Randy D. Dinkins

Factors affecting soybean cotyledonary node transformation

Abstract Cotyledonary node transformation efficiency was evaluated using a sonication assisted Agrobacterium-mediated transformation (SAAT) protocol, three dissimilar A. tumefaciens strains, and explants derived from 28 diverse cultivars and/or genotypes of soybean [Glycine max (L.) Merr.]. The explants were evaluated at 10 and 45 days after co-cultivation for transformation with a binary vector containing both a GUS-intron gene and an NPTII selectable marker. The best overall strain of A. tumefaciens was determined to be KYRT1 based on stable GUS transformation of soybean cotyledonary node explants measured at the terminal 45 day evaluation point. SAAT did not increase stable transformation at 45 days post co-cultivation. SAAT was determined to significantly decrease shoot proliferation of some genotypes, but it is unclear what effect this may have on the recovery of transformed shoots. Significant differences were also detected between genotypes for transformation and shoot proliferation frequency.

Recent Advances in Soybean Transformation

Soybean (Glycine max (L.) Merrill) transformation continues to be problematic even with the efforts of numerous researchers in the field. In spite of this low efficiency, soybean transformation is now routine utilizing the somatic embryogenie and meristematic tissue culture methods. A comparison, including the advantages and disadvantages, of each method are presented in this review. Soybean transformation is currently done using both Agrobacterium tumefaciens and particle bombardment. We review some of the current selectable marker genes in use, and we also describe additional non-standard transformation techniques that have been, or are being attempted, to produce transgenic soybeans.

Gene silencing in transgenic soybean plants transformed via particle bombardment

Transgenes are susceptible to silencing in plants especially when multiple copies of the gene of interest are introduced. Transgenic plants derived by particle bombardment, which is the common method for transforming soybean, have a tendency to have multiple integration events. Three independent transgenic soybean plants obtained via particle bombardment were analyzed for transgene silencing. A GUS transgenic soybean line had at least 100 copies of the GUS gene while there were approximately 60 copies of the transgene in the two soybean lines transformed with a 15-kDa zein storage protein gene from maize. Soybean plants transformed with the GUS gene showed variable GUS expression. The coding region and promoter of the GUS gene in the plants with low expression of GUS were heavily methylated. Variability in GUS expression was observed in the progeny of the high expressors in the T2 and T3 generations as well. Expression level of the 15-kDa zein gene in transgenic soybean plants showed correlation with the level of transgene methylation. The helper component-proteinase from potyviruses is known to suppress post-transcriptional gene silencing. Transgenic plants were inoculated with the soybean mosaic potyvirus (SMV) to test possible effects on transgene silencing in soybean. Infection with SMV did not suppress transgene silencing in these plants and suggests that the silencing in these plants may not be due to post-transcriptional gene silencing.

Agrobacterium tumefaciens– mediated transformation of soybean [Glycine max (L.) Merrill.] using immature zygotic cotyledon explants

Agrobacterium tumefaciens-mediated transformation of soybean [Glycine max (L.) Merrill. cv. Jack] using immature zygotic cotyledons was investigated to identify important factors that affected transformation efficiency and resulted in the production of transgenic soybean somatic embryos. The factors evaluated were initial immature zygotic cotyledon size, Agrobacterium concentration during inoculation and co-culture and the selection regime. Our results showed that 8- to 10-mm zygotic cotyledons exhibited a higher transformation rate, as indicated by transient GUS gene expression, whereas the smaller zygotic cotyledons, at less than 5 mm, died shortly after co-cultivation. However, the smaller zygotic cotyledon explants were found to have a higher embryogenic potential. Analysis of Agrobacterium and immature cotyledon explant interactions involved two Agrobacterium concentrations for the inoculation phase and three co-culture regimes. No differences in explant survival or somatic embyogenic potential were observed between the two Agrobacterium concentrations tested. Analysis of co-culture regimes revealed that the shorter co-culture times resulted in higher explant survival and higher somatic embryo production on the explants, whereas the co-culture time of 4 days severely reduced survival of the cotyledon explants and lowered their embryogenic potential. Analysis of selection regimes revealed that direct placement of cotyledon explants on hygromycin 25 mg/l was detrimental to explant survival, whereas 10 mg/l gave continued growth and subsequent somatic embryo development and plant regeneration. The overall transformation frequency in these experiments, from initial explant to whole plant, was 0.03 %. Three fertile soybean plants were obtained during the course of these experiments. Enzymatic GUS assays and Southern blot hybridizations confirmed the integration of T-DNA and expression of the GUS-intron gene in the three primary transformants. Analysis of 48 progeny revealed that three copies of the transgene were inherited as a single Mendelian locus.

Overexpression of the Arabidopsis thaliana MinE1 bacterial division inhibitor homologue gene alters chloroplast size and morphology in transgenic Arabidopsis and tobacco plants.

Abstract. Higher-plant chloroplast division requires some of the same genes that are involved in prokaryotic cell division. These include the FtsZ and MinD proteins. Other genes that might be involved in higher-plant chloroplast division have yet to be characterized. The Arabidopsis thaliana (L.) Heynh. MinE (AtMinE1) gene was identified in the genomic database, isolated by reverse transcription-polymerase chain reaction and constitutively expressed in tobacco (Nicotiana tabacum L.) and Arabidopsis plants in both the sense and antisense orientation. Confocal and electron-microscopic analysis of the sense-overexpressing AtMinE1 transgenic tobacco and Arabidopsis plants revealed that the chloroplasts were abnormal in size and shape compared to wild-type Arabidopsis and tobacco chloroplasts. Our results, based on the overexpression of the AtMinE1 gene in tobacco and Arabidopsis, confirm that the AtMinE1 gene is involved in plant chloroplast division.

INCREASED SULFUR AMINO ACIDS IN SOYBEAN PLANTS OVEREXPRESSING THE MAIZE 15 kDa ZEIN PROTEIN

SummaryFour transgenic soybean [Glycine max (L.) Merrill] lines were generated containing the maize 15 kDa zein protein gene using somatic embryogenic protocols. The zein gene was inserted behind the β-phaseolin promoter for seed-specific expression. All four lines represent separate transformation events as they were generated in different experiments at different locations. Two of the transformation events produced multiple plants, and these produced identical Southern hybridization patterns (UKY/Z1, UKY/Z2 and UKY/Z3 from the first; and OSU/Z4, OSU/Z8 and OSU/Z10 from the second). Molecular characterization revealed that multiple copies of the zein gene were present in all of the transgenic lines. Immunoblot analysis confirmed the accumulation of the zein protein product in the seeds of the UKY/Z1, UKY/Z2, UKY/Z3, OSU/Z4, OSU/Z8 and OSU/Z10 transgenic lines. However, there was no accumulation of zein protein in the UGA/Z1 line and Northern analysis confirmed that the zein transgene was silenced in this line. It was not possible to analyze the zein expression in the seeds of the UKY/Z4 line, as it was sterile. Amino acid analysis of the UKY and OSU lines confirmed that there was a 12–20% increase in methionine, and 15–35% increase in cysteine content in these lines compared to the control. There were no consistent changes in the content of the other amino acids in the transgenic lines. These results suggest that while the increase in methionine content in these lines is modest, it is possible to increase the methionine content without adversely affecting the protein composition of soybean.

Resistance to Bean pod mottle virus in Transgenic Soybean Lines Expressing the Capsid Polyprotein

ABSTRACT Transgenic fertile soybean plants were generated from somatic embryos of soybean (Glycine max) cv. Jack transformed via particle bombardment with the capsid polyprotein (pCP) gene of Bean pod mottle virus(BPMV). The plant transformation vector (pHIG/BPMV-pCP) utilized in these experiments contained the BPMV-pCP coding sequence, an intron-containing GUS gene, and the hygromycin phosphotransferase gene. Southern blot hybridization analysis showed that 19 transgenic soybean plants selected for resistance to hygromycin contained the genes for GUS and BPMV-pCP. The progeny of five of these transgenic soybean plants (plants 137, 139, 157, 183, and 186) were characterized in detail. An additional transgenic plant (plant 200) contained the intron-GUS and hygromycin resistance genes, but lacked the BPMV-pCP gene and was used as a negative control. Southern blot hybridization analysis of the five transgenic plants showed the presence of three copies of the T-DNA in a similar banding pattern suggesting that they were derived from a single transformation event. Western and northern blot analyses showed that the expression levels of BPMV-pCP and pCP transcript were high in these five pCP plants. Infectivity assays with detached leaves demonstrated that all five pCP plants exhibited resistance to virus infection because they accumulated lower levels of BPMV compared with plant 200 and nontransformed controls. Unlike the T(2) progeny of line 183-1 that segregated with respect to the pCP gene and, consequently, to BPMV resistance, the T(2) progeny of the homozygous line 183-2 showed little or no symptoms in response to rub-inoculation with virions of a severe strain of BPMV. Although BPMV accumulation was evident in leaves on which viruliferous beetles were allowed a 72-h inoculation access period, the upper noninoculated leaves of the T(2) progeny of line 183-2 plants were symptomless and accumulated little or no virus. Because the progeny of this homozygous transgenic line exhibited systemic resistance, they could potentially be useful in generating commercial cultivars resistant to BPMV.

Overexpression of the Arabidopsis thaliana MinD1 gene alters chloroplast size and number in transgenic tobacco plants.

Abstract. The Arabidopsis thaliana (L.) Heynh. minD gene (AtMinD1) was isolated and constitutively expressed in tobacco (Nicotiana tabacum L.) plants using the CaMV 35S promoter. Confocal and electron-microscopic analysis of the AtMinD1 transgenic tobacco lines revealed that the chloroplasts were abnormally large and fewer in number compared with wild-type tobacco plants. The abnormal chloroplasts were less prevalent in guard cells than in mesophyll cells. Chloroplast and nuclear gene expression was not significantly different in AtMinD1-overexpressing plants relative to wild-type tobacco plants. Chloroplast DNA copy number was not affected, based on the relative level of the rbcL gene in transgenic plants. Transgenic tobacco plants constitutively overexpressing AtMinD1 were completely normal phenotypically with respect to growth and development, and also displayed normal photosynthetic electron transport rates. These results show that the ArabidopsisMinD1 gene also functions in a heterologous system and confirm the role of the MinD protein in regulation of chloroplast division.

A Second Protein l-Isoaspartyl Methyltransferase Gene in Arabidopsis Produces Two Transcripts Whose Products Are Sequestered in the Nucleus

The spontaneous and deleterious conversion of l-asparaginyl and l-aspartyl protein residues to l-iso-Asp or d-Asp occurs as proteins age and is accelerated under stressful conditions. Arabidopsis (Arabidopsis L. Heynh.) contains two genes (At3g48330 and At5g50240) encoding protein-l-isoaspartate methyltransferase (EC 2.1.1.77; PIMT), an enzyme capable of correcting this damage. The gene located on chromosome 5 (PIMT2) produces two proteins differing by three amino acids through alternative 3′ splice site selection in the first intron. Recombinant protein from both splicing variants has PIMT activity. Subcellular localization using cell fractionation followed by immunoblot detection, as well as confocal visualization of PIMT:GFP fusions, demonstrated that PIMT1 is cytosolic while a canonical nuclear localization signal, present in PIMT2ψ and the shorter PIMT2ω, is functional. Multiplex reverse transcription-PCR was used to establish PIMT1 and PIMT2 transcript presence and abundance, relative to β-TUBULIN, in various tissues and under a variety of stresses imposed on seeds and seedlings. PIMT1 transcript is constitutively present but can increase, along with PIMT2, in developing seeds presumably in response to increasing endogenous abscisic acid (ABA). Transcript from PIMT2 also increases in establishing seedlings due to exogenous ABA and applied stress presumably through an ABA-dependent pathway. Furthermore, cleaved amplified polymorphic sequences from PIMT2 amplicons determined that ABA preferentially enhances the production of PIMT2ω transcript in leaves and possibly in tissues other than germinating seeds.

EMBRYOGENIC RESPONSE OF MULTIPLE SOYBEAN (GLYCINE MAX (L.) MERR.) CULTIVARS ACROSS THREE LOCATIONS

SummaryNine soybean [Glycine max (L.) Merr.] cultivars representing midwestern, mid-south, and southern US growing regions were evaluated at each of three locations (Athens, GA; Lexington, KY; and Wooster, OH) using uniform embryogenic induction and proliferation protocols in order to evaluate the portability of soybean somatic embryogenic protocols to different locations. The experimental design minimized variation between locations by having all cultivars present at all locations on all days. A quantitative weighted score for primary embryo induction was developed on average embryo number per explant and was used to describe non-embryogenic, poorly embryogenic, moderately embryogenic, and highly embryogenic responses. Ranking of cultivars remained similar across all locations, indicating a uniform transportability of the protocol, at least as far as embryo induction is concerned. Continued proliferation of embryogenic cultures was also measured using a repetitive growth measure but few meaningful conclusions could be made due to the high level of variability including inconsistent growth of cultures between each subculture. Overall, several cultivars were identified as being uniformly embryogenic or non-embryogenic at the primary induction phase at all locations, and we predict that those embryogenic cultivars could be used by any laboratory for high-efficiency induction of embryogenesis. The best of these cultivars, ‘Jack’, was uniformly responsive across all locations and should be selected as the genotype most likely to yield positive results when attempting to culture and genetically engineer soybeans via embryogenic protocols.