Spatial organization of digestion in the larval and imaginal stages of the sciarid fly Trichosia pubescens

Aminopeptidase, amylase, cellulase and trypsin are found in major amounts in the midgut lumen, whereas alkaline phosphatase, cellobiase, α-glucosidase, maltase and trehalase occur mainly in the midgut tissue of Trichosia pubescens larvae. Cellulase and a part of the amylase seem to be derived from the fungi the larvae eat. Based on the molecular weights of the enzymes which pass and of those which do not pass through the peritrophic membrane, it is possible to estimate the peritrophic membrane pores as having diameters of 7.5–8.0 nm. Purification and assays of microvillar enzymes from different larval midgut regions suggest that alkaline phosphatase, cellobiase, α-glucosidase, maltase and trehalase are bound to the plasma membrane chiefly of midgut caeca cells. The results support the hypothesis that digestion starts in the endoperitrophic space under the action of amylase, cellulase and trypsin, goes on in the ectoperitrophic space by amylase, cellulase and aminopeptidase and is completed through the catalytic action of plasma membrane-bound hydrolases. The data lead to the conclusion that the spatial organization in T. pubescens larvae is identical to that of another Sciarid fly (Rhynchosciara americana) despite the finding that the midgut trehalase is bound to the plasma membrane in T. pubescens and soluble in R. americana. With metamorphosis salivary amylase appears, α-glucosidase, trehalase and maltase increase, and the other midgut hydrolases decrease or even disappear. This is in accordance with the fact that the larvae feed on decaying plants and fungi and the imagoes feed on nectar.     

Digestive enzymes associated with the glycocalyx,microvillar membranes and secretory vesicles from midgut cells of Tenebrio molitor larvae

Acetylglucosaminidase, amylase, cellobiase and maltase are more active in anterior midgut cells, whereas aminopeptidase, carboxypeptidase and trypsin are more active in posterior midgut cells of Tenebrio molitor larvae. Differential centrifugation of midgut homogenates prepared in saline (or mannitol) isotonic buffered solutions revealed that aminopeptidase is associated with membranes, which occur in subcellular fractions displaying many microvilli. Carboxypeptidase, trypsin and the carbohydrases are mostly found in the soluble fraction, although significant amounts sediment together with cell vesicles. Data on differential calcium precipitation of midgut homogenates and on partial ultrasound disruption of midgut tissue suggest that aminopeptidase is a microvillar enzyme and that the digestive enzymes recovered in the soluble fraction of cells are loosely bound to the cell glycocalyx. About 5% of the non-absorbable dye amaranth fed to T. molitor larvae remains in the midgut tissue after rinsing. Most dye was recovered in the soluble fraction of midgut cells. This provided further support for the hypothesis that the digestive enzymes found in the soluble fraction are actually extracellular and that the true intracellular enzymes are those associated with cell vesicles. The results suggest that the carbohydrases are secreted by exocytosis from the anterior midgut and carboxypeptidase and trypsin from the posterior midgut.     

Consumption of food and spatial organization of digestion in the cassava hornworm, Erinnyis ello

Fifth-instar Erinnyis ello larvae eat 2.1 times their own weight per day of Euphorbia pulcherrima leaves, with a coefficient of digestibility of 45% and an efficiency of food conversion into tissue of 25%. The food takes about 150 min to go through the gut. Midgut contents have a pH of 9.3–9.8, depending on the region. Cellulase is absent from the gut in E. ello. Significant gut hydrolase activities are found only in midgut. Amylase and trypsin occur in the midgut tissue and contents and in regurgitated material, whereas aminopeptidase, α-glucosidase, β-glucosidase and trehalase are found in major amounts in the midgut tissue, in minor amounts in the midgut contents and are absent from regurgitated material. The results support the hypothesis that digestion starts in the endoperitrophic space under the action of amylase and trypsin and is largely completed in the ectoperitrophic space through the catalytic action of several oligomer and dimer hydrolases. Involvement of a membrane-bound aminopeptidase in the terminal digestion of oligopeptides cannot, at present, be excluded. The finding that less than 7% of the total amylase and trypsin are excreted, after a time identical to the passage time of the food bolus, leads to the proposal for the existence of some mechanism by which those enzymes are recovered from the undigested food before it is excreted.     

Spatial organization of digestion,secretory mechanisms and digestive enzyme properties in Pheropsophus aequinoctialis (Coleoptera: Carabidae)

Aminopeptidase (soluble form M_r 110,000), carboxypeptidase A (soluble form M_r 47,000), maltase (a dimer composed of two identical M_r 60,000 subunits) and trypsin (two charge isomers with M_r 34,000) are found in major amounts in the crop and midgut tissue, whereas amylase (a trimer of three identical M_r 18,000 subunits) and cellobiase (a trimer of three identical M_r 27,000 subunits) occur mainly in the crop and midgut contents. Subcellular fractions of midgut cells were obtained by conventional homogenization, followed by differential centrifugation or differential calcium precipitation. The results suggest that part of the aminopeptidase and carboxypeptidase A activity is bound to microvilli, that major amounts of trypsin and maltase are trapped in the cell glycocalyx and finally that soluble aminopeptidase, amylase and cellobiase occur in intracellular vesicles. The data support the hypothesis that most protein and carbohydrate digestion takes place in the crop under the action of enzymes passed forward from the midgut, after being secreted by exocytosis. Nevertheless, part of the intermediate and final digestion occurs at the surface of the midgut cells. The peculiar features of the digestion of P. aequinoctialis beetles, including their partly fluid peritrophic membranes, are thought to be derived from putative Coleoptera ancestors.     

Subcellular fractionation of midgut cells of the sunn pest Eurygaster integriceps (Hemiptera: Scutelleridae): Enzyme markers of microvillar and perimicrovillar membranes

The subcellular distributions of six digestive and non-digestive enzymes (α-glucosidase, β-glucosidase, alkaline phosphatase, acid phosphatase, aminopeptidase and lactate dehydrogenase) of Eurygaster integriceps have been studied. The subcellular distributions of acid phosphatase and α-glucosidase are similar and the gradient ultracentrifugation profiles of these two enzymes overlap. Two partially membrane-bound enzymes, alkaline phosphatase and β-glucosidase have similar distributions in differential centrifugation fractions, which are different from that of α-glucosidase. Sucrose gradient ultracentrifugation of membranes from luminal contents showed that β-glucosidase carrying membranes are heavier. SDS-polyacrylamide gel electrophoresis (SDS-PAGE) revealed that the profile of proteins extracted from β-glucosidase carrying membranes is different from that of α-glucosidase carrying membranes. We conclude that β-glucosidase and aminopeptidase are markers of microvillar membrane (MM) and perimicrovillar space, respectively, while α-glucosidase and acid phosphatase are perimicrovillar markers. In E. integriceps V1 luminal content is a rich source of PMM and MM and that is used to resolve these membranes.     

The physiological role of the peritrophic membrane and trehalase: Digestive enzymes in the midgut and excreta of starved larvae of Rhynchosciara

Amylase, cellulase, trehalase, aminopeptidase and trypsin were determined using the midgut and trehalose using the haemolymph of starved and of subsequently fed larvae of Rhynchosciara americana. Midgut trehalase activity decreases steadily during starvation and increases again on feeding, whereas haemolymph trehalose titres remain constant, suggesting that trehalase is a true digestive enzyme. The decrease in amylase, cellulase and trypsin activity in the midgut during starvation is of the same order as that recovered from the excreta. Since this finding is exactly what one would expect if enzyme production stops in response to starvation, this supports the hypothesis that synthesis that synthesis of these enzymes is controlled. The excretion rate of amylase, cellulase and trypsin is very low in comparison to their activity inside the peritrophic membrane and the travel time of the food bolus through the gut. It is proposed that the peritrophic membrane separates two extracellular sites for digestion as an adaptation to conserve secreted enzymes. This could be accomplished by the existence of an endo-ectoperitrophic circulation of the enzymes involved in the initial attack on the food and by restricting to the ectoperitrophic fluid the enzymes which participate only in intermediary digestion of food.     

The digestive system of the “stick bug” Cladomorphus phyllinus (Phasmida,Phasmatidae): A morphological,physiological and biochemical analysis

This work presents a detailed morphofunctional study of the digestive system of a phasmid representative, Cladomorphus phyllinus. Cells from anterior midgut exhibit a merocrine secretion, whereas posterior midgut cells show a microapocrine secretion. A complex system of midgut tubules is observed in the posterior midgut which is probably related to the luminal alkalization of this region. Amaranth dye injection into the haemolymph and orally feeding insects with dye indicated that the anterior midgut is water-absorbing, whereas the Malpighian tubules are the main site of water secretion. Thus, a putative counter-current flux of fluid from posterior to anterior midgut may propel enzyme digestive recycling, confirmed by the low rate of enzyme excretion. The foregut and anterior midgut present an acidic pH (5.3 and 5.6, respectively), whereas the posterior midgut is highly alkaline (9.1) which may be related to the digestion of hemicelluloses. Most amylase, trypsin and chymotrypsin activities occur in the foregut and anterior midgut. Maltase is found along the midgut associated with the microvillar glycocalix, while aminopeptidase occurs in the middle and posterior midgut in membrane bound forms. Both amylase and trypsin are secreted mainly by the anterior midgut through an exocytic process as revealed by immunocytochemical data.     

Nature of the anchors of membrane-bound aminopeptidase,amylase, and trypsin and secretory mechanisms in Spodoptera frugiperda (Lepidoptera) midgut cells

Spodoptera frugiperda larvae have a microvillar aminopeptidase and both soluble and membrane-bound forms of amylase and trypsin. Membrane-bound aminopeptidase is solubilized by glycosyl phosphatidylinositol-specific phospholipase C (GPI-PLC) and detergents, suggesting it has a GPI anchor. Membrane-bound trypsin is not affected by GPI-PLC, although it is solubilized by papain and by different detergents. Membrane-bound amylase is similar to trypsin, although once solubilized in detergent it behaves as a hydrophilic protein. Musca domestica trypsin antiserum cross-reacts with only one polypeptide from S. frugiperda midgut. With this antiserum, trypsin was immunolocalized in the anterior midgut cells at the microvillar surface and on the membranes of secretory vesicles found in the apical cytoplasm and inside the microvilli. The data suggest that in this region trypsin is bound to the secretory vesicle membrane by a hydrophobic anchor. Vesicles migrate through the microvilli and are discharged into the lumen by a pinching-off process. Trypsin is then partly processed to a soluble form and partly, still bound to vesicle membranes, incorporated into the peritrophic membrane. In posterior midgut cells, trypsin immunolabelling is randomly distributed inside the secretory vesicles and at the microvilli surface, suggesting exocytosis. Amylase probably follows a route similar to that described for trypsin in anterior midgut, although membrane-bound forms (peptide anchor) solubilize apparently as a consequence of a pH increase inside the vesicles.     

Digestive enzymes in midgut cells,endo-and ectoperitrophic contents,and peritrophic membranes of Spodoptera frugiperda (lepidoptera) larvae

In the midgut of Spodoptera frugiperda larvae, subcellular fractionation data suggest that aminopeptidase and part of amylase, carboxypeptidase A, dipeptidase, and trypsin are bound to the microvillar membranes; that major amounts of soluble dipeptidase, cellobiase, and maltase are trapped in the cell glycocalyx; and finally that soluble carboxypeptidase, amylase, and trypsin occur in intracellular vesicles. Most luminal acetylglucosaminidase is soluble and restricted to the ectoperitrophic contents. Aminopeptidase occurs in minor amounts bound to membranes both in the ectoperitrophic contents and incorporated in the peritrophic membrane. Amylase, carboxypeptidase A, and trypsin are found in minor amounts in the ectoperitrophic contents (both soluble and membrane-bound) and in major amounts in the peritrophic membrane with contents. Part of the activities recovered in the last mentioned contents corresponds to enzyme molecules incorporated in the peritrophic membrane. The results suggest that initial digestion is carried out in major amounts by enzymes in the endoperitrophic space and, in minor amounts, by enzymes immobilized in the peritrophic membrane. Intermediate and final digestion occur at the ectoperitrophic space or at the surface of midgut cells. The results also lend support to the hypothesis that amylase and trypsin are derived from membrane-bound forms, are released in soluble form by a microapocrine mechanism, and are partly incorporated into the peritrophic membrane. © 1994 Wiley-Liss, Inc.     

Ultrastructural and biochemical aspects of digestion in the imagoes of the flyRhynchosciara americana

The midgut of adultRhynchosciara americana Wiedemann (Diptera: Sciaridae) displays, in contrast to the midguts of other adult Diptera, two caeca connected to a ventriculus. All midgut cells exhibit long apical microvilli, and narrow and ramified basal channels with openings to the underlying space. These morphological features are thought to be involved in the absorption of nutrients from food. Enzymatic assays inR. americana adults revealed that amylase occurs in salivary glands and midgut, whereas aminopeptidase, α-glucosidases and trypsin occur only in the midgut, mainly in the ventriculus. There is a soluble (Mr 105000) and a membrane-bound aminopeptidase (solubilized form, Mr 110000). Soluble α-glucosidase inactivates easily and could not be characterized, whereas membrane-bound α-glucosidases were resolved after solubilization into three molecular species (Mr 186000, 105000 and 84000) with different substrate specificities. The activities of trypsin (pH optimum 9.0), which was inhibited completely by soybean trypsin inhibitor, and of amylase (pH optimum 5.5), were not sufficiently high to be further characterized. The data support the assertion thatR. americana adults are able, to a limited extent, to digest and absorb starch and proteins, in addition to nectar sugars. The results, supported by published data, suggest that there is an inverse correlation between the digestive enzyme activities and midgut absorptive surface in insects which has nectar as a major food.     

Physiological adaptations for digesting bacteria. Water fluxes and distribution of digestive enzymes in Musca domestica larval midgut

Dye experiments with Musca domestica larvae suggest that in each passage of food (104 min) water is secreted into the gut lumen in the fore-midgut (1.5 μl) and in the hind-midgut (3.9 μl), and water is absorbed from the gut lumen in the mid-midgut (2.3 μl) and hind-gut (3.6 μl). Hydrolases found to be active mainly in luminal contents were amylase and trypsin (fore- and hind-midgut), and lysozyme and pepsin (mid-midgut), whereas those mainly active in midgut cells were aminopeptidase and trehalase (fore- and hind-midgut). Maltase was found in both contents and cells of hind-midgut. Less than 20% of hind-midgut amylase and trypsin are excreted, after a time identical to the passage time of the food bolus, suggesting that there exists an endo-ectoperitrophic circulation of enzymes, by which these enzymes are recovered from the undigested food before it is excreted. The data led to the proposal that bacteria are killed at mid-midgut through the combined action of low pH, lysozyme and pepsin. Digestion of proteins and starch is largely accomplished in the hind-midgut lumen, whereas the resulting oligopeptides and oligosaccharides are hydrolyzed down to monomers at the surface of proximal hind-midgut cells. The adaptive features of the digestion of housefly maggots are thought to be derived characters evolved from a putative Diptera ancestor.     

Pore formation activity of Cry1Ab toxin from Bacillus thuringiensis in an improved membrane vesicle preparation from Manduca sexta midgut cell microvilli

The pore formation activity of Cry1Ab toxin is analyzed in an improved membrane preparation from apical microvilli structures of Manduca sexta midgut epithelium cells (MEC). A novel methodology is described to isolate MEC and brush border membrane vesicles (BBMV) from purified microvilli structures. The specific enrichment of apical membrane enzyme markers aminopeptidase (APN) and alkaline phosphatase (APh) were 35- and 22-fold, respectively, as compared to the whole midgut cell homogenate. Ligand-blot and Western-blot experiments showed that Cry1A specific receptors were also enriched. The pore formation activity of Cry1Ab toxin was fourfold higher in the microvilli membrane fraction that showed low intrinsic K+ channels and higher APN and APh activities than in the basal-lateral membrane fraction harboring high intrinsic K+ channels. These data suggest that basal-lateral membrane was separated from apical membrane.This procedure should allow more precise studies of the interaction of Cry toxins with their target membranes, avoiding unspecific interaction with other cellular membranes, as well as the study of the pore formation activity induced by Cry toxins in the absence of endogenous channels from M. sexta midgut cells.     

Alkaline phosphatase in HeLa cells. Stimulation by phospholipase A2 and lysophosphatidylcholine.

Treatment of homogenates and plasma membrane preparations from HeLa cells with phospholipase A2 (EC 3.1.1.4) caused a 50% increase in activity of membrane-associated alkaline phosphatase. Lysophosphatidylcholine, dispersed in 0.15 M KCl, affected alkaline phosphatase in a similar fashion by releasing the enzyme from particulate fractions into the incubation medium and by elevating its specific activity. Higher concentrations of lysophosphatidylcholine solubilized additional protein from particulate fractions but did not further increase the specific activity of the released alkaline phosphatase. Particulate fractions from HeLa cells were exposed to the effects of liposomes prepared from lysophosphatidylcholine and cholesterol. The ratio of particulate protein/lysophosphatidylcholine (by weight) required for optimal activation of alkaline phosphatase was one. Kinetic studies indicated that phospholipase A2 and lysophosphatidylcholine enhanced the apparent V of the enzyme but did not significantly alter its apparent Km. The increased release of alkaline phosphatase from the particulate matrix by lysophosphatidylcholine was confirmed by disc electrophoresis. The release of the enzyme by either phospholipase A2 or by lysophosphatidylcholine appeared to be followed by the formation of micelles that contained lysophosphatidylcholine. The new complexes had relatively less cholesterol and more lysophosphatidylcholine than the native membranes. The possibility that lysophosphatidylcholine formed a lipoprotein complex with the solubilized alkaline phosphatase was indicated by a break point in the Arrhenius plot which was evident only in the lysophosphatidylcholine-solubilized enzyme but could not be demonstrated in alkaline phosphatase that had been released with 0.15 M KCl alone.     

Membrane anchors of alkaline phosphatase and trehalase associated with the plasma membrane of larval midgut epithelial cells of the silkworm, Bombyx mori

The larval midgut epithelial cell of the silkworm, Bombyx mori, has two forms of alkaline phosphatase and trehalase, soluble and membrane-bound. Alkaline phosphatase and trehalase of the latter form are found in the brush border membrane and the basolateral membrane, respectively. In this work we studied the membrane anchors of these membrane-bound enzymes. Alkaline phosphatase was solubilized by phosphatidyl-inositol-specific phospholipase C, but not by papain. Conversely, trehalase was released from the membrane by papain, but not by phosphatidylinositol-specific phospholipase C. Both enzymes were solubilized in an amphiphilic form with 0.5% Triton X-100 plus 0.5% sodium deoxycholate (pH 7.0). The detergent-solubilized alkaline phosphatase and trehalase were converted to hydrophilic form on incubation with phosphatidylinositol-specific phospholipase C and papain, respectively. The effects of papain on solubilization and conversion of trehalase were completely inhibited by leupeptin. These results suggest that, in the silkworm larvae, alkaline phosphatase is anchored in the brush-border membrane via a glycosyl-phosphatidylinositol, while trehalase is associated with the basolateral membrane through a hydrophobic segment of the polypeptide.     

Enzymatic characterization of subcellular samples from gypsy moth larval midgut following differential centrifugation and fractionation on Percoll-sucrose gradient

A method is described for isolation of an enriched fraction of plasma membranes from gypsy moth (Lymantria dispar) larval midgut tissue. Following differential centrifugation of tissue homogenate, a microsomal sample is obtained and fractionated on a Percoll®-sucrose gradient that yields 2 distinct regions of high protein concentration: one enriched in plasma membranes, the other in mitochondrial membranes. The procedure is relatively rapid, being completed within approximately 5 h. Protein yields and accompanying specific activities are reported for marker enzymes used to indicate the presence of plasma membranes (leucine aminopeptidase and alkaline phosphatase), endoplasmic reticulum (NADPH-cytochrome c reductase), and mitochondria (succinate dehydrogenase). The apparent differences between the plasma membrane enriched fraction vs. brush border membrane vesicles prepared from insect midguts are discussed, as is the suitability of the plasma membrane enriched fraction for ATP-dependent calcium ion transport studies. © 1992 Wiley-Liss, Inc.     

Studies on the enzymology of purified preparations of brush border from rabbit kidney

1. A method for the preparation of brush border from rabbit kidneys is described. Contamination by other organelles was checked by electron microscopy and by the assay of marker enzymes and was low. 2. Seven enzymes, all hydrolases, were substantially enriched in the brush-border preparation and are considered to be primarily located in this structure. They are: alkaline phosphatase, maltase, trehalase, aminopeptidase A, aminopeptidase M, gamma-glutamyl transpeptidase and a neutral peptidase assayed by its ability to hydrolyse [(125)I]iodoinsulin B chain. 3. Adenosine triphosphatases were also present in the preparation, but showed lower enrichments. 4. Alkaline phosphatase was the most active phosphatase present in the preparation. The weak hydrolysis of AMP may well have been due to this enzyme rather than a specific 5'-nucleotidase. 5. The two disaccharidases in brush border were distinguished by the relative heat-stability of trehalase compared with that of maltase. 6. The individuality of the four peptidases was established by several means. The neutral peptidase and aminopeptidase M, both of which can attack insulin B chain, differed not only in response to inhibitors and activators but also in the inhibitory effect of a guinea-pig antiserum raised to rabbit aminopeptidase M. This antiserum inhibited both the purified and the brush-border activities of aminopeptidase M. The neutral peptidase and gamma-glutamyl transpeptidase were unaffected but aminopeptidase A was weakly inhibited. The characteristic responses to Ca(2+) and serine with borate served to distinguish aminopeptidase A and gamma-glutamyl transpeptidase from other peptidases. 7. No dipeptidases, tripeptidases or carboxypeptidases were identified as brush-border enzymes. 8. Incubation of brush border with papain released almost all the aminopeptidase M activity but only about half the activities of maltase, gamma-glutamyl transpeptidase and aminopeptidase A. No release of alkaline phosphatase, trehalase or the neutral peptidase was observed.     

Developmental changes in midgut trehalase activity and its localization in the silkworm, Bombyx mori

The changes in trehalase activity and its localization in the midgut of the silkworm, Bombyx mori, were studied during larval-pupal-adult development. Trehalase activity in larval midgut epithelium increased with the larval growth, reached a maximum level at the middle of the fifth instar, and then decreased gradually. Trehalase activity in larval midgut was found in the epithelial tissue but not in the digestive juice or the midgut contents.The trehalase activity in the whole midgut started to rise at the onset of spinning and increased abruptly at larval-pupal ecdysis to reach an extremely high level 3 days later. This high activity was maintained throughout the subsequent pharate adult development and dropped suddenly at emergence. The midgut trehalase activity during pupal-adult development was mainly found in the midgut contents but scarcely any in the epithelium.Subcellular distribution of midgut trehalase depended upon larval-pupal-adult development. The activity was concentrated in a precipitate fraction of the epithelium until the middle of the fifth instar. During larval-pupal development, however, the activity increased in the soluble fraction with a concomitant decrease in the precipitate fraction. Almost all the trehalase activity in pupal and pharate adult midgut was recovered in the soluble fraction of the midgut contents. The data are discussed from a viewpoint of the histolysis.     

Ultrastructure and immunolocalization of digestive enzymes in the midgut of Podisus nigrispinus (Heteroptera: Pentatomidae)

The predatory stinkbug Podisus nigrispinus has been utilized in biological control programs. Its midgut is anatomically divided into anterior, middle and posterior regions, which play different roles in the digestive process. We describe the midgut ultrastructure and the secretion of digestive enzymes in the midgut of P. nigrispinus. Midguts were analyzed with transmission electron microscopy and the digestive enzymes amylase, cathepsin L, aminopeptidase and α-glucosidase were immunolocalized. The ultrastructural features of the digestive cells in the anterior, middle and posterior midgut regions suggest that they play a role in digestive enzyme synthesis, ion and nutrient absorption, storage and excretion. The digestive enzymes have different distribution along the midgut regions of the predator P. nigrispinus. Amylase, aminopeptidase and α-glucosidase occur in three midgut regions, whereas cathepsin L occurs in the middle and posterior midgut regions. The anterior midgut region of P. nigrispinus seems to play a role in water absorption, the middle midgut may be involved in nutrient absorption and the posterior midgut region is responsible for water transport to the midgut lumen.     

The encapsulation process in Biomphalaria glabrata experimentally infected with the metastrongylid Angiostrongylus cantonensis: enzyme histochemistry.

Enzyme histochemistry has revealed that encapsulation reactions surrounding larvae of the nematode Angiostrongylus cantonensis 4 wk after infection of the gastropod Biomphalaria glabrata are the sites of highly localized acid phosphatase and nonspecific esterase activities. Lesser amounts of alkaline phosphatase and β-glucuronidase activities also occur within such capsules, but aminopeptidase activity cannot be demonstrated. In addition, it has been ascertained that acid phosphatase activity gradually increases as the encapsulation reaction progresses during the first to the fourth week postinfection.     

Purification of glycosylphosphatidylinositol-anchoring aminopeptidase in from the plasma membrane of larval midgut epithelial cells of the silkworm,Bombyx mori

• 1.1. Aminopeptidase N was selectively released from larval midgut of silkworm, Bombyx mori, by phosphatidylinositol-specific phospholipase C, and purified to a homogeneous state by ion exchange, gel filtration. Con A-Sepharose and 4-aminobenzyl phosphonic acid-agarose column chromatographies.
• 2.2. The purified aminopeptidase N preparation showed 190.8 U/mg of specific activity. Its molecular weight was estimated to be around 100 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.
• 3.3. Purified aminopeptidase N molecule preferentially hydrolyzed Leu-, Ala- and Met-p-nitroanilide as substrates. Especially, Leu-p-nitroanilide proved to be the best substrate for aminopeptidase N from larval midgut of silkworm.
• 4.4. By treatment with phosphatidylinositol-specific phospholipase C, two other hydrolases, alkaline phosphatase and alkaline phosphodiesterase I, were also solubilized from silkworm midgut.