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1. Reference Genome for the Highly Transformable Setaria viridis ME034V

   https://doi.org/10.1534/g3.120.401345  

   Thielen, Peter M; Pendleton, Amanda L; Player, Robert A; Bowden, Kenneth V; Lawton, Thomas J; Wisecaver, Jennifer H (October 2020, G3 Genes|Genomes|Genetics)

   null (Ed.)

   Abstract Setaria viridis (green foxtail) is an important model system for improving cereal crops due to its diploid genome, ease of cultivation, and use of C4 photosynthesis. The S. viridis accession ME034V is exceptionally transformable, but the lack of a sequenced genome for this accession has limited its utility. We present a 397 Mb highly contiguous de novo assembly of ME034V using ultra-long nanopore sequencing technology (read N50 = 41kb). We estimate that this genome is largely complete based on our updated k-mer based genome size estimate of 401 Mb for S. viridis. Genome annotation identified 37,908 protein-coding genes and >300k repetitive elements comprising 46% of the genome. We compared the ME034V assembly with two other previously sequenced Setaria genomes as well as to a diversity panel of 235 S. viridis accessions. We found the genome assemblies to be largely syntenic, but numerous unique polymorphic structural variants were discovered. Several ME034V deletions may be associated with recent retrotransposition of copia and gypsy LTR repeat families, as evidenced by their low genotype frequencies in the sampled population. Lastly, we performed a phylogenomic analysis to identify gene families that have expanded in Setaria, including those involved in specialized metabolism and plant defense response. The high continuity of the ME034V genome assembly validates the utility of ultra-long DNA sequencing to improve genetic resources for emerging model organisms. Structural variation present in Setaria illustrates the importance of obtaining the proper genome reference for genetic experiments. Thus, we anticipate that the ME034V genome will be of significant utility for the Setaria research community. 

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2. Reductive evolution and genomic reduction in Rhodopseudomonas

   https://doi.org/10.1128/aem.00445-25  

   Gallagher, Brian M; Morrison, Hailee M; Bose, Arpita (August 2025, Applied and Environmental Microbiology)

   Reguera, Gemma (Ed.)

   ABSTRACT Rhodopseudomonas palustrisis renowned for its metabolic versatility, supported by a genome that contains pathways for numerous processes. In a recent study, Oda et al. (Appl Environ Microbiol 91:e02056-24, 2025,https://doi.org/10.1128/aem.02056-24) examineR. palustrisDSM127, a strain with a dramatically reduced gene inventory, to study how environmental pressures have influenced gene loss. Missing more than a quarter of its genome reduces its versatility. However, it may improve its efficiency under the conditions in which it still thrives, enhancing its aptitude as a chassis for biotechnology. 

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3. Complete genome sequence of the Gordonia bacteriophage BiggityBass

   https://doi.org/10.1128/mra.00469-22  

   Versoza, Cyril J.; Howell, Abigail A.; Aftab, Tanya; Blanco, Madison; Brar, Akarshi; Chaffee, Elaine; Howell, Nicholas; Leach, Willow; Lobatos, Jackelyn; Luca, Michael; et al (September 2022, Microbiology Resource Announcements)

   Dennehy, John J. (Ed.)

   Here, we characterized the complete genome of the Siphoviridae BiggityBass, a lytic subcluster DR bacteriophage infecting Gordonia terrae CAG3. Its 63.2-kb genome contains 84 protein-coding genes, of which 40 could be assigned a putative function. BiggityBass is related most closely to AnClar and Yago84 with 90.61% and 90.52% nucleotide identity, respectively. 

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4. CRISPR‐Cas9 Genome Editing in the Moss Physcomitrium (Formerly Physcomitrella ) patens

   https://doi.org/10.1002/cpz1.725  

   Wu, Shu‐Zon; Ryken, Samantha E.; Bezanilla, Magdalena (April 2023, Current Protocols)

   Abstract Until recently, precise genome editing has been limited to a few organisms. The ability of Cas9 to generate double stranded DNA breaks at specific genomic sites has greatly expanded molecular toolkits in many organisms and cell types. Before CRISPR‐Cas9 mediated genome editing,P. patenswas unique among plants in its ability to integrate DNA via homologous recombination. However, selection for homologous recombination events was required to obtain edited plants, limiting the types of editing that were possible. Now with CRISPR‐Cas9, molecular manipulations inP. patenshave greatly expanded. This protocol describes a method to generate a variety of different genome edits. The protocol describes a streamlined method to generate the Cas9/sgRNA expression constructs, design homology templates, transform, and quickly genotype plants. © 2023 Wiley Periodicals LLC. Basic Protocol 1: Constructing the Cas9/sgRNA transient expression vector Alternate Protocol 1: Shortcut to generating single and pooled Cas9/sgRNA expression vectors Basic Protocol 2: Designing the oligonucleotide‐based homology‐directed repair (HDR) template Alternate Protocol 2: Designing the plasmid‐based HDR template Basic Protocol 3: Inducing genome editing by transforming CRISPR vector intoP. patensprotoplasts Basic Protocol 4: Identifying edited plants. 

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5. Complete Genome Sequence of the Microbacterium Bacteriophage Chako

   https://doi.org/10.1128/mra.01251-22  

   Milhaven, Mark; Cai, Lindsey; Cherian, Sanjana; Johnson, Kamalei; Salas Perez, Kevin; Blanco, Madison; Garg, Aman; Lobatos, Jackelyn; Mitra, Corinne; Strasser, Maria; et al (January 2023, Microbiology Resource Announcements)

   Roux, Simon (Ed.)

   ABSTRACT We characterized the complete genome sequence of Chako, an obligate lytic bacteriophage with siphovirus morphology from subcluster EA1 that infects Microbacterium foliorum NRRL B-24224. Its 41.6-kb genome contains 62 putative protein-coding genes and is highly similar to that of bacteriophage HanSolo (99.26% nucleotide identity). 

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