The fate of [14C]glucose during cold-hardening in Eurosta solidaginis (Fitch)

Glucose catabolism in overwintering larvae Eurosta solidaginis was examined to determine the relative contributions of glycolysis and the pentose phosphate pathway to polyol synthesis at different temperatures. Rates of ¹⁴CO₂ evolution were determined after injection of [¹⁴C]1-glucose, [¹⁴C]6-glucose, and [¹⁴C]3,4-glucose. In addition incorporation of label from each isotope into sorbitol and glycerol was monitored. The respirometric studies showed a relative increase in pentose phosphate activity between 10 and 5°C. Similar results were obtained from the changes of radioactivities incorporated into glycerol, although the activation of the pentose phosphate pathway was low. The conversion of [¹⁴C]glucose to glycerol was highest at 10°C, suggesting that maximum glycerol synthesis may occur at this temperature. Radioactivity appeared in the sorbitol fraction of larvae incubated at temperatures below 5°C. Late autumn larvae converted more [¹⁴C]glucose than did early autumn larvae.     

Mitochondrial DNA variation among host races of Eurosta solidaginis Fitch (Diptera: Tephritidae)

Eurosta solidaginis Fitch (Diptera: Tephritidae) induces galls on two species of goldenrod, Solidago (Compositae), in the northern regions of the United States. Recent studies have demonstrated that E. solidaginis is comprised of two host races that differ in adult emergence times, mate preference, and host preference. However, it is not known how much genetic variation, if any, exists among E. solidaginis host-associated populations west of Minnesota where the two host races occur in sympatry. Sequencing analysis was used to characterize two mitochondrial gene fragments: (1) NADH1 dehydrogenase (ND1: 539 bp) and (2) cytochrome oxidase II + tRNA(Lys) + tRNA(Asp) (CO2KD: 396 bp) from sympatric, host-associated populations of E. solidaginis in North Dakota. Our results indicated that two genetically distinct lineages exist among E. solidaginis in North Dakota that correspond with host-plant association.     

Effect of cooling rate on the survival of larvae, pupariation, and adult emergence of the gallfly Eurosta solidaginis

Freeze-tolerant third instar larvae of the gallfly Eurosta solidaginis were cooled at 10, 5, 1, and 0.1 degrees C min-1 to -40 degrees C and then warmed to +5 degrees C at 1 degree C min-1. After cooling and warming the larvae were transferred to 21 degrees C and the survival of larvae, success of pupariation, and adult emergence were monitored at daily intervals in comparison to an uncooled control sample. The percentage emergences of flies from larvae cooled at 10, 5, 1, and 0.1 degree C min-1 and in the control were 7, 13, 37, 77, and 67%, respectively. A number of flies in each group emerged with malformed (unextended) wings and an unretracted ptilinum on the head capsule. The percentage emergences of normal flies at the four cooling rates and from the control were 3, 0, 17, 47, and 57%. At 48 hr after exposure all larvae in each treatment were alive. First mortality was observed between 48 and 72 hr after cooling and increased with time at each cooling rate. Mortality was apportioned into four phases of development: larva, pupariation, and early and late pupae. Mortality commenced earlier at the faster cooling rates; at 10 degrees C min-1, 37% of the sample died as larvae and a further 20% failed to complete pupariation, whereas at 0.1 degree C min-1, only 3% died as larvae and 97% formed a puparium.     

The influence of oviposition phenology on survival in host races of Eurosta solidaginis

Phenological differences between host plants can contribute to allochronic isolation of host races of phytophagous insects. Host races of the gallmaking fly, Eurosta solidaginis, that live on different species of goldenrod (Solidago altissima and S. gigantea) exhibit different emergence phenologies. These differences could result from adaptation to corresponding phenological differences between the hosts in periods of optimal suitability for gall formation and survival to adulthood. In order to test this, some flies of each host race were allowed to emerge naturally while the emergence times of others were manipulated to correspond to the emergence and oviposition periods of the other host race. Percent gall formation and survival to adulthood were examined for three oviposition periods: the peak time of emergence and oviposition of the earlier-emerging host race (that from S. gigantea), that of the later-emerging host race (that from S. altissima), and a week after the peak emergence of the host race from S. altissima. Flies of both host races were allowed to ovipuncture plants of the appropriate species during each of these periods. Plant relative growth rates were measured during each of these periods. The experiment was repeated twice over a two-year period. Relative growth rates of both host species were highest during the earliest oviposition period (the period during which the host race from S. gigantea normally emerges). Percent gall formation was significantly correlated with plant relative growth rate, but the coefficient of determination was low. In both years of the study, percent gall formation of both host races was highest during the earliest oviposition period (the period during which the host race from S. gigantea normally oviposits). Likewise, percent survival to adulthood in both host races was highest during the earliest oviposition period. There was no significant effect of oviposition period on the percent of larval death due to parasitism by Eurytoma gigantea or predation by Mordellistena unicolor. These results suggest that the host race from S. altissima does not emerge at the time that its host is optimally suited for gall formation or survival to adulthood. Therefore, differences in emergence phenologies do not appear to be due to corresponding phenological differences between the host species in suitability for gall formation or survival to adulthood.     

Relative effects of cooling and warming rates on mammalian cells during the freeze-thaw cycle

The relative roles of cooling and warming rates on cell survival during a freeze-thaw cycle were investigated. Basically the faster the warming rate, the better the cells survive. One of the factors influencing this is the extended phase transition period at the slower thawing rates. The warming rate had a significant effect on cell damage and recovery, but this was not as great as comparative changes in the cooling rate were. This investigation also showed that under certain freeze-thaw conditions there was a lack of correlation between the two methods used for quantifying cell recovery (RI) and cell damage (PCR) as measured by radiochromate release. The analysis of the relationship between RI and PCR showed that PCR could be used to measure both lethal and nonlethal damage and enabled a clearer interpretation of cellular damage during cooling and thawing to be made.     

The effects of temperature and season on the O2 consumption of third-instar larvae of the goldenrod gall fly (Eurosta solidaginis)

Abstract. Third-instar larvae of the goldenrod gall fly ( Eurosta solidaginis Fitch) live inside ball galls on goldenrod plants from summer to the following spring.Because galls are highly exposed to the weather, larvae experience substantial variations in body temperature.This study documents the oxygen consumption of gall fly larvae with regard to the effects of ambient temperature, seasonal conditioning, and prior exposure to subzero temperature.The body mass of larvae doubles between the late summer and the autumn; it subsequently undergoes a modest decline by early winter.The O₂, consumption of field-acclimatized larvae increases with ambient temperature, especially between 0 and 10°C (Q₁₀= 2.6-3.4).The thermal sensitivity of metabolism declines at higher ambient temperatures, most notably during the autumn/early winter.After exposure to 15°C for 1 week, autumn and early winter larvae maintain much lower rates of O₂ consumption than do late summer specimens.Prior exposure to -5°C for 24 h did not influence the O₂ consumption of larvae.Low thermal sensitivity of O₂ consumption, especially at higher ambient temperatures, is an energy-sparing mechanism during seasonal inactivity.Indeed, the persistence of this metabolic pattern in larvae exposed to 15°C suggests that they have entered a state of diapause.     

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.     

The effect of cooling and warming rates on the survival of cryopreserved L-cells

A tissue culture assay has been used to measure the survival of murine lymphoma cells (L-cells) after freezing and thawing in the presence of 2 M glycerol or 1.6 M dimethyl sulfoxide. The effect of variations in cooling rate (0.1 to 10.0 °C/min) and warming rate (0.3 to 200 °C/min) were studied. It was found that survival exhibited a peak at the “conventional” combination of slow cooling and rapid warming (~1 and 200 °C/ min, respectively). It was also shown, however, that a second peak of similar magnitude occurred when the cells were cooled and rewarmed at 0.2-0.3 °C/min. These results are interpreted on the basis of current theories of freezing injury, stressing the importance of damage produced by the recrystallization of intracellular ice and by solute loading. The ultraslow rates of cooling and rewarming which produced the second survival peak are practicable for whole organs, and their potential importance for organ cryopreservation is apparent.     

Diapause development in frozen larvae of the goldenrod gall fly, Eurosta solidaginis fitch (diptera: tephritidae)

Seasonal changes in metabolic rate and the potential for morphological development demonstrated that third-instar larvae of the goldenrod gall fly, Eurosta solidaginis Fitch, exhibit a distinct winter diapause. Metabolic rate (CO2 production) was significantly lower from 15 October to 9 February than in early autumn (9 September) and spring (1 March) samples. The induction of diapause coincided with the development of cold-hardening, maximum larval mass, and gall senescence, but our experiments did not identify specific cues triggering diapause induction. We examined the influence of exposure to 0 degrees C and -20 degrees C on diapause development. Diapause development in larvae stored at 0 degrees C occurred at approximately the same rate as in nature. Until 15 December the larvae were in the refractory phase of diapause (incapable of morphological development, even at permissive temperatures), but afterward moved to the activated phase within which diapause intensity decreased until termination in February. Diapause development occurred in larvae collected during the winter and stored at -20 degrees C for periods of 1 week to 3 months. Diapause intensity decreased in frozen larvae through the winter but at a slower rate than in larvae stored at 0 degrees C.     

Divergence of Eurosta solidaginis in response to host plant variation and natural enemies

We tested the hypothesis that forest and prairie populations of the gall-inducing fly, Eurosta solidaginis, have diverged in response to variation in selection by its host plant Solidago altissima, and its natural enemies. A reciprocal cross infection design experiment demonstrated that fly populations from the prairie and forest biomes had higher survival on local biome plants compared to foreign biome host plants. Flies from each biome also had an oviposition preference for their local plants. Each fly population induced galls of the size and shape found in their local biome on host plants from both biomes indicating a genetic basis to the differences in gall morphology. Solidago altissima from the prairie and forest biomes retained significant morphological differences in the common garden indicating that they are genetically differentiated, possibly at the subspecies level. The populations are partially reproductively isolated as a result of a combination of prezygotic isolation due to host-associated assortative mating, and postzygotic isolation due to low hybrid survival. We conclude that E. solidaginis is undergoing diversifying selection to adapt to differences between prairie and forest habitats.     

Mild winter temperatures reduce survival and potential fecundity of the goldenrod gall fly, Eurosta solidaginis (Diptera: Tephritidae)

We tested the hypothesis that mild winter temperatures are detrimental to the survival and reproductive potential of insects. We measured survival, body size, and potential fecundity of a freeze tolerant insect, the goldenrod gall fly (Eurosta solidaginis), after overwintering in the laboratory for ~3 mo. frozen at -22 degrees C, unfrozen at 0 degrees C, or unfrozen at 12 degrees C. Larvae held at 12 degrees C suffered high mortality (70%) and relatively low potential fecundity as adults (mean+/-SEM=199+/-11 eggs/female), while those held at 0 degrees C had both low mortality (11%) and high potential fecundity (256+/-15 eggs/female). Freezing (-22 degrees C) increased mortality (30% overall) but did not significantly reduce fecundity (245+/-13 eggs/female). Egg length and width were constant regardless of treatment group or female body size. Analysis of covariance indicated that reduced fecundity in the 12 degrees C group was related to reduced larval body weight following treatment. Patterns of larval weight loss in the experimental treatments were generally correlated with previous reports of latitudinal trends in weight loss through the winter. We conclude that mild winter temperatures may be detrimental to some overwintering insects, particularly species that do not feed following winter diapause. Low temperature and even freezing are beneficial, allowing conservation of energy reserves to maintain high survival and potential fecundity.     

The distribution of risk and density-dependent mortality in the galls of Eurosta solidaginis, the goldenrod gall fly

ABSTRACT.

• 1 This paper explores the net effect of a suite of mortality factors on a sedentary prey, the larvae of the goldenrod gall fly, Eurosta solidaginis Fitch (Diptera: Tephritidae).
• 2 Mortality is caused by unknown factors early in larval development, two species of parasitoid wasp (Hymenoptera: Eurytomidae), an inquiline beetle larva (Coleoptera: Mordellidae), and during the winter months downy woodpeckers Picoides pubescens (L.).
• 3 Distribution of mortality among galls relative to prey (gall) distribution was measured and discussed with respect to the distribution of relative risk of predation.
• 4 Galls are by and large contagiously distributed among quadrats, and mortality is distributed in a comparable pattern to that of galls.
• 5 The pattern of mortality on Eurosta larvae is neither density-dependent nor aggregated independently of gall distribution. Persistence in the system is probably a result of a combination of other factors such as adult mortality and early larval death which may have intergenerational density-dependent effects, and the linkage of locally unstable sub-populations via migration.

     

31P-NMR studies of the freeze-tolerant larvae of the gall fly, Eurosta solidaginis

31P NMR was applied to an examination of the freeze-tolerant larvae of the gall fly, Eurosta solidaginis. Resonances from sugar phosphates, inorganic phosphate, adenylates and arginine phosphate were identified. Two peaks of Pi were identified corresponding to intracellular and extracellular Pi. Anoxia produced an expected decrease in peak intensities of ATP and arginine phosphate while the peak of intracellular Pi was enhanced and shifted to indicate intracellular acidification during anoxia. Spectra of whole larvae were monitored over a temperature range from -30 degrees to +25 degrees C. No abrupt alterations in the spectra were seen at the point of extracellular freezing which occurs at about -8 degrees C but temperature had dramatic effects upon the peak intensities of ATP and arginine phosphate. A reversible increase/decrease in peak intensities, relative to Pi, was observed as temperature was raised/lowered. At 15 degrees and -20 degrees C, the beta peak of ATP was 64% and 2% of the peak intensity of Pi while that of arginine phosphate was 78% and 11%, respectively. This temperature effect was not an artifact of instrumentation (as model solutions containing Pi, ATP and arginine phosphate did not show this effect) or a result of changes in the total amounts of these compounds in the cell with temperature. Rather it is apparent that these molecules become restricted in their rotational movement as temperature is lowered perhaps via binding to subcellular components. Changes in the amounts of freely soluble ATP and arginine phosphate with temperature could have important implications for metabolism and its control. Analysis of the effect of temperature on the chemical shift of Pi was also used to determine pH in the intracellular and extracellular compartments. Temperature change had no effect on extracellular (hemolymph) pH which remained constant at 6.1-6.3. Intracellular pH varied with temperature, however, from pH 6.8 at 15 degrees C to pH 7.3 at -12 degrees C with a change, delta pH/delta 0, of -0.0185 degrees C consistent with alphastat regulation.     

Cuticular lipids and desiccation resistance in overwintering larvae of the goldenrod gall fly, Eurosta solidaginis (Diptera: Tephritidae)

Within their gall, larvae of the goldenrod gall fly (Eurosta solidaginis) experience severe desiccating conditions as well as highly variable thermal conditions and extreme cold during winter. Through the autumn and early winter, field-collected larvae acquired markedly enhanced resistance to desiccation and freezing. At the same time, they increased their cuticular surface hydrocarbons. Hydrocarbons were the major lipid class extracted by hexane or chloroform from the cuticular surface of overwintering gall fly larvae. The major hydrocarbon classes were the 2-methylalkanes which consisted mainly of 2-methyltriacontane. 2-Methyltriacontane comprised 48-68% of the total hydrocarbons during the larval stages. Total hydrocarbons increased from 122 ng/larva in early third instar larvae collected in September to 4900 ng/larva in those collected in January. Although washing of the cuticular surface with chloroform or chloroform:methanol (2:1, v:v) caused marked increases in rates of water loss, treatment with hexane and methanol had little effect on water loss rates.     

Ultrastructural effects of lethal freezing on brain,muscle and Malpighian tubules from freeze-tolerant larvae of the gall fly,Eurosta solidaginis

In preparation for winter low temperatures, larvae of the gall fly, Eurosta solidaginis, accumulate the cryoprotectants glycerol, sorbitol, and trehalose. The fat body cells of these freeze-tolerant larvae can survive intracellular freezing to -80 degrees C for 48 h even though no whole larvae survive this treatment. We hypothesized that some other tissue was more susceptible to freezing and therefore may be responsible for larval death. This paper compares the ultrastructure of brain, muscle, and Malpighian tubules between non-lethally frozen and lethally frozen freeze-tolerant larvae. The nuclei of cortical brain cells from lethally frozen larvae exhibited clumped chromatin and nuclear membranes with occasional expansions or 'blebs' of the intermembranous space, while the cytoplasm contained swollen spheres of endoplasmic reticulum. In contrast, non-lethally frozen brain contained nuclei with evenly dispersed chromatin, smooth nuclear membranes and a cytoplasm free of swollen endoplasmic reticulum. Muscle tissue of lethally frozen larvae contained disrupted myofilaments surrounding the Z-line in comparison to non-lethally frozen muscle which had myofilaments extending all the way to the Z-line. Alterations of Malpighian tubule cells from lethally frozen larvae included an extracted cytoplasm with swollen and rounded mitochondria. In contrast, Malpighian tubule cells from non-lethally frozen larvae had a more concentrated cytoplasm with many rod-shaped mitochondria. Results show alterations to all three tissue types due to lethal freezing. The brain tissue contained the most observable alterations and therefore may be the most susceptible to lethal freeze damage.     

Energy and water conservation in frozen vs. supercooled larvae of the goldenrod gall fly, Eurosta solidaginis (fitch) (Diptera: Tephritidae)

Insects that tolerate severe cold during winter may either supercool or tolerate ice forming within the tissues of the body. To compare the relative advantages of freezing and supercooling, we measured rates of CO(2) production and water loss in frozen and supercooled goldenrod gall fly larvae (Eurosta solidaginis). As an important first step, we measured the time required for ice content and metabolic rate to stabilize upon freezing. Ice content stabilized after only three hours of freezing at -5 degrees C, whereas CO(2) production required 12 hours to stabilize. Subsequent experiments found that freezing greatly reduced both water loss and metabolic rate. Comparisons of supercooled and frozen larvae at -5 degrees C indicated that CO(2) production fell 47% with freezing and water loss decreased 35%. As temperature decreased to -10 and -15 degrees C, CO(2) production fell exponentially and was no longer detectable at -20 degrees C with our measurement system. Our results demonstrate that freezing significantly reduces energy consumption during the winter and may therefore improve winter survival and spring fecundity. The advantages of freezing over supercooling would drive selection toward insect freeze tolerance and also toward higher supercooling points to increase the duration of freezing each winter.