Interaction of recombinant CanPIs with Helicoverpa armigera gut proteases reveals their processing patterns, stability and efficiency (original) (raw)
Related papers
Journal of Insect Physiology, 2010
We evaluated 22 different host and non-host plant protease inhibitors (PIs) for in vivo inhibition of Helicoverpa armigera gut pro-and proteinases, and their biological activity against the pod borer, H. armigera, the most important pest of agriculture and horticultural crops worldwide. In vitro activation of H. armigera gut pro-proteinases (HaGPPs) in larvae fed on non-host plant PIs showed significant in vivo inhibition of HaGPPs activation in solution as well as in gel assays. The larvae fed on diet incorporated with Datura alba ness PIs showed highest inhibition of HaGPPs, followed by Psophocarpus tetragonolobus. Non-host plant PIs from Pongamia pinnata, Mucuna pruriens, Capsicum annuum, and Nigela sativa showed maximum inhibitory potential towards HaGPs in vivo, and also exhibited moderate level of inhibition of pro-proteinases. However, some of non-host plant PIs, such as those from Penganum harmala and Solanum nigrum, and the principal host plant PIs, viz., Cicer arietinum and Cajanus cajan did not inhibit HaGPP activity. Pro-proteinase level increased with the growth of the larvae, and maximum HaGPP activity was observed in the fifth-instars. Larvae fed on diets with D. alba ness PIs showed greater inhibition of HaGPPs as compared to the larvae fed on diets with P. tetragonolobus. Low concentrations of partially purified HaGPs treated with gut extract of larvae fed on D. alba ness showed that out of 10 proteinase isoforms, HaGPs 5 and 9 were activators of pro-proteinases. Larval growth and development were significantly reduced in the larvae fed on the non-host plant PIs, of which D. alba ness resulted in highest stunted growth of H. armigera larvae. The in vivo studies indicated that non-host plant PIs were good candidates as inhibitors of the HaGPs as well as HaGPPs. The PIs from the non-host plants can be expressed in genetically engineered plants to confer resistance to H. armigera. ß
Gene expression patterns of Helicoverpa armigera gut proteases
Insect Biochemistry and Molecular Biology, 2005
Relative quantification of reported gut proteinase cDNAs from Helicoverpa armigera larvae fed on various host plants (cotton, chickpea, pigeonpea, tomato and okra), non-host plant PIs (winged bean, bitter gourd, ground nut, and capsicum) and during larval development has been carried out using semi-quantitative RT-PCR. Five trypsin-like and three chymotrypsin-like proteinases were categorized as insensitive or sensitive to most of the proteinase inhibitors (PIs) and insensitive/sensitive to specific PIs based on their expression analysis. These results were supported by amino acid sequence analysis, where diverged amino acids were observed in the regions, which are reported to be involved in typical trypsin-trypsin inhibitor interactions and critical for proteinase inhibitor resistance. Among exopeptidases (five aminopeptidase and three carboxypeptidase), HaAmi4 and HaAmi5 of aminopeptidase and HaCar1 of carboxypeptidase exhibited considerable differential expression. Elastase and cathepsin B-like proteinases were expressed at negligible levels. The proteases identified in the study would be ideal candidates for further interactions studies with protease inhibitors to understand the structural reasons of protease inhibitor insensitivity r
Plant Protease Inhibitors and their Interactions with Insect Gut Proteinases
The Biology of Plant-Insect Interactions, 2018
Overviews of biochemical, genetic, and molecular perspectives of plant-insect interactions with added emphasis on bioinformatic, genomic, and transcriptome analysis are comprehensively treated in this book. It presents the agro-ecological and evolutionary aspects of plant-insect interactions with an exclusive focus on the climate change effect on the resetting of plant-insect i n t e r a c t i o n s. A v a l u a b l e r e s o u r c e f o r biotechnologists, entomologists, agricultural scientists, and policymakers, the book includes theoretical aspects as a base toward real-world applications of holistic integrated pest management in agro-ecosystems.
Gene, 2007
Novel forms of Pin-II type proteinase inhibitor (PIs) cDNAs (CanPIs) having three or four inhibitory repeat domains (IRD) were isolated from the developing green fruits of Capsicum annuum. Deduced amino acid (aa) sequences of the CanPIs showed up to 15% sequence divergence among each other or reported inhibitors (CanPI-1 AF039398, CanPI-2 AF221097). Amino acid sequence analysis of these CanPIs revealed that three IRD PIs have trypsin inhibitory sites, while four IRD CanPIs have both trypsin and chymotrypsin inhibitory sites. Four CanPIs, two having three IRD (CanPI-3 AY986465 and CanPI-5 DQ005912) and two having four IRD (CanPI-7 DQ005913 and CanPI-9 DQ005915), were cloned in Pichia pastoris to express recombinant CanPIs. Recombinant CanPIs inhibited 90% of bovine trypsin (TI), while chymotrypsin inhibition (CI) varied with the number of chymotrypsin inhibitory sites in the CanPIs. Recombinant inhibitors inhibited over 70% of the gut proteinase activity of Helicoverpa armigera. H. armigera larvae fed on recombinant CanPIs individually incorporated into artificial diet, showed 35% mortality; in addition, weight gain in H. armigera larvae and pupae was severely reduced compared to controls. Of the four CanPIs, CanPI-7, which has two sites for TI and CI, was the only one to have a consistently antagonistic effect on H. armigera growth and development. We conclude that among the four recombinant PIs tested, CanPIs containing diverse IRDs are best suited for developing insect-resistant transgenic plants.
Cathepsin B-like protease from chili pepper revealed by in silico approach
The cathepsin B-like proteases of higher plants are mostly related to stress / damage. The expression of cathepsin B-like transcript in the plant system is regarded the response towards abiotic stimuli, wounding of tissues, organ abscission. We isolated a putative cathepsin B-like proteases partial cDNA from chili pepper (Capsicum frutescens). A cDNA library of wound induced placental tissue transcripts was constructed in the phage vector system. Partial sequencing and in silico analysis revealed high levels of sequence homology to cathepsin B-like cysteine protease from the plants of solanaceae family, but much lower levels with other plant cysteine proteinases. Sequence alignment using ClustalW revealed the consensus sequences of the family solanaceae for cathepsin B-like proteases. Further, translated amino acid sequences by BLASTx revealed the conserved domains among the unrelated families. Name assignment to this cDNA as cathepsin B-like protease was based on nucleotide and translated amino acid sequence similarity which is of 91% and 97% respectively with cathepsin B-like cysteine proteinase of Nicotiana rustica. Our current hypothesis towards the function of this cDNA is that it encodes cathepsin B-like proteases in response to mechanical wounding in plant tissues.
Plant protease inhibitors: a defense strategy in plants
Biotechnology and Molecular Biology …, 2007
Proteases, though essentially indispensable to the maintenance and survival of their host organisms, can be potentially damaging when overexpressed or present in higher concentrations, and their activities need to be correctly regulated. An important means of regulation involves modulation of their activities through interaction with substances, mostly proteins, called protease inhibitors. Some insects and many of the phytopathogenic microorganisms secrete extracellular enzymes and, in particular, enzymes causing proteolytic digestion of proteins, which play important roles in pathogenesis. Plants, however, have also developed mechanisms to fight these pathogenic organisms. One important line of defense that plants have to fight these pathogens is through various inhibitors that act against these proteolytic enzymes. These inhibitors are thus active in endogenous as well as exogenous defense systems. Protease inhibitors active against different mechanistic classes of proteases have been classified into different families on the basis of significant sequence similarities and structural relationships. Specific protease inhibitors are currently being overexpressed in certain transgenic plants to protect them against invaders. The current knowledge about plant protease inhibitors, their structure and their role in plant defense is briefly reviewed.
Journal of Chromatography B-analytical Technologies in The Biomedical and Life Sciences, 2006
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.
2006
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.