Effects of stress on the hemolymph juvenile hormone binding protein titers of Manduca sexta

External stressors disrupt physiological homeostasis; in insects, the response to stress may result in delayed development as the animal attempts to restore homeostasis before proceeding with its complex life cycle. Previous studies have demonstrated that exposure to stress leads to increased levels of the juvenile hormone (JH), a hormone responsible for maintaining the insect larval state. In Manduca sexta, JH is transported to target tissue by a high-affinity binding protein, hemolymph JH binding protein (hJHBP). Since JH titers are elevated in stressed Manduca, we examined levels of hJHBP to better understand (1) the role of JH in regulating hJHBP levels and (2) the hJHBP-regulated bioavailability of hormone at the target site. Fourth stadium Manduca (48 h post-ecdysis) were exposed for 24h to various stressors including nutritional deprivation, microbial infection, cutaneous injury, episodic movement, and temperature elevation. Insects raised on diets lacking nutritional content exhibited mean hJHBP levels that were less than half (45%) those of control insects. Similarly, insects injected with Escherichia coli demonstrated a 47% reduction in hJHBP titers. Cutaneous injury, episodic movement, and temperature elevation lowered hJHBP levels by 47%, 43%, and 38%, respectively. Total hemolymph protein concentration was not affected. After a stress event (injury), a 50% reduction in abundance of fat body hJHBP mRNA was observed within 4h; hJHBP levels did not drop until 24h after injury. Stress in the fourth stadium was manifest in fifth instars, with 100% of the injured insects displaying an extended larval stadium or failing to pupate. Computational modeling of the JH-hJHBP interaction indicates that unbound JH doubles in stressed insects. These results indicate that in response to stress larval hJHBP titers are significantly reduced, increasing JH bioavailability at the target site and thereby impacting development and survival of the insect. Treatment of unstressed insects with physiological doses of JH I did not affect hJHBP levels, suggesting that elevated JH levels were not solely responsible for the observed down-regulation in stressed insects.     

Embryonic expression of juvenile hormone binding protein and its relationship to the toxic effects of juvenile hormone in Manduca sexta

The juvenile hormones (JHs) regulate a diverse array of insect developmental and reproductive processes. One molecular target of JH action is its transporter, hemolymph JH binding protein (hJHBP); in the larva of the tobacco hornworm, Manduca sexta, low doses of JH can immediately increase hJHBP gene expression. Less explored are the effects of JH on embryological development, where early hormonal treatment has been shown to affect embryonic development and pupation. This study examines the egg form of JHBP and its gene expression during embryogenesis of M. sexta, as well as the phenotypic effect JH treatment has on embryos and on JHBP gene expression. We here demonstrate that the preponderance of JHBP found in the egg is maternally derived and that the embryonic gene and protein appear identical to those found in the larva. Expression of the JHBP gene begins in both the embryo itself and extra-embryonic tissues 15 h after fertilization, long before emergence of a functional fat body and circulatory system. Topical application of low JH doses to early embryos resulted in larval abnormalities while high doses of the hormone induced embryonic mortality. These effects are not mediated through regulation of the JHBP gene, since embryonic expression appears invariant in response to JH challenge. The toxicity of JH is tightly correlated with the concentration of unbound hormone.     

Embryonic expression of juvenile hormone binding protein and its relationship to the toxic effects of juvenile hormone in Manduca sexta

The juvenile hormones (JHs) regulate a diverse array of insect developmental and reproductive processes. One molecular target of JH action is its transporter, hemolymph JH binding protein (hJHBP); in the larva of the tobacco hornworm, Manduca sexta, low doses of JH can immediately increase hJHBP gene expression. Less explored are the effects of JH on embryological development, where early hormonal treatment has been shown to affect embryonic development and pupation. This study examines the egg form of JHBP and its gene expression during embryogenesis of M. sexta, as well as the phenotypic effect JH treatment has on embryos and on JHBP gene expression. We here demonstrate that the preponderance of JHBP found in the egg is maternally derived and that the embryonic gene and protein appear identical to those found in the larva. Expression of the JHBP gene begins in both the embryo itself and extra-embryonic tissues 15 h after fertilization, long before emergence of a functional fat body and circulatory system. Topical application of low JH doses to early embryos resulted in larval abnormalities while high doses of the hormone induced embryonic mortality. These effects are not mediated through regulation of the JHBP gene, since embryonic expression appears invariant in response to JH challenge. The toxicity of JH is tightly correlated with the concentration of unbound hormone.     

A novel protein that binds juvenile hormone esterase in fat body tissue and pericardial cells of the tobacco hornworm Manduca sexta L

Juvenile hormone esterase degrades juvenile hormone, which acts in conjunction with ecdysteroids to control gene expression in insects. Circulating juvenile hormone esterase is removed from insect blood by pericardial cells and degraded in lysosomes. In experiments designed to characterize proteins involved in the degradation of juvenile hormone esterase, a pericardial cell cDNA phage display library derived from the tobacco hornworm moth Manduca sexta L. was constructed and screened for proteins that bind juvenile hormone esterase. A 732-base pair cDNA encoding a novel 29-kDa protein (P29) was isolated. Western and Northern analyses indicated that P29 is present in both pericardial cell and fat body tissues and is expressed in each larval instar. In immunoprecipitation experiments, P29 bound injected recombinant juvenile hormone esterase taken up by pericardial cells and native M. sexta juvenile hormone esterase in fat body tissue, where the enzyme is synthesized. Binding assays showed that P29 bound juvenile hormone esterase more strongly than it did a mutant form of the enzyme with mutations that perturb lysosomal targeting. Based on these data, we propose that P29 functions in pericardial cells to facilitate lysosomal degradation of juvenile hormone esterase.     

The homeodomain protein PBX participates in JH-related suppressive regulation on the expression of major plasma protein genes in the silkworm, Bombyx mori

In the silkworm, Bombyx mori, major plasma proteins referred to as 30K proteins are the most abundant proteins in the hemolymph of final (fifth) instar larvae. Surgical extirpation of corpora allata, the source of a juvenile hormone (JH), causes rapid accumulation of 30K proteins in the hemolymph of fourth instar larvae. The 30K protein 6G1 (30K6G1) gene was repressed in primary cultured fat body cells treated with a JH analog (JHA), methoprene. To identify the JH response element present in the promoter region of the 30K6G1 gene, we performed transfection analyses of the 5'-deletion mutants of the 30K6G1 gene using primary cultured fat body cells, gel retardation assays and in vivo footprinting analysis. The results from those analyses revealed that a JH response element exists in the sequence between positions -147 and -140. When the promoter construct mutated at positions -143, -142, and -141 was transfected to fat body primary cultured cells, the suppression effect on the reporter gene expression caused by JHA was reduced. Gel retardation assay using specific antibody revealed that a PBX protein binds to the JH response element. Northern blot analysis revealed that the gene expression of Bombyx PBX is enhanced in the fat body cells by JHA treatment. These results indicate that PBX proteins are involved in the JH signaling pathway and play an important role in suppressing 30K protein gene expression in the fat body of B. mori.     

Juvenile hormone regulation of vitellogenin synthesis in the red flour beetle,Tribolium castaneum

To elucidate the endocrine regulation of vitellogenin (Vg) synthesis in the red flour beetle, Tribolium castaneum, the titers of juvenile hormone (JH) and ecdysteroids in the whole body of female beetles were measured and compared with Vg mRNA levels. Juvenile hormone levels remained high while the ecdysteroid levels declined steadily during 1–5 days post adult emergence (PAE). The Vg mRNA levels began to increase by the end of 3rd day PAE and peaked by the 4th–5th day PAE. Gene expression profiling by microarray and quantitative real-time PCR analyses of RNA isolated from 1 to 5 days PAE beetles revealed that the genes coding for proteins involved in JH biosynthesis and action, but not those involved in 20-hydroxyecdysone (20E) biosynthesis and action had similar expression patterns as the genes coding for Vg. RNA interference (RNAi)-aided knock-down in the expression of these genes showed that both JH and 20E were required for Vg gene expression. However, Vg mRNA was induced by the application of JH III but not by the injection of 20E into the previtellogenic females. These data suggest that JH is required for Vg synthesis in the fat body and 20E influences Vg synthesis through its action on oocyte maturation.     

N-linked glycosylation of G. mellonella juvenile hormone binding protein - comparison of recombinant mutants expressed in P. pastoris cells with native protein

Juvenile hormone (JH) regulates insect growth and development. JH present in the hemolymph is bound to juvenile hormone binding protein (hJHBP) which protects JH from degradation. In G. mellonella, this protein is glycosylated only at one (Asn(94)) of the two potential N-linked glycosylation sites (Asn(4) and Asn(94)). To investigate the function of glycosylation, each of the two potential glycosylation sites in the rJHBP molecule was examined by site-directed mutagenesis. MS analysis revealed that rJHBP overexpressed in the P. pastoris system may appear in a non-glycosylated as well as in a glycosylated form at both sites. We found that mutation at position Asn(94) reduces the level of protein secretion whereas mutation at the Asn(4) site has no effect on protein secretion. Purified rJHBP and its mutated forms (N4W and N94A) have the same JH binding activities similar to that of hJHBP. However, both mutants devoid of the carbohydrate chain are more susceptible to thermal inactivation. It is concluded that glycosylation of JHBP molecule is important for its thermal stability and secretion although it is not required for JH binding activity.     

Expression pattern of enzymes related to juvenile hormone metabolism in the silkworm, <Emphasis Type="Italic">Bombyx mori</Emphasis> L.

The physiological balance of juvenile hormone (JH) in insects depends on its biosynthesis and degradation pathway. Three key enzymes namely, juvenile hormone esterase (JHE), juvenile hormone epoxide hydrolase (JHEH) and juvenile hormone diol kinase (JHDK) are required for degradation in insects. Our present results showed that JHE and JHEH exhibited expression in almost all the tissues. This indicated that JHE and JHEH might degrade JH simultaneously. In addition, the highest levels of JHDK were observed in the midgut, with trace level being found in the malpighian tubule and haemocytes. Since the midgut is a digestive organ and not a JH target, it was hypothesized that both JHE and JHEH hydrolyzed JH to JH diol (JHd) which was then transported to midgut and hydrolyzed further by JHDK, to be finally excreted out of the body. Also the expression studies on JH degradation enzymes in different tissues and stages indicated that the activities of the three enzymes are specific and coincident with the JH functions in silkworm, Bombyx mori L.     

In vitro synthesis, release and uptake of storage proteins by the fat body of Manduca sexta: putative hormonal control

1. Two major proteins (P1 and P2) are synthesized by the fifth instar larval fat body of Manduca sexta and then released into the hemolymph. 2. These proteins are later sequestered by the pre-pupal fat body. 20-Hydroxyecdysone does not appear to affect the synthesis of either protein. 3. When day 2 fifth instar larvae are neck-ligated there is an excessive synthesis (supersynthesis) of P2 (arylphorin). 4. Juvenile hormone I (JH I) applications to ligated animals had no effect, but brain homogenate injections resulted in the inhibition of P2 synthesis. 5. Neck ligations of larvae between days 5 and 6 revealed a head critical period between day 5 + 12 hr and day 5 + 18 hr, after which the head is unnecessary for the sequestration of either protein by the fat body. 6. JH I and JH III applications to ligated larvae before the head critical period do not restore the ability of the fat body to sequester the storage proteins. 7. P1 and P2 appear to be synthesized differentially and P2 is sequestered by the fat body to a much lesser extent than P1. 8. P2 is the hemolymph storage protein of both larval and pupal stages, whereas P1 appears to be the storage protein of the pupal fat body. 9. The data indicate that the synthesis of arylphorin and the resorption of both proteins are controlled by a putative head factor(s).     

cDNA isolation, expression, and hormonal regulation of yolk protein genes in the oriental fruit fly, Bactrocera dorsalis (Hendel) (Diptera: Tephritidae)

Yolk protein (YP) or vitellogenin (Vg), the main component of yolk, is the key nutrient for embryonic development. YPs, encoded from uncleaved genes existing mainly in cyclorraphan flies, are different from VGs that are present in most non-cyclorraphan dipterans and other insects. In this study, cDNAs of two YPs, namely Bdyp1 and Bdyp2 (GenBank accession Nos. AF368053 and AF368054), were isolated in the oriental fruit fly, Bactrocera dorsalis (Hendel). RT-PCR analysis revealed that Bdyp1 and 2 are expressed in the fat body and ovary during egg development. However, the expression profiles of Bdyp1 and 2 in the fat body are different, indicating that divergent mechanisms might exist in the regulation of these two genes. Twenty-hydroxyecdysone (20E) plays a major role in promoting Bdyp1 expression, yet the expression of Bdyp2 exhibits a greater response to juvenile hormone (JH) in fat body in vitro. Unexpectedly, 20E-induced expression of both Bdyp1 and 2 is suppressed by JH prior to 20E treatment of in vitro fat body; conversely, it is enhanced by the addition of JH following 20E treatment.     

Juvenile hormone diol kinase. I. Purification, characterization, and substrate specificity of juvenile hormone-selective diol kinase from Manduca sexta

Manduca sexta juvenile hormone diol kinase (JHDK) catalyzes the conversion of juvenile hormone (JH) diol to JH diol phosphate. JHDK may be the first example of a phosphotransferase directly involved in the catabolism and inactivation of a lipid-soluble hormone. JHDK is an enzyme crucial for secondary metabolism of JH and possesses high specificity and catalytic efficiency for JH diol. In this study, the purification and characterization of native JHDK are described; its enzymatic properties are examined; and its role in cellular JH metabolism is explored. Using a variety of potential substrates, we show that JHDK has a preference for ATP, but will catalyze the formation of JH diol phosphate with GTP as the phosphate donor. JHDK has a nanomolar K(m) for JH I diol and a low micromolar value for MgATP. JH II and III diols also serve as phosphate acceptors with low micromolar K(m), whereas other diol derivatives of terpenoid esters structurally similar to JH metabolites are not phosphorylated. The reaction proceeds via a sequential Bi Bi mechanism. JHDK is active as a homodimer with a subunit molecular mass of 20 kDa. JHDK binds 5'-p-fluorosulfonylbenzoyladenosine and is inhibited by micromolar levels of Ca2+.     

Hormonally-regulated differential expression of the two duplicated insecticyanin genes,ins-a and ins-b,during development of the tobacco hornworm,Manduca sexta

The effects of juvenile hormone (JH) and 20-hydroxyecdysone (20E) on the developmental expression of the two insecticyanin genes, ins-a and ins-b, were investigated with two gene-specific probes. Removal of the corpora allata (-CA, source of JH) clearly delayed and down-regulated the epidermal expression of these genes but enhanced their expression in the fat body during the early development of the fifth instar. Application of JH I to the -CA larvae at the time of head capsule slippage completely restored the normal epidermal expression pattern of the two genes in the early fifth instar, then INS-a mRNA declined prematurely whereas INS-b mRNA remained similar to that in the intact larvae. By contrast, in the fat body of -CA larvae, the exogenous JH had little effect on the levels of INS-a mRNA, but enhanced expression of INS-b mRNA relative to intact larvae. Culture of epidermis from day 1 fifth instar larvae with 40 ng/ml 20E for up to 24 h accelerated the loss of INS-a mRNA without affecting the levels of INS-b mRNA. Both mRNAs declined in isolated larval abdomens over a 24 h period, and this decline was slowed by 1 g methoprene (a JH analog). Together these results indicate that JH controls the levels of the two mRNAs in both the epidermis and fat body, with additional factors involved in regulating these genes in the fat body during the molt and in the epidermis during the growth phase.     

Some effects of allatectomy in the female tsetse,Glossina austeni

The effects of juvenile hormone on the milk gland, ovaries, and fat body of adult female G. austeni were studied by allatectomy and hormone replacement therapy. In the absence of juvenile hormone, milk synthesis is slow, leading to the production, in a few cases, of small larvae over a prolonged inter-larval period. In most cases, no viable larva is produced and the fat body hypertrophies. Replacement of the corpus allatum with C₁₆JH leads to a rapid synthesis of milk, production of normal-sized larvae and a reversal of the effect on the fat body. It is therefore suggested that the milk gland activity is directly influenced by JH. Allatectomy in most cases also results in only one egg being matured. The others do not enter vitellogenesis. Similarly, this effect on the ovaries can be reversed by topical application of C₁₆JH.     

Factors influencing juvenile hormone esterase activity in the wax moth, Galleria mellonella

The effects of juvenile hormone, antiallatotropins, selected surgical procedures and starvation on the juvenile hormone esterase levels in Galleria larvae and pupae were investigated. JH reduced JH esterase activity in larvae but induced the enzyme in 1-day-old pupae. In vitro studies confirmed that the peak of synthesis and/or release of JH esterase from the fat body of last instar larvae occurred 4 days after ecdysis. These studies also showed that fat body from JH-treated larvae released much less enzyme than controls. Antiallatotropins, precocene 2 and ZR 2646 also reduced JH esterase levels in larvae, but ZR 2646 induced JH esterase in pupae. In starved larvae, JH esterase did not increase during the first five days. A minimum of 36 hr of feeding was necessary for the larval esterase activity to increase on schedule on day 4 of the last larval stadium. When day-l larvae were ligated behind the head or the prothorax, they had lower JH esterase levels and yet showed a slight increase in the enzyme when the larvae reached the age of 4 days. The significance of these results is discussed in relation to the possible control of esterase activity during metamorphosis.