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283 results on '"Santangelo, Thomas J."'

9. A novel N4,N4-dimethylcytidine in the archaeal ribosome enhances hyperthermophily.

Author

Fluke, Kristin A., Nan Dai, Wolf, Eric J., Fuchs, Ryan T., Shing Ho, P., Talbott, Victoria, Elkins, Liam, Yueh-Lin Tsai, Schiltz, Jackson, Febvre, Hallie P., Czarny, Ryan, Robb, G. Brett, Corrêa Jr., Ivan R., and Santangelo, Thomas J.

Subjects
RNA modification & restriction, RIBOSOMAL RNA, GENETIC translation, METHYLTRANSFERASES, RNA
Abstract

Ribosome structure and activity are challenged at high temperatures, often demanding modifications to ribosomal RNAs (rRNAs) to retain translation fidelity. LC-MS/MS, bisulfite-sequencing, and high-resolution cryo-EM structures of the archaeal ribosome identified an RNA modification, N4,N4-dimethylcytidine (m42C), at the universally conserved C918 in the 16S rRNA helix 31 loop. Here, we characterize and structurally resolve a class of RNA methyltransferase that generates m4 2C whose function is critical for hyperthermophilic growth. m42C is synthesized by the activity of a unique family of RNA methyltransferase containing a Rossman-fold that targets only intact ribosomes. The phylogenetic distribution of the newly identified m42C synthase family implies that m42C is biologically relevant in each domain. Resistance of m42C to bisulfite-driven deamination suggests that efforts to capture m5C profiles via bisulfite sequencing are also capturing m42C. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Dynamic RNA acetylation revealed by quantitative cross-evolutionary mapping

Author

Sas-Chen, Aldema, Thomas, Justin M., Matzov, Donna, Taoka, Masato, Nance, Kellie D., Nir, Ronit, Bryson, Keri M., Shachar, Ran, Liman, Geraldy L. S., Burkhart, Brett W., Gamage, Supuni Thalalla, Nobe, Yuko, Briney, Chloe A., Levy, Michaella J., Fuchs, Ryan T., Robb, G. Brett, Hartmann, Jesse, Sharma, Sunny, Lin, Qishan, Florens, Laurence, Washburn, Michael P., Isobe, Toshiaki, Santangelo, Thomas J., Shalev-Benami, Moran, Meier, Jordan L., and Schwartz, Schraga

Published
2020
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18. Structure of histone-based chromatin in Archaea

Author

Mattiroli, Francesca, Bhattacharyya, Sudipta, Dyer, Pamela N., White, Alison E., Sandman, Kathleen, Burkhart, Brett W., Byrne, Kyle R., Lee, Thomas, Ahn, Natalie G., Santangelo, Thomas J., Reeve, John N., and Luger, Karolin

Published
2017

31. Archaeal intrinsic transcription termination in vivo

Author

Santangelo, Thomas J., Cubonova, L'ubomira, Skinner, Katherine M., and Reeve, John N.

Subjects
Thermococcus -- Research, Genetic transcription -- Research, Transcription factors -- Research, Biological sciences
Abstract

Thermococcus kodakarensis (formerly Thermococcus kodakaraensis) strains have been constructed with synthetic and natural DNA sequences, predicted to function as archaeal transcription terminators, identically positioned between a constitutive promoter and a [beta]-glycosidase-encoding reporter gene (TK1761). Expression of the reporter gene was almost fully inhibited by the upstream presence of 5'-TTTTTTTT ([T.sub.8]) and was reduced >70% by archaeai intergenic sequences that contained oligo(T) sequences. An archaeal intergenic sequence ([t.sub.mcrA]) that conforms to the bacterial intrinsic terminator motif reduced TKI761 expression ~90%, but this required only the oligo(T) trail sequence and not the inverted-repeat and loop region. Template DNAs were amplified from each T. kodakarensis strain, and transcription in vitro by T. kodakarensis RNA polymerase was terminated by sequences that reduced TK1761 expression in vivo. Termination occurred at additional sites on these linear templates, including at a 5'-AAAAAAAA (As) sequence that did not reduce TK1761 expression in vivo. When these sequences were transcribed on supercoiled plasmid templates, termination occurred almost exclusively at oligo(T) sequences. The results provide the first in vivo experimental evidence for intrinsic termination of archaeal transcription and confirm that archaeal transcription termination is stimulated by oligo(T) sequences and is different from the RNA hairpin-dependent mechanism established for intrinsic bacterial termination. doi: 10.1128/JB.00982-09

Published
2009

32. Polarity in archaeal operon transcription in Thermococcus kodakaraensis

Author

Santangelo, Thomas J., Cubonova, L'ubomira, Matsumi, Rie, Atomi, Haruyuki, Imanaka, Tadayuki, and Reeve, John N.

Subjects
Hyperthermophiles -- Genetic aspects, Genetic transcription -- Research, Bacterial genetics -- Research, Operons -- Properties, Biological sciences
Abstract

An in vivo archaeal gene reporter system has been established based on TK1761, a gene that encodes a nonessential [beta]-glycosidase in Thermococcus kodakaraensis. Following the introduction of nonsense codons into promoter-proximal genes, polarity in operon expression in this archaeon has been established by both microarray hybridization assays and a reporter gene expression system.

Published
2008

33. Bacteriophage N4 virion RNA polymerase interaction with its promoter DNA hairpin

Author

Davydova, Elena K., Santangelo, Thomas J., and Rothman-Denes, Lucia B.

Subjects
Bacteriophages -- Research, Nucleotide sequence -- Research, RNA polymerases -- Research, Science and technology
Abstract

Bacteriophage N4 minivirion RNA polymerase (mini-vRNAP), the RNA polymerase (RNAP) domain of vRNAP, is a member of the T7-1ike RNAP family. Mini-vRNAP recognizes promoters that comprise conserved sequences and a 3-base loop-5-base pair (bp) stem DNA hairpin structure on single-stranded templates. Here, we defined the DNA structural and sequence requirements for mini-vRNAP promoter recognition. Mini-vBNAP binds a 20-nucleotide (nt) N4 P2 promoter deoxyoligonucleotide with high affinity ([K.sub.d] = 2 nM) to form a salt-resistant complex. We show that mini-vRNAP interacts specifically with the central base of the hairpin loop (-11G) and a base at the stem (-8G) and that the guanine 6-keto and 7-imino groups at both positions are essential for binding and complex salt resistance. The major determinant (-11G), which must be presented to mini-vRNAP in the context of a hairpin loop, appears to interact with mini-vRNAP Trp-129. This interaction requires template single-strandedness at positions -2 and -1. Contacts with the promoter are disrupted when the RNA product becomes 11-12 nt long. This detailed description of vRNAP interaction with its promoter hairpin provides insights into RNAP-promoter interactions and explains how the injected vRNAP, which is present in one or two copies, recognizes its promoters on a single copy of the injected genome. T7-like RNA polymerase

Published
2007

38. Cyclic AMP receptor protein and RhaR synergistically activate transcription from the L-rhamnose-responsive rhaSR promoter in Escherichia coli

Author

Wickstrum, Jason R., Santangelo, Thomas J., and Egan, Susan M.

Subjects
Escherichia coli -- Genetic aspects, Gene expression -- Research, Bacterial proteins -- Research, Genetic research, Biological sciences
Abstract

The Escherichia coli rhaSR operon encodes two AraC family transcription activator proteins, RhaS and RhaR, which regulate expression of the L-rhamnose catabolic regulon in response to L-rhamnose availability. RhaR positively regulates rhaSR in response to L-rhamnose, and RhaR activation can be enhanced by the cyclic AMP (cAMP) receptor protein (CRP) protein. CRP is a well-studied global transcription regulator that binds to DNA as a dimer and activates transcription in the presence of cAMP. We investigated the mechanism of CRP activation at rhaSR both alone and in combination with RhaR in vivo and in vitro. Base pair substitutions at potential CRP binding sites in the rhaSR-rhaBAD intergenic region demonstrate that CRP site 3, centered at position -111.5 relative to the rhaSR transcription start site, is required for the majority of the CRP-dependent activation of rhaSR. DNase I footprinting confirms that CRP binds to site 3; CRP binding to the other potential CRP sites at rhaSR was not detected. We show that, at least in vitro, CRP is capable of both RhaR-dependent and RhaR-independent activation of rhaSR from a total of three transcription start sites. In vitro transcription assays indicate that the carboxy-terminal domain of the alpha subunit ([alpha]-CTD) of RNA polymerase is at least partially dispensable for RhaR-dependent activation but that the [alpha]-CTD is required for CRP activation of rhaSR. Although CRP requires the presence of RhaR for efficient in vivo activation of rhaSR, DNase I footprinting assays indicated that cooperative binding between RhaR and CRP does not make a significant contribution to the mechanism of CRP activation at rhaSR. It therefore appears that CRP activates transcription from rhaSR as it would at simple class I promoters, albeit from a relatively distant position.

Published
2005

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