Education & Outreach
REU Alumni
Olive LoGrasso
Mohamed Elgallad
“Characterizing a locus that confers resistance to Beech Bark Disease”
Project Summary:
American beech (Fagus grandifolia) is an ecologically and economically important native species. This species has high-quality wood used for furniture, flooring, and firewood, and its beech nuts are a vital nutrition source for many species ranging from birds to deer and black bears. American beech trees are seriously threatened since its smooth bark makes it susceptible to Beech Bark Disease (BBD). BBD is caused by an insect-fungal complex attack that begins with scale insects (Cryptococcus fagisuga) that attack the tree to feed on its sap. Insect feeding in turn creates points of entry for the fungal pathogens that cause BBD. When American beech trees are evaluated for BBD, some individuals show signs of resistance; this resistance was previously genetically linked to a chromosomal locus. For this project, we gathered samples from infected individuals from Arnot forest for genome sequencing using Nanopore technology. This data was analyzed and compared to previously collected and sequenced samples from both resistant and susceptible trees in an attempt to characterize a locus that provides beech trees with resistance to this insect-fungal attack. This effort will help future conservation and breeding efforts and contribute to the restoration of ecosystems afflicted with BBD. Without intervention, BBD would continue to impact the large number of organisms that depend on this native tree species to survive. Information derived from this research will also provide woodlot managers an early detection tool that would save them time and money.
My Experience:
As a biological sciences undergraduate interested in genetics, bioinformatics is a valuable skill to acquire, especially with how quickly research is evolving. This summer I was fortunate enough to conduct research in the BTI Computational Biology Center (BCBC) with my mentor Dr. Adrian Powell and my PI Dr. Suzy Strickler, both of whom supported and guided me through my research journey which I am extremely grateful for. This summer has been one of the most insightful summers I have experienced, both academically and socially. I had the opportunity to experience what it’s like to be a successful plant scientist while enjoying the beautiful city of Ithaca. I made many genuine connections that taught me numerous valuable lessons. This internship has helped me be more confident in my skills, prepare for graduate school, and it unexpectedly opened many new doors for me, even beyond the academic world.
Rohit Lal
Tony Mao
Albert Sun
Lily Yang
Bowen Zheng
Connor Lane
Tony Kinchen
Sylvia Leggette
Probing the Role of RDR and DCL proteins in Virus Induced Gene Editing in Tomato Plants
Genome editing is an important tool for biological research and crop improvement. Tissue culture is the traditional method for genome editing but requires large time investments, extensive experimental procedures, and can have unintended effects on the genome. Virus induced gene editing (VIGE) uses viral vectors to create heritable edits by delivering single-guide RNA to the meristem via direct delivery. Tobacco Rattle Virus (TRV) has successfully created heritable edits in dicotyledonous plants, but many species exclude viruses from the meristem as part of protection. RNA-dependent RNA polymerase (RDR) and Dicer-like (DCL) genes encode key proteins involved in viral protection in plants. This project seeks to evaluate how they affect VIGE efficiency by creating loss of function mutant tomato plant lines using CRISPR Cas9 and tissue and conducting TRV mediated VIGE on these plants using phytoene desaturase (PDS) as a reporter gene. The loss of function mutants were crossed with high Cas9 expressing, high editing efficiency wildtype plants and then VIGE was conducted on the crossed plants. PDS photobleaching symptoms began showing 11 days post editing after which a western blot was performed to evaluate the Cas9 expression in the crossed plants. Positive sequencing results indicate successful creation of loss of function mutants. Western blot results indicate high Cas9 expression in the crossed plants. This work can lay the foundation for future work on developing protocols for more efficient VIGE work and act as progress towards the overall goal of overcoming the barriers of tissue culture-based genome editing.
I have had the pleasure of working in the Van Eck as part of the BTI/ CROPPS Research Experience for Undergraduates (REU). My project involved evaluating the role of RNA-dependent RNA polymerase (RDR) and Dicer-like (DCL) genes in the efficiency of Virus Induced Gene Editing (VIGE). My mentor, Dr. Fan Xia, has helped me gain an in-depth understanding of CRISPR-Cas9 genome editing methods, the genotyping process, experimental design and problem-solving from a scientific mindset. The Van Eck lab is a collaborative and uplifting environment, and it has been an honor work with these individuals these past 10 weeks.
Gillian Doty
Investigating insect defense systems in groundcherry as a model for related Physalis species
Physalis is a genus of fruit plants native to Central and South America. Goldenberry (Physalis peruviana) has abundant nutritional and medicinal properties that make it desirable for large-scale agricultural production. However, it is susceptible to insect herbivory, which reduces fruit yield and poses a challenge to growers. A close relative of P. peruviana, groundcherry (Physalis grisea), is more resistant to insect herbivores. Its leaves produce specialized metabolites called withanolides that confer insect resistance in other plant species. Withanolide content in P. peruviana may be manipulated to make it more viable for large-scale production. To further explore the application of withanolides as a defense mechanism against insect herbivory, through deterrent or toxic effects, we used CRISPR gene editing to alter withanolide accumulation in P. grisea leaf tissue. We targeted two branch points in the withanolide biosynthetic pathway: BETA-AMYRIN SYNTHASE (PgꞵAS) and STEROL METHYLTRANSFERASE 2 (PgSMT2). Three mutant lines with unique alleles for each gene were recovered. We used these lines in a no-choice insect bioassay in which Trichoplusia ni neonate larvae were placed individually in a petri dish with one leaf disc. The larvae did not exhibit a significant feeding preference for wild type P. grisea or any edited line, and the larvae had similar survival rates on all lines. This may be due to T. ni being a generalist species and having an acute sensitivity to withanolides. Future bioassays will investigate the effect of withanolides on Lema daturphila beetles, which are Physalis specialists and can likely tolerate higher levels of withanolides.
This summer, I had the opportunity to work in Joyce Van Eck’s lab at BTI, using chemical ecology to study insect defense mechanisms in groundcherry as a part of the Physalis Improvement Project. I was closely mentored by Savanah Dale who gave me the freedom to think independently and the support I needed as I delved into a new project. Through my work and the weekly seminar series, I’ve learned about a plethora of plant research projects and their practical applications. Understanding how scientists can use their research to improve crops has enriched my love of plant science and has sparked my interest in plant breeding as a career path.
Madison Plunkert
Elucidating the function of a novel cysteine-rich peptide during flower-to-fruit transition in tomato
During fruit initiation, secreted peptides mediate communication between pollen and the female gametophyte, as well as the embryo sac and the surrounding female tissues. The cysteine-rich peptides (CRPs), a diverse class of secreted peptides that contain an N-terminal secretion signal and a C-terminal cysteine-rich region, play an important role in cell-cell signaling during flower-to-fruit transition. However, their role in tomato fertilization, fruit initiation, and seed formation is still unknown. Previous tissue-specific transcriptomic studies in our lab identified OVULE-SECRETED PROTEIN (OSP), a CRP highly expressed in the tomato ovule integument at anthesis. Based on this expression profile, we hypothesized that OSP may be involved in processes during flower-to-fruit transition, such as micropylar pollen tube guidance, ovule maturation, or seed formation. In this project, we conducted studies aimed at the functional characterization of OSP, which included phylogenetic analysis, a study of OSP spatiotemporal expression patterns, and the phenotypic characterization of OSP-RNAi plants. In addition, we designed and created molecular tools to generate osp knock-out mutants using CRISPR technology. Multiple sequence alignment and phylogeny tools demonstrated that the cysteine motif in OSP is unique to the cultivated tomato and its wild relatives. Using gOSP::YFP transgenic plants and confocal microscopy, we have observed that OSP is expressed in ovaries and fruit at stages surrounding anthesis. Our results suggest that OSP expression in the ovule inner integument beginning prior to anthesis. OSP-RNAi plants with reduced levels of OSP expression showed no abnormal phenotype when we examined seed weight, seed number per fruit, external seed and ovule morphology, and pollen tube guidance. We have therefore assembled a CRISPR vector that includes guide RNAs targeting the OSP coding region. We anticipate that osp knockout mutants will show a stronger phenotype that will help elucidate the function of OSP.
My Experience
The Plant Genome Research Program at BTI has been an invaluable experience. I felt immediately welcomed by my lab and the community at BTI. In addition to learning a variety of microscopy and molecular biology techniques, I had the opportunity to make experimental decisions and develop confidence as a researcher. Through working independently and with my mentor, I am better prepared for a research career. This internship has reinforced my intention to pursue plant science during graduate school, and I look forward to a continued relationship with my lab and the interns I have met this summer.
Allyson Weir
“Functional Characterization of the Tomato Sugar Transporter SWEET10”
Project Summary:
Carbohydrates produced from photosynthesis are crucial to development, growth, and signaling in plants. To maintain optimal plant function, sugars must be moved from the leaf to other areas of the plant by transporters. A novel class of sugar transporters, named Sugar Will Eventually be Exported Transporters or SWEETs has been shown to play a key role in sugar efflux during several physiological processes, however little is known about their role in fruit development. It has been hypothesized that the action of SWEET transporters is needed in specific fruit tissues and stages, allowing efficient utilization of sucrose during fruit and seed development. However, direct molecular genetic evidence of this hypothesis is still lacking. My project aims to elucidate the role of the tomato SWEET transporter, SlSWEET10, in regulating sugar transport during early fruit development. SlSWEET10 is specifically expressed during early fruit development, and mostly in vascular rich tissues such as the columella and the placenta. The SWEETs gene family is split into four clades, with SlSWEET10 belonging to Clade III. In Arabidopsis, several Clade III SWEETs are known to transport sucrose, therefore we hypothesize that SlSWEET10 is involved in the transport of sucrose from the sieve elements into the fruit parenchyma apoplast. In this work, we have analyzed the effect of variable SWEET10 expression on sugar accumulation and fruit weight using transgenic tomato plants. We have identified the subcellular localization of the SWEET10 protein in fruit, and have compared the expression of SWEET10 and its closest homologs in domesticated tomatoes to their wild relatives. Our results suggest that SlSWEET10 plays an important role in sugar transport during early fruit development, a novel, so far unreported function for SWEET transporters. This research will generate insights into the regulation of fruit development and help identify important genes contributing to crop quality.
My Experience:
Through my time at BTI I have become a more confident researcher. Working independently improved my problem-solving skills and critical thinking, while working together with my lab towards one common project has helped to refine my skills in communication and time management. I felt like I was a member of a wider community of plant biologists whose enthusiasm for their work is infectious and inspiring. Through these experiences I have been able to better define my own research interests and have also been able to speak with Cornell professors about the research being conducted in these areas. I have learned more about life as a graduate student, and the process of applying to Cornell PhD programs. Overall, I believe that this summer has been one of the most transformative and educational in my academic career, and I now look even more forward to pursuing a career in plant biology.
Philip Engelgau
Functional characterization of the tomato sugar transporter SWEET10
Project Summary
Tomatoes are one of the most important fleshy fruit crops of modern agriculture. The sugary globe’s versatile nature has led it to become a staple in the dishes of countless cultures across the world. It is this sugar content that differentiates a refreshingly sweet tomato from an unpalatably bitter one. Although a new family of sucrose transporters called SWEETs has been recently discovered in Arabidopsis and rice, little is known of their actions with regards to sugar acquisition in fleshy fruits in general and tomato fruit in particular. Preliminary RNA-seq data has shown that SWEET10, a member of the SWEET family, is highly expressed during early tomato fruit development in the placenta. Due to this early insight, SWEET10 was selected as a suitable candidate for preliminary functional characterization. Comparison of fruit sugar content in wild-type plants and in transgenic RNAi plants in which SWEET10 expression is down-regulated revealed an altered sugar accumulation pattern in the SWEET10 RNAi lines. Using quantitative RT-PCR we showed that auxin regulates the expression of SWEET10 and some of its closest homologs, a finding which may shed light on its expression, and on the regulation of fruit sugar content during ripening.
Our results not only aim to characterize SWEET genes in tomato, but may also provide insight for breeders hoping to harness genetic information to restore the sweeter characteristics of tomatoes that were lost during domestication.
My Experience
My experiences in the Plant Genome Research Program at BTI will be tremendously helpful in my future scientific endeavors. Not only will the laboratory techniques and skills learned be of great assistance, but the very experience of having spent time at a world-class plant research institute will prove valuable. By observing other researchers collaborate between labs and even between institutes I have gained an understanding of the way science is accomplished. The program has also exposed me to the entire spectrum of plant biology research. Having been shown to such a wide array of the dynamic field of plant biology I feel as though I can make more informed decisions for graduate school and beyond. It is due to the aforementioned traits that my summer at BTI has impressed upon me lessons which will aid me at every step of my future.