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1. Catalytic generation of ortho -quinone dimethides via donor/donor rhodium carbenes

   https://doi.org/10.1039/d3sc00734k  

   Gao, Mingchun; Ruiz, Jose M.; Jimenez, Emily; Lo, Anna; Laconsay, Croix J.; Fettinger, James C.; Tantillo, Dean J.; Shaw, Jared T. (June 2023, Chemical Science)

   Substrates engineered to undergo a 1,4-C–H insertion to yield benzocyclobutenes resulted in a novel elimination reaction to yieldortho-quinone dimethide (o-QDM) products that undergo Diels–Alder or hetero-Diels–Alder cycloadditions. 

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2. Draft genome sequences of Flagellimonas sp. MMG031 and Marinobacter sp. MMG032 isolated from the dinoflagellate Symbiodinium pilosum

   https://doi.org/10.1128/mra.00913-24  

   Farrell, Morgan V; Aljaber, Aya M; Amoruso, Madison; Chan, Wyman F; Dael, Jiellen R; De_Tomas, Mathieu L; Delavega, Emily G; Eslava, Jacob M; Holdbrook-Smith, Benjamin J; Lee, Precilla; et al (January 2025, Microbiology Resource Announcements)

   Roux, Simon (Ed.)

   ABSTRACT Here, we report the draft genome sequences ofFlagellimonassp. MMG031 andMarinobactersp. MMG032, isolated from coral-associated dinoflagellateSymbiodinium pilosum, assembled and analyzed by undergraduate students participating in a Marine Microbial Genomics (MMG) course. A genomic comparison suggests MMG031 and MMG032 are novel species and a resource for restoration and biotechnology. 

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3. Genomic characterization of Pseudomonas syringae pv. syringae from Callery pear and the efficiency of associated phages in disease protection

   https://doi.org/10.1128/spectrum.02833-23  

   Holtappels, D; Abelson, S A; Nouth, S C; Rickus, G_E J; Amare, S Z; Giller, J P; Jian, D Z; Koskella, B (March 2024, Microbiology Spectrum)

   Zeng, Quan (Ed.)

   ABSTRACT ThePseudomonas syringaespecies complex is a heterogeneous group of plant pathogenic bacteria associated with a wide distribution of plant species. Advances in genomics are revealing the complex evolutionary history of this species complex and the wide array of genetic adaptations underpinning their diverse lifestyles. Here, we genomically characterize twoP. syringaeisolates collected from diseased Callery pears (Pyrus calleryana) in Berkeley, California in 2019 and 2022. We also isolated a lytic bacteriophage, which we characterized and evaluated for biocontrol efficiency. Using a multilocus sequence analysis and core genome alignment, we classified theP. syringaeisolates as members of phylogroup 2, related to other strains previously isolated fromPyrusandPrunus. An analysis of effector proteins demonstrated an evolutionary conservation of effectoromes across isolates classified in PG2 and yet uncovered unique effector profiles for each, including the two newly identified isolates. Whole-genome sequencing of the associated phage uncovered a novel phage genus related toPseudomonas syringaepv.actinidiaephage PHB09 and theFlaumdravirusgenus. Finally, usingin plantainfection assays, we demonstrate that the phage was equally useful in symptom mitigation of immature pear fruit regardless of the Pss strain tested. Overall, this study demonstrates the diversity ofP. syringaeand their viruses associated with ornamental pear trees, posing spill-over risks to commercial pear trees and the possibility of using phages as biocontrol agents to reduce the impact of disease.IMPORTANCEGlobal change exacerbates the spread and impact of pathogens, especially in agricultural settings. There is a clear need to better monitor the spread and diversity of plant pathogens, including in potential spillover hosts, and for the development of novel and sustainable control strategies. In this study, we characterize the first described strains ofPseudomonas syringaepv.syringaeisolated from Callery pear in Berkeley, California from diseased tissues in an urban environment. We show that these strains have divergent virulence profiles from previously described strains and that they can cause disease in commercial pears. Additionally, we describe a novel bacteriophage that is associated with these strains and explore its potential to act as a biocontrol agent. Together, the data presented here demonstrate that ornamental pear trees harbor novelP. syringaepv.syringaeisolates that potentially pose a risk to local fruit production, or vice versa—but also provide us with novel associated phages, effective in disease mitigation. 

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4. Silica Nanoparticle Dissolution Rate Controls the Suppression of Fusarium Wilt of Watermelon ( Citrullus lanatus )

   https://doi.org/10.1021/acs.est.0c07126  

   Kang, Hyunho; Elmer, Wade; Shen, Yu; Zuverza-Mena, Nubia; Ma, Chuanxin; Botella, Pablo; White, Jason C.; Haynes, Christy L. (January 2021, Environmental Science & Technology)

   null (Ed.)

   Projected population increases over the next 30 years have elevated the need to develop novel agricultural technologies to dramatically increase crop yield, particularly under conditions of high pathogen pressure. In this study, silica nanoparticles (NPs) with tunable dissolution rates were synthesized and applied to watermelon (Citrullus lanatus) to enhance plant growth while mitigating development of the Fusarium wilt disease caused by Fusarium oxysporum f. sp. niveum. The hydrolysis rates of the silica particles were controlled by the degree of condensation or the catalytic activity of aminosilane. The results demonstrate that the plants treated with fast dissolving NPs maintained or increased biomass whereas the particle-free plants had a 34% decrease in biomass. Further, higher silicon concentrations were measured in root parts when the plants were treated with fast dissolving NPs, indicating effective silicic acid delivery. In a follow-up field study over 2.5 months, the fast dissolving NP treatment enhanced fruit yield by 81.5% in comparison to untreated plants. These findings indicate that the colloidal behavior of designed nanoparticles can be critical to nanoparticle-plant interactions, leading to disease suppression and plant health as part of a novel strategy for nanoenabled agriculture. 

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5. Rewiring photosynthesis: a photosystem I-hydrogenase chimera that makes H ₂ in vivo

   https://doi.org/10.1039/c9ee03859k  

   Kanygin, Andrey; Milrad, Yuval; Thummala, Chandrasekhar; Reifschneider, Kiera; Baker, Patricia; Marco, Pini; Yacoby, Iftach; Redding, Kevin E. (January 2020, Energy & Environmental Science)

   Harnessing the power of photosynthesis to catalyze novel light-driven redox chemistry requires a way to intercept electron flow directly from the photosynthetic electron transport chain (PETC). As a proof of concept, an in vivo fusion of photosystem I (PSI) and algal hydrogenase was created by insertion of the HydA sequence into the PsaC subunit. The PSI and hydrogenase portions are co-assembled and active in vivo , effectively creating a new photosystem. Cells expressing only the PSI-hydrogenase chimera make hydrogen at high rates in a light-dependent fashion for several days. In these engineered cells, photosynthetic electron flow is directed away from CO 2 fixation and towards proton reduction, demonstrating the possibility of driving novel redox chemistries using electrons from water splitting and the photosynthetic electron transport chain. 

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