The temperature and humidity preferences of Haemaphysalis longicornis,ixodes holocyclus and Rhipicephalus sanguineus (ixodidae): Studies on engorged larvae

The engorged larvae of Haemaphysalis longicornis, Ixodes holocyclus and Rhipicephalus sanguineus were exposed to a range of temperatures and humidities to see whether the nature of their requirements in the laboratory were similar to the climate within the geographic range of each species. The response of H. longicornis and I. holocyclus to changes in humidity was also studied. Moulting of I. holocyclus larvae occurred from 18 to 28°C and at a saturation deficit of 4 mm Hg or less. The larvae of R. sanguineus moulted between 18 and 38°C and tolerated saturation deficits up to 35 mm Hg. The larvae of H. longicornis moulted between 15 and 38°C at saturation deficits up to 8 mm Hg. When engorged larvae of H. longicornis and I. holocyclus were exposed to very dry conditions for different periods of time and then transferred to moist conditions, the minimum pre-moult period and mortality was increased in comparison with larvae kept continuously under moist conditions. On the other hand, mortality of H. longicornis larvae was reduced in very dry conditions provided that they had been exposed to a moist environment for about 5 days previously. The larvae of I. holocyclus required at least 12 days exposure to a moist environment before any survived to moult in moderately dry conditions. The engorged larvae of both H. longicornis and I. holocyclus lost weight rapidly in dry air, whereas weight loss from R. sanguineus larvae was much slower. The rate of development was fastest in R. sanguineus and slowest in I. holocyclus.     

The temperature and humidity preferences of Haemaphysalis longicornis, Ixodes Holocyclus and Rhipicephalus sanguineus (Ixodidae): studies on eggs

The eggs of Haemaphysalis longicornis, Ixodes holocydus and Rhipicephalus sanguineus were exposed to a range of temperatures and humidities to compare the temperature and humidity requirements of ticks from climatically dissimilar habitats. The response to changes in humidity was also studied with H. longicornis. Hatching in I. holocydus eggs occurred from 18 to 28°C and at a saturation deficit of 2 mm Hg or less. The eggs of R. sanguineus hatched between 18 and 38°C and tolerated saturation deficits up to 20 mm Hg. The eggs of H. longicornis hatched between 18 and 35°C and at saturation deficits up to 8 mm Hg. When eggs of H. longicornis were exposed to moderately dry conditions for different periods of time and then transferred to moist conditions, incubation periods and mortality were reduced in comparison with eggs kept continuously under dry conditions. On the other hand, mortality of H. longicornis eggs was reduced in moderately dry conditions, provided that they had been exposed to a moist environment for about 10 days previously. Weight loss of eggs in dry air and the rate of development of eggs were examined and are discussed. The eggs of I. holocylus lost weight very rapidly in dry air, whereas weight loss from R. sanguineus eggs was much slower. Weight loss from H. longicornis eggs fell between these two rates. The rate of development was fastest in R. sanguineus and slowest in I. holocydus.     

Critical thermal limits, temperature tolerance and water balance of a sub-Antarctic kelp fly, Paractora dreuxi (Diptera: Helcomyzidae)

Paractora dreuxi displays distinct ontogenetic differences in thermal tolerance and water balance. Larvae are moderately freeze tolerant. Mean larval onset of chill coma was -5.1 degrees C, and onset of heat stupor was 35.5 degrees C. Larval supercooling point (SCP) was -3.3 degrees C with 100% recovery, although mortality was high below -4 degrees C. Starvation caused SCP depression in the larvae. Adults were significantly less tolerant, with critical thermal limits of -2.7 and 30.2 degrees C, no survival below the SCP (-9.6 degrees C), and no change in SCP with starvation. Moderate freeze tolerance in the larvae supports the contention that this strategy is common in insects from southern, oceanic islands. Fly larvae survived desiccation in dry air for 30 h, and are thus less desiccation tolerant than most other sub-Antarctic insect larvae. Water loss rates of the adults were significantly lower than those of the larvae. Lipid metabolism did not contribute significantly to water replacement in larvae, which replaced lost body water by drinking fresh water, but not sea water. Kelp fly larvae had excellent haemolymph osmoregulatory abilities. Current climate change has led to increased temperatures and decreased rainfall on Marion Island. These changes are likely to have significant effects on P. dreuxi, and pronounced physiological regulation in larvae suggests that they will be most susceptible to such change.     

Climatic signals from loess-soil sequences in the central Great Plains, USA

Late Quaternary eolian deposits and buried soils in the central Great Plains are interpreted to reflect the fluctuation of climatic conditions under which they formed. The Loveland Loess was deposited approximately between 500 and 100 ka. Within the loess are four zones of pedogenic carbonate accumulation: after 416 ± 35 ka; before 260 ± 25 ka; around 193 ± 22 ka; and before 92 ± 7.0 ka. The pedogenic carbonate zones were probably formed under warm and dry conditions. The moderately weathered Barton sand at the Barton section and the equivalent Sandy Silt II at other sections, deposited between 92 ± 7.0 and 69 ± 6.4 ka, suggest windy, probably warm, and fluctuating moisture consitions. A reddish pedocomplex was formed from 70 to 35 ka under relatively warm and moist climatic conditions with a very low rate of loess deposition. Overlying the reddish pedocomplex is the Sandy Silt I, probably a stratigraphic equivalent to the Roxana Silt dated at 40−30 ka in the Central Lowlands. The Gilman Canyon Formation (35−20 ka), a thick cumulic loessial and organic-matter-rich pedocomplex, developed under relatively moist and probably cool conditions. The Peoria Loess was deposited at a very rapid rate under dry and cold conditions. The Brady Soil (10.5−8.5 ka) was formed under relatively warm and moist conditions. The poorly weathered Bignell Loess was deposited during the warm and dry Altithermal Period (9−5 ka).     

Development of black soldier fly (Diptera: Stratiomyidae) larvae fed dairy manure

Black soldier flies, Hermetia illucens L., are a common colonizer of animal wastes. However, all published development data for this species are from studies using artificial diets. This study represents the first examining black soldier fly development on animal wastes. Additionally, this study examined the ability of black soldier fly larvae to reduce dry matter and associated nutrients in manure. Black soldier fly larvae were fed four rates of dairy manure to determine their effects on larval and adult life history traits. Feed rate affected larval and adult development. Those fed less ration daily weighed less than those fed a greater ration. Additionally, larvae provided the least amount of dairy manure took longer to develop to the prepupal stage; however, they needed less time to reach the adult stage. Adults resulting from larvae provided 27 g dairy manure/d lived 3-4 d less than those fed 70 g dairy manure. Percentage survivorship to the prepupal or adult stages did not differ across treatments. Larvae fed 27 g dairy manure daily reduced manure dry matter mass by 58%, whereas those fed 70 g daily reduced dry matter 33%. Black soldier fly larvae were able to reduce available P by 61-70% and N by 30-50% across treatments. Based on results from this study, the black soldier fly could be used to reduce wastes and associated nutrients in confined bovine facilities.     

Observations on the bionomics of the free-living stages of Trichostrongylus vitrinus

Eggs of Trichostrongylus vitrinus in faecal pellets deposited on grass plots each month from April 1981 to March 1982 developed into infective larvae. From October to March development was slow and mortality of the pre-infective stages was very high. From April to September development was more rapid. The weather was generally dry and mortality of the pre-infective stages was high on plots with short herbage but was lower on most of the plots with long herbage, especially in July and August. In the laboratory, development of eggs into infective larvae was completed at temperatures ranging from 4 degrees C to 27 degrees C in faecal pellets which were either kept moist or dried out slowly, but not in faecal pellets which dried out rapidly. The rate of development increased as the temperature rose. Infective larvae survived for up to 16 months on the herbage of grass plots; some survived during very cold weather in the winter of 1981/82. In the laboratory, infective larvae suspended in tap water survived even longer at 4 degrees C and 10 degrees C but not at higher temperatures. They were rapidly killed by continuous freezing. They survived for up to 8 weeks when subjected to desiccation. The relationship between climatic conditions and the development and survival of the free-living stages is discussed.     

Gas exchange patterns of Pterostichus niger (Carabidae) in dry and moist air

Gas exchange patterns of adult male Pterostichus niger Schaller after hydration (i.e. given access to food and water) are compared in dry air [5–7% relative humidity (RH)] and moist air (90–97% RH) by means of flow‐through CO₂ respirometry combined with infrared probe actography. Of thirty beetles examined, slightly more than 50% showed continuous gas exchange and are not considered further. Of the remaining beetles, the majority (approximately 71%) display a pattern of cyclic gas exchange in both dry and moist air (i.e. CO₂ gas is released in bursts, with a low level of CO₂ release during the interburst periods). A minority of the beetles (four out of 30) are found to exhibit discontinuous gas exchange in both dry and moist air; this is characterized by three clearly separated states of the spiracles: closed (C), flutter (F) and open (O) phases. The pattern of cyclic gas exchange is associated with weak abdominal pulsations. After switching from moist to dry air, a small modulation of the discontinuous gas exchange cycles (maximum mean CO₂ production rate) occurs, providing no clear support for the hygric theory of discontinuous gas exchange in this species (i.e. that it serves to restrict respiratory water loss).     

Hygro- and thermoreceptive tarsal organ in the spider Cupiennius salei

Extracellular recordings were made from moist cells, dry cells and warm cells in the tip pore sensilla of the spider tarsal organ. Stimulation consisted of a rapid shift from an adapting air stream to another one at different levels of partial pressure of water vapor or of temperature. The moist and the dry cells respond antagonistically to sudden changes in humidity. Both hygroreceptors are unusual in being excited in a synergistic manner by pungent vapors of very volatile, polar substances. Presumably, the hygrosensitivity is superimposed on basically chemosensitive receptors. A moist cell at average differential sensitivity is able to discriminate two successive upward steps in humidity when they differ by 11% relative humidity. For a single dry cell, the difference required for a correct discrimination between two downward humidity steps is 10% relative humidity. The moist and the dry cells are unique in that they occur in combination with warm cells. A single warm cell at average differential sensitivity is able to resolve differences in warming steps down to 0.4°C.Abbreviations HR relative humidity - T temperature     

Hydric constraints upon foraging in a terrestrial salamander,Desmognathus ochrophaeus (Amphibia: Plethodontidae)

Summary The time until salamanders voluntarily abandoned foraging (the water time limit) and the amount of water lost when salamanders abandoned foraging (dehydration deficit) were determined for terrestrial plethodontid salamanders, Desmognathus ochrophaeus, foraging at various vapor pressure gradients in the laboratory. Salamander activity was correlated with the rate of water loss and was inversely related to the water time limit. Animals at 0.35–0.86 kPa vapor pressure gradients abandoned foraging and returned to moist retreats significantly sooner than animals in water-saturated air. The early retreat of animals in dry air was related in part to high rates of water loss and in part to the modest dehydration deficit (3.8%) at which animals abandoned foraging. Locomotor performance and foraging ability were unaffected by dehydration until dehydration deficits exceeded 12%. This suggests that salamanders in unsaturated air abandoned foraging at a low dehydration deficit to conserve and replenish water reserves rather than to avoid outright incapacitation or death. Present address: Department of Zoology, University of Guelph, Guelph, Ontario N1G 2W1, Canada     

Water balance in the sugarbeet root maggot Tetanops myopaeformis,during long‐term low‐temperature storage and after freezing

The sugarbeet root maggot Tetanops myopaeformis Röder (Diptera: Ulidiidae) can be stored in moist sand at 4–6 °C for up to 5 years and is freeze‐tolerant. The majority of stored larvae survive in a state of post‐diapause quiescence and the remainder are in a multi‐year diapause. The present study aims to determine larval water content and water loss rates in diapausing and low‐temperature stored larvae. Body water content ranges from 57% to 70.1%. Two distinct groupings of larvae are revealed based on dry weights. The first group consists of the diapausing larvae and larvae stored for 1 year. This group has significantly higher dry weights than the second grouping, which consists of the larvae stored for 2 and 3 years. There are no significant differences within each group. Larval water losses follow a first‐order kinetic relationship with time. Larvae stored for 2 years lose water at a significantly higher rate than diapausing larvae. Larvae exhibit no active water uptake at storage temperatures. A freezing event does not induce a significant decrease in wet weights, nor does it increase larval water loss rates. These results indicate that metabolic water and the microclimate during storage are key factors enabling the long‐term survival of T. myopaeformis larvae during low‐temperature storage, and may provide insights for maintaining other insect species under similar conditions.     

Identification of a gene, Desiccate, contributing to desiccation resistance in Drosophila melanogaster

Suitable alterations in gene expression are believed to allow animals to survive drastic changes in environmental conditions. Drosophila melanogaster larvae cease eating and exit moist food to search for dry pupation sites after the foraging stage in what is known as the wandering stage. Although the behavioral change from foraging to wandering causes desiccation stress, the mechanism by which Drosophila larvae protect themselves from desiccation remains obscure. Here, we identified a gene, CG14686 (designated as Desiccate (Desi)), whose expression was elevated during the wandering stage. The Desi expression level was reversibly decreased by transferring wandering larvae to wet conditions and increased again by transferring them to dry conditions. Elevation of Desi expression was also observed in foraging larvae when they were placed in dry conditions. Desi encoded a 261-amino acid single-pass transmembrane protein with notable motifs, such as SH2 and PDZ domain-binding motifs and a cAMP-dependent protein kinase phosphorylation motif, in the cytoplasmic region, and its expression was observed mainly in the epidermal cells of the larval integuments. Overexpression of Desi slightly increased the larval resistance to desiccation stress during the second instar. Furthermore, Desi RNAi larvae lost more weight under dry conditions, and subsequently, their mortalities significantly increased compared with control larvae. Under dry conditions, consumption of carbohydrate was much higher in Desi RNAi larvae than control larvae. Based on these results, it is reasonable to conclude that Desi contributes to the resistance of Drosophila larvae to desiccation stress.     

Influence of the Season and of Preservation Methods on Wet- and Dry Weights of Larvae of Chironomus plumosus L

Preservation in 70% ethanol or 4% formaldehyde solution resulted in the leaching of ca. 30% arid ca. 10% dry matter, respectively. Subsequent soaking in water considerably increased leaching. The percent ratio of dry weight to live weight decreased during the summer from ca. 15% in June to ca. 11 % in September for the fourth instar larvae. The results indicate that formaldehyde can chemically react with the larvae, thereby increasing their dry weight. The dry weight of the gut content was ca. 4% of the total dry weight.     

Utilisation of prey by antlion larvae (Neuroptera: Myrmeleontidae) in terms of energy and nutrients

Prey utilisation at low prey densities was determined for third instar Cueta sp., Furgella intermedia (Markl) and Palpares annulatus (Stitz) larvae in terms of wet weight, dry weight, energy and nutrients. Prey utilisation was similar to other insects on a wet weight (42-47%), dry weight (46-49%), energetic (40-58%) and nutritive basis (62-79%). Lipids (33-36%) provided energetically the highest contribution of the nutrients ingested. The quantities of water, proteins, nucleic acids, lipids and carbohydrates extracted by the antlion larvae were in proportion to their availability in their prey, the Hodotermes mossambicus larvae. The quantities of nutrients extracted by the antlion larvae at low prey densities were not significantly influenced by the differences in mandible size, antlion body weight or the trapping method (building a pit or not) of the antlion species. It is proposed that a low metabolic rate and the accumulation of fat reserves, and not the extent of prey utilisation, enable P. annulatus larvae to tolerate a 123-d starvation period in which 22.3% of their body weight is lost.     

Respiration in the larvae of the ants Myrmica scabrinodis and Lasius flavus

ABSTRACT. Respiratory rates of larvae of Myrmica scabrinodis Nyl. and Lasius flavus Fab. were measured at 5, 15 and 25°C using the micro-Warburg technique. Larvae collected in the winter and spring were a mixture of all three castes. In the summer collection it was possible to separate the gyne-potential larvae from the others by virtue of their greater size. The respiration of the larvae of both species showed a decreasing response to temperature as they developed. The winter larvae of L. flavus could be categorized into two groups on the basis of the proportions of dry matter. They were also significantly different in their weight-specific respiratory rate, and their response to temperature changes. Gyne larvae were about 7 times as heavy as the others, but their weight-specific respiratory rate was the same as in the other larvae in M. scabrinodis and actually higher in L. flavus. The highest respiratory rates occurred when the dry matter content of the larvae was lowest, in the summer collection for M. scabrinodis and the spring collection for L. flavus.     

Physical and physiological characteristics of Trogoderma glabrum infected with the schizogregarine pathogen Mattesia trogodermae

Physical and physiological characteristics of an infection of Trogoderma glabrum by Mattesia trogodermae were studied. Weights of infected larvae drop markedly between 10 and 20 days post-infection at 30° and 35°C. This loss is less abrupt and not as great when the incubation temperature is 25°C. Reduction of dry matter is gradual during the first 12 days of infection, but drops 70% from 12 to 20 days post-infection.Glycogen reserves in both infected and control insects drop 50% within 3 days after deprivation of food. Healthy insects recover and begin to reconstitute lost glycogen; however, infected larvae continue to deplete glycogen to 15% of prestarvation levels. Similarly, insect protein is reduced 40% within 7 days after starvation and noninfected insects apparently halt protein metabolism at this level. Diseased larvae continue to lose protein to 20% of prestarvation amounts. These losses are at least partially attributable to insect metabolism since infected insects defecate significantly more than control larvae. It is thought that defecation is an effective route of water loss which occurs during the first 20 days of infection. Relative humidities ranging from 0 to 84% had no obvious effects on mortality rates, indicating that water loss is effected through routes other than evaporation through the cuticle, e.g., failure of water retention systems and elimination of body water with feces.     

Desiccation resistance in pre-diapause, diapause and post-diapause larvae of Choristoneura fumiferana (Lepidoptera: Tortricidae)

Desiccation resistance was examined in pre-diapause, diapause and post-diapause larvae of the spruce budworm, Choristoneura fumiferana (Clemens), in terms of passive water evaporation under three desiccation conditions: freeze-drying, desiccant-drying at 2 degrees C and desiccant-drying at 18 degrees C. Diapausing second instar larvae and post-diapause non-feeding second instar larvae showed strongest desiccation resistance: a significant amount of water was retained after repeated drying under desiccating conditions, while pre-diapause first instar larvae and post-diapause feeding second instar larvae lost almost all their water content after one or two drying cycles. A hibernaculum covering had no effect on water evaporation. While dead larvae tended to lose significantly more water than their living counterparts, particularly among first instar larvae, such an impact was much weaker among diapausing second instar larvae. Desiccation resistance was lost when post-diapause second instar larvae were allowed access to water while the level of desiccation resistance was maintained or enhanced when the larvae did not have access to water. These results are discussed in the context of overwintering ecology of the species and possible mechanisms for the desiccation resistance are also discussed.     

Food and water economy and its relation to growth in fifth-instar larvae of the tobacco hornworm, Manduca sexta

Fifth-instar larvae of Manduca sexta were reared on artificial diet at 25°C. Daily measurement of the wet and dry weights of insects, food eaten and faeces produced, allowed the construction of detailed budgets for food and water economy.Approximate digestibility (AD) was about 60% both in dry weight and energetic terms. This did not change significantly on successive days of the instar, despite the very considerable changes that occur in the size of the insect and the amount of food eaten during the same period. Two indices of conversion efficiency (ECI and ECD) also showed only insignificant changes during this time. ECI and ECD were both very high: at their maximal values, ECI was 43% (51% in energy terms) and ECD was 72% (81% in energy terms).Correction of the nutritional indices for the presence of food in the gut reduced their value slightly in all cases.Most of the water requirements of the larva were provided by the diet. The estimated gain from metabolic water was between 3.5 and 10% of the total water input. Faeces accounted for most of the water lost from the body; under our conditions transpirational losses were very small. Almost half of the water taken up with the food was retained in the body.The gut contents are more hydrated than the food. The faeces contain less water than the gut contents. It is suggested that the caterpillars recycle water by absorbing it from the faeces and returning it to the contents of the midgut. A quantitative model of such water movement within the body is presented. The data provide indirect evidence that caterpillars may optimise the retention time of food in the gut (and thus the AD) in order to maximise the absolute rate of nutrient uptake from it.     

Mechanisms to reduce dehydration stress in larvae of the Antarctic midge, Belgica antarctica

The Antarctic midge, Belgica antarctica, is exposed to frequent periods of dehydration during its prolonged larval development in the cold and dry Antarctic environment. In this study, we determined the water requirements of the larvae and the mechanisms it exploits to reduce the stress of drying. Larvae lost water at an exceptionally high rate (>10%/h) and tolerated losing a high portion (>70%) of their water content. Larvae were unable to absorb water from subsaturated water vapor (< or = 0.98 a(v)) to replenish their water stores, thus this midge relies exclusively on the intake of liquid water to increase its pool of body water and maintain water balance. To reduce dehydration stress, the midge employed a variety of mechanisms. Behaviorally, the larvae suppressed water loss by clustering. In response to slow dehydration, glycerol concentration increased 2-fold and trehalose concentration increased 3-fold, responses that are known to decrease the rate of water loss and increase dehydration tolerance. No changes in the mass of cuticular lipids occurred in response to desiccation, but the observed shift to longer hydrocarbons likely contributes to reduced water loss as the larvae dehydrate. As the larvae dehydrated, their oxygen consumption rate dropped, resulting in a reduction of water loss by respiration. Lastly, one bout of slow dehydration also enhanced the larva's ability to survive subsequent dehydration, suggesting that the larvae have the capacity for drought acclimation. Thus, these hydrophilic midge larvae prevent dehydration by multiple mechanisms that collectively reduce the water loss rate and increase dehydration tolerance.     

Water uptake in the cat flea Ctenocephalides felis (Pulicidae: Siphonaptera)

To counteract water loss due to excretion, cuticular transpiration and respiration, various groups of arthropods have developed mechanisms for active uptake of water vapor from unsaturated air. In this study, active uptake capabilities and water loss rates were examined in the various developmental stages of the cat flea, Ctenocephalides felis. To determine critical equilibrium humidity, the lowest relative humidity at which active water uptake can occur, pre-desiccated immature and adult fleas were placed in a series of humidity regimes ranging from 44 to 93% RH. Active uptake occurred in larval stages at relative humidities above 53% and in pre-pupae at 75-93% RH. Pupae and adults did not demonstrate active uptake at any humidity. Optimal uptake for larvae occurred between 20 and 30 degrees C. When placed over Drierite (<10% RH), larval and adult stages demonstrated a higher rate of water loss than pre-pupal and pupal stages. Active water uptake is necessary to ensure proper development of the larvae of C. felis. Active uptake ceases after the larval-pupal ecdysis and it appears that adults have lost the ability to actively uptake water.     

Microclimate,diurnal rhythms and the conquest of the land by arthropods

Summary A review is given of the adaptations of arthropods to life on land. The terrestrial Arthropoda are divided ecologically into two main groups. The first of these includes woodlice, centipedes, miilipedes and their allies which lose water rapidly in dry air and consequently are restricted to damp, dark habitats which they leave only at night when the temperature falls and the relative humidity of the air rises. The second group includes most insects and Arachnida: these are comparatively independent of moist surroundings because their integument possesses an impervious layer of wax which prevents desiccation.