Your search keyword '"Sudarsan, Narasimhan"' showing total 9 results

1. Architectures and complex functions of tandem riboswitches

Author

Sherlock, Madeline E., Higgs, Gadareth, Yu, Diane, Widner, Danielle L., White, Neil A., Sudarsan, Narasimhan, Sadeeshkumar, Harini, Perkins, Kevin R., Mirihana Arachchilage, Gayan, Malkowski, Sarah N., King, Christopher G., Harris, Kimberly A., Gaffield, Glenn, Atilho, Ruben M., and Breaker, Ronald R.

Abstract

ABSTRACTRiboswitch architectures that involve the binding of a single ligand to a single RNA aptamer domain result in ordinary dose-response curves that require approximately a 100-fold change in ligand concentration to cover nearly the full dynamic range for gene regulation. However, by using multiple riboswitches or aptamer domains in tandem, these ligand-sensing structures can produce additional, complex gene control outcomes. In the current study, we have computationally searched for tandem riboswitch architectures in bacteria to provide a more complete understanding of the diverse biological and biochemical functions of gene control elements that are made exclusively of RNA. Numerous different arrangements of tandem homologous riboswitch architectures are exploited by bacteria to create more ‘digital’ gene control devices, which operate over a narrower ligand concentration range. Also, two heterologous riboswitch aptamers are sometimes employed to create two-input Boolean logic gates with various types of genetic outputs. These findings illustrate the sophisticated genetic decisions that can be made by using molecular sensors and switches based only on RNA.

Published

2022

2. Na+riboswitches regulate genes for diverse physiological processes in bacteria

Author

White, Neil, Sadeeshkumar, Harini, Sun, Anna, Sudarsan, Narasimhan, and Breaker, Ronald R.

Abstract

Organisms presumably have mechanisms to monitor and physiologically adapt to changes in cellular Na+concentrations. Only a single bacterial protein has previously been demonstrated to selectively sense Na+and regulate gene expression. Here we report a riboswitch class, previously called the ‘DUF1646 motif’, whose members selectively sense Na+and regulate the expression of genes relevant to sodium biology. Many proteins encoded by Na+-riboswitch-regulated genes are annotated as metal ion transporters, whereas others are involved in mitigating osmotic stress or harnessing Na+gradients for ATP production. Na+riboswitches exhibit dissociation constants in the low mM range, and strongly reject all other alkali and alkaline earth ions. Likewise, only Na+triggers riboswitch-mediated transcription and gene expression changes. These findings reveal that some bacteria use Na+riboswitches to monitor, adjust and exploit Na+concentrations and gradients, and in some instances collaborate with c-di-AMP riboswitches to coordinate gene expression during osmotic stress.

Published

2022

3. Identification of Ligand Analogues that Control c-di-GMP Riboswitches

Author

Furukawa, Kazuhiro, Gu, Hongzhou, Sudarsan, Narasimhan, Hayakawa, Yoshihiro, Hyodo, Mamoru, and Breaker, Ronald R.

Abstract

Riboswitches for the bacterial second messenger c-di-GMP control the expression of genes involved in numerous cellular processes such as virulence, competence, biofilm formation, and flagella synthesis. Therefore, the two known c-di-GMP riboswitch classes represent promising targets for developing novel modulators of bacterial physiology. Here, we examine the binding characteristics of circular and linear c-di-GMP analogues for representatives of both class I and II c-di-GMP riboswitches derived from the pathogenic bacterium Vibrio choleae(class I) and Clostridium difficile(class II). Some compounds exhibit values for apparent dissociation constant (KD) below 1 μM and associate with riboswitch RNAs during transcription with a speed that is sufficient to influence riboswitch function. These findings are consistent with the published structural models for these riboswitches and suggest that large modifications at various positions on the ligand can be made to create novel compounds that target c-di-GMP riboswitches. Moreover, we demonstrate the potential of an engineered allosteric ribozyme for the rapid screening of chemical libraries for compounds that bind c-di-GMP riboswitches.

Published

2012

4. Mechanism for gene control by a natural allosteric group I ribozyme

Author

Chen, Andy G.Y., Sudarsan, Narasimhan, and Breaker, Ronald R.

Abstract

An allosteric ribozyme consisting of a metabolite-sensing riboswitch and a group I self-splicing ribozyme was recently found in the pathogenic bacterium Clostridium difficile. The riboswitch senses the bacterial second messenger c-di-GMP, thereby controlling 5'-splice site choice by the downstream ribozyme. The proximity of this allosteric ribozyme to the open reading frame (ORF) for CD3246 suggests that coenzyme-mediated regulation of splicing controls expression of this putative virulence gene. In the presence of c-di-GMP, the allosteric ribozyme in the CD3246 precursor transcript generates a spliced transcript that retains the riboswitch aptamer. In the absence of c-di-GMP, the ribozyme mediates an alternative GTP attack that results in a truncated transcript (alternative GTP-attack product). Using reporter assays in Escherichia coli, we investigated the difference in gene expression between the spliced product and the alternative GTP-attack product. We provide evidence that CD3246 gene expression is activated if allosteric ribozyme splicing creates a ribosome binding site (RBS) for translation from a UUG start codon. In addition, biochemical and genetic analyses reveal that the riboswitch may further control CD3246 expression by revealing or occluding this newly formed RBS. Therefore, this architecture provides the riboswitch with a mechanism for extended regulation after splicing has occurred or as a backup mechanism for suppression of translation in the event of misregulated splicing.

Published

2011

5. Challenges of ligand identification for riboswitch candidates

Author

Meyer, Michelle M., Hammond, Ming C., Salinas, Yasmmyn, Roth, Adam, Sudarsan, Narasimhan, and Breaker, Ronald R.

Abstract

Expanding DNA sequence databases and improving methods for comparative analysis are being exploited to identify numerous noncoding RNA elements including riboswitches. Ligands for many riboswitch classes usually can be inferred based on the genomic contexts of representative RNAs, and complex formation or genetic regulation subsequently demonstrated experimentally. However, there are several candidate riboswitches for which ligands have not been identified. In this report, we discuss three of the most compelling riboswitch candidates: the ykkC/ykkD, yybP/ykoYand pflRNAs. Each of these RNAs is numerous, phylogenetically widespread, and carries features that are hallmarks of metabolite-binding riboswitches, such as a well-conserved aptamer-like structure and apparent interactions with gene regulation elements such as ribosome binding sites or intrinsic transcription termination stems. These RNAs likely represent only a small sampling of the challenging motifs that researchers will encounter as new noncoding RNAs are identified.

Published

2011

6. 6S RNA is a widespread regulator of eubacterial RNA polymerase that resembles an open promoter.

Author

Barrick, Jeffrey E, Sudarsan, Narasimhan, Weinberg, Zasha, Ruzzo, Walter L, and Breaker, Ronald R

Abstract

6S RNA is an abundant noncoding RNA in Escherichia coli that binds to sigma70 RNA polymerase holoenzyme to globally regulate gene expression in response to the shift from exponential growth to stationary phase. We have computationally identified >100 new 6S RNA homologs in diverse eubacterial lineages. Two abundant Bacillus subtilis RNAs of unknown function (BsrA and BsrB) and cyanobacterial 6Sa RNAs are now recognized as 6S homologs. Structural probing of E. coli 6S RNA and a B. subtilis homolog supports a common secondary structure derived from comparative sequence analysis. The conserved features of 6S RNA suggest that it binds RNA polymerase by mimicking the structure of DNA template in an open promoter complex. Interestingly, the two B. subtilis 6S RNAs are discoordinately expressed during growth, and many proteobacterial 6S RNAs could be cotranscribed with downstream homologs of the E. coli ygfA gene encoding a putative methenyltetrahydrofolate synthetase. The prevalence and robust expression of 6S RNAs emphasize their critical role in bacterial adaptation.

Published

2005

7. An mRNA structure that controls gene expression by binding S-adenosylmethionine

Author

Winkler, Wade C, Nahvi, Ali, Sudarsan, Narasimhan, Barrick, Jeffrey E, and Breaker, Ronald R

Abstract

Riboswitches are metabolite-binding RNA structures that serve as genetic control elements for certain messenger RNAs. These RNA switches have been identified in all three kingdoms of life and are typically responsible for the control of genes whose protein products are involved in the biosynthesis, transport or utilization of the target metabolite. Herein, we report that a highly conserved RNA domain found in bacteria serves as a riboswitch that responds to the coenzyme S-adenosylmethionine (SAM) with remarkably high affinity and specificity. SAM riboswitches undergo structural reorganization upon introduction of SAM, and these allosteric changes regulate the expression of 26 genes in Bacillus subtilis. This and related findings indicate that direct interaction between small metabolites and allosteric mRNAs is an important and widespread form of genetic regulation in bacteria.

Published

2003

8. A common speed limit for RNA-cleaving ribozymes and deoxyribozymes.

Author

Breaker, Ronald R, Emilsson, Gail Mitchell, Lazarev, Denis, Nakamura, Shingo, Puskarz, Izabela J, Roth, Adam, and Sudarsan, Narasimhan

Abstract

It is widely believed that the reason proteins dominate biological catalysis is because polypeptides have greater chemical complexity compared with nucleic acids, and thus should have greater enzymatic power. Consistent with this hypothesis is the fact that protein enzymes typically exhibit chemical rate enhancements that are far more substantial than those achieved by natural and engineered ribozymes. To investigate the true catalytic power of nucleic acids, we determined the kinetic characteristics of 14 classes of engineered ribozymes and deoxyribozymes that accelerate RNA cleavage by internal phosphoester transfer. Half approach a maximum rate constant of approximately 1 min(-1), whereas ribonuclease A catalyzes the same reaction approximately 80,000-fold faster. Additional biochemical analyses indicate that this commonly encountered ribozyme "speed limit" coincides with the theoretical maximum rate enhancement for an enzyme that uses only two specific catalytic strategies. These results indicate that ribozymes using additional catalytic strategies could be made that promote RNA cleavage with rate enhancements that equal those of proteins.

Published

2003

9. Metabolite-binding RNA domains are present in the genes of eukaryotes.

Author

Sudarsan, Narasimhan, Barrick, Jeffrey E, and Breaker, Ronald R

Abstract

Genetic control by metabolite-binding mRNAs is widespread in prokaryotes. These riboswitches are typically located in noncoding regions of mRNA, where they selectively bind their target compound and subsequently modulate gene expression. We have identified mRNA elements in fungi and in plants that match the consensus sequence and structure of thiamine pyrophosphate-binding domains of prokaryotes. In Arabidopsis, the consensus motif resides in the 3'-UTR of a thiamine biosynthetic gene, and the isolated RNA domain binds the corresponding coenzyme in vitro. These results suggest that metabolite-binding mRNAs are possibly involved in eukaryotic gene regulation and that some riboswitches might be representatives of an ancient form of genetic control.

Published

2003