Towards understanding RNA structure in vivo: studies on ribosomal structure and dynamics

RNA molecules play essential roles in diverse cellular functions. Most of these functions depend on the ability of the RNA to fold into a stable structure. In the cell, endogenous RNAs likely adopt many intermediate structures before the final functional structure is formed. These structural changes occur in an environment very different from that of most in vitro explorations of RNA structure-function relationships. For example, the ribosome is a dynamic ribonucleoprotein responsible for synthesizing all the proteins in cells. Ribosomal RNA (rRNA) has been implicated in plying a crucial role in the structural, catalytic, and dynamic aspects of translation. Therefore, it is critical to be able to directly probe RNA structure in its native environment, the cell. RNA SHAPE technology provides accurate and quantitative RNA structure information and is ideal to being adapted to in vivo conditions. In this work I first investigate the mechanism of SHAPE so that we have a better understanding of this important technology. I then show that SHAPE technology can be used to probe RNA structure in vivo. I then use this new technology to obtain structural information for over 1400 16S nucleotides in many conformational states of the 16S rRNA in vivo. In many regions, the in vivo SHAPE chemistry is exactly consistent with in vitro RNA structure studies. However, in several key areas, the in vivo rRNA structure differs from that of its in vitro counterpart. Local, but highly significant, rearrangements in the RNA secondary structure thus appear to contribute to ribosome function in vivo. As further evidence that investigating RNA structure in vivo is necessary for our fundamental understanding of biology, I use in vivo SHAPE to identify a novel secondary mode of action for an antibiotic. This work illustrates that a full understanding of dynamic RNA structure at nucleotide resolution will be critical for complete understanding of RNA function in vivo.Doctor of Philosoph

The Cellular Environment Stabilizes Adenine Riboswitch RNA Structure

There are large differences between the intracellular environment and the conditions widely used to study RNA structure and function in vitro. To assess the effects of the crowded cellular environment on RNA, we examined the structure and ligand-binding function of the adenine riboswitch aptamer domain in healthy, growing Escherichia coli cells at single-nucleotide resolution on the minute timescale using SHAPE. The ligand-bound aptamer structure is essentially the same in cells and in buffer at 1 mM Mg2+, the approximate Mg2+ concentration we measured in cells. In contrast, the in-cell conformation of the ligand-free aptamer is much more similar to the fully folded ligand-bound state. Even adding high Mg2+ concentrations to the buffer used for in vitro analyses did not yield the conformation observed for the free aptamer in cells. The cellular environment thus stabilizes the aptamer significantly more than does Mg2+ alone. Our results show that the intracellular environment has a large effect on RNA structure that ultimately favors highly organized conformations

Ribosome RNA Assembly Intermediates Visualized in Living Cells

In cells, RNAs likely adopt numerous intermediate conformations prior to formation of functional RNA-protein complexes. We used single-nucleotide resolution selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) to probe the structure of Escherichia coli 16S rRNA in healthy growing bacteria. SHAPE-directed modeling indicated that the predominant steady-state RNA conformational ensemble in dividing cells had a base-paired structure different from that expected on the basis of comparative sequence analysis and high-resolution studies of the 30S ribosomal subunit. We identified the major cause of these differences by stopping ongoing in-cell transcription (in essence, an in-cell RNA structure pulse-chase experiment) which caused the RNA to chase into a structure that closely resembled the expected one. Most helices that formed alternate RNA conformations under growth conditions interact directly with tertiary-binding ribosomal proteins and form a C-shape that surrounds the mRNA channel and decoding site. These in-cell experiments lead to a model in which ribosome assembly factors function as molecular struts to preorganize this intermediate and emphasize that the final stages of ribonucleoprotein assembly involve extensive protein-facilitated RNA conformational changes

High-Throughput SHAPE and Hydroxyl Radical Analysis of RNA Structure and Ribonucleoprotein Assembly

RNA folds to form complex structures vital to many cellular functions. Proteins facilitate RNA folding at both the secondary and tertiary structure levels. An absolute prerequisite for understanding RNA folding and ribonucleoprotein (RNP) assembly reactions is a complete understanding of the RNA structure at each stage of the folding or assembly process. Here we provide a guide for comprehensive and high-throughput analysis of RNA secondary and tertiary structure using SHAPE and hydroxyl radical footprinting. As an example of the strong and sometimes surprising conclusions that can emerge from high-throughput analysis of RNA folding and RNP assembly, we summarize the structure of the bI3 group I intron RNA in four distinct states. Dramatic structural rearrangements occur in both secondary and tertiary structure as the RNA folds from the free state to the active, six-component, RNP complex. As high-throughput and high-resolution approaches are applied broadly to large protein-RNA complexes, other proteins previously viewed as making simple contributions to RNA folding are also likely to be found to exert multifaceted, long-range, cooperative, and nonadditive effects on RNA folding. These protein-induced contributions add another level of control, and potential regulatory function, in RNP complexes

The Mechanisms of RNA SHAPE Chemistry

The biological functions of RNA are ultimately governed by the local environment at each nucleotide. Selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE) chemistry is a powerful approach for measuring nucleotide structure and dynamics in diverse biological environments. SHAPE reagents acylate the 2′-hydroxyl group at flexible nucleotides because unconstrained nucleotides preferentially sample rare conformations that enhance the nucleophilicity of the 2′-hydroxyl. The critical corollary is that some constrained nucleotides must be poised for efficient reaction at the 2′-hydroxyl group. To identify such nucleotides, we performed SHAPE on intact crystals of the E. coli ribosome, monitored the reactivity of 1490 nucleotides in 16S ribosomal RNA, and examined those nucleotides that were hyper-reactive towards SHAPE and had well-defined crystallographic conformations. Analysis of these conformations revealed that 2′-hydroxyl reactivity is broadly facilitated by general base catalysis involving multiple RNA functional groups and by two specific orientations of the bridging 3′-phosphate group. Nucleotide analog studies confirmed the contributions of these mechanisms to SHAPE reactivity. These results provide a strong mechanistic explanation for the relationship between SHAPE reactivity and local RNA dynamics and will facilitate interpretation of SHAPE information in the many technologies that make use of this chemistry

In-cell SHAPE reveals that free 30S ribosome subunits are in the inactive state

It has been known for decades that purified small subunits of the ribosome can interconvert between active and inactive conformations in experiments performed under simplified conditions, but the physiological relevance of this switch has remained unclear. We probed the structure of ribosomal RNA in healthy living cells and discovered that stably assembled 30S subunits exist predominantly in the inactive conformation, with structural differences localized in the functionally important decoding region. Disrupting the ability to interconvert between active and inactive conformations compromised translation in cells. In-cell RNA structure probing supports a model in which “inactive” 30S subunits comprise an abundant in-cell state that regulates ribosome function

First-Year Spectroscopy for the SDSS-II Supernova Survey

This paper presents spectroscopy of supernovae discovered in the first season of the Sloan Digital Sky Survey-II Supernova Survey. This program searches for and measures multi-band light curves of supernovae in the redshift range z = 0.05 - 0.4, complementing existing surveys at lower and higher redshifts. Our goal is to better characterize the supernova population, with a particular focus on SNe Ia, improving their utility as cosmological distance indicators and as probes of dark energy. Our supernova spectroscopy program features rapid-response observations using telescopes of a range of apertures, and provides confirmation of the supernova and host-galaxy types as well as precise redshifts. We describe here the target identification and prioritization, data reduction, redshift measurement, and classification of 129 SNe Ia, 16 spectroscopically probable SNe Ia, 7 SNe Ib/c, and 11 SNe II from the first season. We also describe our efforts to measure and remove the substantial host galaxy contamination existing in the majority of our SN spectra.Comment: Accepted for publication in The Astronomical Journal(47pages, 9 figures

Alkenone producers inferred from well-preserved 18S rDNA in Greenland lake sediments

Author Posting. © American Geophysical Union, 2006. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research 111 (2006): G03013, doi:10.1029/2005JG000121.The 18S ribosomal DNA (rDNA) sequences of haptophyte algae were successfully amplified using the polymerase chain reaction (PCR) from water filtrate, surface sediments, and a late-Holocene sediment sample (∼1000 years old) from a group of lakes in the Søndre Strømfjord region of west Greenland. The DNA of the algal primary producer is extremely well preserved in the laminated lake sediments which have been deposited in cold (1°–2°C), anoxic, and sulphidic bottom water. Phylogenetic analyses of the Greenland haptophyte rDNA sequences suggest that alkenones in the Greenland lake sediments are produced by haptophyte algae of the class Prymnesiophyceae. The 18S rDNA sequences from the Greenland samples cluster within a distinct phylotype, differing from both marine haptophytes and from those reported previously from Ace Lake, Antarctica. The similarity of haptophyte rDNA sequences among all samples in this study suggests a single alkenone-based temperature calibration may be applied to these lakes for at least the past 1000 years. These sedimentary archives hold great promise for high-resolution, alkenone-based paleotemperature reconstruction of southern west Greenland, a region sensitive to atmospheric-oceanic climate phenomena such as the North Atlantic Oscillation (NAO).This work was supported by grants from the National Science Foundation (NSF0081478, 0318050, 0318123, 0402383, 0520718), NASA (NAG5-10665, NNG04GJ34G) and the American Chemical Society, Petroleum Research Fund (ACS-PRF38878-AC2) to Y. Huang

A Novel Snf2 Protein Maintains trans-Generational Regulatory States Established by Paramutation in Maize

Paramutations represent heritable epigenetic alterations that cause departures from Mendelian inheritance. While the mechanism responsible is largely unknown, recent results in both mouse and maize suggest paramutations are correlated with RNA molecules capable of affecting changes in gene expression patterns. In maize, multiple required to maintain repression (rmr) loci stabilize these paramutant states. Here we show rmr1 encodes a novel Snf2 protein that affects both small RNA accumulation and cytosine methylation of a proximal transposon fragment at the Pl1-Rhoades allele. However, these cytosine methylation differences do not define the various epigenetic states associated with paramutations. Pedigree analyses also show RMR1 does not mediate the allelic interactions that typically establish paramutations. Strikingly, our mutant analyses show that Pl1-Rhoades RNA transcript levels are altered independently of transcription rates, implicating a post-transcriptional level of RMR1 action. These results suggest the RNA component of maize paramutation maintains small heterochromatic-like domains that can affect, via the activity of a Snf2 protein, the stability of nascent transcripts from adjacent genes by way of a cotranscriptional repression process. These findings highlight a mechanism by which alleles of endogenous loci can acquire novel expression patterns that are meiotically transmissible

Hospital Readmissions Among Persons With Human Immunodeficiency Virus in the United States and Canada, 2005–2018: A Collaboration of Cohort Studies

BackgroundHospital readmission trends for persons with human immunodeficiency virus (PWH) in North America in the context of policy changes, improved antiretroviral therapy (ART), and aging are not well-known. We examined readmissions during 2005-2018 among adult PWH in NA-ACCORD.MethodsLinear risk regression estimated calendar trends in 30-day readmissions, adjusted for demographics, CD4 count, AIDS history, virologic suppression (<400 copies/mL), and cohort.ResultsWe examined 20 189 hospitalizations among 8823 PWH (73% cisgender men, 38% White, 38% Black). PWH hospitalized in 2018 versus 2005 had higher median age (54 vs 44 years), CD4 count (469 vs 274 cells/μL), and virologic suppression (83% vs 49%). Unadjusted 30-day readmissions decreased from 20.1% (95% confidence interval [CI], 17.9%-22.3%) in 2005 to 16.3% (95% CI, 14.1%-18.5%) in 2018. Absolute annual trends were -0.34% (95% CI, -.48% to -.19%) in unadjusted and -0.19% (95% CI, -.35% to -.02%) in adjusted analyses. By index hospitalization reason, there were significant adjusted decreases only for cardiovascular and psychiatric hospitalizations. Readmission reason was most frequently in the same diagnostic category as the index hospitalization.ConclusionsReadmissions decreased over 2005-2018 but remained higher than the general population's. Significant decreases after adjusting for CD4 count and virologic suppression suggest that factors alongside improved ART contributed to lower readmissions. Efforts are needed to further prevent readmissions in PWH