A specific photoaffinity label for hemolymph and ovarian juvenile hormone-binding proteins in Leucophaea maderae

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.     

Further characterization of the juvenile hormone binding protein from the cytosol of a Drosophila cell line: Use of a photoaffinity label

Further characterization of the juvenile hormone (JH) binding protein from the cytosol of Drosophila melanogaster Kc cells has been accomplished with the use of a photoaffinity analogue of JH. The analogue, 10,11-epoxy(2E,6E)farnesyl diazoacetate (EFDA), is tritiated in the 10-position. Following photolysis with short-wave ultraviolet light, it can be demonstrated that [³H]EFDA binds specifically to the cytosolic JH binding protein. This binding is inhibited if irradiation occurs in the presence of either unlabelled JH I or JH III. Both JH homologues protect the binding site equally against [³H]EFDA. No protection is observed with either methoprene or farnesyl acetate, a close structural analogue of EFDA that lacks the diazo photoactivatable group.The cytosolic JH binding protein, following covalent labelling with tritiated EFDA, was characterized by gel filtration column chromatography, velocity sedimentation through sucrose gradients, both native and denaturing gels, and binding to DNA cellulose. The binding protein has a molecular weight of approx. 49,200 and may consist of two subunits.     

Synthesis and secretion of a precursor hemolymph juvenile hormone-binding protein in the adult female cockroach Leucophaea maderae

Hemolymph juvenile hormone-binding protein (JHBP) is synthesized and secreted from fat body in the adult female cockroach, Leucophaea maderae. The data in this paper suggest it is initially secreted from the fat body as a larger peptide whereas data in the accompanying paper demonstrate that JHBP is apolipophorin I. Using media from cultures of fat body maintained in vitro, a JH-binding component was found that is JH III saturable, has a K_D of 1.5 × 10⁻⁸ M, binds JH III > JH II > JH I, and has a sedimentation value of 6.5S on high salt sucrose gradients. Each of these properties is identical to those of the JHBP extracted from the hemolymph. To identify the protein that bound JH, media proteins were photoaffinity labeled with 10-[10,11-³H]epoxyfarnesyl diazoacetate ([³H]EFDA). The results revealed that two media proteins bound [³H]EFDA in the absence of JH III, but not in the presence of 100-fold excess JH III. The molecular weights of the two media peptides were estimated by SDS-PAGE to be 275,000 and 220,000.To determine if the JHBP found in media of fat body cultures was due to hemolymph contamination of fat body, incorporation of [³H]leucine into newly synthesized and secreted fat body proteins during a 48 h culture period was monitored. During the culture period, linear increases in the concentrations of radiolabeled 275 and 220 kD JHBP were observed. Monoclonal antibodies specific for the 220 kD hemolymph JHBP were found to recognize both the 275 and 220 kD JHBPs in the media.To investigate the possibility that the 275 kD protein is a precursor to the 220 kD protein and that components of the hemolymph process or modify the precursor, hemolymph was introduced into fat body cultures and relative concentrations of the 275 and 220 kD media JHBPs were determined. Addition of hemolymph to these organ cultures resulted in an increase in the concentration of radiolabeled 220 kD JHBP and a proportional decrease in the concentration of radiolabeled 275 kD JHBP, suggesting that the 275 kD protein is a precursor to the 220 kD hemolymph JHBP. The mechanism of processing or modification remains undetermined.     

Identification of a juvenile hormone binding protein in the castes of the termite,Reticulitermes flavipes,by photoaffinity labeling

Hemolymph proteins of the Eastern subterranean termite, Reticulitermes flavipes (Isoptera, Rhinotermitidae, Rhinotermitinae) were examined from sterile and reproductive castes using native and denaturing polyacrylamide gel electrophoresis (PAGE). A high-mass protein (ca. 700 kDa) exhibited specific, JH III-displaceable photoaffinity labeling with [³H]EFDA, a diazoacetate analog of JH III. This protein was present in each termite caste, and had the characteristics of a glycosylated lipoprotein, i.e. a lipophorin. The JH-binding subunit of this protein showed a molecular size of 230 kDa using SDS-PAGE. The differences in the hemolymph proteins present in the soldiers, workers, larvae, nymphs, and replacement reproductives of this rhinotermitid are discussed.     

Purification of the Drosophila Kc cell juvenile hormone binding protein

The juvenile hormone binding protein (JHBP) from the cytosol of Drosophila melanogaster Kc cells has been purified with the use of a juvenile hormone photoaffinity analog, 10,11-epoxy (2E, 6E) farnesyl diazoacetate (EFDA). The purification procedure consists of five chromatographic steps and the end product of the purification procedure showed homogeneity by means of both native and SDS polyacrylamide gel electrophoresis. Furthermore, using a racemic mixture of the natural hormone, [³H]juvenile hormone III (JH III), as the radioligand in this purification procedure, we demonstrate that the purified protein is likely the authentic intracellular JHBP.     

Synthesis and secretion of juvenile hormone binding protein by fat body from the cockroach Leucophaea maderae: Protein a immunoassay

Fat body maintained in vitro from adult female Leucophaea maderae synthesizes and secretes at least two peptides (275 and 220 kDa by SDS-PAGE) that can be photoaffinity labelled with the juvenile hormone analog 10-[10,11-³H]epoxyfarnesyl diazoacetate ([³H]EFDA). To determine if the synthesis of these peptides by the fat body is a stage-dependent phenomenon, a protein A immunoassay (PAA assay) for quantifying rates of [³H]leucine incorporation into these peptides was set up and its specificity of binding monitored.To produce antibodies specific for these peptides, hybridoma technology was utilized. Hemolymph juvenile hormone-binding protein (JHBP) was semi-purified on sucrose gradients and used to immunize BALB/c mice. After the mice displayed a relatively high immunotiter to a JHBP solution, their spleens were used for the production of IgG-secreting hybridomas. Successful fusions were initially screened by using an enzyme-linked immunosorbent assay [ELISA], while the specificity of the secreted antibody was determined by using migration patterns of IgG-linked JHBPs on sucrose gradients and reactivity on Western blots.Fixed staphylococci were used as a solid phase adsorbent for isolating [³H]leucine-labelled antigen-antibody complexes. Identification of the isolated IgG-complexed [³H]leucine-peptides by SDS-PAGE fluorography demonstrated the specificity of the staphylococcal protein A immunoassay. Using this immunoassay we have measured rates of synthesis and secretion of [³H]leucine-JHBPs from fat body maintained in vitro and have found their synthesis to be stage-dependent. Fat bodies from early virgin females were least active, while fat bodies from mated females were most active. Injections of JH III into decapitated virgin females stimulated the synthesis of the JHBPs, while mineral oil injections had no effect.     

Binding of juvenile hormone III to lipophorin from the american cockroach Periplaneta americana

Whole hemolymph from the American cockroach, Periplaneta americana, efficiently binds juvenile hormone (JH) III and to a lesser extent JH-I and 10, 11-epoxyfarnesyl diazoacetate (EFDA). The dissociation constants for racemic JH-III and EFDA are 30 ± 2 nM and 1.0 μM, respectively. Isolated lipophorin also binds [³H]JH-III and to a lesser extent JH-I. Other proteins from the hemolymph do not bind JH-III. Binding of JH-III to lipophorin is enantioselective. The dissociation constant, measured with a 92% 10R and 8% 10S mixture, is 21 ± 2 nM. Each lipophorin molecule contains one specific binding site for JH-III. It is concluded that lipophorin is the JH-III-specific transport protein in the hemolymph of the American cockroach. By a combination of photoaffinity labelling and gradient electrophoresis with sodium dodecyl sulphate on polyacrylamide gel, we showed that the JH-III-specific binding site is probably located on apolipophorin I.     

Juvenile hormone binding components of locust fat body

Juvenile hormone (JH) binding components from the fat body of the African migratory locust were analyzed in a search for a potential nuclear JH receptor. Biosynthetically prepared 10R[³H]JH III gave a high proportion of specific binding to isolated nuclei and extracted proteins; data obtained with the JH analogs, [³H]methoprene and [³H]pyriproxyfen, on the other hand, were obscured by abundant non-specific binding. The vast majority of the high affinity JH III binding activity present in cytosolic and nuclear extracts was due to a high molecular weight JH binding protein (JHBP) which has previously been identified in locust hemolymph. This protein has several chromatographic forms which interfered in the search for a nuclear JH receptor. When specific antiserum was used to remove JHBP from nuclear extracts, a novel JH binding activity (NBP) was detected. NBP could be separated from JHBP by precipitation with ammonium sulfate. NBP displayed a high affinity for JH III (Kd = 0.25 nM) and JH I and JH II competed strongly for JH III binding, whereas methoprene and pyriproxyfen showed apparent competition when present in 1,000-fold excess. NBP was present in nuclear extracts at approximately 25,000 sites per cell; levels were similar in male and female locusts and were not greatly affected by the presence or absence of JH. The characteristics of NPB make it a strong candidate for a nuclear JH receptor. © 1995 Wiley-Liss, Inc.     

The structure of a juvenile hormone-binding lipophorin from the hemolymph of Diploptera punctata

The high molecular weight, high affinity juvenile hormone binding protein from the hemolymph of Diploptera punctata was identified as a lipophorin by gradient KBr ultracentrifugation and SDS gradient PAGE. This juvenile hormone binding lipophorin (JHBL) was composed of two subunits, apolipoprotein I (230 kDa mol. wt) and apolipoprotein II (80 kDa mol. wt). The density of the native protein was 1.15 g/ml. Photoaffinity labeling using the JH analog [³H]EFDA demonstrated that the JH binding site resides on apolipoprotein I. The amino acid composition of both native lipophorin and its two subunits was determined and the N-terminal sequence of the 80 kDa apolipoprotein described for 19 of the first 21 amino acids. This sequence did not have similarity to any known protein. The N-terminus of the 230 kDa apolipoprotein was blocked. The specificity of a monoclonal antibody to purified native JHBL was also demonstrated. We show that the monoclonal antibody was specific to the 230 kDa subunit and did not recognize the 80 kDa apolipoprotein.     

Control of active proton transport in turtle urinary bladder by cell pH

The rate of active H+ secretion (JH) across the luminal cell membrane of the turtle bladder decreases linearly with the chemical (delta pH) or electrical potential gradient (delta psi) against which secretion occurs. To examine the control of JH from the cell side of the pump, acid-base changes were imposed on the cellular compartment by increasing serosal[HCO3-] at constant PCO2 or by varying PCO2 at constant [HCO3-]. When serosal [HCO3-] was increased from 0 to 60 mM, cell [H+] decreased, as estimated by the 5,5-dimethyloxazoladine-2,4- dione method. JH was a saturable function of cell [H+], with an apparent Km of 25 nM. When PCO2 was varied between 1 and 20% at various serosal Km of 25 nM. When PCO2 was varied between 1 and 20% at various serosal [HCO3-], the PCO2 required to reach a maximal JH increased with [HCO3-] so that JH was a function of cell [H+] rather than of cell [HCO3-] or CO2. The proton pump was controlled asymmetrically with respect to the pH component of the electrochemical potential for protons, microH. On the cell side of the pump, a delta pH of < 1 U was required to vary JH between maximal and zero values, whereas on the luminal side a delta pH of 3 U was required. Cell [H+] regulates JH by determining the availability of H+ to the pump in a relationship resembling Michaelis-Menten kinetics. Increasing luminal [H+] generates an energy barrier at a luminal pH near 4.4 that equals the free energy (per H+ translocated) of the metabolic driving reaction.     

Biosynthesis and regulation of juvenile hormone III,juvenile hormone III bisepoxide,and methyl farnesoate during the reproductive cycle of the grey fleshfly,Neobellieria (Sarcophaga) bullata

To study the effect of brain signals on the biosynthesis of juvenile hormone by the corpora allata of the grey fleshfly Neobellieria bullata, exposed corpora allata connected to the brain were surgically removed from sugar-fed flies and incubated in vitro with L -[³H-methyl]methionine. After incubation, the media together with the tissues were analyzed by HPLC. [³H]Juvenile hormone III (JH III), [³H]JH III bisepoxide (BE), [³H]methyl farnesoate (MF) and an unknown [³H]labeled metabolite (Un) were identified as the primary products. The rate of synthesis of [³H]JH III bisepoxide was higher than that of [³H]JH III, [³H]MF and [³H]Un. Two days after a liver meal, female flies synthesized more JH III, MF, BE, and the Un than did males. Synthesis of JH III, BE, and MF in females was lower during the previtellogenic, sugar-feeding period than during the vitellogenic liver-feeding period. Isolated corpus cardiacum–corpus allatum (CC-CA) complexes that were incubated in vitro synthesized less JH III, MF, and BE, as compared to complexes that were attached to the brain, indicating that the brain probably modulates the biosynthesis of JH III, MF, and BE in the corpora allata. Upon incubation of brain–CC–CA complexes with Neb-TMOF (10^–8 M), Neb-colloostatin (10^–8 M), ovarian, or brain extracts resulted in significant inhibition of JH III and BE biosynthesis in the presence of ovarian extracts. These results indicate that allatostatin-like factors are present in the ovary of the flesh fly. Arch. Insect Biochem. Physiol. 37:248–256, 1998. © 1998 Wiley–Liss, Inc.     

Photoaffinity labeling of the epithelial sodium channel

Sodium enters tight epithelia across the apical plasma membrane through a sodium channel, a process inhibited by submicromolar concentrations of amiloride and benzamil. Using membrane vesicles from bovine kidney cortex, we found that sodium transport through the sodium channel was inhibited by benzamil with an IC50 of 4 nM. Amiloride (IC50 = 400 nM) was a weaker inhibitor of sodium transport. [3H]Benzamil bound to the vesicles at a single class of high affinity binding sites with a Kd of 5 nM, the similarity of which to the IC50 suggests that these binding sites are associated with the sodium channel. Amiloride displaced bound [3H]benzamil with a Ki of 2,500 nM. Bromobenzamil is a photoactive amiloride analog with potency similar to benzamil in inhibiting sodium transport (IC50 = 5 nM) and binding to the sodium channel (Kd = 6 nM). [3H]Bromobenzamil was specifically photoincorporated into three molecular weight classes of polypeptides with apparent Mr values of 176,000, 77,000, and 47,000. The photoincorporation of [3H]bromobenzamil into these three classes of polypeptides was blocked by addition of excess benzamil and by amiloride in a dose-dependent manner. These data suggest that these polypeptides are components of the epithelial sodium channel.     

Simultaneous preparation of both enantiomers of juvenile hormones labeled at C-10 with tritium at high specific activity

We report an improved method for the synthesis of high specific activity insect [10-(3)H]juvenile hormones (JH) I, II, and III which affords both enantiomers of each in high optical purity. A synthetic route for JH I was modified to give higher yields and purity. We increased the specific activity of the synthetic [10-(3)H]JHs using normal phase liquid chromatography optimized to give near baseline resolution of [10-(3)H]JHs and unlabeled JHs. Racemic [10-(3)H]JHs and their corresponding diol metabolites were enantiomerically separated using a chiral column eluted with 2-propanol:hexane. Acidic hydration of the unnatural antipode of the [10-(3)H]JHs gives the diol antipode with the same stereochemistry as that from epoxide hydrolase action on the natural JH antipode. The [10-(3)H]JH diol enantiomers can also be resolved with the same chiral column using a more polar solvent. The synthesis of high specific activity chiral ethyl ester analogs of JH I and II can also be accomplished using this synthetic route.     

Biosynthesis of (10R)-Juvenile hormone III from farnesoic acid by Aedes aegypti ovary

Synthesis of (10R)-juvenile hormone III (JH III) outside the corpora allata (CA) was investigated in female Aedes aegypti. Intact females or ligated abdomens of blood-fed and sugar-fed females synthesized in vivo [12-³H]JH III-like molecules from [12-³H]-methyl farnesoate, indicating that an organ(s) in the female abdomen, other than the CA, converted methyl farnesoate into JH III. To find out the organ(s) that synthesized JH III-like molecules, ovaries, fat bodies, and midguts were incubated in vitro with [12-³H]methyl farnesoate and the synthesis of JH III-like molecules was compared with JH III synthesized by CA. To identify tissue(s) having both farnesoic acid methyl transferase and farnesoate epoxidase, enzymes that convert farnesoic acid into JH III, ovaries, and fat bodies were removed from sugar and blood-fed females and incubated with [12-³H]farnesoic acid. Chemical derivatization by methoxyhydrin formation followed by esterification with (+)-α-methoxy- α-trifluoromethyl phenylacetic (MTPA) acid chloride and reversed phase liquid chromatography identified (10R)-JH III methoxyhydrin (+)-MTPA ester as the sole JH III-like molecule produced in tissue culture incubation of ovaries. Since only (10R)-JH III is produced and not racemic JH III, the oxidation of farnesoic acid must be enzymatically mediated. Ovaries and corpora allata of female A. aegypti also synthesized [³H,¹⁴C]JH III from L-[methyl-³H]methionine and [¹⁴C]acetate which was characterized by HPLC and gas chromatography. These results suggest that mosquito ovary can synthesize (10R)-JH III from farnesoic acid, and that this tissue synthesizes JH III-like molecules from L-methionine and acetate. © 1994 Wiley-Liss, Inc.     

Covalent cross-linking of prostaglandin E receptor from bovine adrenal medulla with a pertussis toxin-insensitive guanine nucleotide-binding protein

Prostaglandin E2 (PGE2) specifically bound to 100,000 X g pellet prepared from bovine adrenal medulla, and [3H]PGE2-bound proteins were solubilized with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid. The dissociation of bound [3H]PGE2 from the proteins was enhanced by GTP. [3H]PGE2-specifically bound proteins were adsorbed onto a wheat germ agglutinin column and GTP treatment decreased the amount of [3H]PGE2 retained on the column. When [3H]PGE2-bound proteins were cross-linked in the membrane by dithiobis(succinimidyl propionate) and solubilized, bound [3H]PGE2 was no longer dissociated by GTP treatment, suggesting that cross-linking produced a stable and high-affinity complex of PGE receptor with a GTP-binding protein. Covalent cross-linking of the complex was attested by adsorption of dithiobis(succinimidyl propionate)-treated [3H]PGE2-bound proteins to GTP-Sepharose, and co-elution of [35S]guanosine 5'-O-(3-thiotriphosphate) binding activity and immunoreactivities of alpha o and beta subunits of a GTP-binding protein. The cross-linked [3H]PGE2-bound complex was eluted as an apparently single radioactive peak at the position of Mr = 200,000 by gel filtration. These results have demonstrated that PGE receptor is a glycoprotein with an approximate Mr of 110,000, assuming that the Mr of the GTP-binding protein is 90,000. PGE2 neither activated nor inhibited adenylate cyclase activity, and pertussis toxin (islet-activating protein) did not affect PGE2 binding and its GTP sensitivity. These results suggest that the PGE receptor may be functionally associated with a pertussis toxin-insensitive GTP-binding protein and is not coupled to the adenylate cyclase system in bovine adrenal medulla.     

Characterization of juvenile hormone-binding proteins of hemolymph of Locusta migratoria

The binding of juvenile hormone (JH) by components from hemolymph of adult female Locusta migratoria was characterized to establish whether hemolymph JH-binding proteins could be distinguished from a protein of fat body (BP-1) that may be a JH receptor. Hemolymph was analyzed by the hydroxyapatite assay, gel separation chromatography, polyacrylamide gel electrophoresis, and density gradient centrifugation. Three fractions that bound JH were separated from whole hemolymph by DEAE cellulose column chromatography, and these differed from all three cytosol-binding components. The major hemolymph component (H-A) showed relatively stable binding of JH, a slight loss of binding capacity after delipidation, and a K_d for JH-I of 16 nM. The K_ds for JH-l and JH-lll with unfractionated hemolymph were 26 and 42 nM respectively. The order of effectiveness of competitors for binding of [³H]JH-l was JH-lll > JH-l ? methoprene > hydroprene ? acids of methoprene and hydroprene. The data indicated that unlabeled JH-lll was bound more effectively than its radioactive counterpart. The sedimentation values determined by sucrose density gradient ultracentrifugation were 13-14 S for hemolymph, and the sedimentation value was not altered by the inclusion of 0.4 M KCl throughout the gradient. The data indicated that H-A resembled the specific JH carriers and differed from the putative receptor of fat body cytosol by several criteria.     

Protein substrates activate the ATP-dependent protease La by promoting nucleotide binding and release of bound ADP

The interaction of protein substrates with protease La from Escherichia coli enhances its ability to hydrolyze ATP and peptide bonds. These studies were undertaken to clarify how unfolded proteins allosterically stimulate this ATPase activity. The tetrameric protease can bind four molecules of ATP, which activates proteolysis, or four molecules of ADP, which inhibits enzymatic activity. Protein substrates stimulate binding of the nonhydrolyzable ATP analog [3H] adenyl-5'yl imidodiphosphate, although they do not increase the net binding of [3H]ATP or [3H]ADP. Once bound, ATP is quickly hydrolyzed to ADP, which remains noncovalently associated with protease La even through repeated gel filtrations. Exposure to protein substrates (e.g. denatured bovine serum albumin at 37 degrees C) induces the release of all the bound ADP from the enzyme. Nonhydrolyzable ATP analogs bound to the enzyme were not released by these substrates. Proteins that are not degraded (e.g. native bovine serum albumin) and oligopeptides that only bind to the catalytic site do not induce ADP release. Thus, polypeptide substrates have to interact with an allosteric site to induce this effect. The protein-induced ADP release is inhibited by high concentrations of Mg2+ and is highly temperature-dependent. Protein substrates promoted [3H]ATP binding in the presence of ADP and Mg2+ (i.e. ATP-ADP exchange) and reduced the ability of ADP to inhibit the enzyme's peptidase and ATPase activities. These results indicate that: 1) ADP release is a rate-limiting step in protease La function; 2) bound ADP molecules inhibit protein and ATP hydrolysis in vivo; 3) denatured proteins interact with the enzyme's regulatory site and promote ADP release, ATP binding, and their own hydrolysis.     

Effect of cell density on thrombin binding to a specific site on bovine vascular endothelial cells

We studied thrombin binding to proliferating and confluent endothelial cells derived from bovine vascular endothelium. [125]thrombin was incubated with nonconfluent or confluent endothelial cells and both the total amount bound and the amount linked in a 77,000-dalton thrombin- cell complex were determined. Approximately 230,000 molecules of thrombin bound per cell in nonconfluent cultures compared to 12,800 molecules per cell in confluent cultures. Approximately 67,7000 thrombin molecules were bound in an apparently covalent complex, Mr = 77,000, with each cell in sparse cultures, whereas only 4,600 thrombin molecules per cell were bound in this complex with confluent cultures. Similar studies with [125I]thrombin and endothelial cells derived from bovine cornea revealed no difference either in the total amount of thrombin bound or in the amount bound in the 77,000-dalton complex using sparse or confluent cultures. When confluent vascular endothelial cultures were wounded, additional cellular binding sites for the 77,000- dalton complex with thrombin appeared within 24 h. A 237% increase in the amount of thrombin bound to these sites was induced by a wound which resulted in a 20% decrease in cell number in the monolayer. There was no significant increase in thrombin binding to other cellular sites at 24 h. These experiments provide evidence that the first change in thrombin binding after injury is an increase in the cellular sites involved in the 77,000-dalton complex, and suggest that thrombin binding to endothelial cells may be important in the vascular response to injury.     

Nuclear binding sites for juvenile hormone III in the male accessory reproductive glands of Melanoplus sanguinipes

Summary

We have identified a potential nuclear juvenile hormone (JH) receptor in the long hyaline tubules (LHT), part of the male accessory reproductive gland (MARG) of M. sanguinipes. The MARG was incubated in vitro with [³H]JH III, and the distribution of the [³H]JH III among the cellular fractions of the LHT was determined. Some 37±4% of the radioactivity was associated with the crude nuclear pellet, while the cytosolic, microsomal and mitochondrial fractions contained 30±3%, 23±2% and 10±1%, respectively. The bound JH III was measured in nuclear extracts of LHT from males up to 15 days post-eclosion. These results revealed that JH binding increased in an age-dependent manner up to day 7, then levelled off to day 12, to increase again on day 14. The nuclear-binding component in the LHT had a very strong affinity for JH III, with a K_D value of 0.8 nM. Our observations are considered in relation to the potential site and mode of action of JH.