An electroblotting, two-step procedure for the detection of proteinases and the study of proteinase/inhibitor complexes in gelatin-containing polyacrylamide gels.

A two-step gelatin/polyacrylamide gel electrophoresis (gelatin/PAGE) procedure was devised for the detection of proteinases and the study of proteinase/inhibitor interactions in complex biological extracts. The proteins are first resolved by sodium dodecyl sulfate (SDS)-PAGE under reducing or nonreducing conditions, and electrotransferred into a 0.75 mm-thick accompanying polyacrylamide slab gel containing 0.1% w/v porcine gelatin. The active proteinase bands are developed by a gelatin proteolysis step in the accompanying gel in the presence or absence of diagnostic proteinase inhibitors, allowing the assessment of proteinase classes and the visual discrimination of inhibitor-'sensitive' and -'insensitive' proteinases in complex extracts. Alternatively, protein extracts are preincubated with specific reversible inhibitors before electrophoresis, allowing a rapid discrimination of strong and weak interactions implicating proteinases and reversible inhibitors. In comparison with the standard gelatin/PAGE procedure, that involves copolymerization of gelatin with acrylamide in the resolving gel, this new procedure simplifies proteinase patterns, avoids overestimation of proteinase numbers in complex extracts, and allows in certain conditions the estimation of proteinase molecular weights. Stem bromelain (EC 3.4.22.32), bovine trypsin (EC 3.4.21.4), papain (EC 3.4.22.2), and the extracellular (digestive) cysteine proteinases of five herbivorous pests are used as model enzymes to illustrate the usefulness of this approach in detecting proteinases and in studying their interactions with specific proteinaceous inhibitors potentially useful in biotechnology.

Engineering natural and synthetic resistance for nematode management.

Bioengineering strategies are being developed that will provide specific and durable resistance against plant-parasitic nematodes in crops. The strategies come under three categories: (i) transfer of natural resistance genes from plants that have them to plants that do not, to mobilize the defense mechanisms in susceptible crops; (ii) interference with the biochemical signals that nematodes exchange with plants during parasitic interactions, especially those resulting in the formation of specialized feeding sites for the sedentary endoparasites-many nematode genes and many plant genes are potential targets for manipulation; and (iii) expression in plant cells of proteins toxic to nematodes.

Temporal Changes in the Vertical Distribution of Pratylenchus penetrans under Raspberry.

Population densities of Pratylenchus penetrans and the biomass of fine roots of raspberry at depths of 0-5, 5-10, 10-20, and 20-30 cm were determined every 2 weeks for 2 years. The vertical distribution of P. penetrans varied from season to season, but the seasonal changes were not similar for the 2 years. In most seasons, the greatest population density was in the 5 to 10-cm-depth interval. Population densities of P. penetrans were not consistently correlated with the vertical distribution of raspberry roots in any season.

Intraspecific Variation in Ribosomal DNA in Populations of the Potato Cyst Nematode Globodera pallida.

The relationships among a number of populations of Globodera pallida from Britian, the Netherlands, Germany, Switzerland, and South America were examined using PCR amplification of the ribosomal cistron between the 18S and 28S genes that include the two intergenic spacer regions (ITS1 and ITS2) and the 5.8S gene. Amplifications produced a similar-sized product of 1150 bp from all populations. Digestion of the amplified fragment with a number of restriction enzymes showed differences among the populations. The restriction enzyme RsaI distinguished the most populations. The RFLP patterns revealed by this enzyme were complex and could have arisen from heterogeneity between individuals within populations and from differences between the repeats of an individual. Sequence analysis from six of the populations, together with RFLP analysis of PCR products, shows that there is intraspecific variation in the rDNA of G. pallida.

Identification of stable plant cystatin/nematode proteinase complexes using mildly denaturing gelatin/polyacrylamide gel electrophoresis.

The biochemical interactions between two cystatins from rice seeds, oryzacystatin I (OCI) and oryzacystatin II (OCII), and the cysteine proteinases from three plant parasitic nematodes, Meloidogyne hapla, M. incognita and M. javanica, were assessed using standard protease assays and mildly denaturing gelatin/polyacrylamide gel electrophoresis (gelatin/PAGE). Activity detected in extracts of preparasitic second-stage larvae (J2) from M. hapla was optimal at pH 5.5 and was inhibited in vitro by the cysteine proteinase inhibitors trans-epoxysuccinyl-L-leucylamido-(4-guanidino) butane, hen egg cystatin, OCI, and OCII. As demonstrated by class-specific activity staining, all the activity measured between pH 3.5 and pH 7.5 was accounted for by a major proteinase form, Mhp1, and two minor forms, Mhp2 and Mhp3. Mhps were also detected in extracts and excretions of parasitic J2 and adult females, indicating their continuous expression throughout development of M. hapla, and their possible involvement in the extracellular degradation of proteins. Interestingly, the two plant cysteine proteinase inhibitors OCI and OCII showed different degrees of affinity for the major proteinase form, Mhp1. Both inhibitors almost completely inactivated this proteinase in native conditions but, unlike OCII, OCI conserved a high affinity for Mhp1 during mildly denaturing gelatin/PAGE, showing the differential stabilities of the OCI/Mhp1 and OCII/Mhp1 complexes. In contrast to Mhp1, the major cysteine proteinases detected in the two closely related species M. incognita and M. javanica were strongly inhibited by OCII, while the inhibition of OCI was partly prevented during electrophoresis. This species-related efficiency of plant cystatins against nematode cysteine proteinases could have practical implications when planning their use to control nematodes of the genus Meloidogyne.

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 microM) 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 microM). 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.

Assessing the stability of cystatin/cysteine proteinase complexes using mildly-denaturing gelatin-polyacrylamide gel electrophoresis.

A method for assessing the stability of cystatin/cysteine proteinase complexes using mildly-denaturing gelatin-polyacrylamide gel electrophoresis (gelatin-PAGE) is described. As suggested by the use of well-known cystatins (human stefins A and B, and oryzacystatins I and II) and the plant cysteine proteinase papain, the ability of cystatin/cysteine proteinase complexes to remain stable during electrophoresis is associated with the degree of affinity between the enzyme and the inhibitor (and inversely associated with the Ki values), at least with the disulfide bond-lacking cystatins. Complexes with Ki values > or = 10(-8) M (weak interactions) are partly or completely dissociated under the conditions used, while those with lower Ki values (strong interactions) remain stable. As shown by the differential effects of two plant cystatins, oryzacystatins I and II, against a cysteine proteinase present in crude (complex) extracts from a plant pest -- the two-spotted spider mite (Tetranychus urticae Koch), the gelatin-PAGE procedure is suitable for studying the ability of cystatins to form highly stable complexes with cysteine proteinases, without the need for prior purification steps. Considering the well-recognized potential of proteinase inhibitors for pest and pathogen control, this analytical approach will be useful for rapidly assessing the respective potential of various cystatins for protection of plants, animals, and humans.

Use of cellulose acetate electrophoresis in the taxonomy of steinernematids (rhabditida, nematoda).

A steinernematid nematode was isolated from soil samples collected near St. John's, Newfoundland, Canada. On the basis of its morphometry and RFLPs in ribosomal DNA spacer, it was designated as a new strain, NF, of Steinernema feltiae. Cellulose acetate electrophoresis was used to separate isozymes of eight enzymes in infective juveniles of S. feltiae NF as well as four other isolates: S. feltiae Umeå strain, S. feltiae L1C strain, Steinernema carpocapsae All strain, and Steinernema riobravis TX strain. Based on comparisons of the relative electrophoretic mobilities (mu) of the isozymes, one of the eight enzymes (arginine kinase) yielded zymograms that were distinctive for each of the isolates, except for the Umeå and NF strains of S. feltiae, which had identical banding patterns. Four enzymes (fumarate hydratase, phosphoglucoisomerase, phosphoglucomutase, and 6-phosphogluconate dehydrogenase) yielded isozyme banding patterns that were characteristic for all isolates, except for the L1C and NF strains of S. feltiae, which were identical. Two enzymes (aspartate amino transferase and glycerol-3-phosphate dehydrogenase) yielded zymograms that permitted S. carpocapsae All strain to be discriminated from the other four isolates, while the remaining enzyme (mannose-6-phosphate isomerase) was discriminatory for S. riobravis TX strain. Except for one enzyme, the isozyme banding pattern of the NF isolate of S. feltiae was the same as in the L1C strain, isolated 13 years previously from Newfoundland. Cellulose acetate electrophoresis could prove invaluable for taxonomic identification of isolates of steinernematids, provided that a combination of enzymes is used.

Carboxy-terminal truncation of oryzacystatin II by oryzacystatin-insensitive insect digestive proteinases.

The biochemical interactions between digestive proteinases of the Coleoptera pest black vine weevil (Otiorynchus sulcatus) and two plant cysteine proteinase inhibitors, oryzacystatin I (OCI) and oryzacystatin II (OCII), were assessed using gelatin-polyacrylamide gel electrophoresis, OCI-affinity chromatography, and recombinant forms of the two plant inhibitors. The insect proteinases were resolved in gelatin-containing polyacrylamide gels as five major bands, only three of them being totally or partially inactivated by OCI and OCII. The maximal inhibitory effect of both OCs at pH 5.0 was estimated at 40% and the inhibition was stable with time despite the presence of OC-insensitive proteases, indicating the stability of the OCI and OCII effects. After removing OC-sensitive proteinases from the insect crude extract by OCI-affinity chromatography, the effects of the insect cystatin-insensitive proteases on the structural integrity of the free OCs were analyzed. While OCI remained stable, OCII was subjected to limited proteolysis leading to its gradual transformation into a approximately 10.5-kDa unstable intermediate, OCIIi. As shown by the degradation pattern of a glutathione S-transferase (GST)/OCII fusion protein, the appearance of OCIIi resulted from the C-terminal truncation of OCII. Either free or linked to GST, OCIIi was as active against papain and human cathepsin H as OCII, and the initial specificities of the inhibitor for these two cysteine proteinases were conserved after cleavage. Although these observations indicate the high conformational stability of OCII near its active (inhibitory) site, they also suggest a general conformational destabilization of this inhibitor following its initial cleavage, subsequently leading to its complete hydrolysis. This apparent susceptibility of OCII to proteolytic cleavage by the insect proteinases could have major implications when planning the use of this plant cystatin for insect pest control.

Transmission of Nepoviruses by Xiphinema americanum-group Nematodes.

The transmission of North American nepoviruses by putative species belonging to the Xiphinema americanum-group is reviewed. Xiphinema americanum sensu stricto, X. californicum, and X. rivesi each transmit cherry rasp leaf (CRLV), tobacco ringspot (TobRSV), and tomato ringspot nepovirus (TomRSV), and X. bricolensis is a vector of TomRSV. The apparent lack of specificity in the transmission of North American nepoviruses by X. americanum-group species markedly contrasts with the specific associations between European nepoviruses and their vector nematode species. Two complementary projects are described examining the taxonomic identity of putative species in the X. americanum-group, their morphological and genetic relationships, their ontogeny, and their ability to transmit viruses.

Restriction Fragment Length Polymorphism Separates Species of the Xiphinema americanum Group.

The Xiphinema americanum group of species is responsible for vectoring several important virus diseases to perennial crops. Variability of transmission of viruses by different species, and difficulties in separating species by morphometric measurements alone, make it essential to reassess the taxonomic position of several species in the group. The measurement of DNA sequence variability is a sensitive assay that can re-evaluate the separation of species and populations from each other. This study describes how an RFLP approach, in which the restriction sites in transcribed spacers of ribosomal repeats were detected, confirmed the separation of 16 populations of these species into X. americanum, X. rivesi, X. pacificum, and X. bricolensis.

Separation of Three Species of Ditylenchus and Some Host Races of D. dipsaci by Restriction Fragment Length Polymorphism.

This study examined the ribosomal cistron of Ditylenchus destructor, D. myceliophagus and seven host races of D. dipsaci from different geographic locations. The three species showed restriction fragment length polymorphisms (RFLPs) in the ribosomal cistron, the 18S rDNA gene, and the ribosomal internal transcribed spacer (ITS). Southern blot analysis with a 7.5-kb ribosomal cistron probe differentiated the five host races of D. dipsaci examined. Polymerase chain reaction (PCR) amplification of the ITS, followed by digestion with some restriction endonucleases (but not others), produced restriction fragments diagnostic of the giant race. Because the PCR product from D. myceliophagus and the host races of D. dipsaci was about 900 base pairs and the ITS size in D. destructor populations was 1,200 base pairs, mixtures of populations could be detected by PCR amplification. ITS fragments differentiated between D. dipsaci and Aphelenchoides rhyntium in mixed populations. This study establishes the feasibility of differentiation of the host races of D. dipsaci by probing Southern blots with the whole ribosomal cistron.

Effects of Pratylenchus penetrans on the Infection of Strawberry Roots by Gnomonia comari.

The fungus Gnomonia comari, causal agent of strawberry leaf blotch, was inoculated at the crown of young axenized strawberry plants growing in sterilized sand. Only the roots were colonized, and the infection was symptomless. When the fungus colonized the roots in the presence of the root lesion nematode Pratylenchus penetrans, the plants were extremely stunted and their root system was necrotic. Fungal conidiospores were found attached to the cuticle of nematodes extracted from soil inoculated with the two pathogens. These findings indicate that P. penetrans could transport conidiospores through soil.

Effect of Ditylenchus dipsaci and Pratylenchus penetrans on Verticillium Wilt of Alfalfa.

Verticillium albo-atrum wilt symptoms appeared faster and were significantly more severe in the presence of Ditylenchus dipsaci in Vernal, a wilt-susceptible cultivar, than in Marls Kabul, a wilt-resistant cultivar. Winter kill in the field was not affected by the nematode during the first winter, but 50% of plants were killed in the second winter. Forage yield from nematode-infected plants was significantly reduced the second year. Interaction with V. albo-atrum did not significantly reduce forage yields below that of D. dipsaci alone. Pratylenchus penetrans did not increase the severity of wilt symptoms in the presence of V. albo-atrum, nor did it affect forage yield in the greenhouse. It did, however, reduce alfalfa yields in presence of V. albo-atrum under field conditions. D. dipsaci and P. penetrans reproduced faster in Vernal than in Maris Kabul when the fungus was present.

Relationship Between Meloidogyne hapla Density and Damage to Carrots in Organic Soils.

Field and growth chamber experiments were conducted to determine the effect of five initial densities (Pi - 20 - 240/100 cm(3) soil) of Meloidogyne hapla on carrot development and yield of storage roots at maturity. Carrots growing in infested and noninfested organic soil were harvested after 15, 29, 44, 59, and 106 days of growth in controlled environment chambers and after l l 0 days in field plots. Nematodes affected weight of roots and foliage, weight and length of the storage portion of tap roots, and induced malformations (forking), galling, and hairiness of tap roots. In most cases the data could not be represented satisfactorily by the exponential model of Seinhorst: y = m + (l-m) Z(P-t). In growth chambers the weight of mature storage roots was not correlated to initial nematode density, but there was a significant negative correlation between weight of storage roots and initial nematode density in field plots. Tolerance levels were calculated as points where the regression lines reached the growth level on noninoculated plants. The tolerance levels of foliage were higher than those of roots, and increased with age of plants. The tolerance level of marketable weight in field plots, average crop value, and a hypothetical control cost function are used to discuss the possibility of optimizing chemical control of root-knot nematode in organic soils.

Nonfumigant Nematicides for Control of Root-knot Nematode to Protect Carrot Root Growth in Organic Soils.

Greenhouse tests were conducted to determine the effects of two kinds of Meloidogyne hapla inoculum on the growth and quality of carrot roots, and the protection afforded in each case by nonfumigant nematicides in organic soils. For all treatments the percentage of carrots damaged was greater with larvae alone as inoculum than with larvae and eggs, indicating that most of the damage occurs early during formation of the taproot. Fosthietan, aldicarb, and oxamyl at 4 and 6 kg ai/ha protected the roots during formation and gave a lasting control of root-knot nematode. There was some nematode damage to the roots with phenamiphos and carbofuran at 4 and 6 kg ai/ha. Isazophos, diflubenzuron, and fenvalerate gave little protection to carrot roots and did not control root-knot nematode effectively.

Influence of low temperature on rate of development of Meloidogyne incognita and M. hapla larvae.

Development of Meloidogyne incognita and M. hapla larvae in clover roots was studied at 20, 16, 12, and 8 C in growth chambers and in the field from fall through spring, in North Carolina. Larvae of both species invaded roots and developed at 20, 16, and 12 C, but not at 8 C. The time necessary to complete the larval stages at each temperature was determined. The minimal temperature for development of M. incognita larvae was 10.08 C and 8.8 C for M. hapla larvae. In the field, soil temperature at 10 cm deep was favorable for development of larvae until the end of November, and again from February on. All stages of the nematodes survived freezing temperatures in the roots. Reproduction of both species was evident in March or Apri1 after inoculation and accumulation of 8,500 to 11,250 degree-hours.

Influence of chilling and freezing temperatures on infectivity of Meloidogyne incognita and M. hapla.

Egg masses and second-stage larvae of Meloidogyne incognita and M. hapla in soil were exposed to temperatures ranging from 20 to -8 C. Temperature was lowered in 2-day intervals to 16, 12, 8, 4, 0, -4, and -8 C, and the nematodes remained at 4, 0, -4, or -8 C for 18, 14, 10, or 6 days, respectively. Unhatched larvae of both species were more resistant to low temperatures than were embryonic stages. Within the eggs of M. incognita, 7.5% of embryos and 48% of larval stages survived 14 days at 0 C, whereas 9% of embryos and 90% of larval stages in the eggs of M. hapla survived 10 days at -4 C. Second-stage larvae of both species remained infective in sol.1 at 4 or 0 C, but were injured at -4 and -8 C. Infectivily of these larvae was lower in saturated soil than in soil at 51 cm moisture tension at all temperatures.

Influence of low temperature on development of Meloidogyne incognita and M. hapla eggs in egg masses.

Egg masses of Meloidogyne incognita and M. hapla were placed in soil at 10, 12, 16, and 20 C. At regular intervals, eggs from samples of egg masses were released from the gelatinous matrices and their developmental stages recorded. The number of days necessary to complete each stage from gastrulation to hatch is given for each temperature. The minimal temperature threshold for the development of eggs was computed by linear regression to be 8.26 C for M. incognita and 6.74 C for M. hapla.