Phosphomannose isomerase (PMI) catalyzes the reversible interconversion of mannose 6-phosphate and fructose 6-phosphate. Plant cells lacking this enzyme are incapable of surviving on synthetic medium containing mannose as a carbon source. Maize, wheat and barley plants, genetically modified to express the Escherichia coli manA gene (pmi) under the control of a plant promoter, were able to survive selection on mannose-containing medium. Transformation frequencies averaged 45% for maize transformation via Biolisticse, 35% for maize Agrobacterium-mediated transformation, 20% for wheat, 3% for barley, and 2% for watermelon transformation. Moreover, the frequencies exceeded those obtained for maize and wheat using the pat or bar gene with Basta w selection. A preliminary safety assessment has been conducted for PMI. Purified PMI protein demonstrates no adverse effects in an acute mouse toxicity test. Purified PMI protein was readily digested in simulated mammalian gastric and intestinal fluids. Plants derived from sugar beet and corn cells that had been genetically modified to express the E. coli manA gene were evaluated for biochemical changes in mannose-associated pathways. No detectable changes in glycoprotein profiles were detected in PMI-transformed plants as compared to nontransgenic controls. The yield and nutritional composition of grain from PMI-transformed corn plants compared to their non-transformed isogenic counterparts were also determined and no statistically significant differences were found. The inherent safety of a system based on simple sugar metabolism coupled with high transformation frequencies for monocots make pmi an ideal selectable marker for plant transformation.
Three maize genotypes previously shown in the literature to respond to anther culture were tested under various conditions. Studies indicated that embryogenic response ranged from 0 to 100 embryos per 1,000 anthers plated and was significantly lower without cold pretreatment of the anthers. Culture in liquid media tended to produce more embryos than in semi-solid as did the addition of activated charcoal to either liquid or solid culture media. Most results were confounded by plant-to-plant variation which tended to obscure significant differences. In one study, germination rate of androgenetic embryos averaged about 20%, but only 26% of those embryos that germinated completed their reproductive cycle and formed seed albeit through sibpollination since plants could not be selfed. Chromosome counts using root tip squashes indicated that regenerated plants were either haploid or diploid but plants scored as non-diploid yielded as much seed as scored diploids. This suggests that progeny can be recovered even from putative haploids, presumably as a result of "sectoring" in the developing ear. A DNA-specific fluorescent dye was used to visualize the presence of putative embryogenic microspores (PEMs) during the culture period. PEM counts were a function of time in culture and were apparently greater than the number of embryos obtained for a given treatment. The data indicate that, as previously reported for other species, both induction and survival phases also exist in maize anther culture.
Zea mays (maize) genotypes B73, Mo17 and LH38 were evaluated for their capacity to undergo somatic embryogenesis. Over 1500 immature embryos (ie's) of B73, 2900 ie's of LH38 and 400 ie's of Mo17 were excised 10-17 days after pollination and plated on six different media. Overall response, reported as a percentage of the ie's plated that developed embryogenic callus, was 2.1%, 1.6% and 26% for LH38, B73 and Mo17, respectively. Best response on a given medium for each of these genotypes was 9.2% (LH38), 4.4% (B73) and 100% (Mo17). Other parameters examined for their effects on production of embryogenic callus included self vs. sib pollination, ear ranking (1st, 2nd or 3rd ear), and temperature shock, all of which had no significant effect. Plantlets regenerated from selected treatments of B73 have been grown to maturity, selfed or sibbed and seed collected for field evaluation.
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