Influence of temperature and carbon dioxide concentration on juvenile hormone titre and dependent parameters of adult worker honey bees (Apis mellifera L.)

It is known that juvenile hormone plays an important role in the regulation of labour division and of the different life spans, and that the microclimate of the bee hive is characterized by its high CO₂ concentration and its varying temperature depending on the presence of brood.We have investigated the influence of microclimates characteristic of breeding and broodless areas on the juvenile hormone titre in the haemolymph and whole body extracts, on the corpora allata in vitro activity, on the degradation of juvenile hormone and on the dry weight of the hypopharyngeal glands using bees of known ages. A microclimate of 35°C and 1.5% CO₂, as observed in the breeding area, induces a rapid and pronounced increase in the juvenile hormone titre. On the other hand, this titre remains low in bees kept at 27°C and 1.5% CO₂, a microclimate associated with broodless combs. Rates of juvenile hormone synthesis by corpora allata in vitro were found to be extremely low, even in the presence of farnesenic acid, and not related to the juvenile hormone titre. In vitro incubation of juvenile hormone in haemolymph revealed no degradation while injected juvenile hormone was found to be degraded and taken up by the gut at rates only weakly correlated with the juvenile hormone titre.We propose a hypothetical model for the regulation of the juvenile hormone titre as well as the course of labour division by the varying microclimates observed in the bee hive.     

Seasonal changes in juvenile hormone titers and rates of biosynthesis in honey bees

Honey bee colonies can respond to changing environmental conditions by showing plasticity in age related division of labor, and these responses are associated with changes in juvenile hormone. The shift from nest taks to foraging has been especially well characterized; foraging is associated with high juvenile hormone titers and high rates of juvenile hormone biosynthesis, and can be induced prematurely in young bees by juvenile hormone treatment or by a shortage of foragers. However, very few studies have been conducted that study plasticity in division of labor under naturally occurring changes in the environment. To gain further insight into how the environment and juvenile hormone influence foraging behavior, we measured juvenile hormone titers and rates of biosynthesis in workers during times of the year when colony activity in temperate climates is reduced: late fall, winter, and early spring. Juvenile hormone titers and rates of biosynthesis decreased in foragers in the fall as foraging diminished and bees became less active. This demonstration of a natural drop in juvenile hormone confirms and extends previous findings when bees were experimentally induced to revert from foraging to within-hive tasks. In addition, endocrine changes in foragers in the fall are part of a larger seasonally related phenomenon in which juvenile hormone levels in younger, pre-foraging bees also decline in the fall and then increase the following spring as colony activity increases. The seasonal decline in juvenile hormone in foragers was mimicked in summer by placing a honey bee colony in a cold room for 8 days. This suggests that seasonal changes in juvenile hormone are not related to photoperiod changes, but rather to changes in temperature and/or colony social structure that in turn influence endocrine and behavioral development. We also found that active foragers in the late winter and early spring had lower juvenile hormone levels than active foragers in late spring. In light of recent findings of a possible link between juvenile hormone and neuroanatomical plasticity in the bee brain, these results suggest that bees can forage with low juvenile hormone, after previous exposure to some threshold level of juvenile hormone leads to changes in brain structure.     

Juvenile hormone titres and metabolism during starvation-induced supernumerary larval moulting of the tobacco hornworm, Manduca sexta L.

When tobacco hornworm (manduca sexta) larvae are starved for 5 days immediately after ecdysis to the 5th instar, then fed normal diet, they undergo a supernumerary moult instead of metamorphosis. During starvation the titre of juvenile hormone in the haemolymph increased to a maximum of 3 ng juvenile hormone I equivalents/ml (determined by the black Manduca larval bioassay) on the fourth day of starvation, then began a decline which continued through the subsequent feeding period. The changes in juvenile hormone titre were not attributable to changes in haemolymph volume during starvation (only a 5% decrease) and subsequent feeding. During starvation the esterase activity of the haemolymph declined 4-fold with a 2-fold larger decrease in the DFP-insensitive, presumably juvenile hormone specific, esterase activity. Both the total and the juvenile hormone-specific esterase activity then increased as a function of larval weight during the subsequent feeding period. As growth was slow in the prolongedly starved larvae, sufficient juvenile hormone was present at the time of prothoracicotropic hormone (PTTH) and ecdysteroid release at the beginning of the fourth day of feeding to prevent metamorphosis.     

Identification of the juvenile hormone from the cricket, Teleogryllus commodus, and juvenile hormone titre changes

In the cricket, Teleogryllus commodus, eggs, haemolymph of 7th and 8th (last)-larval instars, and haemolymph of adults of both sexes contain only juvenile hormone III. While in the male the hormone titre is independent of previous mating experience, juvenile hormone concentration in haemolymph taken from females 36–38 hr after mating (an event which is followed by oviposition) is at a level 5 times higher than that of virgin females. Based on data gleaned from several research groups the identification of juvenile hormone III as the exclusive juvenile hormone in the Order Orthopteroidea is discussed.     

Quantitative studies on the activity of the corpora allata in adult male Locusta and Schistocerca

Juvenile hormone has been detected in the haemolymph and corpora allata of adult male Locusta and the haemolymph of adult male Schistocera by a modified Galleria bioassay. The hormone was readily detected in the haemolymph of insects immediately after the final ecdysis, but then became difficult to detect until 2 days prior to the onset of sexual maturation. In sexually mature insects the titre of juvenile hormone was maintained at a constant level. The corpora allata of adult male Locusta increased in size throughout adult life. The juvenile hormone content of the corpora allata was low during the period of somatic growth, but increased at the onset of sexual maturation. Sectioning of the nervi corporis allati I in insects immediately after the final ecdysis prevented the normal increase in size of the corpora allata, but did not render them inactive since juvenile hormone was detected in the haemolymph after the operation. The half life of juvenile hormone in the haemolymph of allatectomized adult male Locusta was 1 to 2 hr.     

Inhibition of vitellogenin synthesis in Apis mellifera workers by a juvenile hormone analogue,pyriproxyfen

Insect juvenile hormone (JH) has been related to modulation of vitellogenin (Vg) synthesis, a protein produced by fat body cells, secreted in haemolymph and sequestered by developing oocytes. A stimulatory JH action has been described for the majority of species studied thus far. In some insects, however, Vg synthesis has been inhibited or unaffected by JH. The aim of this study was to re-examine the action of JH on Vg synthesis in Apis mellifera workers, since contrasting effects of this hormone were described. Newly emerged worker bees were treated with different doses of pyriproxyfen (PPN), a potent JH analogue. Vg and total protein were quantified in haemolymph samples of newly emerged up to 6-day-old worker bees. Protein synthesis activity of fat body cultured in vitro and ultrastructure of fat body cells were also examined. High doses (1.25, 2.5, 5 and 10 &mgr;g) of PPN inhibited the onset and accumulation of Vg in the haemolymph of young worker bees in a dose-dependent fashion. This inhibition was not a result of fat body cell degeneration or death, as illustrated by fat body cells ultrastructure analysis, but by impairing Vg synthesis, as demonstrated by in vitro culture of fat body cells. Low doses (0.001, 0.01 and 0.1 &mgr;g) neither affected the normal synthesis and secretion of Vg into the haemolymph nor caused an early onset of Vg in treated bees (which could be interpreted as a JH-activating effect), as shown by Vg quantification at 24-h intervals. The results suggest that a low JH titre in honey bee workers permits the onset and accumulation of Vg in haemolymph, whereas high JH levels turn off Vg synthesis.     

Juvenile hormone esterases in diapause and nondiapause larvae of the European corn borer, Ostrinia nubilalis

Haemolymph levels of juvenile hormone esterase, 1-naphthyl acetate esterase, and juvenile hormone were measured in synchronously staged diapause and nondiapause larvae of the European corn borer, Ostrinia nubilalis. Juvenile hormone esterase levels were monitored using juvenile hormone I as a substrate while juvenile hormone titres were measured with the Galleria bioassay. Haemolymph of nondiapause larvae showed two peaks of juvenile hormone hydrolytic activity: one near the end of the feeding phase and a smaller one just prior to pupal ecdysis. These peaks of enzyme activity correlated well with the low levels of haemolymph juvenile hormone. Juvenile hormone titres were high early in the stadium then showed a second peak during the prepupal stage coinciding with low esterase activity. Diapause haemolymph had peak juvenile hormone esterase activity nearly 4 times the nondiapause level, reaching a peak near the end of the feeding phase. Diapause-destined larvae retained high juvenile hormone titres even during the rise of the high esterase levels. 1-naphthyl acetate esterase levels did not correlate with the juvenile hormone esterase levels in either the diapause or nondiapause haemolymph. High levels of 1-naphthyl acetate esterase activity were associated with moulting periods.     

Effect of juvenile hormone on acid phosphatase activity in six tissues of the milkweed bug

After juvenile hormone treatment on day of ecdysis, the haemolymph, salivary glands, gut, cuticle, testes, and fat body of the fifth instar male milkweed bug were assayed for acid phosphatase activity at daily intervals throughout the instar. Increased acid phosphatase activity after juvenile hormone treatment was found in the haemolymph at the beginning of the instar, in the haemolymph and salivary glands in the middle of the instar, and in the testes near the end of the instar. The significance of these findings is discussed.     

Role of juvenile hormone in regulating tyrosine glucoside synthesis for pupal tanning in Manduca sexta (L.)

Tyrosine glucoside (α-d-glucopyranosyl-O-l-tyrosine) serves as a reservoir of tyrosine and glucose for pupal and adult cuticle formation, tanning, and pigmentation in several Lepidopteran insects. In the tobacco hornworm, Manduca sexta (L.), detectable quantities appear in the haemolymph 1–2 days after ecdysis of the fifth instar and very high concentrations accumulate between the fourth and eighth days of the stadium. If juvenile hormone II or a mimic (methoprene) is injected into fifth-instar larvae at 24-h intervals after ecdysis, tyrosine glucoside synthesis is almost completely suppressed. Temporary starvation of newly ecdysed larvae that results in the maintenance of a high endogenous juvenile hormone titre, also suppresses and delays the onset of tyrosine glucoside synthesis. The decrease and eventual disappearance of juvenile hormone after ecdysis of the last-larval instar appears to be a necessary prerequisite for the synthesis or activation of tyrosine glucoside synthetase along with the initiation of other metamorphic events.     

Juvenile hormone and aggression in honey bees

We determined whether defense by individual bees against non-nestmates in honey bees (Apis mellifera) is correlated with their juvenile hormone (JH) titers, which are known to vary developmentally and seasonally. We bioassayed winter and summer bees for aggressive and non-aggressive individuals. Bees in winter could not be distinguished by task group, but bees in summer were segregated into nurses and guards. JH titers were correlated with aggressive behavior at two levels. First, winter bees and summer nurses, known to have lower JH titers, both showed less aggression toward foreign bees than did summer guards. Second, aggressive individuals had significantly higher JH titers than did non-aggressive bees within each colony. Inter-colonial variation in aggressiveness was maintained during summer and winter, suggesting a genetic basis for these differences. An alarm pheromone test further substantiated the existence of inter-colonial differences. We found significant variation in JH titers among different colonies, but this variation was not significantly associated with colony-level aggressiveness. The correlation between JH and levels of aggressiveness within a colony suggests a regulatory role for JH, but variation among colonies involves factors other than JH.     

The significance of free ecdysteroids in the haemolymph of adult cockroaches

The existence of ecdysteroids in the haemolymph of adult Periplaneta americana has been demonstrated for the first time. It appears that 20-hydroxyecdysone is responsible for most of the observed RIA activity. There is a relatively high titre (28.7 ± 3.7 ng/ml) in females immediately after adult emergence, a decrease over the next 5 days, and a new peak (20.3 ± 4.1 ng/ml) towards the end of the first gonotrophic cycle. The post-emergence peak is also apparent in males, and the titre similarly falls over the next few days. However, the subsequent increase does not occur and the second peak is evidently lacking. The female-specific peak can be abolished by surgical removal of the ovaries, and its appearance is similarly prevented when ovarian development is precluded by allatectomy. The evidence suggests that the ovaries are a major source of haemolymph ecdysteroids in adult females of this species. It remains to be seen whether the female-specific peak is merely the result of an inconsequential leakage from developing oöcytes, or is indeed the secretion of a true hormone with a specific function, possibly the suppression of corpus allatum activity at the time of chorion formation. Certainly, we find no evidence for any involvement of haemolymph ecdysteroids in the suppression of juvenile hormone biosynthesis which accompanies enforced virginity or prolonged starvation in P. americana.The significance of these results is discussed both in relation to other titre determinations and to the evolution of corpus allatum regulation in the Blattaria, with additional comments concerning the humoral environment that prevails when certain juvenile hormone-dependent genes are expressed in the adult female.     

Recovery by the Norway lobster Nephrops norvegicus (L.) from the physiological stresses of trawling: Influence of season and live-storage position

Live Norway lobsters (Nephrops norvegicus L.) were trawled at depths of 30 to 55 m off the coast of Jutland (Denmark) in late winter (March) and in summer (August) in 2006. Water temperatures at the bottom and surface of the sea were 7 °C and 2 °C during the winter, and 12 °C and 21 °C in the summer, respectively. The recovery of specific physiological and metabolic variables from the intense stresses associated with capture (trawling and air-exposure during sorting) was followed in seawater at 5 °C in winter or 18 °C in summer. Recovery was compared in lobsters held individually in two different live-storage positions, either resting vertically on the tail or sitting horizontally. In winter, many animals were alive when brought on board and approximately 86% were still alive at the end of experimentation (96 h). In summer very few animals were alive when brought on board and, of these, approximately 95% were dead at 24 h. When compared with values measured in laboratory controls, the stresses of capture elicited very high haemolymph lactate contents in both seasons, although levels recovered within 24 h. Trawling also caused very high haemolymph glucose concentrations, which differed with season. In winter, haemolymph glucose was elevated for 24 h to levels significantly higher than in summer. In summer, glucose had returned to control levels by 4 h. At 4 h after trawling, haemolymph O₂ status was not markedly influenced in either season, but there were significant disturbances of acid-base status. In winter, a potential metabolic lactic acidosis was compensated by a marked respiratory alkalosis, with significantly increased haemolymph pH and decreased CO₂ total content and partial pressure. These effects disappeared gradually over 96 h. Summer lobsters showed combined metabolic and respiratory acidosis at 4 h, although this had recovered to control values in the small number of survivors sampled at 24 h. The capture stresses elicited very high haemolymph crustacean hyperglycaemic hormone (CHH) titres, significantly higher in summer than in winter. In winter, CHH titre had declined significantly at 24 h, whereas it exhibited a further significant increase at 24 h in summer. Live-storage position had no significant effect on survival or recovery from capture stresses in either season. The results demonstrate that Nephrops were much more stressed by trawling at high summer temperatures and had difficulty recovering from this, with pronounced negative effects on their survival, irrespective of their live-storage position.     

Hormonal control of uric acid storage in the fat body during last-larval instar of Manduca sexta

In the last-larval instar of the tobacco hornworm, Manduca sexta, a switch from excretion of uric acid to storage in the fat body occurs during transition from the feeding to the wandering stage. Neuroendocrine control of this change from excretion to storage was demonstrated by neck-ligation experiments with synchronously reared larvae. Results indicate that a neurohormone is released from the head 24–30 hr before the initiation of wandering and coincident with the first release of ecdysone that initiates metamorphosis. Direct involvement of the moulting hormone was shown by the effects of multiple injections of 20-hydroxyecdysone into the abdomen of larvae that had been ligated before the release of hormone. Urate levels in the fat body were 20- to 100-fold higher from hormone-injected larvae as from saline inject controls. Topically applied juvenile hormone or methoprene reversed the 20-hydroxyecdysone-induced storage of urate. Increased levels of uric acid in the haemolymph during pupal development result from the presence of juvenile hormone, and the abrupt decrease in uric acid concentration in the haemolymph just prior to pupal ecdysis results from a decreased titre of juvenile hormone. Applications of methoprene prevented the decrease in uric acid levels in the haemolymph.     

The mode of regulation of the corpus allatum activity during starvation in adult females of the Colorado potato beetle, Leptinotarsa decemlineata (Say)

When two-day-old female Leptinotarsa decemlineata were starved, their corpus allatum activity, as measured by the radiochemical in vitro assay, was significantly reduced after 24 hr. Such a reduction was not observed when the nerve connections between the central nervous system and the retrocerebral complex were severed and the beetles starved up to 5 days. In some experiments, the rate of juvenile hormone biosynthesis in vitro, was substantiated by measurement of the juvenile hormone titre in the haemolymph by physico-chemical methods. It is concluded that intact nervous connections between the central nervous system and the corpora allata are essential for restraining the juvenile hormone biosynthesis during the initial stages of starvation.Corpora allata from 1-day starved insects were considerably stimulated in vitro by farnesenic acid indicating that juvenile hormone synthesis is controlled enzymatically at a stage prior to the final two steps in the pathway. However, on day 5 of starvation, rate-limitation may occur after formation of this intermediate, since farnesenic acid stimulation was much less at this time.Corpora allata of adult females newly emerged from the soil were activated within 4 hr regardless of feeding.     

Seasonal variation in the titers and biosynthesis of the primer pheromone ethyl oleate in honey bees

Honey bees allocate tasks along reproductive and non-reproductive lines: the queen mates and lays eggs, whereas the workers nurse the brood and forage for food. Among workers, tasks are distributed according to age: young workers nurse and old workers fly out and forage. This task distribution in the colony is further regulated by an increase in juvenile hormone III as workers age and by pheromones. One such compound is ethyl oleate (EO), a primer pheromone that delays the onset of foraging in young workers. EO is produced by foragers when they are exposed to ethanol (from fermented nectar) while gathering food. EO is perceived by younger bees via olfaction. We describe here the seasonal variation of EO production and the effects of Methoprene, a juvenile hormone analog. We found that honey bee workers biosynthesize more EO during the growing season than during the fall and winter months, reaching peak levels at late spring or summer. When caged workers were fed with syrup+d(6)-ethanol, labeled EO accumulated in the honey crop and large amounts exuded to the exoskeleton. Exuded levels were high for several hours after exposure to ethanol. Treatment with Methoprene increased the production of EO in worker bees, by speeding up its movement from biosynthetic sites to the exoskeleton, where EO evaporates. Crop fluid from bees collected monthly during the growing season showed a modest seasonal variation of in vitro EO biosynthetic activity that correlated with the dry and sunny periods during which bees could forage.     

Cellular events in the prothoracic glands and ecdysteroid titres during the last-larval instar of Spodoptera littoralis

Changes in prothoracic gland morphology were correlated to developmental events and ecdysteroid titres (20-hydroxyecdysone equivalents) during the last-larval instar in Spodoptera littoralis. After ecdysis to the last-larval instar the haemolymph ecdysteroid titre remained at about 45 ng/ml, when the prothoracic glands appeared quiescent. The first signs of distinct gland activity, indicated by increased cell size and radial channel formation, were observed at about 12 h prior to the cessation of feeding (36 h after the last-larval moult), accompanied by a gradual increase in ecdysteroid titre to 110 ng/ml haemolymph, at the onset of metamorphosis. During this phase ecdysteroid titres remained at a constant level (140–210 ng/ml haemolymph) and prothoracic gland cellular activity was absent for a short period. The construction of pupation cells occurred when haemolymph ecdysteroids titres increased to 700 ng/ml. A rapid increase in ecdysteroids began on the fourth night (1600 ng/ml haemolymph) reaching a maximal level (4000 ng/ml haemolymph) at the beginning of the fourth day. In freshly moulted pupae a relatively high ecdysteroid titre (1100 ng/ml haemolymph) was still observed, although during a decrease to almost negligible levels. The increase in ecdysteroid level during the third and the fourth nights of the last-larval instar was correlated with the period when almost all the prothoracic gland cells showed signs of high activity. Neck-ligation experiments indicated the necessity of head factors for normal metamorphosis up to the second to third day of the instar. The possibility that the prothoracic glands are under prothoracicotropic hormone regulation at these times is discussed.     

Distribution of haemolymph in the honeybee (Apis mellifica) in relation to season,age and temperature

[¹⁴C]Polyethylene glycol was proved to be a suitable marker for the determination of the extracellular space, which is identical with the volume of the haemolymph in insects. Bees kept at temperatures above 22°C show a fast circulation of haemolymph independent of the season. In winter at 5–25°C, immobilized isolated bees have a thoracic temperature which differs very little from that of the ambient. Under these conditions the time of mixing and the amount of haemolymph in head, thorax and abdomen depends on the temperature. At 5°C bees have much more haemolymph in their heads than at 25°C. At low temperatures the mixing time was increased and finally the mixing process was nearly stopped. Although bees are motionless at 5°C, limited activity of the circulatory system could be shown.The correlation between these distribution studies and the functional status of the bees within their colony is discussed.     

Endocrine events during pre-diapause and non-diapause larval-pupal development of the tobacco hornworm, Manduca sexta

The haemolymph ecdysteroid titre and in vitro capacities of prothoracic glands and corpora allata to synthesize ecdysone and juvenile hormone, respectively, during the last-larval instar of diapause-destined (short-day) and non-diapause-destined (long-day) Manduca sexta were investigated. In general, the ecdysteroid titres for both populations of larvae were the same and exhibited the two peaks characteristic of the haemolymph titre during this developmental stage in Manduca. The only difference in the titre occurred between day 7 plus 12 h and day 7 plus 20 h, when the short-day larval titre did not decrease as quickly as the long-day titre. The in vitro synthesis of ecdysone by prothoracic glands of short- and long-day larvae during the pharate pupal phase of the instar were also essentially the same. Activity fluctuated at times which would support the idea that ecdysone synthesis by the glands is a major contributing factor to the changes in the haemolymph ecdysteroid titre. There was one subtle difference in prothoracic gland activity between the two populations, occurring on day 7 plus 2 h. By day 7 plus 10 h, however, rates of ecdysone synthesis by the short- and long-day glands were comparable. This elevated activity of the short-day glands occurred just prior to the period the haemolymph ecdysteroid titre remained elevated in these larvae. The capacities of corpora allata to synthesize juvenile hormone I and III in vitro were not markedly different in long- and short-day last-instar larvae. At the time of prothoracicotropic hormone release in the early pupa, activity of corpora allata from short- and long-day reared animals was low and also essentially the same. There were a few differences in the levels of synthesis at isolated times, but they were not consistent for both homologues. Overall, there are no compelling differences in the fluctuations of ecdysteroids and juvenile hormones between diapause-destined and non-diapause-destined Manduca larvae. Since these hormones do not appear to play any obviously significant role in the induction of pupal diapause in this insect, the photoperiodic induction of diapause in Manduca appears to be a predominantly brain-centred phenomenon not involving endocrine effectors.     

Influence of a juvenile hormone analogue on vitellogenin synthesis and oögenesis in larvae of Nauphoeta cinerea

In experiments on the synthesis of the vitellogenic protein, farnesylmethylester, a juvenile hormone (JH) analogue, was injected into female Nauphoeta cinerea larvae at various stages during their development. Two and 4 days after injection, 2 μl of haemolymph were assayed in a vitellogenin immunodiffusion test. In second last and last instar larvae less than 6 days before adult ecdysis, high doses (100 μg) of farnesylmethylester are necessary to induce vitellogenin synthesis, whereas older last stage larvae and decapitated adults respond to small doses (1 μg) with the synthesis of vitellogenin. It seems that the competence to synthesize the vitellogenic protein changes at the time of induction of the moulting process. If farnesylmethylester is injected into last instar larvae with a supposedly high titre of ecdysone, the vitellogenic protein can be detected in the haemolymph of a small percentage of animals only.Oöcyte maturation can be observed in last instar larvae injected after the fifth to ninth day with farnesylmethylester. The observed volume changes of the corpora allata suggest that an absence of JH for a short time is necessary for the oöcytes to become competent to grow. Last instar larvae treated with farnesylmethylester become larval-adult intermediates with partly developed oöcytes, demonstrating a simultaneous juvenilizing and gonadotropic influence of the JH analogue. In last instar larvae injected with farnesylmethylester a partial degeneration of already maturing oöcytes is induced at the time when the ecdysone titre is supposedly high and the possible reasons for this are discussed.     

Influence of pollen feeding and physiological condition on pesticide sensitivity of the honey bee Apis mellifera carnica

Summary In two consecutive years heavy bee mortality at end April/early May followed the use of pesticides classed as harmless for bees along road verges. It was thought that old weak winter bees had succumbed to a preparation otherwise innocuous. Extensive tests to reveal any links between the bees' physiological condition and pesticide sensitivity involved 6 hormone herbicides, 11 fungicides and 2 insecticides, all approved harmless for bees and functioning on them wholly or mainly as stomach poisons. As a rule bee sensitivity was measured as LD 50 per os, in smaller tests as percentage mortality. Amount and quality of pollen ingested in the first days of life affected the pesticide sensitivity of young and older bees. Bees fed adequate high quality pollen are less sensitive than counterparts fed inadequate or inferior pollen or pollen substitute; such differences persisted if the LD 50 was calculated for the same body weight. Pesticides containing manganese are an exception. To these, bees fed inadequate pollen are no more or even less sensitive than comparable well-fed bees. Pesticide sensitivity decreases generally from early to late summer. Quality of pollen available for larvae has no effect on poison sensitivity of imagines. Food supply conditions however exert a clear influence: tested with the same pesticides, hive bees from colonies having had a rich early food supply, and young bees bred then, are less sensitive than their counterparts having had moderate or no early food supply. Poison sensitivity of summer bees increases with age; most sensitive are old winter bees which had practiced broodcare in early spring.Inadequate pollen intake can be regarded as causing protein deficiency. Investigation of this in mammals and man indicate that the higher poison sensitivity in bees results from inhibition of the enzymatic decomposition of pesticides. For practical bee protection it is important that all organic fungicides tested are effectively harmless. Hormone hebicides can be ranked as practically harmless even for bees inadequately protein-fed, as long as the approved concentrations are observed. Our tests raised doubts however about the registration as harmless for bees of insecticides based on Endosulfan and Phosalon. Of interest in practice and for the official testing of pesticides are also the high pesticide sensitivity of old winter bees, the decrease in sensitivity of bees on a stable feed from early to late summer, and the sensitivity-reducing influence of pollen-rich food supply promoting development.It is important ecologically that pollens of different plant species vary in nutrient quality for the honey bee: there are perfectly worthless (conifers), poor-to-medium, and highly effective pollen types. As shown in this paper, these differences are relevant not only for the development of the physiological condition and breeding potential of the bee, but also for pesticide sensitivity. That bees gather worthless and poor-quality, sometimes even poisonous, pollen (some Ranunculus sp.) is evidently due to the phagostimulant present in all pollen types.