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1. A CRISPRi-dCas9 System for Archaea and Its Use To Examine Gene Function during Nitrogen Fixation by Methanosarcina acetivorans

   https://doi.org/10.1128/AEM.01402-20  

   Dhamad, Ahmed E.; Lessner, Daniel J. (October 2020, Applied and Environmental Microbiology)

   Atomi, Haruyuki (Ed.)

   ABSTRACT CRISPR-based systems are emerging as the premier method to manipulate many cellular processes. In this study, a simple and efficient CRISPR interference (CRISPRi) system for targeted gene repression in archaea was developed. The Methanosarcina acetivorans CRISPR-Cas9 system was repurposed by replacing Cas9 with the catalytically dead Cas9 (dCas9) to generate a CRISPRi-dCas9 system for targeted gene repression. To test the utility of the system, genes involved in nitrogen (N 2 ) fixation were targeted for dCas9-mediated repression. First, the nif operon ( nifHI 1 I 2 DKEN ) that encodes molybdenum nitrogenase was targeted by separate guide RNAs (gRNAs), one targeting the promoter and the other targeting nifD . Remarkably, growth of M. acetivorans with N 2 was abolished by dCas9-mediated repression of the nif operon with each gRNA. The abundance of nif transcripts was >90% reduced in both strains expressing the gRNAs, and NifD was not detected in cell lysate. Next, we targeted NifB, which is required for nitrogenase cofactor biogenesis. Expression of a gRNA targeting the coding sequence of NifB decreased nifB transcript abundance >85% and impaired but did not abolish growth of M. acetivorans with N 2 . Finally, to ascertain the ability to study gene regulation using CRISPRi-dCas9, nrpR1 , encoding a subunit of the repressor of the nif operon, was targeted. The nrpR1 repression strain grew normally with N 2 but had increased nif operon transcript abundance, consistent with NrpR1 acting as a repressor. These results highlight the utility of the system, whereby a single gRNA when expressed with dCas9 can block transcription of targeted genes and operons in M. acetivorans . IMPORTANCE Genetic tools are needed to understand and manipulate the biology of archaea, which serve critical roles in the biosphere. Methanogenic archaea (methanogens) are essential for the biological production of methane, an intermediate in the global carbon cycle, an important greenhouse gas, and a biofuel. The CRISPRi-dCas9 system in the model methanogen Methanosarcina acetivorans is, to our knowledge, the first Cas9-based CRISPR interference system in archaea. Results demonstrate that the system is remarkably efficient in targeted gene repression and provide new insight into nitrogen fixation by methanogens, the only archaea with nitrogenase. Overall, the CRISPRi-dCas9 system provides a simple, yet powerful, genetic tool to control the expression of target genes and operons in methanogens. 

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2. dCas9 regulator to neutralize competition in CRISPRi circuits

   https://doi.org/10.1038/s41467-021-21772-6  

   Huang, Hsin-Ho; Bellato, Massimo; Qian, Yili; Cárdenas, Pablo; Pasotti, Lorenzo; Magni, Paolo; Del Vecchio, Domitilla (March 2021, Nature Communications)

   Abstract CRISPRi-mediated gene regulation allows simultaneous control of many genes. However, highly specific sgRNA-promoter binding is, alone, insufficient to achieve independent transcriptional regulation of multiple targets. Indeed, due to competition for dCas9, the repression ability of one sgRNA changes significantly when another sgRNA becomes expressed. To solve this problem and decouple sgRNA-mediated regulatory paths, we create a dCas9 concentration regulator that implements negative feedback on dCas9 level. This allows any sgRNA to maintain an approximately constant dose-response curve, independent of other sgRNAs. We demonstrate the regulator performance on both single-stage and layered CRISPRi-based genetic circuits, zeroing competition effects of up to 15-fold changes in circuit I/O response encountered without the dCas9 regulator. The dCas9 regulator decouples sgRNA-mediated regulatory paths, enabling concurrent and independent regulation of multiple genes. This allows predictable composition of CRISPRi-based genetic modules, which is essential in the design of larger scale synthetic genetic circuits. 

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3. Global and gene-specific translational regulation in Escherichia coli across different conditions

   https://doi.org/10.1371/journal.pcbi.1010641  

   Di Zhang, Sophia Hsin-Jung (October 2022, PLOS computational biology)

   How well mRNA transcript levels represent protein abundances has been a controversial issue. Particularly across different environments, correlations between mRNA and protein exhibit remarkable variability from gene to gene. Translational regulation is likely to be one of the key factors contributing to mismatches between mRNA level and protein abundance in bacteria. Here, we quantified genome-wide transcriptome and relative translation efficiency (RTE) under 12 different conditions in Escherichia coli. By quantifying the mRNA-RTE correlation both across genes and across conditions, we uncovered a diversity of gene-specific translational regulations, cooperating with transcriptional regulations, in response to carbon (C), nitrogen (N), and phosphate (P) limitations. Intriguingly, we found that many genes regulating translation are themselves subject to translational regulation, suggesting possible feedbacks. Furthermore, a random forest model suggests that codon usage partially predicts a gene’s cross-condition variability in translation efficiency; such cross-condition variability tends to be an inherent quality of a gene, independent of the specific nutrient limitations. These findings broaden the understanding of translational regulation under different environments and provide novel strategies for the control of translation in synthetic biology. In addition, our data offers a resource for future multi-omics studies. 

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4. Discovering regulators in post transcriptional control of the biological clock of Neurospora crassa using Variable Topology Ensemble Methods on GPUs

   https://doi.org/10.1109/ACCESS.2018.2871876  

   Al-Omari, A.; Griffith, J.; Caranica, C.; Taha, T.; Schuttler, H.-B.; Arnold, J. (October 2018, IEEE access)

   In previous work we reconstructed the entire transcriptional network for all 2,418 clock-associated genes in the model filamentous fungus, N. crassa. Several authors have suggested that there is extensive post-transcriptional control in the genome-wide clock network (IEEE 3: 27, 2015). Here we have successfully reconstructed the entire clock network in N. crassa with a Variable Topology Ensemble Method (VTENS), assigning each clock-associated gene to the regulation of one or more of 5 transcription factors as well as to 6 RNA operons. The resulting network provides a unifying framework to explore the clock’s linkage to metabolism through post-transcriptional regulation, in which ~850 genes are predicted to fall under the regulatory control of an RNA operon. A unique feature of all of the RNA operons inferred is their functional connection to genes connected to the ribosome. We have been successful in distinguishing several hypotheses about regulatory topologies of the clock network through protein profiling of the regulators. 

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5. Improved Super-Resolution Ribosome Profiling Reveals Prevalent Translation of Upstream ORFs and Small ORFs in Arabidopsis

   https://doi.org/10.1093/plcell/koad290  

   Wu, Hsin-Yen Larry; Ai, Qiaoyun; Teixeira, Rita Teresa; Nguyen, Phong H; Song, Gaoyuan; Montes, Christian; Elmore, J Mitch; Walley, Justin W; Hsu, Polly Yingshan (November 2023, The Plant Cell)

   Abstract A crucial step in functional genomics is identifying actively translated open reading frames (ORFs) and linking them to biological functions. The challenge lies in identifying short ORFs, as their identification is greatly influenced by data quality and depth. Here, we improved the coverage of super-resolution Ribo-seq in Arabidopsis (Arabidopsis thaliana), revealing uncharacterized translation events for nuclear, chloroplastic, and mitochondrial genes. Assisted by a transcriptome assembly, we identified 7,751 unconventional translation events, comprising 6,996 upstream ORFs (uORFs) and 209 downstream ORFs on annotated protein-coding genes, as well as 546 ORFs in presumed non-coding RNAs. Proteomics data confirmed the production of stable proteins from some of these unannotated translation events. We present evidence of active translation from primary transcripts of tasiRNAs (TAS1–4) and microRNAs (pri-MIR163, pri-MIR169), and periodic ribosome stalling supporting co-translational decay. Additionally, we developed a method for identifying extremely short uORFs, including 370 minimum uORFs (AUG-stop), and 2,921 tiny uORFs (2–10 amino acids), and 681 uORFs that overlap with each other. Remarkably, these short uORFs exhibit strong translational repression as do longer uORFs. We also systematically discovered 594 uORFs regulated by alternative splicing, suggesting widespread isoform-specific translational control. Finally, these prevalent uORFs are associated with numerous important pathways. In summary, our improved Arabidopsis translational landscape provides valuable resources to study gene expression regulation. 

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