Structure-activity studies reveal two allatostatin receptor types in corpora allata of Diploptera punctata.

Synthetic variants of the octadecapeptide amide ASB2 (AYSYVSEYKRLPVYNFGL-NH(2)), a cockroach allatostatin, were assayed in vitro on corpora allata (CA) from 2-day-old (vitellogenic) and 10-day-old (post-vitellogenic) female Diploptera punctata. The analogs [(17)psi(18),CH(2)-S]ASB2, [D-Trp(17)]ASB2 and [Ile(18)]ASB2 inhibited juvenile hormone (JH) synthesis with simple dose-response curves on sensitive CA from 10-day-old females. These analogs were fully effective but less potent than ASB2. When tested on CA from 2-day-old mated females, which are only partially (65-70%) sensitive to ASB2, the three analogs gave biphasic dose-response curves and elicited a maximal effect only at higher concentrations. The dose-response curve for ASB2 on CA from 2-day-old females had a Hill plot slope of only 0.78+/-0.03. These findings suggested that the observed CA sensitivity to ASB2 may be the result of two partial responses having an IC(50) of approximately 0.35 and 3nM respectively. One partial response, or receptor type, appeared more sensitive than the other to adverse modification of the "message" segment of the peptide. The activity of shorter allatostatins was also studied, indicating that pentapeptides of the YXFGL-amide structure are fully effective, albeit at low potency, as inhibitors of JH biosynthesis.

Identity of a second type of allatostatin from cockroach brains: an octadecapeptide amide with a tyrosine-rich address sequence.

An octadecapeptide that inhibits juvenile hormone synthesis has been isolated by HPLC from brain-retrocerebral complexes of the cockroach Diploptera punctata. The primary structure of this allatostatin has been elucidated by tandem mass spectrometry: Ala-Tyr-Ser-Tyr-Val-Ser-Glu-Tyr-Lys-Arg-Leu-Pro-Val-Tyr-Asn-Phe-Gly-Leu- NH2 (ASB2). The amidated three-residue C terminus of this type B allatostatin is identical to that of four known type A allatostatins, and the preceding three residues show close structural homology. ASB2 has over twice the activity of the type A tridecapeptide Ala-Pro-Ser-Gly-Ala-Gln-Arg-Leu-Tyr-Gly-Phe-Gly-Leu-NH2 (ASA1) in inhibiting juvenile hormone biosynthesis in corpora allata from females in early vitellogenesis (day 2), and its efficacy persists during pregnancy, but it is equally effective as ASA1 on glands from day-10 females (IC50 = 0.31 nM). The octadecapeptide is characterized by a potential dibasic cleavage site, Lys9-Arg10, the integrity of which is needed for high potency. The ASB2-(11-18)-octapeptide amide gives a full response at high concentrations at day 10 (IC50 = 48 nM), but the C-truncated (1-9)-, (1-11)-, and (1-17)-amide fragments of ASB2 are inactive. Thus, the endocrine message is located at the C terminus. N alpha-acetylation of the N-truncated (9-18), (10-18), and (11-18) fragments of ASB2 increases activity relative to the nonacetylated peptides. The site of action of type A and type B allatostatins is located before mevalonate kinase in the biosynthetic pathway for juvenile hormone.

Changes in the sensitivity of adult cockroach corpora allata to a brain allatostatin.

There are major changes in the sensitivity of corpora allata from the cockroach Diploptera punctata toward the allatostatic tridecapeptide APSGAQRLYGFGL-amide (ASAL) during the female reproductive cycle, as revealed by measurement of juvenile hormone (JH) biosynthesis in vitro. Glands from recently molted adult females show only 30-40% inhibition at 10 nM ASAL, falling to a minimum of less than 10% on day 5 at the peak of spontaneous JH synthesis in vitro. The decline in JH synthesis observed in post-vitellogenic females is accompanied by a dramatic increase to ca. 90% ASAL sensitivity at 10 nM by day 6. Then sensitivity slowly wanes during subsequent ovulation and pregnancy to the levels typical of previtellogenic and virgin females. Full dose/response studies reveal a second level of response at ca. 1 microM, which resembles the pattern obtained from whole brain extracts. We conclude that physiological sensitivity to ASAL (IC50 ca. 0.1 nM) is correlated with the preparation for choriogenesis, and we suggest that 1000 times higher doses give a cross-reaction with related allatostatic receptor(s) that confer important sensitivity at other development stages.

Activity of the corpora allata of adult female Leucophaea maderae: effects of mating and feeding.

Juvenile hormone III biosynthesis by corpora allata of adult female Leucophaea maderae was measured by an in vitro radiochemical assay. In fed females, JH III synthesis increases more than 20-fold after mating to a peak of 55 pmol/pair/h on day 9 and then rapidly declines. This increase in JH III synthesis concomitant with rapid oocyte growth in mated females is not observed in virgin females. The corpora allata from starved, virgin females appear to be inactive. The addition of 150 microM 2E,6E-farnesol (a) JH III precursor) to the incubation medium stimulates the corpora allata from starved, virgin females less than the corpora allata from starved, mated females. Both feeding and mating are necessary for the expression of a normal cycle of JH III synthesis in this cockroach.

Identification of an allatostatin from adult Diploptera punctata.

A peptide (allatostatin) causing strong and rapid inhibition of juvenile hormone synthesis in vitro by corpora allata from reproductively active females has been isolated from brain/retrocerebral complexes of the cockroach Diploptera punctata. The primary structure of this 13-residue peptide has been determined: Ala-Pro-Ser-Gly-Ala-Gln-Arg-Leu-Tyr-Gly-Phe-Gly-Leu-NH2. Removal of the terminal amide group caused at least a ten thousandfold loss of activity. This neurohormone has no sequence similarity with any other known neuropeptide. Its target in the biosynthetic pathway is located prior to the conversion of farnesol to juvenile hormone.

The absolute configuration of precocene I dihydrodiols produced by metabolism of precocene I by corpora allata of Locusta migratoria, in vitro.

The corpora allata from adult female Locusta migratoria metabolize precocene I (7-methoxy-2,2-dimethyl-2H-benzo [b]pyran to cis- & trans-precocene I dihydrodiols (3,4-dihydro-7-methoxy-2,2-dimethyl-2H-benzo [b]pyran-3,4-diol). Derivatization of the dihydrodiols with (-)menthoxy acetyl chloride allowed complete resolution of all four optical isomers. When [4-3H]-precocene I was incubated in vitro with Locusta migratoria corpora allata, it was metabolized stereospecifically to (-)trans-(3R,4S) and (+)cis-(3R,4R) dihydrodiols. Approximately half the precosyl residues bound to cellular macromolecules were discharged by heating to 95 degrees C at neutral pH, as dihydrodiols of the same stereochemistry.

Enzymic synthesis of juvenile hormone in locust corpora allata: evidence for a microsomal cytochrome P-450 linked methyl farnesoate epoxidase.

Homogenates of corpora allata from adult Locusta migratoria in phosphate-buffered EDTA have been analysed by sucrose-density-gradient centrifugation. Succinate-cytochrome c reductase activity (mitochondrial) bands between d20/4 1.13-1.15, whereas NADPH-cytochrome c reductase and NADPH-dependent methyl farnesoate 10.11-epoxidase activities band identically between d20/4 1.06-1.12. We conclude that the methyl farnesoate epoxidase is exclusively microsomal. Farnesoic acid O-methyltransferase is an exclusively soluble enzyme which stoichiometrically transfers the S-methyl group from S-adenosylmethionine to farnesoic acid. No carboxyl esterase activity was found. Isolated microsomes were used to obtain an apparent Km = 7.7 X 10-6 M for the epoxidase, although substrate solubility limits the rate to 0.5 V. As expected, the product (juvenile hormone III) is chiral (10 R). The epoxidase is inhibited by excess NADP+ and oxidised cytochrome c, but neither inhibited nor synergised by NADH. NADH supports less than 10% of the NADPH rate of epoxidation. The epoxidase is inhibited by a carbon monoxide/oxygen atmosphere, half-maximal inhibition occurring at a CO/O2 ratio of 4.0. This inhibition is reversed by white-light irradiation.

Corpus allatum activity in vitro during ovarian maturation in the desert locust, Schistocerca gregaria.

1. Radiochemical in vitro assays show that there are large and rapid changes in the spontaneous rate of juvenile hormone synthesis and release during the course of sexual maturation in the locust. 2. Parallel observations on glands incubated with farnesenic acid show that the rate-limiting step is always prior to the stage of esterification of farnesenic acid to the final intermediate, methyl farnesoate. 3. Corresponding changes in oocyte morphometrics do not reveal any clear correlation between endocrine activity of the corpus allatum and either the induction or maintenance of rapid vitellogenesis. 4. Peaks of synthetic activity in the corpus allatum correspond well with the onset of previtellogenic growth in the oocytes. 5. The data do not provide any evidence that 'corpus allatum insufficiency' is responsible for resorption of growing oocytes. 6. It is concluded that short-term in vitro radio-assays provide a valid method for estimating quantitatively the physiological activity of the corpus allatum.

The influence of substrate concentrations on the rate of insect juvenile hormone biosynthesis by corpora allata of the desert locust in vitro.

The rate at which isolated corpora allata of adult female Schistocerca gregaria incorporate [(3)H]farnesenic acid and [(14)C]methionine into C(16)juvenile hormone in vitro was examined at different concentrations of farnesenic acid, methionine, O(2) and H(+) ions. Maximum juvenile hormone biosynthesis is obtained at a farnesenic acid concentration of 20mum. The range of optimum l-methionine concentrations (0.1-0.4mm) encompasses the physiological concentration of this substrate in the haemolymph. Hormone biosynthesis is dependent on O(2), but is not stimulated by hyperbaric oxygen tension. The glands had a maximum synthetic activity at pH8.0, but their activity was more reproducible in the the physiological range pH7.0-7.5. At pH6.5 and less, the synthetic ability was considerably decreased. The relative incorporations of the labelled substrates into methyl farnesoate and C(16) juvenile hormone indicate that [(3)H]farnesenic acid comes into isotopic equilibrium within the gland more rapidly than [(14)C]methionine. The incorporations into methyl farnesoate become stoicheiometric after 20min incubation and into C(16) juvenile hormone after a further 10min. Labelled juvenile hormone is detectable after 10min incubation and the rate of incorporation is constant for up to 4h. It is proposed that the described method may be usefully employed to assess the physiological changes in the enzymic competence of the glands to effect the last two stages in C(16) juvenile hormone biosynthesis.