NORMAL GENOMIC

• Shanmugavelu M, Baytan AR, Chesnut JD, Bonning BC
• A novel protein that binds juvenile hormone esterase in fat body tissue and pericardial cells of the tobacco hornworm Manduca sexta L.
• J Biol Chem. 2000; 275: 1802-6
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• 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.

• Engelmann F, Mala J
• The interactions between juvenile hormone (JH), lipophorin, vitellogenin, and JH esterases in two cockroach species.
• Insect Biochem Mol Biol. 2000; 30: 793-803
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• For the cockroach species Leucophaea maderae and Periplaneta americana two major juvenile hormone (JH)-binding proteins have been identified: lipophorin (Lp) and vitellogenin (Vg). Each of these macromolecules binds JH with an approximate affinity of K(d) of 10 nM. In Leucophaea the concentration of Lp is augmented by JH during vitellogenesis at the same time when Vg is induced de novo. The circulating levels of each of Lp and Vg at mid-vitellogenesis are in the 10 microM range. Similar values have been determined for Periplaneta. Total JH concentrations (bound and free) can be as high as micromolar in Leucophaea. However, because of the large quantities of the two major JH-binding proteins and their high affinity for JH, we can assume that the amount of free (unbound) JH in circulation is extremely low (the actual values are not know).The JH esterases (JHEs) of the hemolymph in both cockroach species have been isolated by anion exchange chromatography. The JHEs of Leucophaea bound to the anion exchange resin more tightly than the JHE of Periplaneta. The V(max) of the Leucophaea esterases fluctuated by a factor of 2 to 3 during vitellogenesis. The K(m) values for the two distinct esterases of Leucophaea were similar (about 0.15x10(-6) M). On the other hand, k(cat) of the JHEs for Leucophaea at ovulation time was two to three times higher than earlier during vitellogenesis, i.e. 23.30 min(-l) compared to 6.20 min(-1). The JHE of Leucophaea is shown to bind JH III with high affinity: K(d)=3x10(-9) M. However, since there are only very small amounts of JH available for degradation (due to the binding to Lp and Vg), the quantitative removal of JH from circulation, and this includes the release of bound JH, is indeed slow, with a measured half-life of 6-8 h. Classical kinetic assumptions are not met in conditions where the enzyme concentrations exceed by far that of the available substrate. Nonetheless, we attempted to determine the initial velocity of JH hydrolysis under natural conditions, i.e. for undiluted hemolymph, by measuring the initial velocities of JH hydrolysis in serially diluted hemolymph and extrapolating to zero dilution. For in vivo conditions we estimated an initial velocity of JH hydrolysis of <0.1 fmol microl hemolymph(-1) min(-1), i.e. four to five orders of magnitude lower than that measured at substrate saturation in vitro.

• Orth AP, Lan Q, Goodman WG
• Ligand regulation of juvenile hormone binding protein mRNA in mutant Manduca sexta.
• Mol Cell Endocrinol. 1999; 149: 61-9
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• Insect hemolymph juvenile hormone binding protein (hJHBP) regulates peripheral titers of its ligands, the juvenile hormones. In larvae of the black (bl) strain of the tobacco hornworm, Manduca sexta, treatment with small doses of juvenile hormone I (JH I) can also regulate titers of hJHBP. To further investigate this regulation, responsiveness of hJHBP mRNA expression to JH I was characterized in vivo. RNA analyzes revealed that transcript levels in fat body, the site of hJHBP synthesis, increased fivefold within several hours of treatment with physiological doses of hormone and remained elevated for approximately 16 h. Sensitivity to JH treatment was found to vary temporally. To ensure transcript identity, a wild-type cDNA clone and a bl RT-PCR fragment were sequenced and found to be 99% homologous. Together, these results suggest that JH participates in regulating expression of its transport protein in bl larvae by modifying the in vivo abundance of hJHBP's mRNA transcript.

• Braun RP, Wyatt GR
• Sequence of the hexameric juvenile hormone-binding protein from the hemolymph of Locusta migratoria.
• J Biol Chem. 1996; 271: 31756-62
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• The cDNA for the hexameric hemolymph juvenile hormone-binding protein (JHBP) from the migratory locust has been cloned and sequenced. Antiserum raised against purified JHBP was used to identify clones in an expression library. The 4.3-kilobase JHBP mRNA codes for 668 amino acids (74.4 kDa) and contains 2 kilobases of 3'-untranslated region. The derived amino acid sequence reveals that locust JHBP represents a new group within the hexamerin family of arthropod proteins. JHBP appears to be more closely related to arthropod hemocyanins, the believed ancestors of the family, than to the other known insect hexamerins. The mRNA shows a high (89%) bias to codons ending in G or C and the codons ending in A or T are clustered and concentrated toward the 5' end, suggesting a mosaic gene structure. The recombinant bacterially expressed protein bound [3H]JH III with the same affinity as the protein from hemolymph. A truncated version of JHBP lacking 53 amino acids from the N terminus did not bind JH III. Hybridization analysis of fat body JHBP mRNA in locusts that had been treated with precocene and a JH analog did not give clear evidence for regulation by JH.

• Wojtasek H, Prestwich GD
• Key disulfide bonds in an insect hormone binding protein: cDNA cloning of a juvenile hormone binding protein of Heliothis virescens and ligand binding by native and mutant forms.
• Biochemistry. 1995; 34: 5234-41
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• The hemolymph juvenile hormone binding protein (JHBP) from the early fifth instar larvae of Heliothis virescens (Lepidoptera, Noctuidae) has been purified, and three cDNA clones for this protein have been isolated from a fat body cDNA library constructed in bacteriophage lambda ZAP XR. The deduced amino acid sequence of the full-length clone predicts a mature protein consisting of 224 residues, a molecular mass of 24,976 Da, and a pI of 5.29. Comparison of the amino acid sequence to that of the previously described JHBP from Manduca sexta shows 51% overall identity with highly conserved N- and C-terminal regions. One of the three clones bound photoactivatable analogs of juvenile hormones with much lower affinity than the other two. This clone had Phe150 in place of the expected Cys150 conserved in other JHBP clones. The F150C mutant of this clone regained native binding affinity. For native Hvir-JHBP, the affinity for [3H]JH I was lower under reducing conditions (87 nM) relative to a 40 nM affinity under nonreducing conditions. The importance of pairs of Cys residues was addressed by preparing Cys to Ala mutants at each site. Expressed proteins were tested for binding affinity by photoaffinity labeling with tritium-labeled JH analogs and by binding assays using (10R,11S)-[3H]JH I. Curiously, the C150A mutant retained full activity, implying that the aberrant C150F was dysfunctional due to steric hindrance rather than to a missing disulfide linkage. Likewise, C29A and C194A had binding affinities unchanged from that of the full-length wild-type clone.(ABSTRACT TRUNCATED AT 250 WORDS)

• Webb TJ, Hurd H
• Microsomal juvenile hormone binding proteins in the follicle cells of Tenebrio molitor.
• Insect Biochem Mol Biol. 1995; 25: 631-7
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• The microsomal fraction of Tenebrio molitor follicle cells has been found to contain both high and low affinity binding sites for juvenile hormone (JH) III. Using Scatchard analysis, the equilibrium dissociation constants, Kd, were calculated as 1.0 x 10(-8) and 4.3 x 10(-7) M respectively. Kinetic data support a rapid binding of the hormone to the site(s), with rate constants of ka = 3.77 x 10(8) M-1 min-1 and kd = 0.0075 min-1. Affinity of the binding site(s) for JH III was higher than for either JH I or methoprene. The significance and possible function of such microsomal binding proteins are discussed, with reference to the perturbance of vitellogenesis found in beetles parasitized by Hymenolepis diminuta.

• Glinka AV, Braun RP, Edwards JP, Wyatt GR
• The use of a juvenile hormone binding protein for the quantitative assay of juvenile hormone.
• Insect Biochem Mol Biol. 1995; 25: 775-81
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• The suitability of the haemolymph juvenile hormone binding protein (JHBP) of Locusta migratoria for use in a competition assay for juvenile hormone (JH) III has been investigated, and a simple quantitative assay procedure using this protein has been developed. JHBP partially purified from haemolymph of precocene treated adult locusts gives rapid and stable binding of [3H]10R-JH III, and can be separated from the unbound hormone with hydroxylapatite (HAP). The sensitivity of the method is such that 0.15 pmol (40 pg) 10R-JH III gives 50% displacement of [3H]10R-JH III from the binding protein. Competition by JH II is about 5 times less and JH I about 10 times less than that by JH III, JH III diol and acid compete at least 1000 times less strongly. A procedure for extraction and assay of JH from 50 microliters haemolymph samples is described, the interference by non-specific haemolymph components is shown to be relatively small, and some data on JH III titres in maturing adult locusts are presented.

• Palli SR et al.
• A nuclear juvenile hormone-binding protein from larvae of Manduca sexta: a putative receptor for the metamorphic action of juvenile hormone.
• Proc Natl Acad Sci U S A. 1994; 91: 6191-5
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• A 29-kDa nuclear juvenile hormone (JH)-binding protein from the epidermis of Manduca sexta larvae was purified by using the photoaffinity analog for JH II ([3H]epoxyhomofarnesyldiazoacetate) and partially sequenced. A 1.1-kb cDNA was isolated by using degenerate oligonucleotide primers for PCR based on these sequences. The cDNA encoded a 262-amino acid protein that showed no similarity with other known proteins, except for short stretches of the interphotoreceptor retinoid-binding protein, rhodopsin, and human nuclear protein p68. Recombinant baculovirus containing this cDNA made a 29-kDa protein that was covalently modified by [3H]epoxyhomofarnesyldiazoacetate and specifically bound the natural enantiomer of JH I (Kd = 10.7 nM). This binding was inhibited by the natural JHs but not by methoprene. Immunocytochemical analysis showed localization of this 29-kDa protein to epidermal nuclei. Both mRNA and protein are present during the intermolt periods; during the larval molt, the mRNA disappears but the protein persists. Later when cells become pupally committed, both the mRNA and protein disappear with a transient reappearance near pupal ecdysis. The properties of this protein are consistent with its being the receptor necessary for the antimetamorphic effects of JH.

• Trowell SC, Hines ER, Herlt AJ, Rickards RW
• Characterization of a juvenile hormone binding lipophorin from the blowfly Lucilia cuprina.
• Comp Biochem Physiol B Biochem Mol Biol. 1994; 109: 339-57
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• The larval haemolymph of the sheep blowfly Lucilia cuprina (Weidemann) contains a juvenile hormone binding protein with a Kd for racemic JH III of 33 +/- 6 nM. The density of the binding sites is 212 +/- 33 pmol/mg haemolymph protein. The binding protein is equally specific for JH III and methyl farnesoate. Some natural juvenoids were ranked for their ability to displace [3H]JH III with JH III > JH II > JH I > JH III acid > JH III diol > JHB3 = no detectable displacement. These data, together with displacement studies for 14 synthetic juvenoids, indicate some characteristics of the JH binding cleft. The binding protein is a high density lipophorin (density = 1.15 g/ml) and has subunit molecular weights of 228 kDa (apolipophorin I) and 70 kDa (apolipophorin II). The N-terminal amino acid sequences of the subunits have no discernible homology to any previously sequenced protein. Lipophorin-specific immunocytochemical staining occurs in a subset of fat body cells.

• Prestwich GD, Touhara K, Riddiford LM, Hammock BD
• Larva lights: a decade of photoaffinity labeling with juvenile hormone analogues.
• Insect Biochem Mol Biol. 1994; 24: 747-61
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• The introduction of photoaffinity labeling into the mode of action of insect hormones and pheromones started 12 yr ago with the photoaffinity labeling of juvenile hormone binding proteins (JHBPs) from cockroaches in the laboratory of the late John K. Koeppe. Applying this technique to Manduca sexta led ultimately to a three-laboratory collaborative project that has begun to dissect the molecular basis for JH transport, metabolism, and nuclear binding and gene activation in Lepidoptera. This review provides (1) a history of the first experiments; (2) an idea of the breadth of the technique in the arthropod classes Insecta, Crustacea, and Arachnida; and (3) evidence for the depth of the technique in unearthing key details about three different types of the molecular action of JH in M. sexta.

• King LE, Zhang J, Tobe SS
• Cytosolic and nuclear juvenile hormone-binding proteins from the brain of Diploptera punctata.
• Gen Comp Endocrinol. 1994; 94: 11-22
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• Cytosol and crude nuclear extracts of brains from female Diploptera punctata were found to contain a juvenile hormone-binding protein. The binding kinetics of the cytosol and nuclear juvenile hormone-binding proteins toward racemic [3H]JH III were determined using the dextran-coated charcoal assay. Both proteins show reversible and saturable binding toward JH III. The mean dissociation constant (Kd) of the brain cytosol binding protein was 66.5 +/- 7.2 nM, whereas the nuclear-binding protein had a lower affinity, with a mean Kd of 170 +/- 22.1 nM. The specificity of both the cytosol and the nuclear binding proteins was determined by competitive displacement experiments with [3H]JH III. For the cytosol binding protein, the order of relative affinity was JH II > (10R)-JH III > (10RS)-JH III approximately JH I. For the nuclear binding protein the order of relative affinity was JH II > JH I > (10R)-JH III > (10RS)-JH III. The JH analog hydroprene (ZR 512) had > 100-fold lower affinity than JH III for both proteins.

• Touhara K, Lerro KA, Bonning BC, Hammock BD, Prestwich GD
• Ligand binding by a recombinant insect juvenile hormone binding protein.
• Biochemistry. 1993; 32: 2068-75
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• A cDNA for the hemolymph juvenile hormone binding protein (JHBP) of larval Manduca sexta has been isolated, sequenced, and expressed in an insect cell line. A recombinant baculovirus, containing the JHBP cDNA fused to the p10 promoter of Autographa californica nuclear polyhedrosis virus, was constructed. Insect cells (Sf9) infected with this virus secreted recombinant JHBP (rJHBP) into the medium (> 50 micrograms/mL), and cotranslational removal of an 18 amino acid leader sequence was observed. rJHBP was cross-reactive with an antiserum prepared to the hemolymph JHBP and was specifically labeled by [3H]EHDA, a photoaffinity analog of JH II, demonstrating that rJHBP was an isoform of the previously reported 32-kDa JHBP [Lerro, K. A., & Prestwich, G.D. (1990) J. Biol. Chem. 265, 19800-19806]. rJHBP was purified from insect cell medium to homogeneity by ion-exchange and gel-filtration chromatography. The purified rJHBP had a higher affinity (KD = 11 nM for JH I and KD = 42 nM for JH II) than that reported for crude hemolymph JHBP (KD = 80 nM for JH I). The circular dichroism (CD) spectrum of purified rJHBP indicated 34% alpha-helix and 23% beta-sheet. The CD spectra of rJHBP in the presence and absence of JH II were the same, indicating no change in secondary structure induced by ligand binding. Thus, the rJHBP expressed in insect cells binds JHs and is suitable for structural and functional analysis.

• Touhara K, Prestwich GD
• Juvenile hormone epoxide hydrolase. Photoaffinity labeling, purification, and characterization from tobacco hornworm eggs.
• J Biol Chem. 1993; 268: 19604-9
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• Juvenile hormone epoxide hydrolase (JHEH), which may play a pivotal role in regulating insect juvenile hormone (JH) titer along with JH esterase, was identified in tobacco hornworm (Manduca sexta) eggs by using photoaffinity analogs of JHs. The UV light-induced covalent labeling with [3H]epoxyhomofarnesyl diazoacetate, a JHII analog, revealed a membrane-associated 50-kDa protein that was selectively and specifically labeled. This 50-kDa protein was copurified 171-fold with the JHEH activity to homogeneity through DEAE-Sephacel, Mono Q, and hydroxylapatite columns, which led us to conclude that the labeled 50-kDa protein was a JHEH. The steady-state kinetics of the purified microsomal JHEH showed that it followed Michaelis-Menten kinetics with Km values of 0.61, 0.55, and 0.28 microM for JHI, II, and III, respectively, and that JHIII showed a significantly higher Vmax than JHI or JHII. JH acid was also converted to the corresponding diol at a rate 4-fold slower than the corresponding JH. Thus, the differences in the binding of substrate and the rate of turnover by JHEH were affected by the epoxyfarnesoate ester moiety of JH and the difference between the cis-11-methyl group of JHIII versus the cis-11-ethyl group of JHI and II. Purified JHEH showed optimal enzyme activity at pH 7.5-8.5. Interestingly, the presence of recombinant M. sexta JH binding protein (JHBP) dramatically decreased the degradation of JH by JHEH in vitro. Since the cytosolic JHBP in eggs closely resembles the hemolymph JHBP, we suggest that cytosolic JHBP may play a role in protecting JHs from JHEH in vivo. Furthermore, JHEH may play a significant role in the secondary metabolism of JH acid generated by JH esterase.

• Park YC, Tesch MJ, Toong YC, Goodman WG
• Affinity purification and binding analysis of the hemolymph juvenile hormone binding protein from Manduca sexta.
• Biochemistry. 1993; 32: 7909-15
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• A high-affinity juvenile hormone binding protein was purified from the hemolymph of the tobacco hornworm, Manduca sexta, employing ammonium sulfate precipitation and affinity and size-separation chromatography. The naturally occurring enantiomer of juvenile hormone III (10R) was converted to juvenile hormone III acid and then covalently attached to aminohexyl-Sepharose 4B. Hemolymph from early fifth stadium (60 h postecdysis) larvae was used as the source of hJHBP. The yield of hJHBP was approximately 25% of the starting material, with 3.5 mg of highly purified, biologically active hJHBP recovered from 100 mL of hemolymph. Binding parameters were examined using equilibrium dialysis and highly purified, enantiomerically correct juvenile hormone I and II and racemic JH III. The equilibrium dissociation constants for juvenile hormone I and II were approximately 6 x 10(-10) M at 4 degrees C, while racemic juvenile hormone III displayed an equilibrium dissociation constant of 1.9 x 10(-9) M. At 25 degrees C the equilibrium dissociation constant for juvenile hormone I was 1.6 x 10(-9) M. Half-times of dissociation were also determined for the three homologs. The half-time of dissociation was 30 s for juvenile hormone I, 20 s for juvenile hormone II, and 13 s for juvenile hormone III at either 4 or 25 degrees C. Using the new equilibrium dissociation constants, we calculate that better than 99% of the circulating juvenile hormone titer may be bound to this hemolymph protein.

• Winder BS, Roberts PE
• Characterization of the proteins from Melanoplus bivittatus that bind juvenile hormone, and a refined EFDA photolabeling technique.
• Int J Biochem. 1992; 24: 1435-46
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• 1. Juvenile hormone (JH) is specifically bound by a protein from hemolymph and fat body cytosol of the grasshopper, Melanoplus bivittatus. 2. This protein has a native molecular weight of 331,000 and subunits of 77,000. 3. Proteins that bind JH were covalently photolabeled with a JH analog, epoxyfarnesyl diazoacetate (EFDA). Samples were irradiated in spot plates and hydroxyapatite was used to separate bound from free [3H]EFDA. Differential solubilization was used to extract unlinked [3H]EFDA and solubilize [3H]EFDA linked to protein. 4. Hemolymph proteins of M(r) 479,000, 240,000 and 77,000 also bound [3H]EFDA. 5. Proteins that bound [3H]EFDA were not vitellogenins.

• Touhara K, Prestwich GD
• Binding site mapping of a photoaffinity-labeled juvenile hormone binding protein.
• Biochem Biophys Res Commun. 1992; 182: 466-73
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• The juvenile hormone binding protein (JHBP) of larval Manduca sexta was labeled by a photoaffinity analog of JH II and purified by preparative IEF and ion-exchange HPLC. The purified [3H]EHDA-labeled JHBP was selectively cleaved by CNBr and by endoproteinases Lys-C and Glu-C. The radioactive peptides were separated by tricine SDS-PAGE and sequenced after blotting to a PVDF membrane. The sequence revealed that Ala184-Asn226 contained a primary binding site of [3H]EHDA. Furthermore, peptide mapping indicated that Asp1-Glu34 also contained a second covalent attachment site of [3H]EHDA. Labeling of the N-terminal region increased when the photolysis was performed at lower temperature. Since Ala184-Asn226 is predicted to be a hydrophobic beta-sheet region, it may participate in the recognition of lipophilic backbone of JH. Five out of six cysteines are located in these two regions, consistent with a model in which the two binding regions connected by disulfide bridges provide a two-sided binding pocket for juvenile hormone.

• Li H, Borst DW
• Characterization of a methyl farnesoate binding protein in hemolymph from Libinia emarginata.
• Gen Comp Endocrinol. 1991; 81: 335-42
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• Hemolymph from Libinia emarginata was tested for its ability to bind methyl farnesoate (MF), a JH-like compound found in many crustaceans. Hemolymph bound MF with moderate affinity (KD = 4.5 x 10(-6) M). Competitive binding studies showed that this binding was specific for MF, with farnesoic acid and JH homologues having less than 30 and 7%, respectively, of the relative binding activity of MF. JH acid and ecdysterone had no binding activity. MF binding activity was lost after pretreatment of hemolymph with heat or protease, suggesting that the binding component was a protein. Gel filtration analysis showed that the binding activity had a molecular weight of about 650,000.

• Jefferies LS, Roberts PE
• A new method of detecting hormone-binding proteins electroblotted onto glass fiber filter: juvenile hormone-binding proteins from grasshopper hemolymph.
• J Steroid Biochem. 1990; 35: 449-55
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• We have developed a new method to identify juvenile hormone (JH)-binding proteins blotted onto glass fiber filter (GFF) after electrophoretic separation. Insect JH regulates reproduction in the two-striped grasshopper, Melanoplus bivittatus. A number of proteins are involved in the delivery of JH from its site of synthesis to the nuclei of fat body cells where it acts to induce vitellogenesis. To identify JH binding proteins, hemolymph was separated by PAGE, electroblotted onto GFF, and incubated in [10-3H]JH-III. The amount of hormone bound by blotted proteins increased with the amount of protein on the filter, was competitively displaced by excess non-labeled hormone, and was affiliated with individual bands on fluorograms of proteins blotted after electrophoretic separation. GFF etched with trifluoroacetic acid was better than nitrocellulose, Zeta Probe, cellulose acetate or unetched GFF. Phosphate (pH 6.0-7.3) or Tris buffers (pH 7.3-8.0) worked equally well for the procedure. Unbound hormone was easily removed by short washes in buffer, and adequate binding for detection was achieved in a 15 min incubation. Preliminary data suggest that this technique may be used to detect receptors, carriers, and binding proteins of steroid hormones.

• Shemshedini L, Wilson TG
• Resistance to juvenile hormone and an insect growth regulator in Drosophila is associated with an altered cytosolic juvenile hormone-binding protein.
• Proc Natl Acad Sci U S A. 1990; 87: 2072-6
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• The Met mutant of Drosophila melanogaster is highly resistant to juvenile hormone III (JH III) or its chemical analog, methoprene, an insect growth regulator. Five major mechanisms of insecticide resistance were examined in Met and susceptible Met+ flies. These two strains showed only minor differences when penetration, excretion, tissue sequestration, or metabolism of [3H]JH III was measured. In contrast, when we examined JH III binding by a cytosolic binding protein from a JH target tissue, Met strains had a 10-fold lower binding affinity than did Met+ strains. Studies using deficiency-bearing chromosomes provide strong evidence that the Met locus controls the binding protein characteristics and may encode the protein. These studies indicate that resistance in Met flies results from reduced binding affinity of a cytosolic binding protein for JH III.

• Kulcsar P, Prestwich GD
• Detection and microsequencing of juvenile hormone-binding proteins of an insect by the use of an iodinated juvenile hormone analog.
• FEBS Lett. 1988; 228: 49-52
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• An [125I]iodinated juvenile hormone (JH) analog can be used as a sensitive and highly selective probe for the visualization of high-affinity, (JH)-specific binding proteins from insect hemolymph samples. The proteins can be detected in their native form using a two-dimensional (isoelectric focusing then native gradipore gel) separation of the crude protein mixture containing the 125I-labeled iodinated JH analog. The proteins can be transferred to activated glass fiber paper by electroblotting, and the location of the bound gamma-emitter can be found by exposure of the dried gel or the electroblot to X-ray film. The radiolabeled protein spot can be excised from the Coomassie-stained glass fiber paper and subjected directly to gas-phase N-terminal amino acid sequencing. This non-destructive, non-denaturing technique may have wide applicability in identifying and sequencing ligand-specific binding proteins in complex mixtures.

• Osir EO, Riddiford LM
• Nuclear binding sites for juvenile hormone and its analogs in the epidermis of the tobacco hornworm.
• J Biol Chem. 1988; 263: 13812-8
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• Juvenile hormones (JH) are sesquiterpene derivatives that regulate both morphogenetic and reproductive development in insects. The larval epidermis of the tobacco hornworm, Manduca sexta, was found to take up both 3H-JH I and a biologically active JH analog, [125I]iodovinylmethoprenol (IVMA), from the incubation medium with 33% of the label going to the nucleus in both cases. An exchange assay using isolated nuclei showed the presence of two binding sites with approximate KD values of 7 and 88 nM for JH I and 4 and 59 nM for IVMA. There were about 10,000 of the high affinity sites per nucleus. The binding of both hormones was sensitive to pH and Pronase digestion. In competition studies, JH II and JH III competed for 3H-JH I binding sites, whereas IVMA, hydroprene, and methoprene did not. In similar studies, methoprene and hydroprene competed for [125I]IVMA binding sites but JH I, JH II, and JH III were all ineffective. These results are consistent with the presence of specific and distinct binding sites for JH and IVMA in these nuclei.

• Koeppe JK, Kovalick GE, Prestwich GD
• A specific photoaffinity label for hemolymph and ovarian juvenile hormone-binding proteins in Leucophaea maderae.
• J Biol Chem. 1984; 259: 3219-23
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• A tritium-labeled diazocarbonyl juvenile hormone (JH) analog, (10-[10,11-3H]epoxyfarnesyl diazoacetate, [3H]EFDA), covalently bound to proteins in both hemolymph and ovarian extracts when reaction mixtures were irradiated with UV light. The addition of various concentrations of unlabeled JH III selectively inhibited [3H]EFDA photoattachment to proteins. Using the Scatchard method of analysis, [3H]EFDA bound specifically and with relatively high affinity (KD = 1.5 X 10(-6) M) to a macromolecule in each extract, although nonspecific binding to other molecules was also present (20-50%). To determine if [3H]EFDA bound at the JH III-binding site on the binding proteins, radioactive [3H]JH III or [3H]EFDA was complexed with proteins in the presence of various concentrations of either unlabeled JH III or JH I under equilibrium conditions. The results demonstrated that the natural hormone, JH III, displaced both bound labeled ligands 4.1 +/- 0.5 times better than the homolog JH I. Thus, the photoaffinity label [3H]EFDA bound at the same site on the protein as [3H] JH III. Fluorescent autoradiography of [3H]EFDA-labeled proteins separated by sodium dodecyl sulfate electrophoresis revealed that several proteins in both hemolymph and ovarian extracts bound [3H]EFDA. To determine the specificity of binding, extracts were irradiated with UV light in the presence of unlabeled JH III and [3H]EFDA. The results demonstrated that JH III prevented photoattachment of [3H]EFDA to a major protein in each extract. The molecular weight of these proteins was estimated at approximately 200,000 for both the hemolymph protein and the ovarian protein.

• Koeppe JK et al.
• Photoaffinity labeling of the hemolymph juvenile hormone binding protein of Manduca sexta.
• Biochemistry. 1984; 23: 6674-9
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• A synthetic analogue of the insect juvenile hormone (JH) III, 10,11-epoxy[10-3H]farnesyl diazoacetate [( 3H]-EFDA), binds to several proteins in a partially purified preparation of hemolymph protein from fourth instar larvae of Manduca sexta when irradiated with UV light. Approximately 80% of this binding could be inhibited by the addition of excess unlabeled JH I. To compare the relative affinity of EFDA for the juvenile hormone binding protein (JHBP) with that of the various JH homologues, the ability of unlabeled EFDA and JH homologues to displace [3H]JH I from binding sites was measured. The relative affinities were EFDA greater than JH I greater than JH II greater than JH III. When Scatchard analysis of the binding of [3H]EFDA or [3H]JH I to the larval JHBP was performed, an estimated apparent KD of 4.5 X 10(-8)M was found for EFDA, whereas for JH I a slightly higher KD of 8.8 X 10(-8) M was calculated. To determine if [3H]EFDA bound at the JH I binding site, displacement of [3H]JH I from the JHBP complex with unlabeled JH I, JH II, and JH III was compared to the displacement of [3H]EFDA with the same homologues. The results demonstrated that the photoaffinity label bound covalently at the JH I binding site on the hemolymph binding protein of Manduca sexta. Fluorescence autoradiography of [3H]EFDA photoaffinity labeled proteins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that [3H]EFDA bound covalently to two major proteins in the absence of JH I.(ABSTRACT TRUNCATED AT 250 WORDS)

• Kovalick GE, Koeppe JK
• Assay and identification of juvenile hormone binding proteins in Leucophaea maderae.
• Mol Cell Endocrinol. 1983; 31: 271-86
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• We modified a binding assay using polyethylene glycol (PEG) to precipitate bound hormone. Optimum precipitation occurred when reaction mixtures were incubated with 10-40% PEG and 1.25-2.5 mg/ml gamma-globulins for 2-90 min at 4 or 23 degrees C. Results from this assay and from the dextran-coated charcoal assay were similar. Addition of phenylmethylsulfonyl fluoride eliminated nonspecific esterase activity in extracts. JH III-binding macromolecules were identified in hemolymph and ovaries of Leucophaea maderae. These molecules were pronase- and heat-sensitive and saturable. Using Scatchard analysis an average KD of 2.04 (+/- 0.32) X 10(-8) M and 1.91 (+/- 0.80) X 10(-8) M was calculated for hemolymph and ovarian binding proteins. JH III had the highest affinity for binding sites, followed by JH I and JH 0. Various extraction procedures caused changes in JH affinity for both binding proteins. At high concentrations the (+) isomer and mixed isomer preparations of methoprene and hydroprene competed for binding sites. Binding proteins had no affinity for the (-) isomer or for the JH III acid.

• Roberts PE, Wyatt GR
• Juvenile hormone binding by components of fat body cytosol from vitellogenic locusts.
• Mol Cell Endocrinol. 1983; 31: 53-69
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• Binding of 3H-labeled juvenile hormone (JH) to cytosol components of fat body from adult female Locusta migratoria, a tissue in which JH stimulates vitellogenin synthesis, has been characterized. Protein-bound JH is separated from unbound hormone with hydroxyapatite, which is found to provide a more sensitive and less variable assay than use of dextran-coated charcoal. By chromatography on DEAE-cellulose, three JH-binding components have been separated from cytosol. BP-I exhibited relatively stable binding with little degradation of the hormone, gave a Kd for JH-I by Scatchard analysis of 1.69 X 10(-8) M, and binding of JH-I was competed by JH-I and several synthetic JH analogs in an order corresponding to their JH activities. These characteristics suggest that BP-I may be a cytoplasmic JH receptor. BP-II, a minor component, also bound JH-I stably, but competition by analogs was not correlated with their hormone activity. BP-III caused rapid degradation of JH to JH acid and may be an esterase.

• Prestwich GD, Kovalick GE, Koeppe JK
• Photoaffinity labelling of juvenile hormone binding proteins in the cockroach Leucophaea maderae.
• Biochem Biophys Res Commun. 1982; 107: 966-73

• Goodman W, Gilbert LI
• The hemolymph titer of juvenile hormone binding protein and binding sites during the fourth larval instar of Manduca sexta.
• Gen Comp Endocrinol. 1978; 35: 27-34

• Peterson RC, Reich MF, Dunn PE, Law JH, Katzenellnbogen JA
• Binding specificity of the juvenile hormone carrier protein from the hemolymph of the tobacco hornworm Manduca sexta Johannson (Lepidoptera: Sphingidae).
• Biochemistry. 1977; 16: 2305-11
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• A series of analogues of insect juvenile hormone (four geometric isomers of methyl epoxyfarnesenate, several para-substituted epoxygeranyl phenyl ethers, and epoxyfarnesol and its acetate and haloacetate derivatives) was prepared to investigate the binding specificity of the hemolymph juvenile hormone binding protein from the tobacco hornworm Manduct sexta. The relative binding affinities were determined by a competition assay against radiolabeled methyl (E,E)-3,11-dimethyl-7-ethyl-cis-10,11-epoxytrideca-2,6-dienoate (JH I). The ratio of dissociation constants was estimated by plotting competitor data according to a linear transformation of the dissociation equations describing competition of two ligands for a binding protein. The importance of the geometry of the sesquiterpene hydrocarbon chain is indicated by the fact that the binding affinity is decreased as Z (cis) double bonds are substituted for E (trans) double bonds in the methyl epoxyfarnesenate series; the unepoxidized analogues do not bind. A carboxylic ester function is important although its orientation can be reversed, as indicated by the good binding of epoxyfarnesyl acetate. In the monoterpene series, methyl epoxygeranoate shows no affinity for the binding protein, but substitution of a phenyl or p-carbomethoxyphenyl ether for the ester function imparts a low, but significant affinity. These data taken together with earlier results indicate that the binding site for juvenile hormone in the hemolymph binding protein is characterized by a sterically defined hydrophobic region with polar sites that recognize the epoxide and the ester functions.

• Kramer KJ, Dunn PE, Peterson RC, Seballos HL, Sanburg LL, Law JH
• Purification and characterization of the carrier protein for juvenile hormone from the hemolymph of the tobacco hornworm Manduca sexta Johannson (Lepidoptera: Sphingidae).
• J Biol Chem. 1976; 251: 4979-85
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• The larval hemolymph of the tobacco hornworm, Manduca sexta, contains a carrier protein that binds specifically and with high affinity the juvenile hormone, an important regulator of insect development. This protein serves to transport the hormone and to protect it from the action of degradative enzymes during early larval stages. Using hemolymph from the last larval stage, we have isolated a pure carrier protein using acetone precipitation, gel filtration, ion exchange chromatography, and preparative isoelectric focusing. Gel filtration, polyacrylamide gel electrophoresis in sodium dodecyl sulfate, and equilibrium ultracentrifugation established that the carrier protein is a single chain polypeptide of approximately 28,000 daltons. The amino acid composition is unexceptional, and no evidence for hexosamine has been obtained. An ion exchange filter disc assay method was used to determine the formation of the complex between the carrier protein and isotopically labeled juvenile hormone. With this technique it was shown that each carrier protein binds one hormone molecule with a dissociation constant of 4.4 +/- 0.2 X 10(-7) M at 0 degrees.

• Hammock B, Nowock J, Goodman W, Stamoudis V, Gilbert LI
• The influence of hemolymph-binding protein on juvenile hormone stability and distribution in Manduca sexta fat body and imaginal discs in vitro.
• Mol Cell Endocrinol. 1975; 3: 167-84
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• The wing discs and fat body of Manduca sexta larvae contain enzymes (i.e. carboxylesterase and epoxide hydratase) that can convert the C18 juvenile hormone (JH) to the acid, diol and acid diol. No evidence of oxidative degradation was noted. In vitro studies suggest that JH can be compartmentalized within the cells of the fat body where it is less accessible to degradative mechanisms. Experiments utilizing a hemolymph-binding protein fraction (BPF) in vitro with fat body and imaginal discs indicate that the BPF retards the uptake of JH by tissues and its subsequent degradation by tissue enzymes. BPF also appears to protect JH from degradation by enzymes released into the medium. By these mechanisms the insect can maintain elevated JH titers for relatively long periods. Binding protein may also keep JH in solution in the hemolymph allowing its rapid distribution throughout the insect. The data suggest that the binding protein plays a key role in maintaining juvenile hormone titers.

• Nowock J, Goodman W, Bollenbacher WE, Gilbert LI
• Synthesis of juvenile hormone binding proteins by the fat body of Manduca sexta.
• Gen Comp Endocrinol. 1975; 27: 230-9

• Solomon KR, Walker WF
• Letter: Juvenile hormone synergists: a possible case of hasty conclusion?
• Science. 1974; 185: 461-2