80 Purification and characterization of male and female gamete recognition molecules of a marine red alga aglaothamnion oosumiense

In red algae, fertilization begins with gamete‐gamete contact between the trichogyne cell wall of the female carpogonium and spermatial coverings. During the fertilization in Aglaothamnion oosumiense, reproductive cells interact with each other through sex specific adhesion molecules on the surface of spermatia and trichogyne. The gamete binding is highly selective suggesting the presence of recognition factors along their surfaces. In the previous studies, we have reported that spermatial binding to trichogynes of a red alga, Aglaothamnion oosumiense is mediated by a lectin‐carbohydrate complementary system. Spermatial binding to trichogynes was inhibited by pre‐incubation of trichogynes with N‐acetyl‐D‐galactosamine and D‐glucose and hence lectins specific to these sugars were expected to present on the surfaces of trichogyne cell wall. We have isolated a new lectin from Aglaothamnion oosumiense by the use of agarose bound N‐acetyl‐D‐galactosamine affinity chromatography and named it as rhodobindin. Rhodobindin agglutinated human erythrocytes as well as spermatia of Aglaothmanion oosumiense. The agglutinating activity of this lectin was inhibited by N‐acetyl‐D‐galactosamine and N‐acetyl‐D‐glucosamine. SDS‐PAGE results showed that this lectin may be monomeric. The molecular weight was determined as 21,876 dalton by matrix‐assisted laser desorption ionization (MALDI) mass‐spectrometry. N‐terminal amino acid sequence of the lectin was analyzed and revealed to have no identity with those of known proteins. The complementary male glycoprotein was also isolated and purified by the use of SBA‐agarose affinity chromatography. The subtractive cloning was carried out to characterize the recognition molecules.     

PURIFICATION OF A SEX‐SPECIFIC LECTIN INVOLVED IN GAMETE BINDING OF AGLAOTHAMNION CALLOPHYLLIDICOLA (RHODOPHYTA)1

Egg and sperm binding and correct recognition is the first stage for successful fertilization. In red algae, spermatial attachment to female trichogynes is mediated by a specific binding between the lectin(s) distributed on the surface of trichogyne and the complementary carbohydrates on the spermatial surface. A female‐specific lectin was isolated from Aglaothamnion callophyllidicola by agarose‐bound fetuin affinity chromatography. Two proteins, 50 and 14 kDa, eluted from the fetuin column were separated using a native‐polyacrylamide gel electrophoresis method and subjected to a gamete binding assay. The 50 kDa protein, which blocked spermatial binding to female trichogynes, was used for further analysis. Internal amino acid sequence of the 50 kDa protein was analyzed using matrix‐assisted laser desorption/ionization‐mass spectrometry and degenerated primers were designed based on the information. A full‐length cDNA encoding the lectin was obtained using rapid amplification of cDNA ends polymerase chain reaction (PCR). The cDNA was 1552 bp in length and coded for a protein of 450 amino acids with a deduced molecular mass of 50.7 kDa, which agreed well with the protein data. Real‐time PCR analysis showed that this protein was up‐regulated about 10‐fold in female thalli. As the protein was novel and showed no significant homology to any known proteins, it was designated Rhodobindin.     

81 Recent introduction of polysiphonia morrowii (ceramiales, rhodophyta) to punta arenas, chile

In red algae, fertilization begins with gamete-gamete contact between the trichogyne cell wall of the female carpogonium and spermatial coverings. During the fertilization in Aglaothamnion oosumiense , reproductive cells interact with each other through sex specific adhesion molecules on the surface of spermatia and trichogyne. The gamete binding is highly selective suggesting the presence of recognition factors along their surfaces. In the previous studies, we have reported that spermatial binding to trichogynes of a red alga, Aglaothamnion oosumiense is mediated by a lectin-carbohydrate complementary system. Spermatial binding to trichogynes was inhibited by pre-incubation of trichogynes with N-acetyl-D-galactosamine and D-glucose and hence lectins specific to these sugars were expected to present on the surfaces of trichogyne cell wall. We have isolated a new lectin from Aglaothamnion oosumiense by the use of agarose bound N-acetyl-D-galactosamine affinity chromatography and named it as rhodobindin. Rhodobindin agglutinated human erythrocytes as well as spermatia of Aglaothmanion oosumiense . The agglutinating activity of this lectin was inhibited by N-acetyl-D-galactosamine and N-acetyl-D-glucosamine. SDS-PAGE results showed that this lectin may be monomeric. The molecular weight was determined as 21,876 dalton by matrix-assisted laser desorption ionization (MALDI) mass-spectrometry. N-terminal amino acid sequence of the lectin was analyzed and revealed to have no identity with those of known proteins. The complementary male glycoprotein was also isolated and purified by the use of SBA-agarose affinity chromatography. The subtractive cloning was carried out to characterize the recognition molecules.     

Gamete recognition during fertilization in a red alga,Antithamnion nipponicum

Summary Fertilization in the marine red algaAntithamnion nipponicum is a highly specific process involving non-motile male gametes, spermatia, and female receptive structures, carpogonia. FITC-lectin and Calcofluor white ST labelling show that the outer cell walls of spermatia differ from vegetative cells in carbohydrate composition. Specific binding of the lectins to spermatial walls was confirmed by lectin-gold labelling on thin sections. Gametic recognition inAntithamnion nipponicum is based on the interaction of a surface carbohydrate on the spermatia with a surface carbohydrate receptor on the trichogynes. Spermatial binding to trichogynes is inhibited by pre-incubation with concanavalin A and trichogyne receptors are blocked by the complementary carbohydrate -D-methyl mannose. The inhibitory effects of concanavalin A to spermatial binding of trichogynes is reversed by preincubation with -D-methyl mannose. The combination of long spermatial appendages and a carbohydrate-carbohydrate receptor-based gamete recognition mechanism make fertilization in this species an efficient process.     

137 Gamete Recognition and Sexual Isolation in a Red Alga,Aglaothamnion Byssoides (Rhdophyta)

The binding of fluorescein isothiocyanate (FITC) conjugated lectins to gametes of Aglaothamnion byssoides Itono during the fertilization was studied by the use of confocal microscope. The physiological effects of lectins and carbohydrates on gamete binding were also examined. Three lectins, concanavalin A (ConA), Soybean agglutinin (SBA) and wheat germ agglutinin (WGA) bound to the surface of spermatia, but each lectin labeled different region of the spermatium. SBA bound only to the spermatial appendages but ConA bound to the whole spermatial surface except spermatial appendages. WGA labeled narrow region which connects spermatial body and appendages. During fertilization, ConA and WGA specific substances on the spermatial surface moved towards the area contacting with trichogyne and accumulated on the surface of fertilization canal. Spermatial binding to trichogynes was inhibited by pre‐incubation of spermatia with SBA, while trichogyne receptors were blocked by the complementary carbohydrate, N‐acetyl‐D‐galactosamine. WGA and its complementary carbohydrate had little effect on gamete binding. For searching the step of sexual isolation, crossing experiment was performed between Aglaothamnion byssoides and twelve other red algal species. Results showed that the gamete recognition was genus‐specific: the gametes bound freely with their partners of the same genus. When two species from same genus were crossed, sexual isolation occurs gradually during the fertilization process. Therefore, sexual isolation in red algae appears to be determined by multi‐step process and gamete binding is the initial step.     

THE ROLE OF F-ACTIN DURING FERTILIZATION IN THE RED ALGA AGLAOTHAMNION OOSUMIENSE (RHODOPHYTA)

The actin cytoskeletons in spermatia and trichogynes of Aglaothamnion oosumiense Itono were studied using fluorescein isothiocyanate (FITC) conjugated phalloidin and the cytoskeletal inhibitors, potassium iodide (KI), cytochalasin-B, and latrunculin-A. Microfilaments were localized to the distal ends of elongated spermatia and trichogynes and were more prominent in the trichogyne before spermatium binding. The actin cytoskeleton in spermatia and trichogynes was disrupted by treatment with 0.6 M KI, 100 μM cytochalasin-B, or 10 μM latrunculin-A. The actin cytoskeleton in trichogynes recovered within 24 h of removal from the inhibitor, but no recovery was observed in spermatia. Spermatial nuclei entered mitosis as soon as spermatia attached to the trichogyne. The greatest percentage (50%– 60%) of spermatia having completed mitosis was obtained at 60 min after spermatial binding to trichogynes. During mitosis, actin accumulated in the center of the spermatium, thereby separating the two daughter nuclei. Cytoskeletal inhibitors did not affect initial binding of spermatia to trichogynes but did block subsequent stages of fertilization, including spermatial mitosis and gamete fusion. The accumulation of cellulose or β-linked polysaccharide on the spermatial surface was also blocked by treatment with actin inhibitors. Exposure of the trichogyne to actin inhibitors after gamete fusion caused spermatial nuclei in trichogynes to stop moving and to condense. These results suggest that the microfilaments involved in nuclear division, cellulose deposition into the spermatial wall, gamete fusion, and migration of spermatial nuclei in trichogynes during fertilization in Aglaothamnion oosumiense.     

138 Molecular Evolution of Glutamine Synthetase In Protists

The binding of fluorescein isothiocyanate (FITC) conjugated lectins to gametes of Aglaothamnion byssoides Itono during the fertilization was studied by the use of confocal microscope. The physiological effects of lectins and carbohydrates on gamete binding were also examined. Three lectins, concanavalin A (ConA), Soybean agglutinin (SBA) and wheat germ agglutinin (WGA) bound to the surface of spermatia, but each lectin labeled different region of the spermatium. SBA bound only to the spermatial appendages but ConA bound to the whole spermatial surface except spermatial appendages. WGA labeled narrow region which connects spermatial body and appendages. During fertilization, ConA and WGA specific substances on the spermatial surface moved towards the area contacting with trichogyne and accumulated on the surface of fertilization canal. Spermatial binding to trichogynes was inhibited by pre-incubation of spermatia with SBA, while trichogyne receptors were blocked by the complementary carbohydrate, N-acetyl-D-galactosamine. WGA and its complementary carbohydrate had little effect on gamete binding. For searching the step of sexual isolation, crossing experiment was performed between Aglaothamnion byssoides and twelve other red algal species. Results showed that the gamete recognition was genus-specific: the gametes bound freely with their partners of the same genus. When two species from same genus were crossed, sexual isolation occurs gradually during the fertilization process. Therefore, sexual isolation in red algae appears to be determined by multi-step process and gamete binding is the initial step.     

Fertilization and the cytoskeleton in the red alga Bostrychia moritziana (Rhodomelaceae,Rhodophyta)

Time-lapse videomicroscopy was used to observe the effects of various cytoskeletal inhibitors on three important fertilization events in Bostrychia moritziana: spermatial mitosis, gamete fusion (formation of a fertilization pore) and nuclear migration along the trichogyne. The microtubule inhibitor oryzalin disrupted spermatial mitosis but had no other effect on fertilization. The actin inhibitors, jasplakinolide, cytochalasin B, latrunculin A and B and mycalolide B inhibited gamete fusion while BDM, a myosin-disrupting drug, inhibited all three major fertilization events. FL-Phallacidin was used to stain actin filaments in spermatia and trichogynes while microtubules were labelled with antibodies at appropriate stages of fertilization. Microtubules were only evident during spermatial nuclear division. Actin filaments were present in both trichogynes and spermatia throughout fertilization; they formed a discrete ring around the fertilization pore and ensheathed male nuclei as the latter migrated into and along the trichogyne. These results suggest that the actin/myosin system plays a role in the events of fertilization.     

Cell-Cell Recognition during Fertilization in a Red Alga, Antithamnion sparsum (Ceramiaceae, Rhodophyta)

A gamete recognition mechanism in Antithamnion sparsum Tokidais proposed based on experiments using various lectins and carbohydrates.Spermatial binding to trichogynes is inhibited by pre-incubationof spermatia with concanavalin A (ConA) and/or L-fucose, whiletrichogyne receptors are blocked by the complementary carbohydrate-methyl D-mannose and/or the lectin Ulex europaeus agglutinin(UeA1). Binding inhibition (40–50%) was observed with10–50 mM carbohydrates and 25–50 µg ml^-1 lectins.The inhibitory effects of ConA and UeA1 is partially reversed(to 80–90% of controls) by addition of -methyl D-mannoseand L-fucose, respectively. Lectin binding to spermatial surfaceswas visualized by Fluorescein isothiocyanate (FITC) conjugatedConA, whereas carbohydrate receptors along the trichogyne andspermatium were localized with -mannosylated-FITC-albumin andL-fucosylated-FITC-albumin, respectively. These results suggestthat gamete recognition in Antithamnion sparsum is mediatedby a double-docking recognition system consisting of spermatiapossessing surface L-fucose receptors and -methyl D-mannosemoiety, and trichogynes possessing the complementary receptors. (Received December 5, 1995; Accepted April 22, 1996)     

ATTACHMENT AND FUSION OF GAMETES DURING FERTILIZATION OF PALMARIA SP. (RHODOPHYTA)1

Fertilization of cultured microscopic female gametophytes by spermatia from field-collected male gametophytes of Palmaria sp. was observed by light and transmission electron microscopy. Liberated spermatia had a prophase-arrested nucleus with a pair of polar rings. The protoplast of spermatia was covered with ca. a 3-μm-thick hyaline covering. After spermatium inoculation, the spermatial covering was attached specifically to the coat surrounding the cell wall of the trichogyne. The spermatial covering was eliminated only at the site of gamete attachment, resulting in direct attachment of the spermatial plasma membrane to the trichogyne within 5 min after spermatium inoculation. This direct attachment was followed by completion of spermatial nuclear division and cell wall formation. The polar rings disappeared before prometaphase. The cytoplasm of the binucleate spermatium invaded the trichogyne cell wall and subsequently fused with the trichogyne cytoplasm. The trichogyne could fuse with many spermatia, and many male nuclei (the derivative nuclei of spermatial nuclear division) could enter the trichogyne cytoplasm.     

PROGRESSION OF SPERMATIAL NUCLEAR DIVISION REQUIRES CALCIUM INFLUX DURING FERTILIZATION OF THE RED ALGA PALMARIA SP.1

During fertilization of the red alga Palmaria sp. (Palmariales), the prophase-arrested nucleus of the uninucleate spermatium resumes its division after direct attachment of the spermatium to the trichogyne of a carpogonium. Treatments that reduce Ca²⁺ influx inhibit the progression of spermatial nuclear division. The ratio of the number of spermatia released from prophase arrest (those in meta-phase to binucleate stages) to the total spermatia attached to trichogynes was significantly reduced by incubating the spermatia in the culture solution having low Ca²⁺ concentration. Similar inhibition was observed by addition of either inorganic (La³⁺ and Co²⁺) or organic (nifedipine and tetramethrin) Ca²⁺ channel inhibitors to the culture solution containing 10 mM Ca²⁺. These results indicate that the prophase/metaphase transition of spermatial nuclear division requires an influx of Ca²⁺ and suggest that Ca²⁺ acts as a second messenger to the mechanical or chemical stimulus that initiates mitotic progression of spermatia in this alga.     

SPECIALIZED APPENDAGES ON SPERMATIA FROM THE RED ALGA AGLAOTHAMNION NEGLECTUM (CERAMIALES,CERAMIACEAE) SPECIFICALLY BIND WITH TRICHOGYNES1

Spermatia from Aglaothamnion neglectum Feldmann-Mazoyer specifically bind with trichogynes and hairs of female thalli, One of the functions of hairs on female thalli appears to be the catching of spermatia. Fertilization can occur if a spermatium binds first with a hair and then binds with a trichogyne. The binding of spermatia with trichogynes is not species specific, but only occurs beween closely related species. Spermatia have fimbriate coneshaped appendages projecting from each end that are responsible for initial binding with trichogynes.     

Fine structure of spermatial surface in the red alga Antithamnion nipponicum (Rhodophyta)

In the ceramiacean red alga Antithamnion nipponicum Yamada et Inagaki, the structure of the spermatial covering and appendages was examined using confocal laser scanning microscopy, scanning and transmission electron microscopy. The liberated spermatium was subspherical, ca 4.5 μm in size with a colorless covering 2.7–3.0‐μm thick. Two flexible, ribbon‐like appendages arose from the periphery of the spermatial covering. The appendages averaged 80 μm in length and were 0.5–0.6 μm width in most parts. Each appendage consisted of a number of thin longitudinal fibrils. Concanavalin A conjugated with fluorescein isothiocyanate, colloidal gold orferritin, bound specifically with the inner layer of spermatial covering and spermatial appendages. When the liberated spermatia were incubated with mature female gametophytes, the spermatial appendages entangled around the tricho‐gyne.     

ULTRASTRUCTURE AND CYTOCHEMISTRY OF EARLY SPERMATANGIAL DEVELOPMENT IN ANTITHAMNION NIPPONICUM (CERAMIACEAE,RHODOPHYTA)1

Spermatial development and differentiation of wall components were investigated by electron microscopy and cytochemical methods in Antithamnion nipponicum Yamada et Inagaki. The spermatium is composed of two parts, a globular head and two appendages projecting from near the basal portion. The appendages originate form spermatangial vesicles (SVs) and follow a developmental sequence beginning as amorphous material and ending as fully formed fibrous structures compressed with in the SVs. SV formation is due to contributions initially from endoplasmic reticulum and later form dictyosome-derived vesicles. Chemical differentiation of the spermatial wall occurs early in its development. Calcofluor white ST does not label spermatial walls, indicating an absence of cellulose polysaccharides, which are abundant in vegetative cell walls. Labeled lectins show that α-d -methyl manose and / or α-d -glucose as well as N-acetyl-glucosamine, β-d -galactose, and α-l -fucose moieties are present on the spermatial wall but not in the vegetative cell wall. The glyconjugate with α-d -methyl mannose and / or glucose residues, previously reported as a gamete recognition molecule in this species, is distributed along the surface of spermatia as well as in the SV during spermatangial development.     

ELECTRON MICROSCOPIC OBSERVATIONS ON THE DIFFERENTIATION AND RELEASE OF SPERMATIA IN THE MARINE RED ALGA POLYSIPHONIA HENDRYI (CERAMIALES,RHODOMELACEAE)

Spermatial differentiation in Polysiphonia hendryi begins after nonpolar, avacuolate spermatia are cleaved from their mother cells. The spermatia and their mother cells are embedded within the spermatangium, a confluent wall matrix of the male branch. As the young spermatium enlarges and becomes ellipsoid, the wall fibrils of the spermatangium are compressed, forming a separating layer. Spermatia become polar with rough endoplasmic reticulum coalescing to form a large, fibrillar spermatial vacuole that becomes extracytoplasmic in later development. Following spermatial vacuole formation, dictyosomes form and deposit a spermatial wall, severing the spermatial mother-cell pit connection. Enlargement of younger spermatia, which are lateral to the older ones, squeezes the maturing spermatia, pushing them from the male branch, and leaving a scar that compresses and heals. Through this release mechanism, new sites are created for additional spermatial proliferation.     

STUDIES ON DEVELOPING AND RELEASED SPERMATIA IN THE RED ALGA,TIFFANIELLA SNYDERAE (RHODOPHYTA)1

Developing and released spermatia of the red alga, Tiffaniella snyderae (Farl.) Abb. were studied. Spermatia were observed under hydrodynamically defined conditions and found to be released from the exposed spermatangial heads in a spermatium-plus-strand unit that remained connected to the spermatangial head. Interactions of single-spermatial strands resulted in the formation of multi-spermatial strands as long as 600 μm with as many as 47 spermatia along their length; however, most were 100–200 μm with 8–21 spermatia. Strand length and number of spermatia were correlated. Spermatial strands contracted or extended and rotated as the water velocity past the plant was changed, and in still water the strands retracted into a clump on the spermatangial head surface. Each strand type exhibited a characteristic threshold water velocity at which it reached maximum length, and above which it broke and was carried away. Fluorescence microscopy showed that the strands did not contain nucleic acid (DNA) and could thus be differentiated from filamentous blue-green algal and bacterial epiphytes. Histochemical staining indicated that the strands and spermatial vesicles contained an acidic, sulfated polysaccharide. Chelation of Ca²⁺ with EGTA resulted in strand breakdown suggesting that this divalent cation may be involved in strand integrity. Scanning electron microscopy revealed that release from the spermatangia occurred through tears in the cuticle covering the spermatangial head if it was still present, or from exposed spermatangia. Individual spermatia were attached tangentially to a well-defined strand 0.64 μm in diameter in the contracted state to 0.2 μm in the extended state. Transmission electron microscopy of spermatangial heads showed that immature spermatangia were characterized by a centrally positioned nucleus and abundant ER cisternae filled with a moderately electron dense granular material. Later in development the spermatangia acquire two spermatial vesicles containing highly convoluted fibrillar contents. The cell becomes polarized with the nucleus displaced apically and the spermatial vesicles occupying the basal half of the spermatangium. At maturity one of the vesicles is released basally. Liberated spermatia contain a membrane-bound nucleus and mitochondria and are associated with an oblong accumulation of fibrous material similar in size and position to the strand observed with the SEM. These strands are discussed in relation to red algal fertilization and other phases of the red algal life-history.     

THE DEVELOPMENT AND REPRODUCTIVE MORPHOLOGY OF HALOSACCION AMERICANUM I. K. LEE (RHODOPHYTA,PALMARIALES)1

Halosaccion americanum, a member of Palmariaceae, was grown in culture from spores and the life history was critically examined by the use of scanning EM and light microscopy. A mature tetrasporangium of H. americanum produces four spores that germinate to form two male and two female gametophytes. The male gametophytes grow to maturity in approximately eight months and macroscopically resemble the tetrasporophyte. Following the first division of the tetraspore, the two-celled female gametophyte consists of a vegetative cell and a carpogonium with trichogynes. Fertilization is accomplished by spermatia from male plants of the preceding generation, as male plants of the same season are immature. Spermatia are formed in a continuous layer over the surface of the mature male gametophytes and, when released, are entrained in long strands of mucous. Spermatia adhere to and fuse with trichogynes and, nuclear fusions presumably follow. The carposporophyte is absent; the new tetrasporophyte develops directly from the fertilized carpogonium. Growth of the sporophyte eventually obliterates the female gametophyte, and development into a mature tetrasporophyte proceeds over a period of approximately eight months. The development of H. americanum, with its extremely abbreviated female gametophyte stage and direct development of the tetrasporophyte from the zygote, indicates that this rhodophyte has the same life history as reported for other members of the Palmariales.     

Sialic acid-binding dwarf elder four-chain lectin displays nucleic acid N-glycosidase activity

Sialic acid-binding dwarf elder agglutinin (SEA) present only in rhizomes of the medicinal plant Sambucus ebulus L., was found to be a tetrameric glycoprotein consisting of two covalently-associated dimers of an enzymic A chain with rRNA N-glycosidase activity (EC 3.2.2.22) linked to a B chain with agglutinin properties. The lectin inhibited protein synthesis by a cell-free system and depurinated ribosomes. Cloning of the corresponding gene and molecular modeling of the deduced amino acid sequence demonstrated that SEA has a three-dimensional structure which resembles that reported for other two tetrameric type 2 RIPs from Sambucus (SNAI and SSA). The lectin agglutinated red blood cells and displayed sugar affinity for sialic acid residues apart from d-galactose, binding to the mucin-producing gut goblet cells. Since sialic acid is present in animal cells, especially in epithelial lining gut cells, but not in plants, SEA could play a role in the defense against insect attack.     

Purification,cDNA cloning and recombinant protein expression of a phloem lectin-like anti-insect defense protein BPLP from the phloem exudate of the wax gourd,Benincasa hispida

Latex and other exudates in plants contain various proteins that are thought to play important defensive roles against herbivorous insects and pathogens. Herein, the defensive effects of phloem exudates against the Eri silkworm, Samia ricini (Saturniidae, Lepidoptera) in several cucurbitaceous plants were investigated. It was found that phloem exudates are responsible for the defensive activities of cucurbitaceous plants, such as the wax gourd Benincasa hispida and Cucumis melo, especially in B. hispida, whose leaves showed the strongest growth-inhibitory activity of all the cucurbitaceous plants tested. A 35 kDa proteinaceous growth-inhibitory factor against insects designated BPLP (B. hispida Phloem Lectin-like Protein) was next isolated and purified from the B. hispida exudate, using anion exchange and gel filtration chromatography. A very low concentration (70 μg/g) of BPLP significantly inhibited growth of S. ricini larvae. The full-length cDNA (1076 bp) encoding BPLP was cloned and its nucleotide sequence was determined. The deduced amino acid sequence of BPLP had 51% identity with a cucurbitaceous phloem lectin (phloem protein 2, PP2), and showed binding specificity to oligomers of N-acetylglucosamine. Some features of BPLP indicated that it does not have a cysteine residue and it is composed of two repeats of similar sequences, suggesting that BPLP is distinct from PP2. Recombinant BPLP, obtained by expressing the cDNA in Escherichia coli, showed both chitin-binding lectin activity and growth-inhibitory activity against S. ricini larvae. The present study thus provides experimental evidence that phloem exudates of Cucurbitaceae plants, analogous to plant latex, play defensive roles against insect herbivores, especially against chewing insects, and contain defensive substances toxic to them.