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1. Agrobacterium ‐mediated Cuscuta campestris transformation as a tool for understanding plant–plant interactions

   https://doi.org/10.1111/nph.20140  

   Adhikari, Supral; Mudalige, Asha; Phillips, Lydia; Lee, Hyeyoung; Bernal‐Galeano, Vivian; Gruszewski, Hope; Westwood, James_H; Park, So‐Yon (October 2024, New Phytologist)

   Summary Cuscuta campestris, a stem parasitic plant, has served as a valuable model plant for the exploration of plant–plant interactions and molecular trafficking. However, a major barrier toC. campestrisresearch is that a method to generate stable transgenic plants has not yet been developed.Here, we describe the development of aCuscutatransformation protocol using various reporter genes (GFP, GUS, or RUBY) and morphogenic genes (CcWUS2andCcGRF/GIF), leading to a robust protocol forAgrobacterium‐mediatedC. campestristransformation.The stably transformed and regenerated RUBYC. campestrisplants produced haustoria, the signature organ of parasitic plants, and these were functional in forming host attachments. The locations of T‐DNA integration in the parasite genome were confirmed through TAIL‐PCR. TransformedC. campestrisalso produced flowers and viable transgenic seeds exhibiting betalain pigment, providing proof of germline transmission of the RUBY transgene. Furthermore, RUBY is not only a useful selectable marker for theAgrobacterium‐mediated transformation, but may also provide insight into the movement of molecules fromC. campestristo the host during parasitism.Thus, the protocol for transformation ofC. campestrisreported here overcomes a major obstacle toCuscutaresearch and opens new possibilities for studying parasitic plants and their interactions with hosts. 

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2. Mobile Host mRNAs Are Translated to Protein in the Associated Parasitic Plant Cuscuta campestris

   https://doi.org/10.3390/plants11010093  

   Park, So-Yon; Shimizu, Kohki; Brown, Jocelyn; Aoki, Koh; Westwood, James H. (January 2022, Plants)

   Cuscuta spp. are obligate parasites that connect to host vascular tissue using a haustorium. In addition to water, nutrients, and metabolites, a large number of mRNAs are bidirectionally exchanged between Cuscuta spp. and their hosts. This trans-specific movement of mRNAs raises questions about whether these molecules function in the recipient species. To address the possibility that mobile mRNAs are ultimately translated, we built upon recent studies that demonstrate a role for transfer RNA (tRNA)-like structures (TLSs) in enhancing mRNA systemic movement. C. campestris was grown on Arabidopsis that expressed a β-glucuronidase (GUS) reporter transgene either alone or in GUS-tRNA fusions. Histochemical staining revealed localization in tissue of C. campestris grown on Arabidopsis with GUS-tRNA fusions, but not in C. campestris grown on Arabidopsis with GUS alone. This corresponded with detection of GUS transcripts in Cuscuta on Arabidopsis with GUS-tRNA, but not in C. campestris on Arabidopsis with GUS alone. Similar results were obtained with Arabidopsis host plants expressing the same constructs containing an endoplasmic reticulum localization signal. In C. campestris, GUS activity was localized in the companion cells or phloem parenchyma cells adjacent to sieve tubes. We conclude that host-derived GUS mRNAs are translated in C. campestris and that the TLS fusion enhances RNA mobility in the host-parasite interactions. 

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3. An artificial host system enables the obligate parasite Cuscuta campestris to grow and reproduce in vitro

   https://doi.org/10.1093/plphys/kiac106  

   Bernal-Galeano, Vivian; Beard, Keely; Westwood, James H (March 2022, Plant Physiology)

   Abstract Cuscuta campestris is an obligate parasitic plant that requires a host to complete its life cycle. Parasite–host connections occur via a haustorium, a unique organ that acts as a bridge for the uptake of water, nutrients, and macromolecules. Research on Cuscuta is often complicated by host influences, but comparable systems for growing the parasite in the absence of a host do not exist. We developed an axenic method to grow C. campestris on an artificial host system (AHS). We evaluated the effects of nutrients and phytohormones on parasite haustoria development and growth. Haustorium morphology and gene expression were also characterized. The AHS consists of an inert, fibrous stick that mimics a host stem, wicking water and nutrients to the parasite. It enables C. campestris to exhibit a parasitic habit and develop through all stages of its life cycle, including production of new shoots and viable seeds. The phytohormones 1-naphthaleneacetic acid and 6-benzylaminopurine affect haustoria morphology and increase parasite fresh weight and biomass. Unigene expression in AHS haustoria reflects processes similar to those in haustoria on living host plants. The AHS is a methodological improvement for studying Cuscuta biology by avoiding specific host effects on the parasite and giving researchers full control of the parasite environment. 

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4. Chromosome level assembly and annotation of Cuscuta campestris Yunck. (“field dodder”), a model parasitic plant

   https://doi.org/10.1093/g3journal/jkaf193  

   Cerda-Herrera, Juan D; Zhang, Huiting; Wafula, Eric K; Adhikari, Supral; Park, So-Yon; Carey, Sarah B; Harkess, Alex; Ralph, Paula E; Westwood, James H; Axtell, Michael J; et al (August 2025, G3: Genes, Genomes, Genetics)

   Wong, A (Ed.)

   Abstract We present the first chromosome-level genome assembly and annotation for the genus Cuscuta, a twining and leafless parasitic plant of the morning glory family (Convolvulaceae). C. campestris, the study species, is a widely studied model parasite, due in part to its worldwide occurrence as a weed of agricultural and natural plant communities. The species has served as a model parasite for studies of parasite biology, haustorium development, growth responses to chemical and light stimuli, gene content and expression, horizontal gene transfer, and interspecies RNA movement and has a recently developed transformation system. The 505 Mb (1C) genome is assembled into 31 chromosomes and supports annotation of 47,199 protein-coding genes, 214 small RNA loci (including 146 haustoria-specific miRNAs), and 3,238 interspecies mobile mRNA loci. C. campestris is a recent tetraploid with a high retention of duplicated genes and chromosomes, with less than 8% nucleotide divergence between homoeologous chromosomes. We also show that transformation of C. campestris with the RUBY marker system allows visualization of transformed Cuscuta-derived fluorescent mobile molecules that have entered the host stem. This genome, with an associated genome browser and BLAST server, will be of value for scientists performing fundamental research in a wide range of molecular, developmental, population, and evolutionary biology, as well as serve as a research tool for studying interspecies mobile molecules, generating genetic markers for species and genotype identification, and developing highly specific herbicides. 

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5. The seed transcriptome of Rafflesia reveals horizontal gene transfer and convergent evolution: Implications for conserving the world's largest flower

   https://doi.org/10.1002/ppp3.10370  

   Molina, Jeanmaire; Wicaksono, Adhityo; Michael, Todd_P; Kwak, Su‐Hwan; Pedales, Ronniel_D; Joly‐Lopez, Zoé; Petrus, Semar; Mamerto, Allen; Tomek, Brian; Ahmed, Sumaya; et al (April 2023, PLANTS, PEOPLE, PLANET)

   Societal Impact Statement Rafflesiais a genus of parasitic plants with the largest flowers in the world, unique to the threatened forest habitats of tropical Asia. Here, we report on genes that are active (the transcriptome) inRafflesiaseeds as part of a larger effort to understandRafflesia.Rafflesiahas never been grown successfully outside of its native range. Consequently, seed banking is not yet possible, precluding a critical management strategy for conservation. The study ofRafflesiaseed biology is a critical step to improve its cultivation, which will educate the public about unique species and the importance of conserving their habitats. SummaryRafflesiais of great interest as one of the only two plants known to have completely lost its chloroplast genome.Rafflesiais a holoparasite and an endophyte that lives inside the tissues of its host, a tropical grape vine (Tetrastigma), emerging only to bloom—with the largest flower of any plant. Here, we report the firstRafflesiaseed transcriptome and compare it with those of other plants to deepen our understanding of its extraordinary life history.We assembled a transcriptome from RNA extracted from seeds of the Philippine endemicRafflesia speciosaand compared this with those of other plants, includingArabidopsis, parasitic plantsStrigaandCuscuta, and the mycoheterotrophic orchidAnoectochilus.Genetic and metabolic seed pathways inRafflesiawere generally similar to the other plant species. However, there were some notable exceptions. We found evidence of horizontal transfer of a gene potentially involved in circumventing host defenses. Moreover, we identified a possible convergence among parasitic plants becauseRafflesia,Striga, andCuscutashared important similarities. We were unable to find evidence of genes involved in mycorrhizal symbiosis, suggesting that mycoheterotrophy is unlikely to play a role inRafflesiaparasitism.To date, ex situ propagation ofRafflesiaby seed has been mostly unsuccessful. Our research is a bold step forward in understanding the fundamentals ofRafflesiaseed biology that will inform the continued propagation and seed‐banking efforts concerning this recalcitrant plant. We discuss our findings in the broader context of the conservation of a genus in peril. 

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