Decreasing yield loss and increasing the value of soybeans is part of KSU’s mission to improve Kansas’ agriculture. Our proposal is taking a genetic engineering approach to this mission allowing us to utilize traits outside the scope of conventional breeding. The four objectives of this project are to introduce and evaluate new traits into soybean for increased SCN resistance, increased fungal resistance, improved drought tolerance or resistance to Dectes stem borer.

Fungal pathogens and parasitic nematodes are important, persistent problems that cause large economic losses across the Midwest. For example, the total estimated loss for the US in 2010 due to SCN was 118 million bushels or $1.25 billion. Root Knot Nematodes is also a major factor in soybean yield loss in the southern US and has the potential to become a problem for Kansas producers. Charcoal rot is the major fungal disease in the state of Kansas and losses in 2002 were estimated at 9%. Phytophthora root rot and Fusarium virguliforme (Sudden Death Syndrome, SDS) are other fungal pests that are beginning to make their presence in Kansas (SDS was at record levels in the 2004 growing season). It is timely to find methods to efficiently control to these pathogens, as there is little or no natural sources of resistance found in our germplasm. Dectes stem borer is becoming an increasing problem in the state with the potential for significant economic loss. Drought is also a major environmental stress that limits production. Novel approaches such as using antimicrobial peptides have merit and should be explored. Finding transgenic solutions to soybean diseases and environmental stresses would complement the efforts of the conventional breeding program by adding additional sources of resistance.

1. Enhance Soybean Cyst Nematode (SCN) resistance in transgenic soybean by modifying current strategies. Test the effectiveness of gene silencing constructions for root knot nematode resistance using RKN genes homologous to effective SCN genes.
2. Transgenic approaches for increased fungal resistance with emphasis on SDS resistance.
3. Improve drought tolerance in soybean by manipulating drought tolerance-associated genes.
4. Evaluation of potential transgenic solutions to stem borer.

Objective 1: Enhance Soybean Cyst Nematode (SCN) resistance in transgenic soybean by modifying gene silencing strategies.
For the past few years we have been evaluating the effectiveness of traits to provide resistance to soybean cyst nematodes (SCN). Many of these traits have been designed to silence specific genes within the nematode and we have demonstrated a reduction in cyst numbers on these transgenic lines. We can further increase the resistance level by 1) using alternative gene sequences of these genes and 2) increasing the levels of siRNA produced by the plant. We have been targeting approximately 200-300 nucleotides of a given nematode gene with our current gene silencing approach. This is approximately 10 to 30% of the entire sequence of most target genes. Although we have demonstrated the effectiveness of this method, targeting alternate sequences of a particular gene may improve the silencing effect. We propose to take two of the genes previously used (one high and one low cyst/egg reduction from the bioassay) and target alternative sequences of the genes for gene silencing. Such a study will provide us with critical data in regards to the selection of future target sequences.

In general, the RNAi mechanism for gene silencing is based on a large (exponential) amplification of small interfering RNA (siRNA) molecules that bind to a specific gene sequence. Many laboratories including our own use this approach to effectively silence the plant’s own genes. For endogenous plant genes, the RNAi mechanism will produce siRNA molecules that recognize the total gene sequence, even if only 10% of the entire gene sequence is targeted, which in turn will cause a very high degree (possibly complete) of gene silencing. Our current methodology produces only siRNAs that correspond to the specific sequence (200 to 300 bp) fragment found in our DNA construction. The quantity of siRNA species does not increase exponentially because the nematode gene target is not found in the plant. We propose to over-express the targeted nematode gene sequence (either in the sense or antisense orientation) together with the RNAi vector construction. This approach should allow the exponential accumulation of siRNA species in the transgenic soybean plants thereby allowing a greater number of siRNA molecules to be ingested by the feeding nematode. This increase in siRNA ingested by the nematode should translate into increased SCN resistance. We have alternative transgenic approach to reduce SCN reproduction that is ongoing and an update will be given at the formal proposal presentation in December.

To assess the effectiveness of the above strategies greenhouse SCN bioassays on composite plants or transgenic soybean lines, as well as negative controls, will be performed. Lines will be planted into SCN infected soil (~6000 eggs/100 cm3) and grown in the greenhouse for five weeks. Soybean roots will then be washed free of soil and debris, SCN cysts removed from each plant and the number of cysts, eggs and root weight data will be collected for each replicate. Data collected from each bioassay will be examined by analysis of variance with the GLM procedure in SAS. Many of the transgenic lines made for SCN control have sequences similar enough to RKN genes so these will also be tested to see if they provide cross protection (i.e. resistance to both SCN and RKN). Additionally we will field test this material in 2019.
Transgenic lines generated from this research project will be incorporated into elite Kansas lines under the KSC funded project “Breeding and Management of Soybean for Improved Performance”. Where intellectual property rights are involved, the Kansas State University Research Foundation will be advised and they will assist us in the transfer of technology to third parties.

Objective 2. Transgenic approaches for increased fungal resistance with emphasis on SDS.
Sudden Death Syndrome (SDS) is caused by Fusarium virguliforme, a soil-borne fungus. Disease symptoms have been attributed to specific toxins produced by the fungus. One study indicated that when the fungal toxin gene FvTox1 was turned off in the pathogen by mutations, no symptoms developed on infected soybeans (Pudake et al., 2013). Our previous work using a gene silencing strategy targeting SCN genes is showing promising results and would serve as a model silencing the FvTox1 gene in F. virguliforme. With Chris Little we have successfully established a seedling assay for testing our transgenics using a hairy root bioassay. We have created silencing vectors for the FvTox1 gene, begun engineering soybean cultures, and plan to challenge the transgenic material with F. virguliforme. A positive result would be indicated by inhibition of fungal growth and absence of the disease. In addition to the FvTox1 gene we will look at other targets to silence in the fungus.

Additionally, we will investigate a separate approach to produce fungal resistance. Defensins and their relatives are peptides or small proteins that can inhibit antimicrobial growth (De Lucca and Walsh, 1999). These peptides are present in plants, insects, and vertebrates. We have selected five peptides from various sources, optimized expression for soybean, created expression vectors, and transformed soybean cultures. Seeds recovered from transgenics will be used first evaluate growth inhibition on F. virguliforme (SDS) but will screen other pathogens such as Macrophomina phaseolina (charcoal rot). For bioassays we will cooperate with Dr. Chris Little, KSU’s row crop pathologist.

Objective 3: Improve drought tolerance in soybean by manipulating drought tolerance-associated genes.
Drought is one of critical abiotic stresses limiting soybean production in Kansas. Changing expression patterns in drought related genes may increase tolerance. The transcriptional factors (proteins that regulates gene expression) belonging to the NAC (NAM, ATAF and CUC) gene family are closely related to drought-responsive genes in plants. Many members of NAC family enhanced drought tolerance have been reported. For example, the alteration of root architecture by osNAC9 in rice improved plant drought resistance and grain yield (Redillas et al., 2012). In recent analysis of soybean NAC gene family related to drought tolerance, several specific genes were identified in drought tolerant cultivars (Hussain et al., 2017). Our goal with this objective is to overexpress and/or down regulate selected transcription factors in hairy roots and evaluated root architecture and their response to drought conditions. Any genes that show potential we will then produce stable transgenic lines for further evaluations.

Objective 4. Evaluation of potential transgenic solutions to stem borer.
Recent findings made under the KSC funded project “Development of soybean host plant resistance and other management options for the soybean stem borer” (C.M. Smith, PI) have demonstrated the potential for stem borer development and viability by gene silencing. Similar to our SCN work we propose to engineer soybean with these gene-silencing constructs and then provide C.M. Smith these transgenic cultures and lines for his KSC funded program. In the FY2019 we are making the vectors for hairy root analysis and for stable transgenic plants. In FY2020 we will continue with bioassays and generate transgenic lines of the appropriate vectors.

Update:
COVID-19 continues restricted our research for the 1st quarter of the grant. University is still in phase 3 of their research plan which minimized workstaff to essential personal only and has encouraged tele-work where possible to minimize presence on campus. The lab technician and PD have reduced hours in lab but continue to maintain current cultures not to lose our transgenic soybean cultures. Lines in the greenhouse were harvested for seeds and new plants from the ongoing tissue culture process were moved to greenhouse for seed production.

Work on the dectes stem borer material continues on hold as the PD from C.M. Smith’s lab is still stuck in Columbia due to the covid-19 pandemic. We continue to advance these lines to the next generation while we wait for her return.

Due to the herbicide issue with the SCN field plot the data was not usable and the experiment was terminated. However we were able to recover the next generation of seed from this experiment.

Update:
Host-derived RNAi silencing for the stem borer in soybean:
We are continuing to recover positive putative tissues and regenerating plants for this project. We have identified 15 new putative clones from one construction and 23 from a second construction which are being increased for PCR testing, These lines have been split with half being regenerated into plants and the other portion for molecular testing. From previous identified lines we have regenerated plants and grown these to maturity and have begun to harvest seeds.

The SDS resistance projects with FvTox1 silencing construction we continued to regenerate additional lines and moving them into the greenhouse for seed production. Currently we have harvested seeds from 4 plants.

Update:
Host-derived RNAi silencing for the stem borer in soybean:
We are continuing to recover positive putative tissues and regenerating plants for this project. We have identified 23 putative clones from one construction and 41 from a second construction which are being increased for PCR testing, These lines have been split with half being regenerated into plants and the other portion for molecular testing. From previous identified lines we have regenerated plants and grown these to maturity. We are harvested seeds from five different plants with harvesting continuing. In a small pilot greenhouse experiment we have taken four plants from two different transgenic lines and added adult stem borers to these plants. After maturity we will note if Deteces develop within these lines and compare them to control plants.

The SDS resistance projects with FvTox1 silencing construction we continued to regenerate additional lines and moving them into the greenhouse for seed production. Currently we have identified 8 additional putative clones and regenerated 5 plants from these events. These have been placed in the greenhouse for maturation.

Update:
This funding cycle had its challenges due to the pandemic and personnel changes. COVID-19 restricted our research for the first couple of quarters of the funding cycle. The University policies minimized the work staff to essential personal only and then limited the number of personnel in the labs that could be present at one time. We had one post doc that was out of the country for a significant time because of entry restrictions due to the pandemic. We also had another post doc take a position with Syngenta. A new postdoc was hired in the third quarter and was soon took over the molecular efforts on the project.

Host-derived RNAi silencing for the stem borer in soybean:
We have identified several lines from two of the three DNA constructions and are advancing them in the greenhouse. Additional events are coming through the transformation pipeline. We have set up a number of plants in the greenhouse and began infesting them with field caught Dectes. This experiment will continue in the next quarter.

For the Sudden Death Syndrome (SDS) resistance project we continued to regenerate additional lines containing the FvTox1 silencing construction and moving them into the greenhouse for seed production. Several lines have been confirmed to contain the transgene and we are starting with expression analysis. These lines are also being advanced to homozygousity in the greenhouse.

For the drought tolerance project knocking down transcription factor GmNAC177, GmNAC174:
we have performed gDNA PCR for the detection of transgene integration in GmNAC177 RNAi putative clones identified in the transformation pipeline. We have several GmNAC177 lines confirmed by PCR showing integration of both the RNAi arms. Some of these events have been moved to the greenhouse and growth chambers for seed production. We will further confirm transgene integration in these lines in T1 generation. We are also working towards generating an RNAi construct targeting transcription factor GmNAC174. We have amplified the RNAi fragment from soybean c-DNA and cloned it into gateway vector pCR8. This is the first step in making a transformation vector. Once, the construct is confirmed we will move forward for generation of transgenic lines.

For the SCN/RNAi project we were unable to perform a field test this year. There was a glitch in the field notification process and before it was discovered I was too late to have a good test in the field. However, we continue to advance these lines into adapted cultivars. Additionally, we have started talks on potentially licensing the SCN resistance project to an industrial partner.

This funding cycle had its challenges due to the pandemic and personnel changes. COVID-19 restricted our research for the first couple of quarters of the funding cycle. The University policies minimized the work staff to essential personal only and then limited the number of personnel in the labs that could be present at one time. We had one post doc that was out of the country for a significant time because of entry restrictions due to the pandemic. We also had another post doc take a position with Syngenta. A new postdoc was hired in the third quarter and was soon took over the molecular efforts on the project.

Host-derived RNAi silencing for the stem borer in soybean:
We have identified several lines from two of the three DNA constructions and are advancing them in the greenhouse. Additional events are coming through the transformation pipeline. We have set up a number of plants in the greenhouse and began infesting them with field caught Dectes. This experiment will continue in the next quarter.

For the Sudden Death Syndrome (SDS) resistance project we continued to regenerate additional lines containing the FvTox1 silencing construction and moving them into the greenhouse for seed production. Several lines have been confirmed to contain the transgene and we are starting with expression analysis. These lines are also being advanced to homozygousity in the greenhouse.

For the drought tolerance project knocking down transcription factor GmNAC177, GmNAC174:
we have performed gDNA PCR for the detection of transgene integration in GmNAC177 RNAi putative clones identified in the transformation pipeline. We have several GmNAC177 lines confirmed by PCR showing integration of both the RNAi arms. Some of these events have been moved to the greenhouse and growth chambers for seed production. We will further confirm transgene integration in these lines in T1 generation. We are also working towards generating an RNAi construct targeting transcription factor GmNAC174. We have amplified the RNAi fragment from soybean c-DNA and cloned it into gateway vector pCR8. This is the first step in making a transformation vector. Once, the construct is confirmed we will move forward for generation of transgenic lines.

For the SCN/RNAi project we were unable to perform a field test this year. There was a glitch in the field notification process and before it was discovered I was too late to have a good test in the field. However, we continue to advance these lines into adapted cultivars. Additionally, we have started talks on potentially licensing the SCN resistance project to an industrial partner.

This project will benefit farmers by providing new transgenic sources of resistance/tolerances to soybean diseases, insects and environmental stresses. This research would complement the efforts of conventional breeding programs by adding additional component to their breeding strategies.