to the suspending medium by the anoxic root segments were measured by high-performance liquid chromatography and (1)H nuclear magnetic resonance spectroscopy, and volatile metabolites were measured by gas chromatography and gas chromatography-mass spectrometry. The beneficial effect of nitrate on cytoplasmic pH regulation under anoxia occurred despite limited metabolism of nitrate under anoxia, and modest effects on the ions and metabolites, including fermentation end products, released from the anoxic root segments. Interestingly, exposing roots grown and treated in the absence of nitrate to micromolar levels of nitrite during anoxia had a beneficial effect on the cytoplasmic pH that was comparable to the effect observed for roots grown and treated in the presence of nitrate. It is argued that nitrate itself is not directly responsible for improved pH regulation under anoxia, contrary to the usual assumption, and that nitrite rather than nitrate should be the focus for further work on the beneficial effect of nitrate on flooding tolerance.     

Effects of anoxia and the mitochondrion on expression of aerobic nuclear COX genes in yeast: evidence for a signaling pathway from the mitochondrial genome to the nucleus

Eucaryotic cells contain at least two general classes of oxygen-regulated nuclear genes: aerobic genes and hypoxic genes. Hypoxic genes are induced upon exposure to anoxia while aerobic genes are down-regulated. Recently, it has been reported that induction of some hypoxic nuclear genes in mammals and yeast requires mitochondrial respiration and that cytochrome-c oxidase functions as an oxygen sensor during this process. In this study, we have examined the role of the mitochondrion and cytochrome-c oxidase in the expression of yeast aerobic nuclear COX genes. We have found that the down-regulation of these genes in anoxic cells is reflected in reduced levels of their subunit polypeptides and that cytochrome-c oxidase subunits I, II, III, Vb, VI, VII, and VIIa are present in promitochondria from anoxic cells. By using nuclear cox mutants and mitochondrial rho(0) and mit(-) mutants, we have found that neither respiration nor cytochrome-c oxidase is required for the down-regulation of these genes in cells exposed to anoxia but that a mitochondrial genome is required for their full expression under both normoxic and anoxic conditions. This requirement for a mitochondrial genome is unrelated to the presence or absence of a functional holocytochrome-c oxidase. We have also found that the down-regulation of these genes in cells exposed to anoxia and the down-regulation that results from the absence of a mitochondrial genome are independent of one another. These findings indicate that the mitochondrial genome, acting independently of respiration and oxidative phosphorylation, affects the expression of the aerobic nuclear COX genes and suggest the existence of a signaling pathway from the mitochondrial genome to the nucleus.     

Anoxia tolerance in rice seedlings: exogenous glucose improves growth of an anoxia-'intolerant', but not of a 'tolerant' genotype

This study demonstrated that, in rice seedlings, genotypic differencein tolerance to anoxia only occurred when anoxia was imposedat imbibition, but not at 3 d after imbibition. When seeds wereimbibed and grown in anoxia, IR22 (anoxia-‘intolerant’)grew much slower and had lower soluble sugar concentrationsin coleoptiles and seeds than Amaroo (anoxia-‘tolerant’),while Calrose was intermediate. After 3 d in anoxia, the sugarconcentrations in embryos and endosperms of anoxic seedlingswere nearly 4-fold lower in IR22 than in Amaroo. Sugar deficitin the embryo of IR22 is presumably due to the limitation ofsugar mobilization rather than the capacity of transport asshown by similar sugar accumulation ratios of 1.8 between embryoand endosperm in IR22 and Amaroo at 3 d in anoxia. With 20 molm^–3 exogenous glucose, coleoptile extension and freshweight increments in anoxic seedlings of IR22 were much closerto those in the two other genotypes, nevertheless protein concentrationremained lowest on a fresh weight basis in the coleoptiles ofIR22; indicating that protein synthesis has a lower priorityfor energy apportionment during anoxia than processes crucialto coleoptile extension. In contrast to these responses to anoxiaimposed at imbibition, IR22 had nearly the same high toleranceto anoxia as Calrose and Amaroo, when anoxia was imposed onseedlings subsequent to 48 h aeration followed by 16 h hypoxicpretreatment. In fact, coleoptiles of anoxic IR22 had highersugar concentrations and grew faster than Calrose, and exogenousglucose had no effect on the coleoptile extension of IR22. Excisedcoleoptile tips of IR22 and Amaroo with exogenous glucose hadsimilar rates of ethanol production and were equally tolerantto anoxia. In conclusion, much of the anoxia ‘intolerance’of IR22 when germinated in anoxia could be attributed to limitedsubstrate availability to the embryo and coleoptile, presumablydue to slow starch hydrolysis in the endosperm. Key words: Anoxia, coleoptile, embryo, endosperm, ethanol production, germination, growth, Oryza sativa L., solute net uptake or loss, sugar availability.