Agrobacterium-mediated sorghum transformation.

Agrobacterium tumefaciens was used to genetically transform sorghum. Immature embryos of a public (P898012) and a commercial line (PHI391) of sorghum were used as the target explants. The Agrobacterium strain used was LBA4404 carrying a 'Super-binary' vector with a bar gene as a selectable marker for herbicide resistance in the plant cells. A series of parameter tests was used to establish a baseline for conditions to be used in stable transformation experiments. A number of different transformation conditions were tested and a total of 131 stably transformed events were produced from 6175 embryos in these two sorghum lines. Statistical analysis showed that the source of the embryos had a very significant impact on transformation efficiency, with field-grown embryos producing a higher transformation frequency than greenhouse-grown embryos. Southern blot analysis of DNA from leaf tissues of T0 plants confirmed the integration of the T-DNA into the sorghum genome. Mendelian segregation in the T1 generation was confirmed by herbicide resistance screening. This is the first report of successful use of Agrobacterium for production of stably transformed sorghum plants. The Agrobacterium method we used yields a higher frequency of stable transformation that other methods reported previously.

Use of ubiquitin fusions to augment protein expression in transgenic plants.

A major goal of plant biotechnology is the production of genetically engineered crops that express natural or foreign proteins at high levels. To enhance protein accumulation in transgenic plants, we developed a set of vectors that express proteins and peptides as C-terminal translational fusions with ubiquitin (UBQ). Studies of several proteins in tobacco (Nicotiana tabacum) showed that: (a) proteins can be readily expressed in plants as UBQ fusions; (b) by the action of endogenous UBQ-specific proteases (Ubps), these fusions are rapidly and precisely processed in vivo to release the fused protein moieties in free forms; (c) the synthesis of a protein as a UBQ fusion can significantly augment its accumulation; (d) proper processing and localization of a protein targeted to either the apoplast or the chloroplast is not affected by the N-terminal UBQ sequence; and (e) single amino acid substitutions surrounding the cleavage site can inhibit in vivo processing of the fusion by Ubps. Noncleavable UBQ fusions of beta-glucuronidase became extensively modified, with additional UBQs in planta. Because multiubiquitinated proteins are the preferred substrates of the 26S proteasome, noncleavable fusions may be useful for decreasing protein half-life. Based on their ability to augment protein accumulation and the sequence specificity of Ubps, UBQ fusions offer a versatile way to express plant proteins.

Phytochrome A overexpression in transgenic tobacco. Correlation of dwarf phenotype with high concentrations of phytochrome in vascular tissue and attenuated gibberellin levels.

Phytochromes are a family of related chromoproteins that regulate photomorphogenesis in plants. Ectopic overexpression of the phytochrome A in several plant species has pleiotropic effects, including substantial dwarfing, increased pigmentation, and delayed leaf senescence. We show here that the dwarf response is related to a reduction in active gibberellins (GAs) in tobacco (Nicotiana tabacum) overexpressing oat phytochrome A under the control of the cauliflower mosaic virus (CaMV) 35S promoter and can be suppressed by foliar applications of gibberellic acid. In transgenic seedlings, high concentrations of oat phytochrome A were detected in stem and petiole vascular tissue (consistent with the activity of the CaMV 35S promoter), implicating vascular tissue as a potential site of phytochrome A action. To examine the efficacy of this cellular site, oat phytochrome A was also expressed using Arabidopsis chlorophyll a/b-binding protein (CAB) and the Arabidopsis ubiquitin (UBQ1) promoters. Neither promoter was as effective as CaMV 35S in expressing phytochrome in vascular tissue or in inducing the dwarf phenotype. Collectively, these data indicate that the spatial distribution of ectopic phytochrome is important in eliciting the dwarf response and suggest that the phenotype is invoked by elevated levels of the far-red-absorbing form of phytochrome within vascular tissue repressing GA biosynthesis.

Carboxy-terminal deletion analysis of oat phytochrome A reveals the presence of separate domains required for structure and biological activity.

A series of seven carboxy-terminal deletion mutants of oat phytochrome A were stably expressed in transgenic tobacco to localize phytochrome domains involved in chromophore attachment, spectral integrity, photoreversibility between the red light (Pr)- and far-red light (Pfr)-absorbing forms, dimerization, and biological activity. Amino acids necessary for chromophore attachment in vivo were localized to the amino-terminal 398 residues because mutant proteins this small had covalently bound chromophore. Deletion mutants from the carboxy terminus to residue 653 were spectrally indistinguishable from the full-length chromoprotein. In contrast, further truncation to residue 399 resulted in a chromoprotein with a bleached Pfr absorbance spectrum, Pr and Pfr absorbance maxima shifted toward shorter wavelengths, and reduced Pfr to Pr phototransformation efficiency. Thus, residues between 399 ad 652 are required for spectral integrity but are not essential for chromophore attachment. The sequence(s) between residues 919 and 1093 appears to be necessary for dimerization. Carboxy-terminal mutants containing this region behaved as dimers under nondenaturing conditions in vitro, whereas truncations without this region behaved as monomers. None of the plants expressing high levels of deletion mutants lacking the 35 carboxy-terminal amino acids displayed the light-exaggerated phenotype characteristic of plants expressing biologically active phytochrome A, even when the truncated phytochromes were expressed at levels 6- to 15-fold greater than that effective for the full-length chromoprotein. Collectively, these data show that the phytochrome protein contains several separable carboxy-terminal domains required for structure/function and identify a domain within 35 residues of the carboxy terminus that is critical for the biological activity of the photoreceptor in vivo.

Phytochrome requires the 6-kDa N-terminal domain for full biological activity.

Phytochrome is a red/far-red-absorbing photoreceptor that controls many aspects of plant photomorphogenesis. Because proteolytic removal of approximately 6 kDa from the N terminus of 124-kDa oat phytochrome substantially alters many physicochemical properties of the chromoprotein, it has been proposed that the N terminus is required for biological activity. Here we test this hypothesis by comparing tobacco plants expressing full-length oat phytochrome (FL) with plants expressing a 118-kDa oat phytochrome lacking amino acids 7-69 (NA phytochrome). NA phytochrome, like its FL counterpart, exists as a homodimer in solution, is capable of covalently binding chromophore to form a red/far-red-photoreversible product, and is rapidly degraded in vivo after photoconversion to the far-red-absorbing form. However, like proteolytically degraded phytochrome missing the N terminus, the absorption maxima of the red- and far-red-light-absorbing forms of NA phytochrome are blue shifted relative to the maxima of the FL chromoprotein, and the rate of dark reversion of the far-red- to red-light-absorbing form is substantially increased. Tobacco plants producing high levels of NA phytochrome do not exhibit the light-exaggerated phenotype characteristic of FL phytochrome overexpression. By comparison of phytochrome-dose-phenotype-response curves generated by using a series of transgenic lines expressing various levels of FL or NA phytochrome, we demonstrate that NA phytochrome has less than 1/5th the biological activity of FL phytochrome expressed in tobacco. Furthermore, the shape of the dose-response curve for plants expressing FL phytochrome indicates that there is a sharp transition between phenotypically normal and abnormal plants over a relatively narrow range of phytochrome content, demonstrating that precise control of phytochrome levels is critical to photomorphogenesis.

Novel applications of the ubiquitin-dependent proteolytic pathway in plant genetic engineering.

One goal of plant genetic engineering is the manipulation of protein levels within crop plants. New insights into the ubiquitin-dependent proteolytic pathway provide potential novel ways of enhancing levels of desired proteins by synthesizing them as ubiquitin fusions, and reducing levels of undesired proteins by selective protein degradation. As a result, the ubiquitin pathway should become a useful tool for many aspects of plant biotechnology.

Hypoxically inducible barley lactate dehydrogenase: cDNA cloning and molecular analysis.

In the roots of barley and other cereals, hypoxia induces a set of five isozymes of L-lactate dehydrogenase [LDH; (S)-lactate:NADH oxidoreductase, EC 1.1.1.27]. Biochemical and genetic data indicate that the five LDH isozymes are tetramers that arise from random association of the products of two Ldh loci. To investigate this system, cDNA clones of LDH were isolated from a lambda gt11 cDNA library derived from hypoxically treated barley roots. The library was screened with antiserum raised against barley LDH purified approximately 3000-fold by an improved three-step procedure. Immunopositive clones were rescreened with a cDNA probe synthesized by the polymerase chain reaction using primers modeled from the amino acid sequences of two tryptic LDH peptides. Two types of LDH clones were found. Nucleotide sequence analysis of one representative insert of each type (respectively, 1305 and 1166 base pairs) revealed open reading frames encoding 10 peptide fragments of LDH. The 1305-base-pair insert included the entire coding region of a 356-residue LDH monomer. The nucleotide sequences of the two LDH cDNAs were 92% identical in the coding region, but highly divergent in the 3' noncoding region, and thus probably correspond to the two postulated Ldh loci. The deduced amino acid sequences of the two barley LDHs were 96% identical to each other and very similar to those from vertebrate and bacterial LDHs. RNA blot hybridization showed a single mRNA band of 1.5 kilobases whose level rose about 8-fold in roots during hypoxic induction, as did the level of translatable LDH message.

Light-stimulated accumulation of the peroxisomal enzymes hydroxypyruvate reductase and serine:glyoxylate aminotransferase and their translatable mRNAs in cotyledons of cucumber seedlings.

The development of peroxisomal enzymes in cotyledons of cucumber seedlings is strongly dependent on light. In light-grown seedlings, activities of two peroxisomal enzymes, hydroxypyruvate reductase (HPR) and serine: glyoxylate aminotransferase (SGAT), were barely detectable until three days postimbibition, after which time both activities increased rapidly and linearly for at least three days. In the dark, the activities of these enzymes increased slightly over the same time period, but only to about 5% to 10% of 7-day light-induced levels. When 51/2-day dark-grown seedlings were transferred into white light, activities of HPR and SGAT began to increase after approximately 8 h. HPR protein was shown by an immunoprecipitation assay to increase concurrently with enzymatic activity in both light- and dark-grown cotyledons. Immunoblotting results suggested that the amounts of SGAT-A and SGAT-B, the two subunits of SGAT, also developed along with SGAT activity. The relative levels of translatable mRNAs encoding HPR, SGAT-A, and SGAT-B were also light-dependent, and increased with a developmental pattern similar to enzyme activity and protein levels in light- and dark-grown cotyledons. In 51/2-day dark-grown cotyledons that were transferred to the light, translatable mRNAs for SGAT-A and SGAT-B began to increase within 1 h of illumination and continued of increase rapidly and linearly for the next 24 h in the light to a new steady-state level that was 45 times that of dark controls. Translatable HPR mRNA exhibited a biphasic pattern of accumulation, with a three-fold increase during the first 6 h of illumination, followed by an additional six-fold increase between 8 and 24 h. The accumulation of translationally active mRNA for both enzymes preceded the accumulation of the corresponding protein and enzyme activity by about 8 h. Our data suggest that the rise in enzyme activity depends on an increase in translatable mRNA for these enzymes and is regulated at a pretranslational level, most likely involving transcription of new mRNA.

Isolation of serine:glyoxylate aminotransferase from cucumber cotyledons.

Serine:glyoxylate aminotransferase, a marker enzyme for leaf peroxisomes, has been purified to homogeneity from cucumber cotyledons (Cucumis sativus cv Improved Long Green). The isolation procedure involved precipitation with polyethyleneimine, a two-step ammonium sulfate fractionation (35 to 45%), gel filtration on Ultrogel AcA 34, and ion exchange chromatography on diethylaminoethyl-cellulose, first in the presence of pyridoxal-5-phosphate, and then in its absence. The enzyme was purified approximately 690-fold to a final specific activity of 34.4 units per milligram. Electrophoresis of the purified enzyme on sodium dodecyl sulfate-polyacrylamide gels revealed two polypeptide bands with apparent molecular weights of approximately 47,000 and 45,000. Both polypeptides coeluted with enzyme activity under all chromatographic conditions investigated, both were localized to the peroxisome, and both accumulated in cotyledons as enzyme activity increased during development. The two polypeptides appear not to be structurally related, since they showed little immunological cross-reactivity and gave rise to different peptide fragments when subjected to partial proteolytic digestion. Antiserum raised against either the denatured enzyme or the 45,000-dalton polypeptide did not react with any other polypeptides present in a crude cotyledonary homogenate. The purified enzyme also had alanine:glyoxylate aminotransferase activity, but was about twice as active with serine as the amino donor.

Purification and characterization of hydroxypyruvate reductase from cucumber cotyledons.

Hydroxypyruvate reductase (HPR), a marker enzyme of peroxisomes, has been purified to homogeneity from cotyledons of light-grown cucumber seedlings (Cucumis sativus var. Improved Long Green). In addition, the peroxisomal location of both HPR and serine-glyoxylate aminotransferase has been confirmed in cucumber cotyledons. The isolation procedure involved Polymin-P precipitation, a two-step precipitation with ammonium sulfate (35 and 50% saturation), affinity chromatography on Cibacron Blueagarose, and ion-exchange chromatography on DEAE-cellulose. HPR was purified 541-fold to a final specific activity of 525 +/- 19 micromoles per minute per milligram of protein. Enzyme homogeneity was established by native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The native molecular weight was 91 to 95 kilodaltons, approximately double the apparent subunit molecular weight of 40,500 +/- 1,400. With hydroxypyruvate as substrate, the pH optimum was 7.1 and K(m) values were 62 +/- 6 and 5.8 +/- 0.7 micromolar for hydroxypyruvate and NADH, respectively. With glyoxylate as substrate, the pH optimum was 6.0, and the K(m) values for glyoxylate and NADH were 5700 +/- 600 and 2.9 +/- 0.5 micromolar, respectively. Antibodies to HPR were raised in mice (by the ascites tumor method) and in rabbits, and their monospecificity was demonstrated by a modified Western blot immunodetection technique.