A new Bacillus thuringiensis protein for Western corn rootworm control

The Western corn rootworm (WCR) Diabrotica virgifera virgifera LeConte is one of the most economically important insect pests in North America. Since 2003, transgenic maize expressing WCR-active proteins from Bacillus thuringiensis (Bt) have been widely adopted as the main approach to controlling WCR in the U.S. However, the emergence of field resistance to the Bt proteins in current commercial products has been documented in recent years, highlighting the need to develop additional tools for controlling this devasting pest. Here we report the discovery of Vpb4Da2 (initially assigned as Vip4Da2), a new insecticidal protein highly selective against WCR, through high-throughput genome sequencing of a Bt strain sourced from grain dust samples collected in the eastern and central regions of the US. Vpb4Da2 contains a sequence and domain signature distinct from families of other WCR-active proteins. Under field conditions, transgenic maize expressing Vpb4Da2 demonstrates commercial-level (at or below NIS 0.25) root protection against WCR, and reduces WCR beetle emergence by ≥ 97%. Our studies also conclude that Vpb4Da2 controls WCR populations that are resistant to WCR-active transgenic maize expressing Cry3Bb1, Cry34Ab1/Cry35Ab1 (reassigned as Gpp34Ab1/Tpp35Ab1), or DvSnf7 RNA. Based on these findings, Vpb4Da2 represents a valuable new tool for protecting maize against WCR.

Evaluation of glyphosate resistance in Arabidopsis thaliana expressing an altered target site EPSPS

BACKGROUND

Glyphosate-resistant goosegrass has recently evolved and is homozygous for the double mutant of EPSPS (T102 I, P106 S or TIPS). These same mutations combined with EPSPS overexpression, have been used to create transgenic glyphosate-resistant crops. Arabidopsis thaliana (Wt EPSPS Ki ∼ 0.5 μM) was engineered to express a variant AtEPSPS-T102 I, P106 A (TIPA Ki = 150 μM) to determine the resistance magnitude for a more potent variant EPSPS that might evolve in weeds.

RESULTS

Transgenic A. thaliana plants, homozygous for one, two or four copies of AtEPSPS-TIPA, had resistance (IC50 values, R/S) as measured by seed production ranging from 4.3- to 16-fold. Plants treated in reproductive stage were male sterile with a range of R/S from 10.1- to 40.6-fold. A significant hormesis (∼ 63% gain in fresh weight) was observed for all genotypes when treated at the initiation of reproductive stage with 0.013 kg ha-1 . AtEPSPS-TIPA enzyme activity was proportional to copy number and correlated with resistance magnitude.

CONCLUSIONS

A. thaliana, as a model weed expressing one copy of AtEPSPS-TIPA (300-fold more resistant), had only 4.3-fold resistance to glyphosate for seed production. Resistance behaved as a single dominant allele. Vegetative tissue resistance was 4.7-fold greater than reproductive tissue resistance and was linear with gene copy number. © 2017 The Authors. Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

A transgenic approach for controlling Lygus in cotton

Lygus species of plant-feeding insects have emerged as economically important pests of cotton in the United States. These species are not controlled by commercial Bacillus thuringiensis (Bt) cotton varieties resulting in economic losses and increased application of insecticide. Previously, a Bt crystal protein (Cry51Aa2) was reported with insecticidal activity against Lygus spp. However, transgenic cotton plants expressing this protein did not exhibit effective protection from Lygus feeding damage. Here we employ various optimization strategies, informed in part by protein crystallography and modelling, to identify limited amino-acid substitutions in Cry51Aa2 that increase insecticidal activity towards Lygus spp. by >200-fold. Transgenic cotton expressing the variant protein, Cry51Aa2.834_16, reduce populations of Lygus spp. up to 30-fold in whole-plant caged field trials. One transgenic event, designated MON88702, has been selected for further development of cotton varieties that could potentially reduce or eliminate insecticide application for control of Lygus and the associated environmental impacts.

Plant-feeding insects of the Lygus genus have emerged as a major pest effecting cotton crops in the USA. Here the authors optimize the insecticidal activity of a Bacillus thuringiensis crystal protein and produce transgenic plants that are resistant to feeding damage by Lygus species.

Cotton plants expressing a hemipteran-active Bacillus thuringiensis crystal protein impact the development and survival of Lygus hesperus (Hemiptera: Miridae) nymphs

The plant bugs Lygus hesperus Knight (Hemiptera: Miridae) and L. lineolaris (Palisot de Beauvois) have emerged as economic pests of cotton in the United States. These hemipteran species are refractory to the insect control traits found in genetically modified commercial varieties of cotton. In this article, we report the isolation and characterization of a 35 kDa crystal protein from Bacillus thuringiensis, designated TIC807, which causes reduced mass gain and mortality of L. hesperus and L. lineolaris nymphs when presented in an artificial diet feeding assay. Cotton plants expressing the TIC807 protein were observed to impact the survival and development of L. hesperus nymphs in a concentration-dependent manner. These results, demonstrating in planta activity of a Lygus insecticidal protein, represent an important milestone in the development of cotton varieties protected from Lygus feeding damage.

Dicamba monooxygenase: structural insights into a dynamic Rieske oxygenase that catalyzes an exocyclic monooxygenation

Dicamba (2-methoxy-3,6-dichlorobenzoic acid) O-demethylase (DMO) is the terminal Rieske oxygenase of a three-component system that includes a ferredoxin and a reductase. It catalyzes the NADH-dependent oxidative demethylation of the broad leaf herbicide dicamba. DMO represents the first crystal structure of a Rieske non-heme iron oxygenase that performs an exocyclic monooxygenation, incorporating O(2) into a side-chain moiety and not a ring system. The structure reveals a 3-fold symmetric trimer (alpha(3)) in the crystallographic asymmetric unit with similar arrangement of neighboring inter-subunit Rieske domain and non-heme iron site enabling electron transport consistent with other structurally characterized Rieske oxygenases. While the Rieske domain is similar, differences are observed in the catalytic domain, which is smaller in sequence length than those described previously, yet possessing an active-site cavity of larger volume when compared to oxygenases with larger substrates. Consistent with the amphipathic substrate, the active site is designed to interact with both the carboxylate and aromatic ring with both key polar and hydrophobic interactions observed. DMO structures were solved with and without substrate (dicamba), product (3,6-dichlorosalicylic acid), and either cobalt or iron in the non-heme iron site. The substitution of cobalt for iron revealed an uncommon mode of non-heme iron binding trapped by the non-catalytic Co(2+), which, we postulate, may be transiently present in the native enzyme during the catalytic cycle. Thus, we present four DMO structures with resolutions ranging from 1.95 to 2.2 A, which, in sum, provide a snapshot of a dynamic enzyme where metal binding and substrate binding are coupled to observed structural changes in the non-heme iron and catalytic sites.

Frequent homologous recombination events between molecules of one RNA component in a multipartite RNA virus

Brome mosaic bromovirus (BMV), a tripartite plus-sense RNA virus, has been used as a model system to study homologous RNA recombination among molecules of the same RNA component. Pairs of BMV RNA3 variants carrying marker mutations at different locations were coinoculated on a local lesion host, and the progeny RNA3 in a large number of lesions was analyzed. The majority of doubly infected lesions accumulated the RNA3 recombinants. The distribution of the recombinant types was relatively even, indicating that both RNA3 counterparts could serve as donor or as acceptor molecules. The frequency of crossovers between one pair of RNA3 variants, which possessed closely located markers, was similar to that of another pair of RNA3 variants with more distant markers, suggesting the existence of an internal recombination hot spot. The majority of crossovers were precise, but some recombinants had minor sequence modifications, possibly marking the sites of imprecise homologous crossovers. Our results suggest discontinuous RNA replication, with the replicase changing among the homologous RNA templates and generating RNA diversity. This approach can be easily extended to other RNA viruses for identification of homologous recombination hot spots.

Potyvirus aphid transmission requires helper component and homologous coat protein for maximal efficiency

Aphid transmission of potyviruses depends on the presence of specific sequence domains in two virus encoded proteins, the coat protein (CP) and helper component-proteinase (HC-Pro). Aphid transmissable peanut stripe virus (PStV), like most potyviruses, has an Asp-Ala-Gly (DAG) motif in the amino-terminal part of the CP. Peanut Mottle Virus (PeMoV) was determined to be highly aphid transmissible but has a unique Asp-Ala-Ala-Ala (DAAA) motif. To determine if the DAAA motif could functionally replace the DAG motif in PStV, mutations were made in a full-length cDNA clone of PStV. All of the mutations in the CP DAG motif abolished aphid transmissibility of PStV but did not affect virus infectivity. The aphid transmissibility of the PStV-DAAA mutant was partially restored by feeding aphids an artificial diet containing purified virus and PeMoV HC-Pro. The PStV-DAAA virus was poorly transmitted by aphids in vitro with HC-Pro purified from PStV or tobacco vein mottling virus (TVMV) infected plants. These experiments support the theory that specific HC-Pro/CP interactions are required for efficient aphid transmission. Based upon the sequence comparisons of 16 potyviral HC-Pro proteins several conserved motifs and striking differences have been identified. PeMoV was determined to have an Ala-Ser-Cys (ASC) HC-Pro motif instead of a highly conserved Cys-Cys-Cys (CCC) motif. We have predicted that this CCC motif could play an important role in the specific interaction between the HC-Pro and the CP DAG motif.

Structure-based rationale for the rescue of systemic movement of brome mosaic virus by spontaneous second-site mutations in the coat protein gene

We describe spontaneous second-site reversions within the coat protein open reading frame that rescue the systemic-spread phenotype and increase virion stability of a mutant of brome mosaic virus. Based on the crystal structure of the related cowpea chlorotic mottle virus, we show that the modified residues are spatially clustered to affect the formation of hexamers and pentamers and therefore virion stability.

Nla and Nlb of peanut stripe potyvirus are present in the nucleus of infected cells, but do not form inclusions

We investigated, by immunological and gene-fusion methods, whether the failure of peanut stripe potyvirus (PStV)-encoded nuclear inclusion proteins a (Nla) and b (Nlb) to form nuclear inclusions is due to the lack of their in vivo accumulation or the inability of one or both proteins to be transported into the nucleus Nla domains (Nla-VPg and Nla-proteinase), full-length Nlb, and full-length cylindrical inclusion (CI) protein of PStV were cloned, expressed in Escherichia coli, and used for antisera production. Immunoblot analysis of accumulation of Nla, Nlb, and CI in time course experiments revealed that they accumulated to similar levels in PStV-infected Nicotiana benthamiana. In immunocytochemical studies with electron microscopy, antiserum against Nla-VPg, Nla-Pro, and Nlb specifically labeled Nla and Nlb proteins throughout the nuclei of PStV-infected cells, in the absence of nuclear inclusions. Translational fusions were made between Nla and Nlb to either the green fluorescence protein or the beta-glucuronidase in vectors for transient gene expression or stable expression in transgenic plants respectively. Fusion proteins containing Nla accumulated in the nucleus, whereas fusion proteins containing Nlb accumulated in a punctate pattern in the cytoplasm. These data indicate that at least Nla possesses a nuclear localization signal.

The cDNA sequence and infectious transcripts of peanut stripe virus

A full-length cDNA clone of the blotch isolate of the peanut stripe potyvirus (PStV) RNA genome was constructed downstream from the bacteriophage SP6 RNA polymerase promoter. The full-length PStV cDNA clone (PStVSF9) was sequenced and compared to the previously published sequence of PStV-B. In vitro-synthesized PStV transcripts capped with m7GpppG were infectious in Nicotiana benthamiana plants, and the progeny virus was aphid transmissible. To confirm the origin of infection, a mutant PStV (PStVDAE), with a Gly14 to Glu mutation in the coat protein-encoding gene, was constructed. Transcripts from PStVDAE produced symptoms indistinguishable from native or PStVSF9 virus, but was not transmitted by aphids.

Foreign complementary sequences facilitate genetic RNA recombination in brome mosaic virus

We have demonstrated that local antisense sequences can mediate genetic recombination within the 3' noncoding region among brome mosaic virus (BMV) RNAs (P. Nagy and J. J. Bujarski, 1993, Proc. Natl. Acad. Sci. USA 90, 6390-6394). Here we show that foreign complementary inserts can direct crossovers between BMV RNA3 components within an internal region. A 170-nt polynucleotide derived from the cowpea chlorotic mottle virus (CCMV) RNA3 was inserted just upstream of the initiation codon of the BMV coat protein open reading frame in either sense or antisense orientations. The resulting respective mutants, BCC+ and BCC-, maintained unchanged CCMV inserts when inoculated separately on leaves of a local lesion host for BMV. In contrast, when a mixture containing both mutated RNAs3 was inoculated, a significant fraction of lesions accumulated the BMV RNA3 lacking the CCMV insert. The presence of a 3' marker mutation confirmed that the BMV RNA3 progeny arose due to crossovers between BCC+ and BCC- within the complementary sequences. The highest frequency of recombinant appearance was observed when the RNA mixtures were annealed prior to inoculation on the host plants. Our results confirm a concept predicting the general nature of the heteroduplex-mediated recombination functioning in RNA viruses. Examples of possible applications of this approach in recombinant RNA technology are discussed.

Mutational analysis of the coat protein gene of brome mosaic virus: effects on replication and movement in barley and in Chenopodium hybridum

The coat protein (CP) open reading frame (ORF) of brome mosaic virus (BMV) has been mutated to study host-related CP functions in barley, a systemic host, and in Chenopodium hybridum L. which supports both local lesion formation and systemic spread of BMV. To test the role of the N-terminal region of CP, mutants C1 to C3, which synthesized the CP lacking first seven amino acids, and mutant D1, which had Trp 22 and Thr 23 replaced with Phe-Gly-Ser, were generated. C1 to C3 inhibited virus systemic spread in C. hybridum but not in barley while D1 only reduced virus accumulation in noninoculated leaves of C. hybridum. More internal CP regions were tested by mutation of Lys 63 to Leu (mutant SP3) and Lys 129 to Arg (mutant SP1). SP1 behaved similarly to C1 to C3 while SP3 similarly to D1. In addition, SP3 reduced concentrations of RNA3 and RNA4 in both hosts. Apparently, various CP regions differentially affect, either directly or indirectly, virus translocation in different hosts, suggesting both the CP and host factors to be important for virus spread. Larger deletions in the CP ORF (mutants BB4 and SX1) or a decrease of CP production by using a frameshift mutant C, inhibited virus systemic spread in both hosts, and delayed the appearance of smaller local lesions on C. hybridum. Thus, the CP is not required for cell-to-cell movement but is required for systemic translocation of BMV.

Nucleotide sequence and genome organization of peanut stripe potyvirus

A blotch isolate of peanut stripe virus (PStV) was cloned, sequenced and compared with other full-length potyvirus sequences. The viral genome was 10059 nucleotides (nt) in length excluding the poly(A) tail. Two potential AUG start codons were identified in the 5' non-translated region. Analysis of in vitro translation products from transcripts containing the first 600 nt of the PStV genome indicated that the first AUG (nt 134 to 136) was preferred over the second AUG (nt 146 to 148) for initiation of translation. Within the single large open reading frame, eight processed proteins were predicted. In general, motifs conserved in other potyviral sequences were also found in the PStV genome. The presence of a 6K protein between the P3 and CI proteins was predicted. An altered amino acid motif, from FI(V)VRG to FMIIRG, within the carboxyl terminus of the P1 protein, separates the PStV sequence from the majority of potyvirus sequences. Based on comparisons with available full-length potyvirus genome sequences, PStV was found to be most closely related to soybean mosaic virus.

Molecular studies of genetic RNA-RNA recombination in brome mosaic virus

It is well known that DNA-based organisms rearrange and repair their genomic DNA through recombination processes, and that these rearrangements serve as a powerful source of variability and adaptation for these organisms. In RNA viruses' genetic recombination is defined as any process leading to the exchange of information between viral RNAs. There are two types of recombination events: legitimate and illegitimate. While legitimate (homologous) recombination occurs between closely related sequences at corresponding positions, illegitimate (nonhomologous) recombination could happen at any position among the unrelated RNA molecules. In order to differentiate between the symmetrical and asymmetrical homologous crosses, Lai defined the former as homologous recombination and the latter as aberrant homologous recombination. This chapter uses brome mosaic virus (BMV), a multicomponent plant RNA virus, as an example to discuss the progress in studying the mechanism of genetic recombination in positive-stranded RNA viruses. Studies described in this chapter summarize the molecular approaches used to increase the frequency of recombination among BMV RNA segments and, more importantly, to target the sites of crossovers to specific BMV RNA regions. It demonstrates that the latter can be accomplished by introducing local complementarities to the recombining substrates.