Characterization and distribution of chymotrypsin-like and other digestive proteases in Colorado potato beetle larvae

Chymotrypsin-like, carboxypeptidase A-like and leucine aminopeptidase-like activities have been detected in the midgut of Colorado potato beetle larvae, Leptinotarsa decemlineata Say (Coleoptera: Chrysomelidae), in addition to the previously identified cathepsin B, D, and H. We have characterized a new chymotrypsin-like activity using the specific substrates N- succinyl-L-alanyl-L-alanyl-L-prolyl-L-phenylalanine-p-nitroanilide and N-benzoyl-L-tyrosine p-nitroanilide. This novel proteinase, with a pH optimum of 5.5–6.5, was neither activated by thiol compounds nor inhibited by cysteine proteinase inhibitors. Among several serine proteinase inhibitors tested, PMSF was the most effective. Gelatin-containing SDS-PAGE gels and activity staining after gel electrophoresis indicated that chymotrypsin-like activity was associated with a major band of about 63 Kda and a minor band of about 100 Kda. The major exopeptidases found in the larval midgut extracts were leucine aminopeptidase and carboxypeptidase A. Most endo- and exoproteolytic activities studied were evenly distributed among the midgut sections, indicating that there is no clear regional differentiation in the digestion of proteins. Chymotrypsin and cathepsin B, D, and H were mainly located in the endoperitrophic and ectoperitrophic spaces, with only a small activity associated with the midgut epithelium. In contrast, leucine aminopeptidase was mainly located on the wall tissue, although some activity was distributed between the ecto- and endoperitrophic spaces. The potential roles of Colorado potato beetle digestive chymotrypsin in the proteolytic activation of the δ-endotoxin from Bacillus thuringiensis, and in the use of protease inhibitors to disrupt protein digestion, are discussed. Arch. Insect Biochem. Physiol. 36:181–201, 1997. © 1997 Wiley-Liss, Inc.     

Substrate specificity in the control of digestive enzymes in larvae of the black carpet beetle

When starved larvae of the black carpet beetle, Attagenus megatoma, were fed selected diets, increases in proteolytic, trypsin, and chymotrypsin activity were correlated with total midgut protein and not with the amount of food consumed. Although larvae initially consumed more of a starch diet than of 2 diets that contained added protein, total protease activity in these larvae was minimal. Starch-fed larvae and larvae fed a casein-sucrose diet had a consistently higher level of sucrase activity than larvae fed an all-casein diet. These total results support a secretagogue mechanism for control of digestive enzyme synthesis in insects. In addition, the absence of parallel stimulation of different digestive enzymes by a single substrate (starch) indicated nutrient class specificity in the control of inducible midgut enzymes in this species.     

A freeze-dried diet to test pathogens of Colorado potato beetle

The Colorado potato beetle is an important pest on potato, eggplant, and tomato. Because Colorado potato beetles develop resistance to insecticides quickly, new methods are needed for control. Bacillus thuringiensis is the only bacterium to successfully control Colorado potato beetle. Until recently, one of the drawbacks to testing bacteria against the Colorado potato beetle has been the lack of an artificial diet for screening. Previous artificial diets will only be consumed by Colorado potato beetle larvae when fresh. To improve storage, we developed a freeze-dried diet, based on a 96-well plate, suitable to feed larvae for the duration of a bioassay. Individual diet components were tested both for their effect on insect growth and on pathogen toxicity. When the preservatives, methylparaben and sorbic acid, were removed from the diet, the average weight of second instar larvae increased from 7.9 mg to greater than 9.8 mg. The preservatives inhibited the growth of two of the bacteria tested, Photorhabdus luminescens HM and Chromobacterium sp. PRAA. The removal of these preservatives also allowed for fungal growth and reduced survival from 94 to 38%. Removing diet preservatives, that inhibited the growth of Chromobacterium sp. PRAA, increased the total mortality of the larvae as well as reducing the time needed to kill 50% of the larvae. Compared to incorporation of bacteria into molten diet, the total mortality of Colorado potato beetle fed either P. luminescens HM or Chromobacterium sp. PRAA on freeze-dried diet doubled. Preparation of freeze-dried diet need not be synchronized with the insect or the pathogen. The freeze-dried diet gave consistent results as measured by low control mortality and pathogen toxicity over time.     

Characterization of the Mamestra configurata (Lepidoptera: Noctuidae) larval midgut protease complement and adaptation to feeding on artificial diet,Brassica species,and protease inhibitor

The midgut protease profiles from 5th instar Mamestra configurata larvae fed various diets (standard artificial diet, low protein diet, low protein diet with soybean trypsin inhibitor [SBTI], or Brassica napus) were characterized by one‐dimensional enzymography in gelatin gels. The gut protease profile of larvae fed B. napus possessed protease activities of molecular masses of approximately 33 and 55 kDa, which were not present in the guts of larvae fed artificial diet. Similarly, larvae fed artificial diet had protease activities of molecular masses of approximately 21, 30, and 100 kDa that were absent in larvae fed B. napus. Protease profiles changed within 12 to 24 h after switching larvae from artificial diet to plant diet and vice versa. The gut protease profiles from larvae fed various other brassicaceous species and lines having different secondary metabolite profiles did not differ despite significant differences in larval growth rates on the different host plants. Genes encoding putative digestive proteolytic enzymes, including four carboxypeptidases, five aminopeptidases, and 48 serine proteases, were identified in cDNA libraries from 4th instar M. configurata midgut tissue. Many of the protease‐encoding genes were expressed at similar levels on all diets; however, three chymoptrypsin‐like genes (McSP23, McSP27, and McSP37) were expressed at much higher levels on standard artificial diet and diet containing SBTI as was the trypsin‐like gene McSP34. The expression of the trypsin‐like gene McSP50 was highest on B. napus. The adaptation of M. configurata digestive biochemistry to different diets is discussed in the context of the flexibility of polyphagous insects to changing diet sources. Published 2010 Wiley Periodicals, Inc.     

Co‐expression of the proteinase inhibitors oryzacystatin I and oryzacystatin II in transgenic potato alters Colorado potato beetle larval development

Colorado potato beetle (CPB; Leptinotarsa decemlineata Say, Coleoptera: Chrysomelidae) has shown a remarkable adaptability to a variety of control measures. Although oryzacystatin I and II (OCI and OCII) have potential in controlling pests that use cysteine proteinases for food digestion, expression of a single OC gene in potato exhibited a minimal or no effect on CPB fitness traits. The aim of this study was to examine the effect of coexpressed OCI and OCII in potato (Solanum tuberosum L.) cultivars Desiree, Draga?evka and Jelica on CPB larvae. Growth parameters, consumption rates and food utilization, as well as activity of proteases of CPB larvae were assayed. Second and third instar larvae fed on transformed leaves molted earlier and had higher relative growth and consumption rates than larvae fed on nontransformed leaves, while efficiency of food utilization was unaffected. In contrast, fourth instar maximum weight gain and amount of leaves consumed were about 20% lower for the larvae fed on transgenic potato. Analysis of total protease activity of third instar larvae revealed reduction in overall proteolytic activity measured by azocasein hydrolysis, accompanied with inhibition of cysteine proteinase activity 24 h after ingestion of potato leaves expressing OCI and OCII. However, after long‐term feeding on transformed leaves proteolytic activities of larvae became similar to the controls. Although feeding on OCI/OCII leaves did not affect larval survival, coexpression of OC genes reduced the development time and thus significantly decreased plant damage caused by CPB larvae.     

Fitness and feeding are affected in the two-spotted stinkbug,Perillus bioculatus,by the cysteine proteinase inhibitor,oryzacystatin I

Plant resistance to insect pests based on recombinant proteinase inhibitors (Pis) could interfere with natural enemies of target pests, as their own proteolytic systems may also be sensitive to large spectrum PIs. Oryzacystatin I (OCI) is a potential insect pest resistance factor currently engineered into a variety of crop plants, including potato Solanum tuberosum. Potential for OCI interfering with female reproduction in Perillus bioculatus, a stinkbug predator of Colorado potato beetle, Leptinotarsa decemlineata, was studied by chronic feeding for 18 days on prey loaded with 1–16 μg OCI/day. Mortality of treated females was negligible, but fertility was reduced by up to 50%. Additional dose-dependent effects in reproducing females included delayed oviposition, reduced fecundity, lower egg mass size, and reduced egg eclosion incidence. Females fed for 18 days on OCI at ≤4 μg/day returned to normal oviposition when switched to prey without OCI after 18 days of treatment, but negative effects persisted for at least 10 days at higher doses. Affected reproduction in P. bioculatus is consistent with the use of OCI-sensitive digestive proteinases by this stinkbug. However, azocaseinase activity in whole body extracts of OCI-fed females increased about twofold indicating compensation, and OCI-sensitive proteinases were still present in extracts. When timed for delay to trigger attack on Colorado potato beetle larvae under controlled conditions, stinkbugs feeding on OCI appeared consistently hungrier than controls fed at similar rate, suggesting that predation by stinkbugs exposed to OCI-recombinant foliage would be higher than normal. Arch. Insect Biochem. Physiol. 38:74–83, 1998. © 1998 Wiley-Liss, Inc.     

Physiological response of Colorado potato beetle and beet armyworm larvae to depletion of wound-inducible proteinase inhibitors in transgenic potato plants

Larvae of Colorado potato beetle (CPB), Leptinotarsa decemlineata, and beet armyworm (BAW), Spodoptera exigua, reared on potato plants in which wound-induced accumulation of proteinase inhibitors (PIs) was largely reduced through antisense-mediated depletion of a specific lipoxygenase (LOX H3) had significantly larger weight gains than those fed on non-transformed plants. The midgut endoproteolytic activities of CPB larvae fed on non-transformed potato were significantly higher than those from larvae fed on LOX-H3-deficient plants. However, none of these proteolytic activities was inhibited by potato leaf extracts, regardless of the plant that they were fed on. Taken together, these data suggest that CPB, a leaf-feeding specialist of solanaceous plants, is largely adapted to the inducible PIs of potato, though the metabolic cost associated with the hyperproduction of digestive proteases may account for the 14-31% lower weight gain of larvae fed on non-transformed plants. The effect of LOX-H3 depletion on insect performance was more evident with larvae of the polyphagous BAW (52-63% higher weight gain and 73% higher fecundity when reared on LOX-H3-deficient plants). The poorer larval performance of BAW on non-transformed plants may be due to the susceptibility to inhibition by potato leaf tissues of most BAW digestive proteases. Indeed, BAW larvae fed on non-transformed potato showed a significant reduction in most endoproteolytic activities compared to larvae fed on LOX-H3-deficient plants, suggesting a that these insects deal poorly with induced plant defences in potato.     

Colorado potato beetles compensate for tomato cathepsin D inhibitor expressed in transgenic potato

We reported earlier the importance of digestive cathepsin D-like activity for initiating dietary protein hydrolysis in Colorado potato beetle, Leptinotarsa decemlineata Say [Brunelle et al. (1999) Arch. Insect Biochem. Physiol. 42:88-98]. We assessed here whether transgenic lines of potato (Solanum tuberosum L.) expressing a cathepsin D inhibitor (CDI) from tomato would show resistance to the beetle, or if the insect would compensate for the loss of cathepsin D activity after ingesting the recombinant inhibitor. Transgenic potato lines expressing tomato CDI were developed by Agrobacterium tumefaciens genetic transformation, and selected based on their relative amount of CDI. After confirming the absence of detectable visible effects of CDI on the plant's phenotype, diet assays with control and transgenic lines were carried out to assess the impact of the inhibitor on growth and development of the insect. Leaf consumption, relative growth rate, molting incidence, and digestive protease activity were monitored at 12-h intervals over 132 h for 3rd-instar larvae provided with transgenic potato foliage. Leaf consumption and relative growth rate were slightly reduced during the first 12 h for larvae fed CDI, but no significant differences were observed thereafter. In contrast, time for molting to the 4th larval stage was significantly longer for larvae fed modified plants, with developmental delays of approximately 10 h (0.5 day) compared to control larvae. Recombinant CDI also had an impact on the insect's digestive physiology, readily inducing overproduction of digestive proteases (rubiscases), followed by a gradual decrease of total and pepstatin-sensitive activity. Overall, these observations show the ability of Colorado potato beetle to compensate for the loss of cathepsin D activity by modulating its digestive protease complement in response to aspartate-type inhibitors in the diet. From a practical viewpoint, these data stress the importance of devising improved strategies for the effective inhibition of insect digestive proteinases in vivo, based on the use of hybrid inhibitors active against different protease classes.     

Combining genetic engineering and traditional breeding to provide elevated resistance in potatoes to Colorado potato beetle

The sustainable deployment of resistant crop varieties is a critical issue for the implementation of biotechnology in crop pest management. Feeding, biomass accumulation, and mortality were evaluated for susceptible, insecticide‐resistant, and Bacillus thuringiensis (Bt) Cry 3A‐selected Colorado potato beetle (Leptinotarsa decemlineata Say) (Coleoptera, Chrysomelidae) larvae fed on: cultivated potato, a Solanum chacoense line expressing leptine glycoalkaloids, a transformed line expressing Bt toxin, or the leptine line transformed to express Bt toxin. Larvae selected for resistance to Bt‐Cry3A performed better on Bt foliage, but not as well on the leptine foliage, compared to susceptible or insecticide‐resistant larvae. Neither leptine nor Bt toxin completely inhibited the feeding and growth of 3rd and 4th instars of all three strains of Colorado potato beetle. However, for all three strains of Colorado potato beetle on leptine + Bt foliage, feeding was almost zero, growth was zero or negative, and mortality was near 100%.     

Pymetrozine causes a nontarget pest, the Colorado potato beetle (Coleoptera: Chrysomelidae), to leave potato plants

Pymetrozine is a selective insecticide that targets aphids. Published assessments of the effects of pymetrozine on nontarget organisms focus mainly on predatory insects, and they rarely indicate toxicity. In a laboratory bioassay, survival of Colorado potato beetle, Leptinotarsa decemlineata (Say) (Coleoptera: Chrysomelidae), larvae was not affected by pymetrozine exposure. We subsequently used pymetrozine to implement low-aphid-density treatments in a field experiment that involved separate manipulations of Colorado potato beetle density. Unexpectedly, the addition of Colorado potato beetle adults and eggs did not increase the densities of Colorado potato beetle larvae in plots that were sprayed with pymetrozine (applied with water and an adjuvant). In control plots sprayed with water and adjuvant (without pymetrozine), addition of Colorado potato beetles increased densities of their larvae. Data collected on a smaller scale suggest that a behavioral mechanism underlies the population-level pattern: Colorado potato beetle larvae become more active and are less likely to remain on a host plant after exposure to pymetrozine. Thus, potato, Solanum tuberosum L., growers who use pymetrozine against aphids also might benefit in terms of Colorado potato beetle control.     

Colorado potato beetles show differential digestive compensatory responses to host plants expressing distinct sets of defense proteins

Herbivorous insects fed plants expressing proteinase inhibitors (PIs) compensate for the loss of digestive proteolytic functions by producing novel proteinases. We assessed here whether such compensatory responses represent a general, non-specific adaptation to defense-related proteins in host plant tissues, or if distinct responses occur depending on the stress exerted on the plant. As a model, growth, development, and digestive proteases of the Colorado potato beetle (Leptinotarsa decemlineata Say) were monitored after feeding larvae with plants pre-treated with either methyl jasmonate or arachidonic acid, two compounds inducing different sets of defense genes in potato. In brief, larvae fed plants treated with jasmonate or arachidonate were negatively affected compared to larvae fed non-treated plants, suggesting the potency of both molecules to induce partial resistance to potato beetles in potato. On the other hand, larvae fed treated plants partially compensated for the presence of defense-related proteins by adapting their digestive proteolytic system, both quantitatively and qualitatively. These compensatory processes varied depending on the treatment, the larvae fed arachidonate-treated plants showing the most dramatic response. Compensation to jasmonate and arachidonate was also influenced by a cysteine PI from rice expressed in the plant, pointing out the possible indirect effects of recombinant defense proteins on naturally-occurring plant-insect interactions. These observations, while showing the potential of jasmonate and arachidonate as inducers of partial resistance to the potato beetle in potato, also suggest that digestive compensation in herbivorous insects is determined, at least in part, by defense-related compounds found in the plant in response to different stress stimuli or as a result of ectopic expression in transgenic plants.     

Synthesis of active oryzacystatin I in transgenic potato plants

Summary Transformation of potato (Solanum tuberosum L.) with cysteine proteinase inhibitor (PI) genes represents a potential way of controlling the major insect pest Colorado potato beetle (CPB; Leptinotarsa decemlineata Say). The present study describes the Agrobacterium-mediated transformation of potato (cv. Kennebec) with an oryzacystatin I (OCI) cDNA clone linked to a CaMV 35S promoter. The transgenic plants accumulated active OCI in potato leaves, as demonstrated by the papain-inhibitory activity of transgenic plant leaf extracts. In addition to their anti-papain activity, the extracts also caused a partial but significant inhibition of CPB digestive proteinases, similar to that observed with pure inhibitors. Recombinant OCI did not alter the activity of the major potato leaf endogenous proteinases, which seemed to be of the serine-type. Therefore we suggest that the OCI cDNA can be used for the production of CPB-resistant transgenic potato plants without interfering with endogenous proteinases of these plants.Abbreviations CPB Colorado potato beetle - E-64 trans-epoxy-succinyl-L-leucylamido (4-guanidino) butane - OCI oryzacystatin I - PI proteinase inhibitor - PMSF phenylmethylsulfonyl fluoride     

Diverse enzymatic specificities of digestive proteases, 'intestains', enable Colorado potato beetle larvae to counteract the potato defence mechanism

In response to insect attack, high levels of proteinase inhibitors are synthesised in potato leaves. This can cause inefficient protein digestion in insects, leading to reduced growth, delayed development and lower fecundity. It has been suggested that Colorado potato beetle overcomes this defence mechanism by inducing the production of a set of cysteine proteases that are resistant to potato proteinase inhibitors. Experiments with gut extracts showed that these proteases have unusual inhibition profiles as they are not inhibited by most of the cystatins but are strongly inhibited by thyropins. In this study we have isolated three cysteine proteases from adapted guts of Colorado potato beetle larvae, named intestains 1, 2 and 3, the first cysteine proteases known to be involved in extracellular protein digestion. The N-terminal sequences suggest their classification into the papain family. Intestains differ in substrate specificities and inhibitory profiles. Their substrate specificities suggest that intestains 1 and 2 are general digestive enzymes, while intestain 3 has a more specific function. The inhibitory profile of intestain 1 is similar to that of proteases of the papain family. However, the Ki values for the interaction of intestain 2 with the same set of inhibitors are several hundred fold higher, which would enable the enzyme to circumvent the potato defence mechanism characterised by high concentrations of protease inhibitors in attacked potato leaves. A further, different strategy of the Colorado potato beetle to avoid potato defence is exhibited by intestain 3, which is able to cleave off the N-terminus of model cystatin and thus inactivate the inhibitor. These results suggest that the Colorado potato beetle combines different strategies to counteract plant defence mechanisms.     

Host plant defenses of black (Solanum nigrum L.) and red nightshade (Solanum villosum Mill.) against specialist Solanaceae herbivore Leptinotarsa decemlineata (Say)

Black nightshade (Solanum nigrum, S. nigrum L.) and red nightshade ( Solanum villosum, S. villosum Mill.) are medicinal plants from the Solanaceae family that synthesize glycoalkaloids and other secondary metabolites. To recognize the potential insecticide activity of these compounds, leaf extracts (containing glycoalkaloid and methanol fractions) were tested for enzyme inhibition, antifeedant activity and toxicity. For in‐vitro glutathione S‐transferase (GST) inhibition activity, we used insecticide‐resistant Colorado potato beetle, Leptinotarsa decemlineata ( L. decemlineata; Say) midgut and fat‐body homogenate. In‐vivo toxicity and the antifeedant activity were performed using larval bioassays. The methanol extracts had greater GST inhibitory activity compared to the glycoalkaloids, as well as greater 2nd instar larvae mortality and antifeedant activity. Furthermore, the green leaf volatile compound, cis‐hex‐3‐enyl acetate, at the concentration of 5 ppm, caused 50% mortality of 2nd instar larvae. Our findings suggest the potential usefulness of S. nigrum and S. villosum extracts to control L. decemlineata.     

Isolation and immunochemical characterization of neuropeptides from the midgut of the Colorado potato beetleLeptinotarsa decemlineata

The midgut of the Colorado potato beetle showed endocrine cells immunopositive to monoclonals like MAC-18, MAC-3 and polyclonals to FMRF-amide and AKH-241. Extraction and HPLC-fractionation of the midgut extracts after partial purification and characterization showed immunopositive reaction to the monoclonals and also showed myotropic activity stimulating the potato beetle gut. Molecular mass of the two active peptides isolated were 22 and 26 kDa respectively. Both these peptides could be immunocytochemically demonstrated in the brain neurosecretory cells of the red cotton bug,Dysdercus cingulatus and the castor semilooper,Achaea janata as well.     

Growth compensation and faster development of Colorado potato beetle (Coleoptera: Chrysomelidae) feeding on potato foliage expressing oryzacystatin I

Feeding, growth, development, and food conversion efficiency of Colorado potato beetle larvae reared on foliage from a “Kennebec” potato line expressing oryzacystatin I (OCI) at about 1% of its total soluble proteins were compared to those of larvae feeding on untransformed foliage from the same line. During stages L1 to L3, larvae feeding on OCI consumed leaf material 14% faster, gained weight 28% faster, and weighed 20% more at the end of the L3 stage, compared to controls. Continued exceptional performance on OCI during the final L4 stage was expressed as faster development than controls, an effect that persisted during pupal development and resulted in emergence of similar weight adults 1 day earlier than controls. Larvae initially maintained on control foliage and switched to OCI foliage during L4 did not overcompensate as those on OCI foliage throughout development, but performed similarly to larvae on control foliage throughout. Total azocaseinase activity in midgut extracts from these 4th instars 1 d after switching to OCI foliage was sensitive to inhibition by a recombinant form of OCI expressed in Escherichia coli, but was no longer sensitive 4 d after switching, indicating a gradual adaptation of the insect digestive protease system, based on the production of OCI insensitive proteases. Despite OCI potato foliage being consumed faster by small larvae using it for food, there was no indication that it was less efficient than untransformed foliage as food protein. Arch. Insect Biochem. Physiol. 40:69–79, 1999. © 1999 Wiley‐Liss, Inc.     

Two new bacterial pathogens of Colorado potato beetle Coleoptera: Chrysomelidae)

Other than Bacillus thuringiensis Berliner, few bacteria are lethal to the Colorado potato beetle (Leptinotarsa decemlineata [Say]), a major pest of potatoes and eggplant. Expanded use of biologicals for the control of Colorado potato beetle will improve resistance management, reduce pesticide use, and produce novel compounds for potential use in transgenic plants. Using freeze-dried, rehydrated artificial diet in pellet form to screen bacteria lethal to other insects, we determined that strains of Photorhabdus luminescens killed Colorado potato beetle larvae. The LC50 for second instar larvae of strain HM5-1 was 6.4 +/- 1.87 x 10(7) cells per diet pellet. In an attempt to find additional naturally occurring P. luminescens strains toxic to Colorado potato beetle larvae, we recovered, from soil, bacteria that produced a purple pigment. This bacterial strain, identified as Chromobacterium sp. by 16S ribosomal DNA sequencing, was also toxic to Colorado potato beetle larvae within 3 d. The LC50 for second instar larvae for these bacteria was 2.0 +/- 0.79 x 10(8) cells per diet pellet, while the LC50 was approximately 1 log lower for third instar larvae. P. luminescens appeared to kill by means of a protein toxin that may be similar to the described lepidopteran protein toxins. Based on the heat and acid stability, the toxin or toxins that Chromobacterium sp. produces, while not fully characterized, do not appear to be typical proteins. In both bacteria, the toxins are made after exponential growth ceases.     

Response of digestive cysteine proteinases from the colorado potato beetle (Leptinotarsa decemlineata) and the black vine weevil (Otiorynchus sulcatus) to a recombinant form of human stefin A

The effects of the cystatins, human stefin A (HSA) and oryzacystatin I (OCI) on digestive cysteine proteinases of the Colorado potato beetle (CPB), Leptinotarsa decemlineata, and the black vine weevil (BVW), Otiorynchus sulcatus, were assessed using complementary inhibition assays, cystatin-affinity chromatography, and recombinant forms of the two inhibitors. For both insects, either HSA and OCI used in excess (10 or 20 μM) caused partial and stable inhibition of total proteolytic (azocaseinase) activity, but unlike for OCI the HSA-mediated inhibitions were significantly increased when the inhibitor was used in large excess (100 μM). As demonstrated by complementary inhibition assays, this two-step inhibition of the insect proteases by HSA was due to the differential inactivation of two distinct cysteine proteinase populations in either insect extracts, the rapidly (strongly) inhibited population corresponding to the OCI-sensitive fraction. After removing the cystatin-sensitive proteinases from CPB and BVW midgut extracts using OCI- (or HSA-) affinity chromatography, the effects of the insect “non-target” proteases on the structural integrity of the two cystatins were assessed. While OCI remained essentially stable, HSA was subjected to hydrolysis without the accumulation of detectable stable intermediates, suggesting the presence of multiple exposed cleavage sites sensitive to the action of the insect proteases on this cystatin. This apparent susceptibility of HSA to proteolytic cleavage may partially explain its low efficiency to inactivate the insect OCI-insensitive cysteine proteinases when not used in large excess. It could also have major implications when planning the use of cystatin-expressing transgenic plants for the control of coleopteran pests. © 1996 Wiley-Liss, Inc.     

Glandular hairs on Solatium polyadenium lessen damage by the Colorado beetle

Four-lobed glandular hairs on the leaves and stems of the potato species Solanum polyadenium provide a form of resistance to larvae of the Colorado beetle Leptinotarsa decemlineata. On contact, a sticky material was discharged from these hairs trapping a few larvae and encasing the feet of others. Larvae with encased feet fell from the plants to die.     

Impact of crimson clover dying mulch on two eggplant insect herbivores

Eggplant Solanum melongena L., is often colonized by two early season insect defoliators. The Colorado potato beetle (CPB), Leptinotarsa decemlineata (Say), and flea beetles Epitrix spp., emerge from their overwintering sites in early spring and seek out emerging host plants such as eggplant. During the 2009 and 2010 growing season, field studies were conducted to investigate the impact of inter‐planting eggplant into a crimson clover (CC), Trifolium incarnatum L., winter cover crop on populations of flea beetles, CPB and their associated arthropod predators. The experiment consisted also of two levels of insecticide usage such as an application of azadirachtins plus pyrethrins followed by several applications of spinosad or no insecticide sprays as subplot treatments. During both study years, significantly fewer (adults, larvae and egg masses) were found on eggplant inter‐planted into CC than in bare‐ground (BG) eggplant plots. Although flea beetle abundance was greater in BG eggplant during 2010, they appeared to be less influenced by the presence of CC than were CPB. Additionally, there was no apparent impact of insecticide treatment on CPB populations on eggplant inter‐planted into CC. However, there was a decline in CPB following treatments with insecticides in BG eggplant plots. This suggests that a winter cover crop such as CC can be used to help manage CPB in eggplant, however, using this tactic in tandem with insecticide sprays may not result in greater CPB management.