Identification and characterization of digestive serine proteases from inhibitor-resistant Helicoverpa zea larval midgut

Protease inhibitors mediate a natural form of plant defence against insects, by interfering with the digestive system of the insect. In this paper, affinity chromatography was used to isolate trypsins and chymotrypsins from Helicoverpa zea larvae, which had been raised on inhibitor-containing diet. Sensitivity of the fractions to inhibition by plant proteinase inhibitors was tested, and compared to the sensitivity of proteinases found in insects raised on diet to which no inhibitor had been added. The isolated chymotrypsin activity was found to be less sensitive to plant protease inhibitors. The sensitivity of the isolated trypsin activity was found to be intermediate between completely sensitive trypsins and completely insensitive forms that have been previously described. Mass spectrometry was used to identify one trypsin and two chymotrypsins in the partially purified protease fraction. The sequence features of these proteases are discussed in relation to their sensitivity to inhibitors. The results provide insight in the enzymes deployed by Helicoverpa larvae to overcome plant defence.     

Cloning and characterization of chymotrypsin- and trypsin-like cDNAs from the gut of the Hessian fly [Mayetiola destructor (Say)

Fifteen unique cDNA clones encoding trypsin- or chymotrypsin-like proteins were cloned and characterized from a gut cDNA library derived from Hessian fly [Mayetiola destructor (Say)] larvae. Based on sequence similarities, the cDNAs were sorted into five gene groups, which were named MDP1 to MDP5. Two of the gene groups, MDP1 and MDP2, encoded chymotrypsin-like proteins; the other three encoded putative trypsins. All deduced proteins have conserved His(87), Asp(136), and Ser(241) residues for the catalytic triad and three pairs of cysteine residues for disulfide bridge configurations. The substrate specificity determination residue at position 235 was also conserved in the putative trypsins and chymotrypsins. In addition, all the deduced protein precursors had a typical secretion signal peptide and activation peptide. Northern blot analysis revealed that all these gene groups were exclusively expressed in the larval stage. The expression profiles for each gene group differed significantly in different ages of the larva, as well as in different tissues. Protease activity analysis of gut extract, using specific inhibitors, demonstrated that serine proteases were the major digestive enzymes in the gut of M. destructor larvae. Serine protease inhibitors inhibited as much as 90% proteolytic activities of gut extract, whereas inhibitors specific to other proteases, including cysteine proteases, aspartic proteases, and metallo-proteases, inhibited only 10-24% of gut protease activity.     

Midgut proteases from Mamestra configurata (Lepidoptera: Noctuidae) larvae: characterization,cDNA cloning,and expressed sequence tag analysis

The activities of digestive protease within the midgut of Mamestra configurata (bertha armyworm) larvae were examined using specific substrates and protease inhibitors. The bulk of the activity was associated with serine proteases comprising trypsin-, chymotrypsin-, and elastase-like enzymes. At least 10-15 serine protease isozymes were detected using one-dimension gelatin gel electrophoresis. Cysteine or aspartic protease activities were not present; however, amino- and carboxypeptidase activities were associated with the midgut extract. Midgut proteases were active in the pH range of 5.0-12.0 with peaks at pH 7.5 and 11.0. In general, the middle region of the midgut exhibited a higher pH (approximately 8.0) than either the posterior or anterior regions (approximately 7.3-7.7). Moulting larvae possessed a neutral gut pH that was 0.5-1.5 units below that of feeding larvae. Degenerate PCR and expressed sequence tag (EST)-based approaches were used to isolate 30 distinct serine protease encoding cDNAs from a midgut-specific cDNA library including 8 putative trypsins, 9 chymotrypsins, 1 elastase, and 12 whose potential activities could not be determined. cDNAs encoding three amino- and two carboxypeptidases were also identified. Larvae feeding upon artificial diet containing 0.2% soybean trypsin inhibitor experienced a significant delay in development.     

Collagenolytic activity of crustacean midgut serine proteases: comparison with the bacterial and mammalian enzymes.

1. We have investigated the collagenolytic activity of the following serine proteases: proteinase K, subtilisin Novo, Staphylococcal endoproteinase Glu-C, Streptomyces pronases, the trypsins and chymotrypsins from shrimp midgut and bovine pancreas. 2. By assays on both the insoluble 3H-collagen fibrils and the soluble type I collagen, it was demonstrated that the shrimp midgut serine proteases, and less efficiently, the pronases from Streptomyces griseus, could hydrolyze collagen while the other serine proteases tested could not. 3. Our data indicate that the trypsins and chymotrypsins of shrimp (Penaeus monodon) directly and indirectly digest native collagen, and that the indirect pathway probably involves activation of procollagenase in the native collagen by these serine proteases.     

Molecular mechanisms of tolerance to cyanobacterial protease inhibitors revealed by clonal differences in Daphnia magna

Protease inhibitors of primary producers are a major food quality constraint for herbivores. In nutrient‐rich freshwater ecosystems, the interaction between primary producers and herbivores is mainly represented by Daphnia and cyanobacteria. Protease inhibitors have been found in many cyanobacterial blooms. These inhibitors have been shown (both in vitro and in situ) to inhibit the most important group of digestive proteases in the daphnid's gut, that is, trypsins and chymotrypsins. In this study, we fed four different Daphnia magna genotypes with the trypsin‐inhibitor‐containing cyanobacterial strain Microcystis aeruginosa PCC 7806 Mut. Upon exposure to dietary trypsin inhibitors, all D. magna genotypes showed increased gene expression of digestive trypsins and chymotrypsins. Exposure to dietary trypsin inhibitors resulted in increased activity of chymotrypsins and reduced activity of trypsin. Strong intraspecific differences in tolerance of the four D. magna genotypes to the dietary trypsin inhibitors were found. The degree of tolerance depended on the D. magna genotype. The genotypes' tolerance was positively correlated with the residual trypsin activity and the different IC₅₀ values of the trypsins. On the genetic level, the different trypsin loci varied between the D. magna genotypes. The two tolerant Daphnia genotypes that both originate from the same lake, which frequently produces cyanobacterial blooms, clustered in a neighbour‐joining phylogenetic tree based on the three trypsin loci. This suggests that the genetic variability of trypsin loci was an important cause for the observed intraspecific variability in tolerance to cyanobacterial trypsin inhibitors. Based on these findings, it is reasonable to assume that such genetic variability can also be found in natural populations and thus constitutes the basis for local adaptation of natural populations to dietary protease inhibitors.     

Identification of six chymotrypsin cDNAs from larval midguts of Helicoverpa zea and Agrotis ipsilon feeding on the soybean (Kunitz) trypsin inhibitor

Lepidopteran insects like Helicoverpa zea and Agrotis ipsilon produce STI-insensitive trypsins in the midgut following ingestion of dietary plant proteinase inhibitors like STI [Broadway, R. M., J. Insect Physiol. 43(9) (1997) 855-874]. In this paper, the effects of dietary STI on a related family of midgut serine proteinases, the chymotrypsins, were investigated. STI-insensitive midgut chymotrypsins were detected in larvae of H. zea and A. ipsilon feeding on diets containing 1% STI while STI-sensitive chymotrypsins were present in larvae feeding on diets containing 0% STI. These chymotrypsins were unaffected by TPCK, a diagnostic inhibitor of mammalian chymotrypsins but were fully inhibited by chymostatin. Four midgut cDNA libraries were constructed from larvae of each species fed either 0% STI or 1% STI diets. Six full-length cDNAs(1) encoding diverse preprochymotrypsins were isolated (three from H. zea and three from A. ipsilon) with certain sequence motifs that set them apart from their mammalian counterparts. Northern blots showed that some chymotrypsin mRNA were detected at higher levels while others were down-regulated when comparing insects reared on 0% STI and 1% STI diets. Southern hybridizations suggested that (like mammals) both species contained several chymotrypsin genes. A full-length chymotrypsin gene(1) from H. zea was sequenced for the first time and the presence of four introns was deduced. A first time comparison of 5' upstream regions(1) from three chymotrypsin genes and two trypsin genes of A. ipsilon indicated the presence of putative TATA boxes and regulatory elements. However a lack of consensus motifs in these upstream regions suggested the likelihood of multiple trans factors for regulation of genes encoding digestive proteinases and a complex response mechanism linked to ingestion of proteinase inhibitors.     

Biochemical and molecular characterization of serine proteases from larvae of Chrysomya bezziana, the Old World Screwworm fly

The diversity of serine proteases secreted from Chrysomya bezziana larvae was investigated biochemically and by PCR and sequence analysis. Cation-exchange chromatography of purified larval serine proteases resolved four trypsin-like activities and three chymotrypsin-like activities as discerned by kinetic studies with benzoyl-Arg-p-nitroanilide and succinyl-Ala-Ala-Pro-Phe-p-nitroanilide. Amino-terminal sequencing of the three most abundant fractions gave two sequences, which were homologous to other Dipteran trypsins and chymotrypsins. Analysis of products generated by PCR of cDNA from whole larvae using specific primers based on the amino-terminal sequences and generic serine protease primers identified 22 different sequences, while phylogenetic analysis of the deduced amino acid sequences differentiated two trypsin-like and four chymotrypsin-like families. Phylogenetic comparisons with Dipteran and mammalian serine protease sequences showed that all the Chrysomya bezziana sequences clustered with Dipteran sequences. The Chrysomya bezziana chymotrypsin-like sequences segregated within a Dipteran cluster of chymotrypsin sequences, but were well dispersed amongst these sequences. The largest Chrysomya bezziana serine protease family, the trypB family, clustered tightly as a group, and was closely related to a Lucilia cuprina trypsin but distinct from Drosophila melanogaster alpha and beta trypsins. The trypB family contains ten highly homologous sequences and probably represents an example of concerted evolution of a trypsin gene in Chrysomya bezziana.     

Phyto-inspired cyclic peptides derived from plant Pin-II type protease inhibitor reactive center loops for crop protection from insect pests

BackgroundNatural defence of plants against insect pests involves protease inhibitors (PIs) that interfere with insect digestive proteases. Pin-II type plant PIs are wound inducible upon insect damage and possess multiple inhibitory repeat domains that can inhibit trypsin and chymotrypsin-like proteases in the insect midgut. Yet, their agricultural ex-vivo application is limited due to large molecular size and environmental instability, which could be overcome by small peptides.MethodsBicyclic peptides were designed by grafting Pin-II PIs derived reactive center loop (RCL) on synthetic tris(bromomethyl)benzene scaffold. In vitro binding with trypsin-like proteases was evaluated by biochemical and biophysical assays, followed by molecular dynamics simulations. In vivo effects on two major lepidopteran insect pests, Helicoverpa armigera and Spodoptera litura were studied upon feeding with peptide treated leaves. Affinity based pull down assays were used to identify target proteins in insect gut.ResultsBicyclic RCLs showed ten-fold enhanced protease inhibition compared to their linear counterparts. They exhibited feeding deterrence and growth reduction of lepidopteran insects. Bicyclic peptides predominantly interact with midgut serine proteases. Possible binding modes involve simultaneous interaction with the active site and specificity-determining residues of insect gut trypsin.ConclusionBicyclic peptides are potent inhibitors of serine proteases in the insect midgut. They cause feeding aversion and larval growth retardation. Bi-domain cyclic peptides interact with two sites on trypsin, leading to enhanced efficacy over linear RCL peptides.General significanceBicyclic peptides mimic natural PIs by inhibiting insect proteases leading to growth reduction, thus, could be used as pest control molecules in agriculture.     

Identification and recombinant expression of a novel chymotrypsin from Spodoptera exigua

A novel chymotrypsin which is expressed in the midgut of the lepidopteran insect Spodoptera exigua is described. This enzyme, referred to as SeCT34, represents a novel class of chymotrypsins. Its amino-acid sequence shares common features of gut chymotrpysins, but can be clearly distinguished from other serine proteinases that are expressed in the insect gut. Most notable, SeCT34 contains a chymotrypsin activation site and the highly conserved motive DSGGP in the catalytic domain around the active-site serine is changed to DSGSA. Recombinant expression of SeCT34 was achieved in Sf21 insect cells using a special baculovirus vector, which has been engineered for optimized protein production. This is the first example of recombinant expression of an active serine proteinase which functions in the lepidopteran digestive tract. Purified recombinant SeCT34 enzyme was characterized by its ability to hydrolyze various synthetic substrates and its susceptibility to proteinase inhibitors. It appeared to be highly selective for substrates carrying a phenylalanine residue at the cleavage site. SeCT34 showed a pH-dependence and sensitivity to inhibitors, which is characteristic for semi-purified lepidopteran gut proteinases. Expression analysis revealed that SeCT34 was only expressed in the midgut of larvae at the end of their last instar, just before the onset of pupation. This suggests a possible role of this protein in the proteolytic remodelling that occurs in the gut during the larval to pupal molt.     

Finding protein-protein interaction patterns by contact map matching

We propose a novel method for defining patterns of contacts present in protein-protein complexes. A new use of the traditional contact maps (more frequently used for representation of the intra-chain contacts) is presented for analysis of inter-chain contacts. Using an algorithm based on image processing techniques, we can compare protein-protein interaction maps and also obtain a dissimilarity score between them. The same algorithm used to compare the maps can align the contacts of all the complexes and be helpful in the determination of a pattern of conserved interactions at the interfaces. We present an example for the application of this method by analyzing the pattern of interaction of bovine pancreatic trypsin inhibitors and trypsins, chymotrypsins, a thrombin, a matriptase, and a kallikrein - all classified as serine proteases. We found 20 contacts conserved in trypsins and chymotrypsins and 3 specific ones are present in all the serine protease complexes studied. The method was able to identify important contacts for the protein family studied and the results are in agreement with the literature.     

Bacillus subtillis RTSBA6 6.00, a new strain isolated from gut of Helicoverpa armigera (Lepidoptera: Noctuidae) produces chymotrypsin-like proteases

Exploring bacterial communities with proteolytic activity from the gut of the Helicoverpa armigera (Hubner) (Lepidoptera: Noctuidae) insect pests was the purpose of this study. As initial efforts to achieve this goal here we report the isolation of new Bacillus subtillis RTSBA6 6.00 strain from the gut of H. armigera and demonstrated as proteases producer. Zymographic analysis revealed 12 proteolytic bands with apparent molecular weights ranging from 20 to 185 kDa. Although some activity was detected at acidic pH, the major activity was observed at slight alkaline pH (7.8). The optimum temperature was found to be 35 °C with complete loss of activity at 70 °C. All proteases were completely inactivated by PMSF (phenylmethylsulfonyl fluoride) and TPCK (N-tosyl-l-phenylalanine chloromethyl ketone), suggesting that proteases secreted by B. subtillis RTSBA6 6.00 belong to serine proteases class with chymotrypsin-like activity. The occurrence of protease producing bacterial community in the gut of the H. armigera advocates its probable assistance to insect in proteinaceous food digestion and adaptation to protease inhibitors of host plants.     

Phenotypic changes and the fate of digestive enzymes during induction of amber disease in larvae of the New Zealand grass grub (Costelytra zealandica)

Amber disease of the New Zealand grass grub Costelytra zealandica (Coleoptera: Scarabaeidae) is caused by ingestion of pADAP plasmid carrying isolates of Serratia entomophila or Serratia proteamaculans (Enterobacteriaceae) and causes infected larvae to cease feeding and clear their midgut to a pale amber colour where midgut serine protease activities are virtually eliminated. Using bacterial strains and mutants expressing combinations of the anti-feeding (afp) and gut clearance (sep) gene clusters from pADAP, we manipulated the disease phenotype and demonstrated directly the relationship between gene clusters, phenotype and loss of enzyme activity. Treatment with afp-expressing strains caused cessation of feeding without gut clearance where midgut protease activity was maintained at levels similar to that of healthy larvae. Treatment with strains expressing sep-genes caused gut clearance followed by a virtual elimination of trypsin and chymotrypsin titre in the midgut indicating both the loss of pre-existing enzyme from the lumen and a failure to replenish enzyme levels in this region by secretion from the epithelium. Monitoring of enzymatic activity through the alimentary tract during expression of disease showed that loss of serine protease activity in the midgut was matched by a surge of protease activity in the hindgut and frass pellets, indicating a flushing and elimination of the midgut contents. The blocking of enzyme secretion through amber disease appears to be selective as leucine aminopeptidase and α-amylase were still detected in the midgut of diseased larvae.