Alleviating peanut allergy using genetic engineering: the silencing of the immunodominant allergen Ara h 2 leads to its significant reduction and a decrease in peanut allergenicity

Peanut allergy is one of the most life-threatening food allergies and one of the serious challenges facing the peanut and food industries. Current proposed solutions focus primarily on ways to alter the immune system of patients allergic to peanut. However, with the advent of genetic engineering novel strategies can be proposed to solve the problem of peanut allergy from the source. The objectives of this study were to eliminate the immunodominant Ara h 2 protein from transgenic peanut using RNA interference (RNAi), and to evaluate the allergenicity of resulting transgenic peanut seeds. A 265-bp-long PCR product was generated from the coding region of Ara h 2 genomic DNA, and cloned as inverted repeats in pHANNIBAL, an RNAi-inducing plant transformation vector. The Ara h 2-specific RNAi transformation cassette was subcloned into a binary pART27 vector to construct plasmid pDK28. Transgenic peanuts were produced by infecting peanut hypocotyl explants with Agrobacterium tumefaciens EHA 105 harbouring the pDK28 construct. A total of 59 kanamycin-resistant peanut plants were regenerated with phenotype and growth rates comparable to wild type. PCR and Southern analyses revealed that 44% of plants stably integrated the transgene. Sandwich ELISA performed using Ara h 2-mAbs revealed a significant (P < 0.05) reduction in Ara h 2 content in several transgenic seeds. Western immunobloting performed with Ara h 2-mAb corroborated the results obtained with ELISA and showed absence of the Ara h 2 protein from crude extracts of several transgenic seeds of the T(0) plants. The allergenicity of transgenic peanut seeds expressed as IgE binding capacity was evaluated by ELISA using sera of patients allergic to peanut. The data showed a significant decrease in the IgE binding capacity of selected transgenic seeds compared to wild type, hence, demonstrating the feasibility of alleviating peanut allergy using the RNAi technology.

Screening of a peanut (Arachis hypogaea L.) cDNA library to isolate a Bowman-Birk trypsin inhibitor clone

Peanut crop losses due to insect and pest infestation cost peanut farmers nearly 20% of their annual yields. The conventional use of chemicals to combat this problem is costly and toxic to humans and livestock and leads to the development of resistance by target insects. Transgenic plants expressing a trypsin inhibitor gene in tobacco and cowpea have proven to be efficient for resistance against insects. Therefore, a transgenic peanut overexpressing a trypsin inhibitor gene could be an alternative solution to the use of toxic chemicals. Five Bowman-Birk trypsin inhibitor (BBTI) proteins were previously isolated from peanut. However, to date, neither cDNA nor genomic DNA sequences are available. The objective of this research was to screen a peanut cDNA library to isolate and sequence at least one full-length peanut BBTI cDNA clone. Two heterologous oligonucleotides were constructed on the basis of a garden pea (Pisum sativa) trypsin inhibitor nucleotide sequence and used as probes to screen a peanut lambda gt-11 cDNA library. Two positive and identical cDNA clones were isolated, subcloned into a pBluescript vector, and sequenced. Sequence analysis revealed a full-length BBTI cDNA of about 243 bp, with a start codon ATG at position +1 and a stop codon TGA at position +243. In the 3' end, two poly adenylation signals (AATAAA) were identified at positions +261 and +269. The isolated cDNA clone encodes a protein of 80 amino acid residues including a leader sequence of 11 amino acids. The deduced amino acid sequence is 100% identical to published sequences of peanut BBTI AI, AII, BI, and BIII and 81% identical to BII.

Genomic organization of peanut allergen gene, Ara h 3

Type 1 hypersensitivity to peanut proteins is a well-recognized health problem. Several peanut seed storage proteins have been identified as allergens. Ara h 3, a glycinin protein, is one of the important peanut allergens. Although amino acid and cDNA sequences are available for Ara h 3, there is not information at the genomic level. The objectives of this study were to isolate, sequence, and characterize the genomic clone of peanut allergen, Ara h 3. A peanut genomic library was screened, using two [32P] end-labeled oligonucleotide probes designed based on cDNA sequences of Ara h 3 and Ara h 4. Four positives lambda FIX II clones were obtained after four rounds of screenings. Digestion with Sac I resulted in two fragments of 1.5 and 10 kb hybridizing to the probes. Both fragments were subcloned into p-Bluescript vector and sequenced. The Ara h 3 gene spans 3.5 kb and consists of four exons, three introns, 5' and 3' flanking regions. The open reading frame is 2008 bp long and can encode a polypeptide of 538 amino acids residues. Sequences analogous to a TATA-box (TATAAAT), CAAT-box (AGGA), G-box (TCCTACGTGTCC) and several cis-elements were found in the promoter region. In the 3' downstream region, three polyadenylation signals (AATAAA) were identified.

cDNA clone of a putative peanut (Arachis hypogaea L.) trypsin inhibitor has homology with peanut allergens Ara h 3 and Ara h 4

Trypsin inhibitors are pathogenesis-related (PR) proteins, which play an important role in the plant defense mechanism against insects and pathogens. Peanut trypsin inhibitors are low molecular mass seed storage proteins. Like peanut allergens, they are stable to acid and heat, resistant to digestion, and can have a negative impact on human health. In peanut, five Bowman-Birk trypsin inhibitors (BBTI) have been isolated and amino acid sequences published. However, to date, no peanut BBTI sequence is available at both the cDNA and the genomic levels. The objectives of this investigation were (i) to synthesize degenerate oligonucleotides based on conserved regions of published amino acid sequences of BBTI, BII, and BIII; (ii) to isolate, sequence, and analyze at least one positive peanut trypsin inhibitor cDNA clone using the synthesized (32)P-labeled oligonucleotides as probes; and (iii) to determine its trypsin inhibitory activity. Thirty-two degenerate oligonucleotides DNA primers of 24 nucleotides each were synthesized based on the published amino acid sequences of peanut BBTI, and two were selected as probes to screen a peanut Lambda gt 11 cDNA library. Three putative positive clones were isolated, purified, and subcloned, and one was sequenced. Sequence analysis revealed a partial cDNA clone of 643 bp with a start codon. This clone shares 93 and 96% nucleotide sequence homology with peanut allergens Ara h 3 and Ara h 4 cDNA clones, respectively. A trypsin inhibitor assay revealed that peanut allergen Ara h 3 has a trypsin inhibitory activity of 11 238 TIA/mg protein. We concluded that peanut allergen Ara h 3 may also function as a trypsin inhibitor.

Structure and organization of the genomic clone of a major peanut allergen gene, Ara h 1

Peanut is one of the most allergenic foods. It contains multiple seed storage proteins identified as allergens, which are responsible for triggering IgE-mediated allergic reactions. Ara h 1 is a major peanut allergen recognized by over 90% of peanut sensitive population. The objectives of this study were to isolate, sequence, and determine the structure and organization of at least one genomic clone encoding Ara h 1. Two 100 bp oligonucleotides were synthesized and used as probes to screen a peanut genomic library constructed in a Lambda FIX II vector. After three rounds of screening, four putative positive clones were selected and their DNA digested with SacI. A unique 12-13 kb insert fragment was released, confirmed positive by Southern hybridization, subcloned into a pBluescript vector, and sequenced. Sequence analysis revealed a full-length Ara h 1 gene of 4447 bp with four exons of 721, 176, 81 and 903 bp and three introns of 71, 249 and 74 bp. The deduced amino acid encodes a protein of 626 residues that is identical to the Ara h 1 cDNA clone P41b. Several well characterized elements for promoter strength were found in the promoter region of Ara h 1 and include two TATA-boxes (TATATAAATA and TTATATATAT) at positions -89 and -348, respectively; a CAAT-box (CAAT) at position -133, a GC-box (CGGGACCGGGCCGG GCCTTCGGGCCGGGCCGGGT) at position -475, two G-boxes (TAACACGTACAC and ATGGACGTGAAA) at positions -264 and -1808, respectively; two RY elements (CATGCAC and CATGCAT) at positions -235 and -278, respectively; and other cis-element sequences. In the 3' UTR, a poly-A signal (AATAAA) was found at +2350, two additional stop codons (TAA) at +2303 and +2306, and TTTG/CTA/G motifs. Three introns and a potentially strong promoter could explain the high expression of the Ara h 1 gene. Amino acid sequence comparisons revealed high sequence similarity with other plant vicilins, member of the cupin superfamily.