Divergent mechanisms of frost-hardiness in two populations of the gall fly, Eurosta solidaginsis

Two populations of the gall fly Eurosta solidaginsis utilize different strategies to endure seasonal exposure to temperatures below freezing. Both populations are freezing tolerant. In north temperate populations, supercooling points rise from ?10.2°C to ?6.2°C following exposures to temperatures below freezing. This level is maintained throughout winter and ensures frequent and prolonged periods of tissue freezing. South temperate populations depress the supercooling point to ?14.2°C during autumn and early winter, and this depression precludes extracellular ice formation during periods of supra-optimal temperature fluctuations. During mid-winter, supercooling points rise to the same level as in northern groups.Both populations accumulate three principal cryoprotective agents following first frost exposures (glycerol, sorbitol and trehalose). Cryoprotectants levels do not peak in northern populations until 4–6 weeks after first frost. In southern populations the accumulation profile is characterized by a high initial rate of synthesis, a protective overshoot and pronounced seasonal fluctuations. The relative survival advantages of each strategy are discussed.     

Changes in abundance of aquaporin-like proteins occurs concomitantly with seasonal acquisition of freeze tolerance in the goldenrod gall fly, Eurosta solidaginis

The accumulation of cryoprotectants and the redistribution of water between body compartments play central roles in the capacity of insects to survive freezing. Aquaporins (AQPs) allow for rapid redistribution of water and small solutes (e.g. glycerol) across the cell membrane and were recently implicated in promoting freeze tolerance. Here, we examined whether aquaporin-like protein abundance correlated with the seasonal acquisition of freezing tolerance in the goldenrod gall fly, Eurosta solidaginis (Diptera: Tephritidae). Through the autumn, larvae became tolerant of freezing at progressively lower temperatures and accumulated the cryoprotectant glycerol. Furthermore, larvae significantly increased the abundance of membrane-bound aquaporin and aquaglyceroporin-like proteins from July through January. Acute exposure of larvae to cold and desiccation resulted in upregulation of the AQP3-like proteins in October, suggesting that their abundance is regulated by environmental cues. The seasonal increase in abundance of both putative aquaporins and aquaglyceroporins supports the hypothesis that these proteins are closely tied to the seasonal acquisition of freeze tolerance, functioning to permit cells to quickly lose water and take-up glycerol during extracellular ice formation, as well as reestablish water and glycerol concentrations upon thawing.     

Cell differentiation during the ontogeny of larval salivary glands of the fly, Telmatoscopus albipunctatus

Using the larvae, pharate pupa, and pharate adults of the moth fly, Telmatoscopus albipunctatus, histological and ultrastructural features of the salivary glands were investigated. The gland lumen contains a milky secretion from the first instar. This secretion continues to ccur at all subsequent developmental stages; with the onset of the pharate pupal stage, however, the secretion becomes transparent and rather viscous. Histochemical tests revealed that it is mainly proteinaceous. Glands from the same developmental stage may respond differently to PAS-reaction.Various cell organelles were compared at consecutive stages of larval development and of secretory activity of the salivary glands. In first and second instar larvae autophagic vacuoles are virtually absent in the salivary gland cells. They were occasionally found in the third instar, when they appear to be engaged in the process of organelle turnover. Histolysis of the larval glands is initiated towards the close of the fourth instar when the number of autophagic vacuoles starts to increase. Simultaneously, the cytoplasm, previously full of ribosomes and endoplasmic reticulum, starts losing these structures. At the beginning of the pharate adult stage, the cytoplasm becomes practically devoid of all structures other than those engaged in autophagy.Polyteny of the chromosomes during ontogeny of the larval salivary glands is also discussed.     

Geographical and diapause-related cold tolerance in the blow fly,Calliphora vicina

Three geographical strains of the blow fly, Calliphora vicina, were tested for cold tolerance at 0 degrees, -4 degrees and -8 degrees C. Survival to eclosion after 1 to 18 days of cold exposure was greater for diapause-destined larvae than for nondiapause-destined larvae of the two northern strains (Nallikari, Finland 65 degrees N and Edinburgh, Scotland 55 degrees N) but not for the southernmost strain (Barga, Italy 44 degrees N) where no clear differences were apparent. Diapause-destined larvae of the Edinburgh strain were more cold tolerant than those from Nallikari, at both -4 degrees and -8 degrees C, a difference possibly attributable to the long-lasting snow cover in the more northern locality, which might insulate the overwintering soil microclimate. At 0 degrees C, however, Nallikari larvae were more cold tolerant than Edinburgh or Barga. This was also the case for nondiapause-destined larvae, indicating that cold tolerance may occur, in part, independently of the diapause programme. In all three strains diapausing larvae were more cold tolerant than same-age (nondiapausing) pupae. For Nallikari, but not Barga, wandering larvae from short-day exposed flies, therefore initially programmed for diapause, but diverted from the diapause pathway by larval breeding at 19 degrees C, were significantly more cold tolerant than nondiapause larvae from long-day parents, indicating some maternal regulation of larval cold tolerance. There was, however, no evidence for an additional cold hardiness in larvae acclimatised to cold by a gradual reduction of temperature.     

Experimental studies on the cold tolerance of Alaskozetes antarcticus

The cold tolerance mechanism of the Antarctic terrestrial mite Alaskozetes antarcticus (Michael) was investigated in cultured animals. Freezing is fatal in this species and winter survival occurs by means of supercooling, which is enhanced by the presence of glycerol in the body. There is an inverse, linear relationship between the concentration of glycerol and the supercooling point, which may be as low as ?30°C. Feeding detracts from supercooling ability by providing ice nucleators in the gut which initiate freezing at relatively high sub-zero temperatures. Experiments on the effects of various environmental factors showed that low temperature acclimation gave rise to increased glycerol concentrations and suppressed feeding, while desiccation also stimulated glycerol production. Photoperiod had no effect on cold tolerance in this species. The juvenile instars of A. antarcticus were found to possess a greater degree of low temperature tolerance than adults.     

Differential thermal tolerance and energetic trajectories during ontogeny in porcelain crabs,genus Petrolisthes

Thermal tolerance limits of marine intertidal zone organisms are elevated compared to subtidal species, but are typically just slightly higher than maximal habitat temperatures. The small thermal safety margins maintained by intertidal zone organisms suggest that high thermal tolerance is associated with a physiological cost. If true, we hypothesize that species that transition between intertidal zone and planktonic habitats during ontogeny, will adjust their thermal tolerance accordingly to capitalize upon potential energy savings while in a thermally benign habitat. We tested this hypothesis in porcelain crabs that transition between the thermally stressful, intertidal zone as embryos, to the thermally benign pelagic zone as larvae, and back at settlement. We found the more thermally tolerant, mid-intertidal zone species, Petrolisthes cinctipes, and the less thermally tolerant, subtidal zone species, Petrolisthes manimacilis, exhibited reduced thermal tolerance (LT₅₀) in the transition from embryos to larvae. This was associated with an increased oxygen consumption rate in both species, though P. cinctipes exhibited a significantly greater increase in oxygen consumption. P. cinctipes also showed an increase in thermal tolerance in settled juveniles compared to pelagic zoea I larvae, resulting in an overall V-shaped thermal tolerance relationship during ontogeny, while in P. manimaculis thermal tolerance was significantly lower in juveniles compared to zoea I. In neither species were these changes (zoea I to juvenile) associated with a significant change in metabolism. While embryos and juveniles of P. cinctipes have thermal tolerance limits near intertidal habitat thermal maxima (∼32.5 °C), all three life-history stages in P. manimaculis (especially embryos and larvae) exhibit considerable thermal safety margins. The mechanisms underlying this “excess” thermal tolerance in P. manimacilis embryos are unknown, but suggest that patterns of thermal tolerance in early life history stages are species-specific.     

Temperature dependence-independence of antifreeze turnover in Eurosta solidaginis (Fitch)

Temperature effects on antifreeze metabolism were investigated in two populations (northern and southern) of the golden rod gallfly, Eurosta solidaginis. Sorbitol production was temperature dependent and was triggered by short-term exposure to < +10°C. The maximal rate sorbitol synthesis occurred at 0°C. For both populations, sorbitol was rapidly catabolized during warm acclimation at +20°C. During the first 12 h of warm acclimation, sorbitol levels decreased by 36% (19.7 ± 0.6) to 12.6 ± 1.2 μg/mg) and by 83% (to 3.3 ± 1.7 μg/mg) after 48 h in the northern population. The southern population decreased sorbitol levels 64% (11.8 ± 0.69 to 4.2 ± 0.62) after 48 h. The southern population resynthesized more sorbitol than did the northern population upon re-exposure to 0°C. Glycerol levels increased linearly during the experimental period independent of temperature.     

Absence of metabolic cold adaptation and compensatory acclimation in the Antarctic fly, Belgica antarctica

The respiratory metabolism in larvae of the Antarctic fly, Belgica antarctica Jacobs (Diptera: Chironomidae) was investigated at Palmer Station, Anvers Island (64°46′S, 64°03′W). Oxygen consumption was linearly related to temperature from 0 to 20°C, respectively, 49 and 338 nl/mg live wt/hr. Maintenance at 0 and 10°C for 8 days had no differential effect on the metabolic rate, suggesting that larvae lack the ability for compensatory acclimation. A comparison of standard metabolism for polar and temperate chironomids revealed no elevation of metabolic rate in polar forms. However, polar species exhibited lower activation energies than temperate forms indicating that the respiratory metabolism of polar chironomids is relatively temperature independent.     

Critical periods for developmental acclimation to cold in the Queensland fruit fly, Dacus tryoni

Rapid acclimation to cold can occur in Dacus tryoni during two short stages of its life history: the stage immediately prior to the “hopping larva” phase and the “pharate adult” stage within the puparium. Transfer from 25 to 15°C at either of these stages can produce full acclimation to cold within a few days. Acclimation is not detectable at other times in puparial life: during adult life it takes over 100 days.     

Environmental triggers to cryoprotectant modulation in separate populations of the gall fly, Eurost a solidaginis (Fitch)

Northern and southern populations of the gall fly Eurosta solidaginis utilize quantitatively distinct adaptive strategies when exposed to a laboratory simulation of winter temperatures. Both populations are freezing tolerant and rely in part on the temperature-dependent accumulation of glycerol and sorbitol, and static but elevated levels of trehalose for protection. The accumulation triggers are time-temperature dependent. For northern and southern populations, exposure to 5°C for periods exceeding 24 hr, but less than 5 days or 5°C with a gradual reduction (1°C/day) results in the accumulation of sorbitol at 1.5 μg/mg/day. Glycerol levels remain essentially constant between 10° and ?25°C in each population. However, the concentration of glycerol in the Minnesota population is 3–4 times greater that that of the Texas specimens. Haemolymph melting points varied quantitatively with changing cryoprotectant levels. No significant difference was noted between the supercooling points of each population. This suggests that ice-nucleator levels were comparable throughout the exposure period.     

Cold shock and cold tolerance in larvae and pupae of the blow fly, Lucilia sericata

Abstract.  Understanding the effects of low winter temperatures on mortality is essential in the development of a full understanding of the long-term population dynamics of any insect. The present study aims to examine the survival of pupae and larvae of the blow fly, Lucilia sericata , at overwintering temperatures. Groups of pupae and diapausing and nondiapausing third-stage larvae of L. sericata are maintained in cooled incubators at either 3 °C and 6 °C. Groups are removed from the incubators at 3–4-day intervals and transferred either to−8 °C or to 25 °C. After 1 h in the freezer, the larvae and pupae exposed to this cold-shock are also transferred to 25 °C. Larvae and pupae are then allowed to continue development and the number of adults emerging from each group is counted. The results demonstrate that survival decreases linearly with the period of exposure at both 3 °C and 6 °C. Mortality is higher at 3 °C than at 6 °C and, in groups that receive the cold shock, cold-shock reduces emergence by over 50%. However, there is no consistent tendency for diapausing larvae to survive prolonged cold or cold shock better than other life-cycle stages. The results suggest that the facultative development of an overwintering diapause stage in L. sericata does not appear to be an adaptation to enhance cold tolerance or resistance to cold shock. It is concluded that the survival of overwintering L. sericata is likely to be relatively less affected by low temperatures than it is by, for example, biotic factors, particularly given the buffered soil environment and short time-scales over which periods of cold act.     

Heterologous expression of antifreeze protein gene AnAFP from Ammopiptanthus nanus enhances cold tolerance in Escherichia coli and tobacco

Antifreeze proteins are a class of polypeptides produced by certain animals, plants, fungi and bacteria that permit their survival under the subzero environments. Ammopiptanthus nanus is the unique evergreen broadleaf bush endemic to the Mid-Asia deserts. It survives at the west edge of the Tarim Basin from the disappearance of the ancient Mediterranean in the Tertiary Period. Its distribution region is characterized by the arid climate and extreme temperatures, where the extreme temperatures range from − 30 °C to 40 °C. In the present study, the antifreeze protein gene AnAFP of A. nanus was used to transform Escherichia coli and tobacco, after bioinformatics analysis for its possible function. The transformed E. coli strain expressed the heterologous AnAFP gene under the induction of isopropyl β-D-thiogalactopyranoside, and demonstrated significant enhancement of cold tolerance. The transformed tobacco lines expressed the heterologous AnAFP gene in response to cold stress, and showed a less change of relative electrical conductivity under cold stress, and a less wilting phenotype after 16 h of − 3 °C cold stress and thawing for 1 h than the untransformed wild-type plants. All these results imply the potential value of the AnAFP gene to be used in genetic modification of commercially important crops for improvement of cold tolerance.     

Acquisition of freezing tolerance in early autumn and seasonal changes in gall water content influence inoculative freezing of gall fly larvae,Eurosta solidaginis (Diptera,Tephritidae)

We examined seasonal changes in freeze tolerance and the susceptibility of larvae of the gall fly, Eurosta solidaginis to inoculative freezing within the goldenrod gall (Solidago sp.). In late September, when the water content of the galls was high (approximately 55%), more than half of the larvae froze within their galls when held at -2.5 degrees C for 24 h, and nearly all larvae froze at -4 or -6 degrees C. At this time, most larvae survived freezing at > or = -4 degrees C. By October plants had senesced, and their water content had decreased to 33%. Correspondingly, the number of larvae that froze by inoculation at -4 and -6 degrees C also decreased, however the proportion of larvae that survived freezing increased markedly. Gall water content reached its lowest value (10%) in November, when few larvae froze during exposure to subzero temperatures > or = -6 degrees C. In winter, rain and melting snow transiently increased gall water content to values as high as 64% causing many larvae to freeze when exposed to temperatures as high as -4 degrees C. However, in the absence of precipitation, gall tissues dried and, as before, larvae were not likely to freeze by inoculation. Consequently, in nature larvae freeze earlier in the autumn and/or at higher temperatures than would be predicted based on the temperature of crystallization (T(c)) of isolated larvae. However, even in early September when environmental temperatures are relatively high, larvae exhibited limited levels of freezing tolerance sufficient to protect them if they did freeze.     

The ecology of cold hardiness in different populations of the black currant gall mite, Cecidophyopsis ribis

Population samples of C. ribis from eastern Norway, western Norway, and England, and cuttings of 5 black currant varieties were exposed for different periods to -18.5°±0.5° C and mites also to 6°. Mite mortality, mite emigration, egg production at 6°, and bud burst of the cuttings, were observed.Marked differences were found between the mite populations both in their ability to produce eggs at 6°, and in cold hardiness at -18.5°. Mortality during cold treatment was inversely related to mite density in different buds as well as in different zones of each bud. Mite emigration was greatly facilitated when the side of the bud touched the twig.When comparing cold hardiness of the mites with that of black currant cuttings, cold treatment of the cuttings as a control measure appeared to be of little promise against the Norwegian populations of C. ribis. With the English population, however, a reasonable safety margin seemed to exist between exposures giving complete kill of the mites, and those which damage the cuttings.

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Zusammenfassung Populationsproben von C. ribis von Rygge, Ost-Norwegen; Hjelmeland, West-Norwegen; und Reading, England, wurden für verschiedene Zeiten Temperaturen von -18.5±0,5° und 6° ausgesetzt. Unbefallene Stecklinge der folgenden fünf Schwarze Johannisbeer-Sorten wurden in ähnlicher Weise mit Kälte von -18.5° behandelt: Bang up, Booskop Giant, Brødtorp, Silvergieter's Zwarte und Wellington XXX. Mortalität, Abwanderung und Eiproduktion der Milben bei 6° und das Knospenaufbrechen der Johannisbeer-Reiser wurden beobachtet.Die Milben von Rygge waren am meisten, die von Reading am wenigsten kälteresistent, während Milben von Hjelmeland eine mittlere Kälteresistenz aufwiesen (Fig. 1). Milben von Rygge, und in geringerem Maße die von Hjelmeland, produzierten bei 6° eine beträchtliche Anzahl Eier, während die Eiproduktion der englischen Population bei dieser Temperatur fast vollständig zum Stillstand gelangte (Tabelle III).Die Mortalität während der Kälte war umgekehrt proportional zur Milbendichte in verschiedenen Knospen (Fig. 2) sowohl wie in verschiedenen Zonen jeder Knospe (Tabelle I). Niedrige Wintertemperaturen wirken demnach nicht als Regulationsfaktor auf die Populationsdynamik dieser Art.Die Wirkung der Kältebehandlung auf die Milbenabwanderung ist in Tabelle II dargestellt. Die Abwanderung der Milben wurde sehr erleichtert, wenn eine Seite der Knospe den Zweig berührte (Fig. 4).Mit einer möglichen Ausnahme von Booskop Giant und Brødtorp konnten die Sorten der Schwarzen Johannisbeeren 16 Tage lang -18,5° ohne sichtbaren Schaden für den Knospenaustrieb unterworfen werden. Milben aus Ost-Norwegen überlebten 16 Tage Kältebehandlung in allen und Milben aus West-Norwegen in einer der Prüfungen. Kältebehandlung der Stecklinge scheint deshalb als Bekämpfungsmaßnahme gegen die norwegischen Populationen von C. ribis wenig erfolgversprechend. In den englischen Milbenpopulationen wurde dagegen nach 9 oder 10 Tagen 100% Mortalität erzielt. Dies scheint einen erträglichen Sicherheitszeitraum zwischen Behandlungen, die vollständige Abtötung der Milben ergeben, und solchen, die den Stecklingen schaden, offenzulassen.

     

The ontogeny of agonistic behaviour in the blue gourami, Trichogaster trichopterus (Pisces,Anabantoidei)

The development of agonistic behaviour in the blue gourami, Trichogaster trichopterus, was studied from hatching to four months of age. Larval motor patterns appear first as simple, uncoordinated, and irregular movements and gradually become regular and well coordinated, forming integrated complex patterns, such as swimming, surfacing, and feeding. Most motor patterns used in agonistic interactions are first exhibited in non-social contexts. Initial interactions between young fish consist of Approach and investigation in a feeding context, in some cases followed by nibbling, Biting, and Chasing by one fish. Later, initial Approaches are separated from Biting and Chasing by Lateral Displays, circling, Tail Beating, and Fin Tugging, and by Appeasement behaviour that inhibits Chasing and Biting by the opponent.Agonistic behaviour of socially isolated fish, when paired in dyadic encounters as adults, indicates that the role of social experience as an integrator and regulator of social behaviour may change progressively during development and become more important as ontogeny proceeds.     

Freezing and cellular metabolism in the gall fly larva,Eurosta solidaginis

Summary The effects of extracellular freezing on intracellular metabolism were monitored over both a short (9 h) and long (12 weeks) time course using the freeze tolerant larvae of the gall fly,Eurosta solidaginis.The process of freezing, monitored over the short time course, had no effect upon cellular energy levels (adenylates, arginine phosphate) but initiated a rise in glucose-6-P and lactate levels. This suggests that freezing initiates a shift towards glycolysis as the predominant mode of energy production. The process of thawing at 3°C (after 24 h at –16°C) also had no effect, even transient, on cellular energy levels demonstrating that thawing and the rapid redistribution of water and solutes which must accompany it does not disrupt cellular metabolism. During thawing accumulated lactate was quickly cleared with a t 1/2 of 20–30 min.Long term freezing at –16°C had dramatic effects on energy metabolism. Freezing for up to 1 week had minimal effects with only a small drop in arginine phosphate reserves and an increase in lactate content noted. Between 1 and 2 weeks of freezing, however, larvae showed strong signs of energy stress. The arginine phosphate pool fell from 75% to 30% of control levels, ATP content dropped by 50% and energy charge dropped to 0.75. This state, with continued lactate accumulation, was maintained through 4 weeks of freezing. Between 6 and 12 weeks of freezing energy stress became even greater. Phosphagen and ATP contents dropped to 5 and 25% of control values and energy charge decreased to about 0.50. Despite this stress, however, 94% of larvae survived 12 weeks of freezing with an 86% hatch rate of adults. The data demonstrate that the larvae can survive prolonged periods of winter freezing drawing upon glycolysis and phosphagen reserves to supply the continued basal energy demands of the cell.