Phospholipid synthesis in the fat body endoplasmic reticulum during primary and secondary juvenile hormone stimulation of vitellogenesis inLeucophaea maderae

Summary Juvenile hormone (JH) treatment coordinately stimulated the dose-dependent synthesis of vitellogenin and endoplasmic reticulum (ER) membrane phospholipids in fat body cells from allatectomized adult females ofLeucophaea maderae. Animals were pulse-labeled in vivo with [³²P] to simultaneously measure the rates of synthesis of the phosphorylated subunits of vitellogenin and the structural phospholipids of the ER membranes. Phospholipid synthesis in ER membranes from nontarget tissues for JH such as thoracic muscle, midgut, and larval fat body was unresponsive to hormone treatment. The proliferation of ER in response to JH treatment was thus restricted to tissue that was competent to synthesize vitellogenin.Primary and secondary vitellogenin induction was measured in allatectomized adult females treated 12 days apart with JH-III. The time-course of the primary response for vitellogenin and ER phospholipid synthesis was characterized by a 24 h latent period, a rapid increase to a maximum at 72 h, and then a gradual decline. During secondary induction, vitellogenin accumulated in the hemolymph nearly twice as fast as before and peaked at a concentration of 38 g/l. This vitellogenin titer was approximately two-fold higher than that found at the height of the primary response. During both primary and secondary stimulation with JH, ER phospholipid synthesis, as measured by [¹⁴C]choline incorporation into microsomal phosphatidylcholine, was stimulated five-fold over the untreated control animals. The amplified production of vitellogenin during the secondary response was associated with a 24 h-earlier peak of ER phospholipid synthesis in the fat body.     

Isolation and sequence of a partial vitellogenin cDNA from the cockroach,Blattella germanica (L.) (Dictyoptera,Blattellidae), and characterization of the vitellogenin gene expression

A partial cDNA clone of the vitellogenin gene from the cockroach Blattella germanica has been isolated from a cDNA expression library using an anti-vitellin–vitellogenin antiserum probe. The analysis of cDNA inserts gave a sequence of 2,645 nucleotides corresponding to the 3′ region. The deduced amino acid sequence is 825 residues long and is similar to the homologous portion of the vitellogenin of other insect species, especially that of the mosquito Aedes aegypti. RNA hybridization studies indicated that the vitellogenin gene expression is limited to the fat body of adult females. The pattern of expression during the first vitellogenic cycle was approximately parallel to that of vitellogenin production by the fat body previously described. The availability of a cDNA probe for the B. germanica vitellogenin gene represents a useful tool to study the molecular action of hormones affecting vitellogenin synthesis in this species. Arch. Insect Biochem. Physiol. 38:137–146, 1998. © 1998 Wiley-Liss, Inc.     

Juvenile hormone-controlled vitellogenin synthesis in Locusta migratoria fat body. Hormonal induction in vivo.

Biosynthetic processes related to the production of vitellogenin (yolk precursor protein) have been examined in the fat body of adult female Locusta migratoria. Vitellogenin-producing capacity was assayed by incubation of fat body with [³H]leucine, followed by precipitation from the medium with specific antiserum. In normal development, vitellogenin synthesis began at about Day 7 after emergence and became maximal at about Day 13, when this protein accounted for 60% of the total fat body protein output. The production of other proteins increased to a lesser extent, becoming maximal at about Day 6. The incorporation of uridine into fat body RNA rose to a maximum at Day 8, which coincided with a marked increase in tissue RNA content. The DNA content in adult female fat body approximately doubled between Days 3 and 8. Vitellogenin synthesis, and the increases in RNA and DNA, were prevented by removal of the corpora allata (the source of juvenile hormone). In allatectomized locusts, vitellogenin synthesis was induced by JH or an analog, ZR-515. Applied topically in acetone, these gave steep dose-response curves, half-maximal at 75 and 150 μg, respectively. After a single treatment with ZR-515, fat body vitellogenin production rose slowly during 48 hr, then steeply to a maximum at 72 hr, but after decay of this effect during 10 days, a second application of ZR-515 induced renewed synthesis with little initial lag. Hormone treatment produced a smaller increase in the output of other proteins, and an increase in incorporation into RNA which preceded the major rise in vitellogenin synthesis. Male fat body produced little or no vitellogenin. These results are consistent with action of JH at the gene level.     

Ovarian maturation in Leucophaea maderae: Juvenile hormone regulation of thymidine uptake into follicle cell DNA

Our research demonstrates that juvenile hormone (JH I) stimulates thymidine incorporation into ovarian follicle cell DNA in the ovoviviparous cockroach, Leucophaea maderae.A rapid, quantitative method for monitoring ³H-thymidine incorporation into ovarian DNA, in vitro, is described. Cultured ovarian tissue from L. maderae incorporates ³H-thymidine into DNA at a linear rate between 16 and 120 min; analysis of the incorporated label revealed at least 98% of it to be in DNA.Using L. maderae females that had been mated 7 days after adult emergence, we monitored the following biochemical phenomena during the 18–22 day period of terminal oöcyte growth: (1) ³H-thymidine incorporation into ovarian DNA: (2) general protein synthesis in fat body; and (3) specific fat body vitellogenin synthesis.Decapitation of mated females with maturing oöcytes arrested both ovarian DNA synthesis and fat body vitellogenin synthesis. Substantial restoration of both types of synthesis was induced by injection of JH I. The resumption of thymidine incorporation into DNA was localized in the follicular epithelium of the terminal oöcyte.In decapitated virgin females, injection of JH I stimulated oöcyte growth and ³H-thymidine incorporation into ovarian DNA. Dose and time response curves indicate that peak stimulation of ovarian DNA synthesis occurred between 72 and 96 hr after administration of a single optimal dose of 25 μg JH I. The concurrent manifestation of ³H-thymidine uptake into ovarian DNA and activity within the fat body indicates that a similar hormonal mode of action may be operative with respect to both tissue types in virgin females.     

Fat body is the site of vitellogenin synthesis in the soft tick,Ornithodoros moubata

Summary Vitellogenin (Vg) synthesis in cultured tissues was analysed biochemically in a soft tick,Ornithodoros moubata. Nine tissue fractions dissected from reproductive females were incubated in vitro in a specially designed Ringer containing³⁵S-methionine. The synthesis of total protein and Vg was assayed by the radioactivity incorporated into precipitates with trichloroacetic acid and antivitellin (Vn)-serum, respectively. Fat body was the most active tissue in Vg synthesis, which comprised 46% of the Vg synthesis by all tissues and 42% of total protein synthesis by fat body. Protein synthesized by the fat body and precipitated with anti-Vn-serum was shown by electrophoresis and fluorography, to consist of six radioactive polypeptides corresponding to the components of Vg. Vg synthesized in cultured fat body was first accumulated in the tissue and secreted into the medium during incubation. Some tissues other than fat body showed low Vg synthesis (in each, less than 12% of total protein synthesis) which, however, may be due to contamination by fat body cells as seen with the scanning electron microscope (SEM). SEM also showed that fat body cells in the active stage of Vg synthesis expanded about 10-fold in length. Immunohistochemical analysis showed a very strong reaction with anti-Vn-IgG in the cytoplasm of fat body from reproductive females. Fat body from unfed females and other tissues including midgut, did not show any specific fluorescence. A positive reaction was obtained with developing oocytes. These results indicate that the fat body is the only site of Vg synthesis in this tick.Abbreviations Vg vitellogenin - Vn vitellin - SDS sodium dodecyl sulfate - PAGE polyacrylamide gel electrophoresis - SEM scanning electron microscopy - TCA trichloroacetic acid     

Proteolytic enzymes and blood digestion in the mosquito,Culex nigripalpus

The synthesis of proteolytic enzymes in the fat body and midgut of female Culex nigripalpus was followed. The effects of brain factor(s) and RNA levels in the fat body were correlated with the synthesis of proteolytic enzymes. Trypsinlike activity in the midgut of C. nigripalpus accounted for 80% of total proteolytic activity, whereas chymotrypsinlike activity accounted for 5–7% of total proteolytic activity. Synthesis of porteases in the midgut and fat body reached a peak at 35 h and 22 h after the blood meal, respectively. In the fat body, proteolytic enzyme activity fell to a low level 30 h after the blood meal, but activity in the midgut reached a low level 58 h after the blood meal. The presence of low protease activity in the fat body at the time of peak vitellogenin synthesis indicated that processing of vitellogenin was not done in this tissue. Fat bodies incubated in vitro in the presence of [¹⁴C]valine synthesized a [¹⁴C]labeled trypsinlike molecule identified as such with antitrypsin antibodies and specific substrate p-toluene-sulphonyl-L-arginine methylester (TAME) and on disc gel electrophoresis in the presence of dodecyl sulfate. The sizes of the proteins found inside and outside the peritrophic membrane were determined by gel-chromatography and disc gel electrophoresis in the presence of dodecyl sulfate. The molecular weight (± SEM) of the largest polypeptide that migrated through the peritrophic membrane into the ectoperitrophic space was found to be 23,000 ± 2,000 daltons. Based on these results, a model is proposed to account for blood digestion in the mosquito midgut, along with the role of the peritrophic membrane.     

Biosynthesis,purification, and characterization of Aedes aegypti vitellin and vitellogenin

Vitellin, the major egg yolk protein, and vitellogenin, the hemolymph precursor of egg yolk protein, have been purified to apparent homogeneity from the mosquito Aedes aegypti. The purification procedure included chromatography on ion exchange, hydrophobic, and gel filtration columns. Vitellin and vitellogenin have a similar molecular weight (M_r 300,000) on gel filtration columns. However, the molecular weights of vitellin and vitellogenin, as determined from SDS electrophoresis, were 393,000 and 337,000, respectively. Vitellin in sodium dodecyl sulfate released six subunits of molecular weight 116,000, 83,000, 75,000, 54,000, 36,000, and 29,000, whereas vitellogenin released only three subunits (155,000, 120,000, and 62,000). The average molecular weights of vitellin and vitellogenin after gel filtration and SDS electrophoresis were 346,000 and 318,000, respectively. Vitellin has a high content of aspartic acid and glutamic acid, and a low content of histidine, methionine, cysteine, and tryptophan. Vitellin also contains 0.9% mol of glucosamine and no galactosamine. The isoelectric points of vitellin and vitellogenin are at pH 6.4 and 6.3, respectively. Aedes aegypti fat bodies incubated for short intervals in tissue culture medium in the presence of [³H]valine showed incorporation by radio-immunoprecipitation and SDS electrophoresis into three primary vitellogenin polypeptides of molecular weights (± SEM) 156,000 ± 4,000, 114,000 ± 5,000, and 62,000 ± 400 inside the fat body and 162,000 ± 3,000, 118,200 ± 2,000, and 63,000 ± 300 in the medium. These results suggest that the molecular weight of vitellogenin synthesized inside the fat body (M_r 332,000) remains unchanged when secreted into the hemolymph (M_r 343,000). The three vitellogenin subunits are processed by the ovary into six subunits which are then deposited in the yolk granules as vitellin.     

The vitellogenin of Leucophaea maderae: Synthesis as a large phosphorylated precursor

Phosphorylation of vitellogenin (yolk protein precursor) and vitellin (major yolk protein) polypeptides of Leucophaea maderae was studied by [³²P]ortho phosphate labeling and subsequent sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) autoradiography. The vitellogenin molecule was isolated from the hemolymph and fat body by antibody precipitation and high-performance liquid chromatography (HPLC), and shown to consist of at least five polypeptides (“subunits”) which had apparent molecular masses of 155, 112, 95, 92 and 54 kD. Labeling studies with ³²P showed that the covalently attached phosphorus was distributed in an uneven fashion among the five polypeptides. The two heavily-phosphorylated polypeptides, 112 and 54 kD, corresponded to the large and small, mature vitellin subunits. Quantitative SDS-PAGE analysis of long-term ³²P-labeled vitellin showed that these large and small “subunits” contained 55 and 30%, respectively, of the total radioactivity.When fat body was pulse-labeled with ³²P we found a heavily-phosphorylated intracellular 215 kD polypeptide which was precipitable with anti-vitellogenin. The synthesis of this intracellular precursorform of vitellogenin (pre-Vg) was under absolute juvenile hormone control. In vitro³²P pulse-chase experiments showed that pre-Vg was proteolytically processed within the fat body into some (or possibly all) of the mature vitellogenin subnits. Furthermore, peptide mapping confirmed that all of the phosphorylated vitellogenin subunits were derived from pre-Vg. Since previous studies have shown that phosphoserine residues account for essentially all of the covalently-attached phosphorus of the native vitellogenin molecule, we speculate that the asymmetric pattern of vitellogenin and vitellin subunit-phosphorylation is due to an uneven distribution of phosphoserine residues along the initial pre-Vg polypeptide chain. Finally, we conclude that phosphorylation of vitellogenin occurred post-translationally in the fat body endoplasmic reticulum because we could identify ³²P-labeled pre-Vg in purified microsomal vesicles but not in nascent vitellogenin polypeptide chains attached to vitellogenin polyribosomes.     

Activation of vitellogenin synthesis in the mosquito Aedes aegypti by ecdysone

Injected β-ecdysone was found to induce the synthesis of yolk protein (vitellogenin) in adult female Aedes aegypti without a blood meal. After injection of 5 μg ecdysone per mosquito, vitellogenin constituted 80 per cent of the total protein secreted by explanted fat body, a proportion comparable to that produced by fat body from blood-fed females. Moreover, the time course of induction of vitellogenin synthesis in ecdysone-injected mosquitoes was similar to that triggered by a blood meal. Response to ecdysone is dosedependent: 0·5 μg per female was required to stimulate synthesis to 50 per cent of the level found 18 hr after a blood meal. Ecdysone was effective in decapitated or ovariectomized mosquitoes, and also when applied directly to fat body preparations in vitro. Thus it appears that ecdysone acts directly on the fat body to induce specific protein synthesis, as does the vitellogenin stimulating hormone (VSH) from the ovary of blood-fed mosquitoes. These results suggest that ecdysone can replace VSH in inducing vitellogenin synthesis in the unfed mosquito.     

Ultrastructural immunocytochemical localization of vitellogenin in the fat body of the blowfly,Calliphora vicina Rob.-Desv. (erythrocephala Meig.) by use of the unlabeled antibody-enzyme method

Summary The unlabeled antibody-enzyme method was used to demonstrate ultrastructurally the specific localization of vitellogenin in the fat body of Calliphora. In control flies the binding sites to vitellogenin were localized in secretory granules situated in the Golgi complex, and in larger bodies named composite secretory granules. These composite granules appear to be formed when a part of a Golgi complex containing secretory granules and a number of small vesicles become surrounded by a common membrane. Ovariectomized flies, which apparently do not produce secretory granules, exhibited no immunocytochemical staining. Ovariectomized flies in which the administration of ecdysterone induced formation of secretory granules, also revealed specific staining on these granules. This is the first ultrastructural evidence of: (a) the specific localization of vitellogenin in secretory granules of the fat body of an insect; (b) the relationship between the presence of the ovary, and of ecdysterone, and the synthesis of vitellogenin by the fat body.     

Hepatopancreas is the extraovarian site of vitellogenin synthesis in black tiger shrimp, Penaeus monodon

The site of yolk protein synthesis in crustaceans has long been a subject of controversy. The vitellogenin gene structure was partially reported only very recently in Macrobrachium rosenbergii, after which the hepatopancreas was confirmed as the extraovarian site of vitellogenin synthesis in that species. Ovaries are the most frequently reported as the site of yolk protein synthesis in penaeid shrimp. Using cDNA reversed-transcribed from mRNA isolated from the hepatopancreas of vitellogenic female shrimp, Penaeus monodon, we found that its deduced amino acid sequence had high identity of 48% with that from M. rosenbergii vitellogenin. A similar location of the intron in the sequenced region of genomic DNA was also found between these two species. We therefore concluded that the hepatopancreas the extraovarian site of vitellogenin synthesis in P. monodon in vivo. The partial structure of vitellogenin gene is presented in this study.     

S6 protein kinase activates Juvenile Hormone and vitellogenin production in the cockroach Blattella germanica

Nutritional status regulates different processes, such as growth and development, through TOR (target of rapamycin) and insulin receptor signalling pathways. The ribosomal S6 protein kinase (S6K) is a downstream element of both pathways. Using cDNA from the German cockroach Blattella germanica (L.), two S6K isoform sequences (BgS6K) are cloned. The long isoform differs from the short one by the insertion of a 22‐amino acid duplication, involving the key phosphorylation position Thr³⁹⁰. As a result of this, the long isoform presents a new, potentially regulatory phosphorylation site. RNA interference knockdown of both BgS6K isoforms induces an increase in the length of the last nymphal instar, together with a reduction in the mRNA levels of a number of enzymes of the Juvenile Hormone biosynthetic pathway in the corpora allata, vitellogenin mRNA levels in the fat body and basal oocyte length. Thus, BgS6K is important for nymphal development and is necessary for the full induction of Juvenile Hormone synthesis and vitellogenin production in adult females.     

Response of cultured Aedes aegypti fat bodies to 20-hydroxyecdysone

Fat bodies from non-blood-fed Aedes aegypti, stimulated in vitro by 10⁻⁴ M and 10⁻⁶ M of 20-hydroxyecdysone, were found to synthesize and release vitellogenin into the culture medium. Vitellogenin-specific monoclonal antibodies were utilized in an enzyme-linked immunosorbent assay procedure for quantification of vitellogenin in small aliquots of medium taken periodically from the culture. A minimal exposure of 5 h to 20-hydroxyecdysone was shown to be needed before the fat bodies would respond. Time-course of vitellogenin production in vitro was found to be identical to that observed in vivo. Vitellogenin-titre profiles were also investigated in cultured fat bodies from blood-fed A. aegypti. In all cases, response patterns were not affected by the presence or absence of 20-hydroxyecdysone after the fat bodies had been stimulated by blood meal to produce vitellogenin. We suggest here that initiation and control of vitellogenin synthesis is a programmed response to 20-hydroxyecdysone.     

Termite queens have disproportionately more DNA in their fat body cells: reproductive division of labor and endoreduplication

Increases in DNA content caused by endoreduplication are widely observed in the metabolically active tissues of plants and animals. During egg production, insect females synthesize very large amounts of vitellogenin in their fat bodies, and female fat bodies of some insects become polyploid to accelerate vitellogenin production. Social insects have developed reproductive division of labor, wherein queens lay most of the eggs while other individuals have reduced fertility and undertake tasks required for maintaining the colony. Therefore, only queens are engaged in vitellogenin synthesis for egg production in social insects. Here, we show that termite queens have disproportionately more DNA in their fat body cells. Our DNA content analysis using flow cytometry demonstrated that more cells contained 4C‐DNA than 2C‐DNA in the fat bodies of Reticulitermes speratus queens. This high level of endoreduplication was not found in the fat body cells of other castes. This caste‐dependent doubling of DNA content in fat body cells suggests that termites exploit endoreduplication to boost egg production, in conjunction with the development of reproductive division of labor. This study highlights nuclear polyploidization as an adaptive strategy in social insects.     

A novel protein produced by the vitellogenic fat body and accumulated in mosquito oocytes

Summary The fat body of vitellogenic mosquitoes was found to synthesize and secrete another protein in addition to vitellogenin, that accumulated in developing oocytes. In the tissues, this protein has M_r = 53000 on SDS-PAGE under reducing or non-reducing conditions. This protein is glycosylated as shown by [³H]mannose incorporation and experiments with tunicamycin. Polyclonal antibodies were produced using the ovarian 53-kDa peptide. Immunoblot analysis demonstrated the immunological identity of 53 kDa peptides from the fat body and the ovary. Furthermore, the 53-kDa protein (53KP) is synthesized and secreted exclusively by the vitellogenic fat body. Radioimmunoassay showed that 53KP is produced by the female fat body as early as 4 h and reaches its peak near 24 h after the initiation of vitellogenesis. Synthesis then drops to low levels by 36 h and declines to background levels by 48 h. In vitro experiments conducted on fat bodies of previtellogenic females demonstrated that the synthesis and secretion of 53KP can be stimulated by a physiological dose of 20-hydroxyecdysone (10^–6 M). Immunocytochemical studies of the ovary demonstrate that 53KP is present in channels between follicle cells, in the perioocytic space and in yolk granules of the developing oocytes. This suggests that 53KP is accumulated in the oocytes by a pathway similar to that of vitellogenin.     

Control of vitellogenin synthesis in the Monarch butterfly by juvenile hormone.

Yolk formation in the Monarch butterfly, as in many other insects, entails juvenile hormone-induced synthesis in the fat body, transport in the hemolymph, and uptake into the oocytes of specific sex-limited protein, the vitellogenin. In the Monarch, vitellogenin first appears in the hemolymph 1 day after emergence of the adult butterfly and then rises rapidly in concentration for at least 3 days. The synthesis of vitellogenin in adult females was shown by the incorporation of [³H]leucine. Active labeling was observed at the same time as the presence of vitellogenin in the hemolymph was first detectable, and the radioactivity in vitellogenin expressed as a percentage of radioactivity in total blood proteins reached 50–60% 3 days after adult emergence. The appearance of vitellogenin was prevented by ligature of freshly emerged butterflies at the neck and restored by injection of juvenile hormone. A low yet significant stimulation of vitellogenin synthesis could be detected as early as 10 hr after administration of the hormone into neck-ligated butterflies, and after 30 to 50 hr about 40% of the total blood protein label was found in the specific protein. With C₁₈-juvenile hormone (JH-I), 0.1 μg per animal was effective in inducing a low level of vitellogenin synthesis, and between 0.01 and 1 μg, a linear relationship between synthesis and log dose was observed. The synthetic analog ZR-512 was also active. In a preliminary experiment, actinomycin D effectively blocked the induction of vitellogenin synthesis.     

Juvenile hormone-controlled vitellogenin synthesis in Locusta migratoria fat body: Cytological development

Cytological development in the fat body of adult female Locusta migratoria, related to vitellogenin synthesis, has been studied by light and electron microscopy. In the newly-emerged adult, the cells are filled with lipid droplets, which indent the nucleus, and with fields of glycogen, while ribosomes and endoplasmic reticulum are scarce. Correlated with the onset of vitellogenin synthesis, about day 8 of adult life, the nucleus enlarges, lipid droplets and glycogen decrease, and rough endoplasmic reticulum and Golgi complexes become the most abundant organelles. These changes reflect a conversion of the principal role of the fat body from nutrient storage to the synthesis and secretion of protein. They are prevented by allatectomy, and restored by subsequent treatment with the juvenile hormone analogue, ZR-515. Late in the first gonotrophic cycle, about day 20, dense bodies, vesicle-containing bodies and lysosomes are seen, indicating recycling of cellular materials. Five days after ZR-515 treatment, when protein synthesis has declined, the rough endoplasmic reticulum appears in arrays adjacent to lipid droplets, possibly awaiting reactivation. By the use of ferritin-labelled antivitellin immunoglobulin, vitellogenin has been localized intracellularly in the RER saccules and Golgi vesicles, and extracellularly in channels between the folded plasma membranes, showing sites of accumulation and secretion of this protein.     

EFFECT OF ECDYSTERONE ON VITELLOGENIN CONCENTRATION IN HAEMOLYMPH OF MALE AND FEMALE SARCOPHAGA BULLATA

Using Polyacrylamide gel electrophoresis, cycloheximide, incorporation of ³H-labelled amino acids and immunological methods, we have demonstrated that injection of ecdy- sterone induces de novo synthesis and release of vitellogenin in both sexes of Sarcophaga bullata. Vitellogenin concentrations were measured by the Mancini-radial immunodiffusion technique. In males a dose as low as 1 ng always makes vitellogenin appear in the haemolymph but very reproducible results are only obtained when doses varying from 10 to 250 ng were injected. In this range, the dose-response curve was linear on a semi- logarithmic scale.

In females, vitellogenin concentration remained low until a few hours after liver feeding and thereafter it rose sharply and reached its maximum about 24 h after the protein meal. 100 μg 6-hydroxydopamine HCl, injected before liver feeding in 4-day-old females, inhibited vitellogenin synthesis and yolk deposition, probably by interfering with the release of a brain hormone. This inhibitory effect on vitellogenin synthesis, but not that on yolk deposition, could be overruled by injection of ecdysterone. Juvenile hormone was ineffective on both. Females, ovariectomized on day 2 or 3, accumulated vitellogenin in their haemolymph, indicating that the continuous presence of the ovaries was not required for vitellogenin synthesis. The possible relation between the gonadotrophs hormone from the brain, vitellogenin synthesis and moulting hormone metabolism is discussed.     

Assembly and secretion of lipophorin by the larval fat body of the southwestern corn borer,Diatraea grandiosella: An in vitro study

The synthesis, processing, and secretion of lipophorin by the larval fat body of the southwestern corn borer, Diatraea grandiosella, was examined using in vitro techniques. Pulse-labeling of lipophorin with [³⁵S]methionine showed that apolipophorin-I and -II were each synthesized and secreted from the fat body into Grace's medium with an intracellular transit time of about 45 min. Secretion of the apolipoproteins from the fat body became insensitive to the presence of monensin, which disrupts protein processing in the Golgi complex, at 30 min, indicating that most of the pulse-labeled apolipoprotein has transited the Golgi complex by this time. Three inhibitors of protein processing, carbonylcyanide m-chlorophenyl hydrazone, monensin, and brefeldin A, inhibited secretion of lipophorin into medium. Puromycin treatment did not appear to result in the secretion into the medium of lipophorin particles containing incomplete translation products of apolipophorin-I or -II. Incubation of fat bodies with [³H]oleate resulted in the secretion of lipophorin containing [³H]glycerides, a process that was inhibited by cycloheximide, puromycin, and monensin, indicating that apolipoprotein synthesis is required for secretion of [³H]glyceride on nascent lipophorin particles. In contrast, suramin, which has been shown to block the binding of lipophorin to plasma membrane receptors, inhibited the synthesis and secretion of lipophorin, but it did not appear to inhibit the transfer of [³H]lipid from the fat body to lipophorin. Inhibitors of protein synthesis and processing, therefore, can be used to distinguish between secretion of lipophorin-associated lipids and secretion of lipids mediated by the lipid-transfer particle outside the plasma membrane of the fat body.