Extended in vitro culture of Microplitis croceipes teratocytes and secretion of TSP14 protein

Teratocytes, cells which originate from the serosal membrane of some Braconidae and Scelionidae, can be found in the hemocoel of permissive hosts during part or all of the developmental time of the parasitoid larva. Teratocytes from Microplitis croceipes are known to secrete biologically active proteins, which contribute to developmental arrest and failure to pupate of Heliothis virescens larvae. One such protein, which has a molecular weight of approximately 14 kDa is called TSP14. The presence of parasitoid larvae is essential to maintain teratocytes under in vitro conditions with protein-free EX-CELL 400. The teratocyte viability was maintained in vitro for at least 12 days in the presence of larvae when medium was exchanged every three days. Western blots show that TSP14 was secreted during the entire period of exchanges. In the absence of parasitoid larvae, teratocyte viability was only 30% by day 6 and no TSP14 had been secreted. In the absence of parasitoid larvae, teratocytes maintained in vitro in EX-CELL 400 medium supplemented with 10% FBS remained viable for at least nine days and secreted TSP14 for at least six days. This suggests that parasitoid larval secretions are sufficient but not uniquely essential to maintain teratocyte viability. Parasitoid larvae maintained in the absence of teratocytes did not secrete TSP14 and their secretory products did not inhibit pupation of H. virescens larvae.     

Dinocampus (=Perilitus) coccinellae teratocyte-specific polypeptide: its accumulative property,localization and characterization

Dinocampus (=Perilitus) coccinellae (Braconidae: Hymenoptera) teratocytes synthesize a teratocyte-specific polypeptide (TSP) with a high molecular weight of 540kDa. The TSP has a tendency to accumulate in the teratocyte cells without release after synthesis ([Okuda and Kadono-Okuda, 1995]), which was confirmed in this study. Pulse-chase fluorography indicated that teratocytes at a younger stage (6 days after parasitization)secreted negligible TSP into the medium after synthesis, while teratocytes at an older stage (11 days after parasitization)secreted the synthesized products into the medium, although the amount released was still low. Western blot with anti-TSP serum showed that only a small amount of TSP appeared in the parasitized host hemolymph, even when TSP synthesis by teratocytes was actively taking place, which also supported the accumulative nature of TSP. The immunoelectronmicroscopic studies revealed that the TSP was localized specifically in high electron-dense vacuoles. Lectin blot analysis identified TSP as a high mannose glycoprotein. The amino acid composition of the major subunit of the TSP was quite similar to that of nutritive proteins such as vitellogenin and storage proteins of some insects. These characterization data, together with the accumulation property of the TSP indicates that Dinocampus teratocyte primarily plays a nutritive role for the developing parasitoid larvae. TSP exhibited esterase activity, which indicates that TSP may have an additional function in the host-parasitoid reaction.     

Effects of Microplitis croceipes Teratocytes on Host Haemolymph Protein Content and Fat Body Proliferation

Qualitative and quantitative changes in haemolymph proteins in Heliothis virescens were observed in larvae injected with either Microplitis croceipes teratocytes or teratocyte secreted proteins (TSP). Haemolymph protein titres in hosts receiving either 0.5 or 1 larval equivalent (LE) of teratocytes were similar to those of parasitized larvae, whereas a single injection of 4LE of TSP was required to induce a similar response. SDS-PAGE showed that the 82kDa monomer of riboflavin-binding protein and the 74/76kDa monomers of storage proteins were significantly reduced in parasitized larvae and in nonparasitized larvae treated with TSP. Concentrations of a 155kDa monomer (insectacyanin chromoprotein) also were reduced in parasitized larvae and those injected with either teratocytes or TSP. Two monomers (56 and 60kDa) were unique to parasitized larvae. Treated larvae required several days longer than controls to reach a comparable premetamorphic stage (burrowing-digging). Reductions in fat body proliferation similar to those seen in parasitized larvae were observed in larvae treated with either 1LE of teratocytes, or with 2 or 4LEs of TSP. Perivisceral fat body weights from larvae treated with either 0.25 or 0.5LE of teratocytes were significantly reduced, but less so than those which received 1LE. Thus, fat body proliferation in both teratocyte- and TSP-treated larvae was inhibited in a dose-dependent manner. Both light- and transmission electron microscopy observations revealed cytological differences in fat body tissues of larvae injected with either teratocytes or TSP from the condition observed in parasitized larvae and noninjected controls. Gross dissection of periviseral fat body from parasitized, teratocyte-injected and TSP-injected larvae showed tissue much less developed and differing considerably in appearance from controls. Observed differences included reduced size and/or number of lipid bodies and qualitative and quantitative changes in other cytoplasmic organelles.     

Expression and characterization of a novel teratocyte protein of the braconid,Microplitis croceipes (cresson)

Microplitis croceipes wasps overcome host immunity by inducing changes in host physiology using factors derived from the embryo and/or larva. Teratocytes of some parasitic wasps circulate in the host hemolymph after egg hatch and synthesize proteins (TSPs), some of which are secreted to alter host physiology in support of endoparasitoid development. TSPs appear to alter host physiology, at least in part, by inhibiting synthesis of certain proteins. M. croceipes teratocytes synthesize a 13.9 kDa protein (TSP14), which inhibits synthesis of host proteins that are linked to larval growth and development. A cDNA encoding TSP14 was generated by RT-PCR from teratocyte RNA, and cloned into yeast expression vectors to produce sufficient recombinant protein for functional analyses. RecTSP14 was produced using the yeast expression system at a concentration of more than 300 micrograms/L. The recTSP14 inhibited in vitro translation of larval Heliothis virescens RNA, with the activity sensitive to boiling, protein concentration, incubation time, and storage temperatures. Although recTSP14 inhibited translation of some cellular RNAs in vitro, the in vivo incorporation of [35S]-methionine into proteins of selected insect and mammalian cell lines was not inhibited. These findings suggest that recTSP14 entry is cell type-specific and required to inhibit synthesis of target protein(s).     

Host regulation by the aphid parasitoid Aphidius ervi: the role of teratocytes

The biochemical profile and metabolism of Acyrthosiphon pisum(Harris) (Homoptera, Aphididae) are markedly altered and redirected in response to parasitization by the endophagous braconid Aphidius erviHaliday (Hymenoptera, Braconidae). In the present study, the role played in the host regulation process by teratocytes, cells deriving from the dissociation of the embryonic membrane of the parasitoid, is taken into consideration. The protein synthesis activity of these cells of embryonic origin is analysed in vitroand an essential characterization of those proteins de novosynthesized and released in the incubation medium is provided. Teratocytes, obtained by dissecting parasitized host aphids, 3, 4 and 5 days after parasitoid oviposition, were incubated in vitroand, at the end of the incubation period, were separated from the medium for SDS-PAGE analysis of both cellular and secreted proteins. Various cellular proteins were more abundant as the time between parasitization and teratocyte collection increased. Furthermore, two proteins, showing an approximate molecular mass of 15 kD (p15) and 45 kD (p45) respectively, were abundantly secreted in the incubation medium by 5 day-old teratocytes. Incubations in presence of ³⁵S radiolabelled amino acids indicated that p15 and p45 are both synthesized by A. erviteratocytes. The amino acid composition of these two proteins was similar to that reported for other insect proteins with a demonstrated nutritional function. The p45 protein was found to be glycosylated. A tentative physiological model describing the host regulation role played by different parasitoid-derived factors is proposed.     

Juvenile hormone esterase activity and ecdysteroid titer in Heliothis virescens larvae injected with Microplitis croceipes teratocytes

Juvenile hormone esterase (JHE) activity in the hemolymph of 5th-instar Heliothis virescens larvae injected with Microplitis croceipes teratocytes was inversely related to the number of teratocytes injected. JHE activity in the hemolymph of larvae injected with 750 3-day-old teratocytes (the approximate number from one parasitoid embryo) was depressed to less than 5% of those levels found in control larvae. During the latter portion of the digging stage and in the burrowing-digging (BD) stage JHE activity in larvae treated with 350 teratocytes was approximately 40% of control values. However, injection of 180 teratocytes did not significantly affect JHE titers. Two-day-old teratocytes caused the greatest reduction in JHE titer with decreasing effects observed with injections of 3- to 6-day-old teratocytes. Nevertheless, because 2-day-old teratocytes were difficult to separate from host hemocytes, 3-day-old teratocytes were used in most of these studies. Injections of nonparasitized H. virescens hemolymph plasma, Micrococcus luteus bacterial cell walls, washed M. croceipes eggs, or teratocytes from Cotesia congregata did not depress JHE titers. Teratocyte injections also significantly reduced growth of host fat body. Ecdysteroid titers in cell formation, day 2 (CF2) larvae injected as new 5th instars with 350 3-day-old teratocytes failed to increase, as compared to noninjected and saline-injected controls. An injection of 1 μg/larva of 20-hydroxyecdysone at the BD stage permitted normal pupation in 50% of the teratocyte-treated larvae as compared to 0% pupation for teratocyte-treated control larvae not treated with 20-hydroxyecdysone. Teratocytes seem to be responsible for the inhibition of JHE release and thus indirectly impact on ecdysteroid titers. © 1992 Wiley-Liss, Inc.     

Host regulation effects on Heliothis virescens (F.) larvae inducd by teratocytes of Cardiochiles nigriceps Viereck (Lepidoptera,Noctuidae-Hymenoptera,Braconidae)

Teratocytes deriving from the serosal membrane of Cardiochiles nigriceps Viereck, obtained “in vitro” from embryos hatched on a semidefined medium, were injected at different numbers and in different developmental stages of nonparasitized Heliothis virescens (F.) last instar larvae. Host development was affected by teratocyte injections and the responses registered ranged from normal to complete inhibition of pupation, according to the number of teratocytes injected and the developmental stage of the larva at time of injection. Complete pupation failure was observed when teratocytes derived from 4C nigriceps embryos were injected into 1st day 5th instar (new-slender stage) host larvae. Complete pupation occurred when teratocytes from 2 embryos were injected into 3rd or 4th day 5th instars (burrow-digging or day 1 cell formation stage). Intermediate responses, such as the formation of pupal cuticle without ecdysis or with only partial ecdysis, were obtained with intermediate teratocyte numbers, or host developmental stages. All pupae derived from teratocyte injected larvae failed to develop into adults normally obtained from control injected larvae. The larval weight just before pupation was negatively affected only when teratocyte injections were performed on 1st day 5th instar H. virescens larvae. Teratocyte injections altered the hemolymph protein titer to a level similar to that occurring in parasitized larvae. At the same time the ecdysteroid titer was characterized by a late significant increase, which reached values almost 3 times greater than found in normally parasitized larvae, and also surpassed the highest values registered for nonparasitized larvae. Ligation of parasitized larvae between the meso- and metathorax demonstrated that when the prothoracic glands were excluded, there was almost no ecdysteroid production posterior to the ligation. Ligations performed on parasitized larvae to isolate parasitoid eggs before hatching in the last abdominal segments, demonstrated that only virus and venom determined a reduction of the ecdysteroid titer. On the basis of these results the possible role of teratocytes in affecting the biological activity of ecdysteroids is postulated and discussed in a wider context of host-parasitoid physiological interactions.     

Protein synthesis by the milk gland and fat body of the tsetse fly,Glossina pallidipes

The patterns of protein synthesis by the milk gland and the fat body of female Glossinapallidipes during the pregnancy cycle were studied by incubation with [³⁵S]methionine both in vivo and in vitro. The pattern of protein synthesis by the milk gland changed with the stage of the larva in the uterus. Very little synthesis occurred in the milk gland until the first instar larva hatched. Then four proteins (13, 16, 24 and 72 kDa) were prominently synthesized. As the larva matured, the synthesis of 19, 38, 40 and 72 kDa proteins increased, whereas that of the 13 and 24 kDa proteins decreased. Just before larviposition, only the 16 and 72 kDa proteins were still being synthesized. The milk gland secreted into the medium primarily the 13, 16, 19 and 72 kDa proteins, all of which were found in the larval gut after a 5 hr pulse of labeled methionine in vivo. During most of the pregnancy cycle protein synthesis in the fat body was low compared to that of the milk gland and only small amounts of several low molecular weight proteins (less than or equal to 16 kDa) were released into the medium. But when a large third instar larva was present in the uterus, the fat body synthesized and secreted a 72 kDa and a 15–17 kDa complex of proteins.     

Characterization of a cDNA encoding a putative chitinase from teratocytes of the endoparasitoid Toxoneuron nigriceps

Females of insect endoparasitoids inject substances along with the egg at oviposition, which can regulate or induce changes in a number of host physiological processes to benefit the developing parasitoid. These changes can be caused by substances such as venoms, calyx fluids, or symbiotic‐associated virus particles (polydnavirus), which are injected by females along with their eggs, and by substances secreted by parasitoid‐derived tissues (teratocytes) or the developing parasitoid larvae. Teratocytes (dissociated cells of the serosal membrane after parasitoid eclosion) release substances that have roles (i) in parasitoid nutrition, (ii) in the digestion of host tissues, and (iii) in the regulation of host development. Teratocytes of Toxoneuron nigriceps (Viereck) (Hymenoptera: Braconidae) have been implicated in the arrestment of the host development and in the regulation of circulating levels of host ecdysteroids. Here we describe the cDNA of a teratocyte‐secreted chitinase and its expression during parasitoid development, and discuss its putative role in this host–parasitoid association.     

Quantification and development of teratocytes in novel-association host-parasitoid combinations

We studied the development of teratocytes derived from two congeneric gregarious endoparasitic species, Cotesia chilonis and C. flavipes, parasitizing two congeneric novel hosts, Diatraea saccharalis and D. grandiosella. The host-parasitoid combinations studied allowed us to investigate relationships between host suitability and teratocyte development. D. saccharalis was a suitable host for both parasitoids, whereas D. grandiosella was suitable for C. chilonis development but often encapsulated C. flavipes progeny. Encapsulation of C. flavipes by D. grandiosella commenced around the time of parasitoid egg hatch, when teratocytes were released into the host's hemolymph. The gregarious parasitoids studied here released about 200 teratocytes per egg. Both absolute and normalized (teratocytes/parasitoid) numbers decreased over time. D. saccharalis supported more C. flavipes-derived teratocytes than D. grandiosella, possibly because of the unsuitability of the latter host. On intermediate assay days the number of C. flavipes-derived teratocytes was greater than for C. chilonis. However, C. chilonis-derived teratocytes grew larger than C. flavipes. Teratocytes in all host-parasitoid combinations doubled in size during parasitoid development. Teratocytes generally grew larger in D. grandiosella, which was a less suitable host.     

Ligand blot analysis of juvenile hormone esterase binding proteins in Manduca sexta L

Biotinylated recombinant juvenile hormone esterase (JHE) was used for ligand blotting of proteins from fat body tissue and pericardial athrocytes of Manduca sexta. Proteins were separated by SDS-polyacrylamide gel electrophoresis or by two-dimensional electrophoresis. Eight putative JHE binding proteins were detected in fat body tissue and in pericardial athrocytes of both M. sexta and Heliothis virescens. The predominant bands were 29, 72, 75, 125 and 240kDa, with minor bands at 50, 80 and 205kDa. All putative JHE binding proteins were present from the second through to the fifth instar larvae of M. sexta. On wide-range isoelectric focusing, the 29kDa JHE binding protein separated into three species with isoelectric points of 6.5, 6.6 and 6.8. Biotinylated-JHE did not bind recombinant M. sexta-derived juvenile hormone binding protein. The mutant JHE with mutations K29R and K524R binds weakly to the JHE binding protein P29, relative to binding of wild-type JHE [Shanmugavelu et al., J. Biol. Chem., 275 (2000) 1802-1806]. A similar reduction in binding was not seen for the 29kDa binding protein identified here in pericardial athrocytes by ligand blot. This result is discussed.     

Cultivation of teratocytes of the egg parasitoid telenomus heliothidis (hymenoptera: Scelionidae)

Summary A method for in vitro cultivation of teratocytes from the egg parasitoidTelenomus heliothidis (Hymenoptera: Scelionidae) is described. Parasitoid eggs, from which teratocytes were derived, were collected from 24-h-oldHeliothis virescens (Lepidoptera: Noctuidae) eggs previously parasitized byT. heliothidis females. Optimal culture conditions, including species and concentration of serum, were determined experimentally. Thirty percentManduca sexta hemolymph or 10% chicken serum in Hink’s TNH-FH medium were found to generate the most satisfactory number of teratocytes per parasitoid larva. Teratocytes cultivated in vitro showed similar development and morphology to those produced in vivo. However, cultured teratocytes lived approximately 10 times longer than teratocytes in natural hosts and were not dependent upon the presence of the parasitoid larva for normal development.     

Juvenile hormone esterase (JHE) from Tenebrio molitor: full-length cDNA sequence,in vitro expression,and characterization of the recombinant protein

Juvenile hormone regulates the development and reproduction in a variety of insects. Juvenile hormone esterase (JHE) is a selective enzyme, which hydrolyzes the methyl ester of JH and alters its activity. In Tenebrio molitor, JHE has been previously purified from pupae and a partial cDNA was amplified by RT-PCR using fat body mRNA. The previous report indicated that several forms of the JHE protein were present in pupal homogenate. In this study, we report the full-length cDNA, which was obtained by RACE methods. The deduced protein sequence corresponds to peptides from two proteins of different molecular weights in the previous study. The coding region of the full-length cDNA was subcloned into the AcMNPV genome and high levels of expression of the JHE enzyme from the viral p10 promoter were demonstrated in cell culture. The majority of JHE is secreted from the cells as a soluble enzyme. The recombinant JHE enzyme was biochemically characterized. The recombinant protein appears by PAGE analysis as a monomer of approximately the same MW (66000) and pI (4.9) as was expected from the deduced amino acid sequence of the cDNA.     

菜蛾盘绒茧蜂对寄主小菜蛾幼虫营养的调节和利用

寄主小菜蛾Plutella xylostella被内寄生蜂菜蛾盘绒茧蜂Cotesia plutellae寄生后,其取食、发育及营养代谢在各种寄生因子的作用下伴随幼蜂的发育而发生很大的变化,畸形细胞作为调节因子之一也发挥了重要的作用。本实验通过比较被寄生和未被寄生小菜蛾血淋巴蛋白浓度以及两种血淋巴对菜蛾盘绒茧蜂幼蜂进行体外培养的培养液的蛋白浓度,发现被寄生小菜蛾血淋巴比未被寄生小菜蛾血淋巴的蛋白浓度略低但差异不显著,而未被寄生小菜蛾血淋巴幼蜂培养液的蛋白浓度显著低于被寄生小菜蛾血淋巴幼蜂培养液的蛋白浓度,证明畸形细胞的蛋白质分泌功能。被寄生后期, 小菜蛾体重明显大于未被寄生的小菜蛾体重,而脂肪体重量相比正好相反;通过显微染色观察,在小菜蛾念珠状脂肪体表面粘附有畸形细胞,对脂肪体进行分解破坏而使其成颗粒状; 蛋白含量和脂滴浓度测定也表明,脂肪体的可溶性蛋白含量和脂滴浓度也迅速降低,同比低于未被寄生小菜蛾。而与此同时,幼蜂正处在快速生长阶段,中肠酯酶的活性逐步上升,幼蜂得以快速消化吸收小菜蛾体内的营养直到完成幼虫发育,整个幼蜂的脂滴浓度也达到了最大值。因此寄生后期,推测在畸形细胞的协助下,幼蜂吸收了寄主小菜蛾体内的营养为自身生长发育所用。     

Systematic analysis of a wasp parasitism arsenal

Parasitoid wasps are among the most diverse insects on earth with many species causing major mortality in host populations. Parasitoids introduce a variety of factors into hosts to promote parasitism, including symbiotic viruses, venom, teratocytes and wasp larvae. Polydnavirus‐carrying wasps use viruses to globally suppress host immunity and prevent rejection of developing parasites. Although prior results provide detailed insights into the genes viruses deliver to hosts, little is known about other products. RNAseq and proteomics were used to characterize the proteins secreted by venom glands, teratocytes and larvae from Microplitis demolitor, which carries M. demolitor bracovirus (MdBV). These data revealed that venom glands and teratocytes secrete large amounts of a small number of products relative to ovaries and larvae. Venom and teratocyte products exhibited almost no overlap with one another or MdBV genes, which suggested that M. demolitor effector molecules are functionally partitioned according to their source. This finding was well illustrated in the case of MdBV and teratocytes. Many viral proteins have immunosuppressive functions that include disruption of antimicrobial peptide production, yet this study showed that teratocytes express high levels of the antimicrobial peptide hymenoptaecin, which likely compensates for MdBV‐mediated immunosuppression. A second key finding was the prevalence of duplications among genes encoding venom and teratocyte molecules. Several of these gene families share similarities with proteins from other species, while also showing specificity of expression in venom glands or teratocytes. Overall, these results provide the first comprehensive analysis of the proteins a polydnavirus‐carrying wasp introduces into its host.     

一种中红侧沟茧蜂畸形细胞分泌的寄生特异蛋白

SDS-PAGE电泳表明,黏虫Pseudaletia separa-ta、棉铃虫 Helicoverpa armigera、小地老虎 Agrotisypsilon的幼虫受中红侧沟茧蜂Microplitis mediator寄生后,血淋巴中都出现一个98.6 kDa的寄生特异蛋白(p98.6)。畸形细胞(teratocytes)的体外培养发现,p98.6是由来自中红侧沟茧蜂胚胎浆膜层的畸形细胞分泌的。这一结果将为研究寄生蜂的寄生生理和畸形细胞在协调寄生蜂和寄主关系中的作用打下基础。     

Developmental changes in teratocytes of the braconid wasp Cotesia congregata in larvae of the tobacco hornworm,Manduca sexta

The endoparasitic wasp Cotesia congregata develops in the hemocoel of larval stages of the tobacco hornworm, Manduca sexta. Teratocytes were released from the serosal membrane during hatching of the first instar wasp larva at 2-3days after oviposition; about 160 cells were released per embryo. The cells increased in diameter from about 10 to >200&mgr;m prior to wasp emergence. Nascent microvilli, visible on the cell surface before hatching of the first instar larva, rapidly increased in length and number following release of the cells. Irrespective of when the wasps were due to emerge, or how many parasitoids were present in the host, dramatic cytological changes occurred in the cells during the last instar of the host's development. Many of these morphological and ultrastructural changes were symptomatic of the cytological features of degenerating or apoptotic cells, and large numbers of vesicles appeared interspersed amongst the microvilli. The nucleus developed extensive dentritic ramifications, and the chromatin condensed in large clumps on the inner nuclear membrane. At the final stages of the wasps' development, the nucleus occupied the bulk of the interior of the cell. The cytoplasm gradually grew dramatically more electronluscent and less granular, as did the nucleoplasm, which is also indicative of impending cell death. Following the parasites' emergence, many of the cells underwent extensive blebbing of the cell surface. Teratocytes within a host appeared heterogeneous with respect to their morphological appearance. Analysis of the proteins secreted by teratocytes in vitro following labelling with (35)S-methionine showed that many (>30) polypeptides were synthesized de novo and secreted by the cells; some proteins were clearly targeted for secretion. We presume that the cells likely secrete a large number of proteins in vivo as well as in vitro.     

Comparison of proteins synthesized by polarized caprine oviductal epithelial cells and oviductal explants in vitro

Our objectives were to compare proteins secreted by caprine oviductal explants and oviductal epithelial (OE) cells in vitro. Oviducts were collected from goats on Days 1 (n=5) and 5 (n=5) of the estrous cycle. Radiolabeled secretory proteins from tissue segments and cell cultures were visualized using SDS-PAGE and fluorography. After culture, media from ampulla oviduct segments collected on Days 1 and 5 of the estrous cycle contained an acidic 97 kDa protein, which was greatly reduced in culture medium obtained from infundibulum and isthmus oviduct segments. A complex of low molecular weight proteins (14-26 kDa) could be modulated by estradiol when OE cells were cultured on plastic. This complex was constitutively expressed when OE cells were cultured on Matrigel-coated filters. Polarized OE cells were also capable of compartment-specific secretion of [L-(35)S]-methionine-labeled proteins. A 45 kDa acidic protein was predominantly secreted into the apical compartment while a 66 kDa acidic protein was preferentially localized in the basal compartment. Proteins secreted by OE cells were similar to proteins secreted by tissue segments in vitro. Therefore, under well-defined culture conditions OE cells may be useful in enhancing in vitro fertilization or early embryonic development.     

A function for pericardial cells in an insect

The pericardial cells (PCs) of fifth instar Calpodes ethlius larvae are functionally adapted for filtering hemolymph and sequestering and digesting proteins. They also have a structure appropriate for the synthesis of proteins for secretion. PC secretion has been investigated by labelling the cells with [³⁵S]methionine ti vitro with detection of newly synthesized polypeptides appearing in the medium by electrophoresis and fluorography. Sources possibly contributing to the appearance of newly synthesized polypeptides in the medium, such as cell breakdown and fat body contamination have been ruled out. The post-incubation medium of PCs contains at least six newly synthesized polypeptides. Three of these polypeptides, having relative molecular masses of 82, 57 and 43 kDa, react with antibodies to hemolymph. At least one additional polypeptide is similar by two-dimensional analysis to that naturally present in hemolymph. PCs incubated together with the heart to which they are normally attached, secrete additional polypeptides that are presumed to come from the heart. The 82 kDa polypeptide secreted by the PCs is similar to the subunits of arylphorin secreted by fat body and other tissues. We conclude that PCs secrete proteins into the hemolymph although the amount may be small relative to that of the fat body.