Complementation of the pina (null) allele with the wild type Pina sequence restores a soft phenotype in transgenic wheat.

The tightly linked puroindoline genes, Pina and Pinb, control grain texture in wheat, with wild type forms of both giving soft, and a sequence alteration affecting protein expression or function in either giving rise to hard wheat. Previous experiments have shown that addition of wild type Pina in the presence of mutated Pinb gave intermediate grain texture but addition of wild type Pinb gave soft grain. This raises questions as to whether Pina may be less functional than Pinb. Our goal here was to develop and characterize wheat lines expressing the wild type Pina-D1a sequence in hard wheat with the null mutation (Pina-D1b) for Pina. Three transgenic lines plus Bobwhite were evaluated in two environments. Grain texture, grain protein, and kernel weight were determined for the transgenic lines and Bobwhite. The three transgenic lines had soft phenotype, and none of the transgenic lines differed from Bobwhite for grain protein or kernel weight. The soft phenotype was accompanied by increases in Pina transcript accumulation. Total Triton X-114 extractable PINA and PINB increased from 2.5 to 5.5 times those from a soft wheat reference sample, and friabilin, PINA and PINB bound to starch, increased from 3.8 to 7.8 times those of the soft wheat reference. Bobwhite showed no starch bound PINA, but transgenic lines had levels from 5.3 to 13.7 times those of the soft wheat reference sample. Starch bound PINB in transgenic lines also increased from 0.9 to 2.5 times that for the soft wheat reference sample. The transgenic expression of wild type Pina sequence in the Pina null genotype gave soft grain with the characteristics of soft wheat including increased starch bound friabilin. The results support the hypothesis that both wild type Pin genes need to be present for friabilin formation and soft grain.

Engineering deoxynivalenol metabolism in wheat through the expression of a fungal trichothecene acetyltransferase gene.

Fusarium head blight occurs in cereals throughout the world and is especially important in humid growing regions. Fusarium head blight (FHB) has re-emerged as a major disease of wheat and barley in the U.S. and Canada since 1993. The primary causal agents of FHB, Fusarium graminearum and Fusarium culmorum, can produce deoxynivalenol (DON), a trichothecene mycotoxin that enhances disease severity and poses a health hazard to humans and monogastric animals. To reduce the effects of DON on wheat, we have introduced FsTRI101, a Fusarium sporotrichioides gene formerly known as TriR, into the regenerable cultivar Bobwhite. TRI101 encodes an enzyme that transfers an acetyl moiety to the C3 hydroxyl group of trichothecenes. Four different transgenic plants carrying the FsTRI101 gene were identified. Although expression levels varied among the four lines, all of them accumulated FsTRI101 transcripts in endosperm and glume. TRI101-encoded acetyltransferase activity was detected in endosperm extracts of a single plant that accumulated FsTRI101 mRNA. Greenhouse resistance tests indicated that the accumulation of FsTRI101-encoded acetyltransferase in this plant confers partial protection against the spread of F. graminearum in inoculated wheat heads (spikes).

A recombinant protein of two high molecular weight glutenins alters gluten polymer formation in transgenic wheat.

Wheat high molecular weight glutenin subunits (HMW-GS) are the most important determinants of its superiority for making leavened bread. Following synthesis, these proteins are sequestered into the endoplasmic reticulum and assemble into extremely large elastic polymers, linked by noncovalent and intermolecular disulfide bonds. To study the structural requirements for the assembly of HMW-GS, we have expressed in transgenic wheat a recombinant protein between two cognate x- and y-type subunits. In contrast to the natural polymerized x- and y-type HMW-GS, a significant amount of the recombinant subunit remained monomeric. Nonreducing SDS-polyacrylamide gel electrophoresis, coupled with limited proteolysis, showed that the monomeric form of the recombinant subunit contained an unusual intramolecular disulfide bond, linking an N-terminal cysteine to the single C-terminal cysteine residue. In addition, sucrose gradient analysis revealed that this intramolecular disulfide bond impeded the ability of the recombinant subunit to assemble into polymers. Despite of its altered assembly, a notable amount of the overexpressed recombinant subunit was also present in glutenin polymers. Moreover, its presence significantly altered the subunit composition of the polymer. Our results show that it is possible to modify gluten assembly and properties by expressing recombinant HMW-GS in transgenic wheat, and have a major implication for the improvement of wheat bread-making quality.

Expression of a novel high-molecular-weight glutenin subunit gene in transgenic wheat.

High-molecular-weight glutenin subunits (HMW-GS), one class of seed storage proteins, are important determinants of the bread-making quality of wheat flour. To change the amount and composition of these proteins via genetic engineering, a gene encoding a novel hybrid subunit under the control of native HMW-GS regulatory sequences was inserted into wheat. Of 26 independent transgenic lines identified by bialaphos selection, 18 expressed the cotransformed hybrid HMW-GS gene in their seed. The hybrid subunit accumulated to levels comparable to those of the native HMW-GS. These results show that a native HMW-GS gene promoter can be used to obtain high levels of expression of seed storage and, potentially, other proteins in transgenic wheat endosperm. Transgene expression was stable for at least three seed generations in the majority of lines. These experiments demonstrate the feasibility of constructing wheat plants with novel seed protein compositions.

Cryopreserved callus: a source of protoplasts for rice transformation.

We cryopreserved whole rice calli (Oryza sativa L cv Taipei 309) to investigate the ability of the surviving cells to regenerate plants and yield protoplasts competent for genetic transformation. Four out of six callus lines cryopreserved after four months in culture contained small sectors able to continue cell division and subsequently regenerate fertile plants. Both cryopreservation efficiency and regeneration ability decreased when using eight month old cultures. High yields of protoplasts were obtained from different cryopreserved callus lines. Protoplasts were transfected with chimeric genes consisting of the maize ubiquitin 1 promoter, first exon and first intron fused to the coding region of either the GUS or BAR marker genes. Levels of transient gene expression from both marker genes were similar to those previously obtained using protoplasts derived from callus that had not been frozen. Stable transformants were selected by their resistance to Bialaphos and could be identified with the pH indicator chlorophenol red. Southern blot analysis confirmed the integration of the BAR gene into the rice genome. Therefore, cryopreservation does not affect the ability of rice cells to integrate and express foreign genes.

Activity of a maize ubiquitin promoter in transgenic rice.

We have used the maize ubiquitin 1 promoter, first exon and first intron (UBI) for rice (Oryza sativa L. cv. Taipei 309) transformation experiments and studied its expression in transgenic calli and plants. UBI directed significantly higher levels of transient gene expression than other promoter/intron combinations used for rice transformation. We exploited these high levels of expression to identify stable transformants obtained from callus-derived protoplasts co-transfected with two chimeric genes. The genes consisted of UBI fused to the coding regions of the uidA and bar marker genes (UBI:GUS and UBI:BAR). UBI:GUS expression increased in response to thermal stress in both transfected protoplasts and transgenic rice calli. Histochemical localization of GUS activity revealed that UBI was most active in rapidly dividing cells. This promoter is expressed in many, but not all, rice tissues and undergoes important changes in activity during the development of transgenic rice plants.

Rapid Production of Multiple Independent Lines of Fertile Transgenic Wheat (Triticum aestivum).

Improvement of wheat (Triticum aestivum) by biotechnological approaches is currently limited by a lack of efficient and reliable transformation methodology. In this report, we detail a protocol for transformation of a highly embryogenic wheat cultivar, Bobwhite. Calli derived from immature embryos, 0.5 to 1 mm long, were bombarded with microprojectiles coated with DNA containing as marker genes the bar gene, encoding phosphinothricin-resistance, and the gene encoding [beta]-glucuronidase (GUS), each under control of a maize ubiquitin promoter. The bombardment was performed 5 d after embryo excision, just after initiation of callus proliferation. The ability of plantlets to root in the presence of 1 or 3 mg/L of bialaphos was the most reliable selection criteria used to identify transformed plants. Stable transformation was confirmed by marker gene expression assays and the presence of the bar sequences in high molecular weight chromosomal DNA of the resultant plants. Nine independent lines of fertile transgenic wheat plants have been obtained thus far, at a frequency of 1 to 2 per 1000 embryos bombarded. On average, 168 d elapsed between embryo excision for bombardment and anthesis of the T0 plants. The transmission of both the resistance phenotype and bar DNA to the T1 generation verified that germline transformation had occurred.

Purification and characterization of wheat alpha-gliadin synthesized in the yeast, Saccharomyces cerevisiae.

The development of efficient methods for production and purification of plant seed storage proteins in heterologous microbial hosts would facilitate structure-function studies of these proteins. This report describes such methods applied to the production and isolation of wheat alpha-gliadin, a prolamine-type seed storage protein, from Saccharomyces cerevisiae. Beginning with the vector, growth conditions, and extraction methods of Neill et al. [Gene 55 (1987) 303-317], we implemented several improvements to increase the yields of alpha-gliadin per volume of yeast cell culture. The CYCl::Gli-A2-Y transcriptional fusion vector, pAY31 (Neill et al., 1987), was modified by replacing the ARS1 region of replication with that of the 2 mu plasmid of yeast. We formulated a new medium, a derivative of synthetic defined (SD) medium supplemented with several nitrogen sources, that allows both selection for maintenance of plasmids and growth to high cell densities. Stationary phase cultures of cells bearing the modified expression vector, and grown in this medium with glycerol and lactate as carbon sources, contain significantly higher levels of alpha-gliadin than log-phase cultures grown in SD glucose. Sonication in 80% ethanol selectively and efficiently extracts the alpha-gliadin from cell pellets of small- or large-scale cultures, allowing the purification of several hundred micrograms of the wheat protein per liter in just a few high-yield steps. The alpha-gliadin isolated from yeast elutes at the same position in HPLC as the A-gliadin fraction purified from wheat flour. N-terminal amino acid (aa) sequencing reveals that the signal peptide is removed from the gliadin precursor in yeast cells.(ABSTRACT TRUNCATED AT 250 WORDS)

The detection of mitotic and meiotic aneuploidy in yeast using a gene dosage selection system.

A system is described in which spontaneous and chemically-induced mitotic and meiotic hyperploidy can be assayed in the same diploid culture of Saccharomyces cerevisiae. Monitoring gene dosage changes at two loci on chromosome VIII, the test utilizes a leaky temperature-sensitive allele arg4-8 and low level copper resistance conferred by the single copy allele cup1s. An extra chromosome VIII provides simultaneous increased dosage for both genes, resulting in colonies that are both prototrophic for arginine at 30 degrees C and copper resistant. During mitotic cell divisions in diploids, spontaneous chromosome VIII hyperploids (trisomes and tetrasomes) occur at a frequency of 6.4 x 10(-6) per viable cell. Among ascospores, the spontaneous chromosome VIII disome frequency is 5.5 x 10(-6) per viable spore. The tubulin-binding reagent methyl benzimidazol-2-yl carbamate (MBC) elicits enhanced levels of mitotic and meiotic aneuploidy relative to control levels. The system represents a novel model for examining chromosome behavior during mitosis and meiosis and provides a sensitive and quantifiable procedure for examining chemically induced aneuploidy.

The structure and evolution of the human beta-globin gene family.

We present the results of a detailed comparison of the primary structure of human beta-like globin genes and their flanking sequences. Among the sequences located 5' to these genes are two highly conserved regions which include the sequences ATA and CCAAT located 31 +/- 1 and 77 +/- 10 bp, respectively, 5' to the mRNA capping site. Similar sequences are found in the corresponding locations in most other eucaryotic structural genes. Calculation of the divergence times of individual beta-like globin gene pairs provides the first description of the evolutionary relationships within a gene family based entirely on direct nucleotide sequence comparisons. In addition, the evolutionary relationship of the embryonic epsilon-globin gene to the other human beta-like globin genes is defined for the first time. Finally, we describe a model for the involvement of short direct repeat sequences in the generation of deletions in the noncoding and coding regions of beta-like globin genes during evolution.

Human fetal G gamma- and A gamma-globin genes: complete nucleotide sequences suggest that DNA can be exchanged between these duplicated genes.

We present the nucleotide sequences of the G gamma-and A gamma-globin genes from one chromosome (A) and of most of the A gamma gene from the other chromosome (B) of the same individual. All three genes have a small, highly conserved intervening sequence (IVS1) of 122 bp located between codons 30 and 31 and a large intervening sequence (IVS2) of variable length (866-904 bp) between codons 104 and 105. A stretch of simple sequence DNA occurs in IVS2 which appears to be a hot spot for recombination. On the 5' side of this simple sequence, the allelic A gamma genes differ considerably in IVS2 whereas the nonallelic G gamma and A gamma genes from chromosome A differ only slightly. Yet on the 3' side of the simple sequence, the allelic genes differ only slightly whereas the nonallelic genes differ considerably. We hypothesize that the 5' two thirds of the A gamma gene on chromosome A has been "converted" by an intergenic exchange to become more like the G gamma gene on its own chromosome A than it is like the allelic A gamma gene on the other chromosome B. Our sequence data suggest that intergenic conversions occur in the germ line. The DNA sequence differences between two chromosomes from a single individual strongly suggest that DNA sequence polymorphisms for localized deletions, additions and base substitutions are very common in human populations.

Cloning human fetal gamma globin and mouse alpha-type globin DNA: preparation and screening of shotgun collections.

Shotgun collections of Charon 3A bacteriophages containing Eco RI fragments of human and mouse DNA were constructed with the use of in vitro packaging. Plaques were screened by hybridization, and globin-specific clones were isolated from both human (Charon 3AHs51.1) and mouse (Charon 3AMm30.5). The fragments cloned were detected in unfractionated genomic DNA by the Southern method of hybridization.

Cloning human fetal gamma globin and mouse alpha-type globin DNA: characterization and partial sequencing.

Two globin-related clones isolated from collections of bacteriophages containing unfractionated Eco RI fragments of human and mouse DNA were characterized. Charon3AHs51.1Hbgamma includes 2.7 kilobase pairs of human DNA containing a large part of a fetal gamma globin chain structural gene; Charon 3AMm30.5 includes 4.7 kilobase pairs of mouse DNA related to alpha globin. The human fetal gamma globin gene has within its coding region two intervening sequences of noncoding DNA, IVS 1 and IVS 2, of approximately 1-0 and 900 base pairs. Sequence IVS 1 is located at the position of one of the two intervening sequences occurring in adult globin genes; IVS 2 is located at the position of the other.

Charon phages: safer derivatives of bacteriophage lambda for DNA cloning.

The Charon lambda bacteriophages have been developed as vectors for cloning. Their construction incorporates mutations that make them simple to use and also greatly increases their safety for the biological containment of cloned recombinant DNA. Three of the Charon vector phages, 3A, 4A, and 16A, have been certified for use as EK2 vector-host systems, when propagated in bulk in a special bacterial host, DP50SupF. We present here some of the data on which the safety of these systems was evaluated. DNA fragments ranging in size from 0 to 2.2 X 10(4) base pairs can be cloned in these EK2 Charon phages.