scholarly journals Synthesis of modified nucleotide polymers by the poly(U) polymerase Cid1: Application to direct RNA sequencing on nanopores.

RNA ◽  
2021 ◽  
pp. rna.078898.121
Author(s):  
Jenny Vo ◽  
Logan Mulroney ◽  
Jen Quick-Cleveland ◽  
Miten Jain ◽  
Mark Akeson ◽  
...  
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Nucleic Acids ◽  
Rna Polymerase ◽  
Schizosaccharomyces Pombe ◽  
Rna Polymerase Ii ◽  
Rna Sequencing ◽  
Rna Molecules ◽  
Current Trace ◽  
Detection And Quantification

Understanding transcriptomes requires documenting the structures, modifications, and abundances of RNAs as well as their proximity to other molecules. The methods that make this possible depend critically on enzymes (including mutant derivatives) that act on nucleic acids for capturing and sequencing RNA. We tested two 3′ nucleotidyl transferases, Saccharomyces cerevisiae poly(A) polymerase and Schizosaccharomyces pombe Cid1, for the ability to add base and sugar modified rNTPs to free RNA 3′ ends, eventually focusing on Cid1. Although unable to polymerize ΨTP or 1meΨTP, Cid1 can use 5meUTP and 4thioUTP. Surprisingly, Cid1 can use inosine triphosphate to add poly(I) to the 3′ ends of a wide variety of RNA molecules. Most poly(A) mRNAs efficiently acquire a uniform tract of about 50 inosine residues from Cid1, whereas non-poly(A) RNAs acquire longer, more heterogeneous tails. Here we test these activities for use in direct RNA sequencing on nanopores, and find that Cid1-mediated poly(I)-tailing permits detection and quantification of both mRNAs and non-poly(A) RNAs simultaneously, as well as enabling the analysis of nascent RNAs associated with RNA polymerase II. Poly(I) produces a different current trace than poly(A), enabling recognition of native RNA 3′ end sequence lost by in vitro poly(A) addition. Addition of poly(I) by Cid1 offers a broadly useful alternative to poly(A) capture for direct RNA sequencing on nanopores.

scholarly journals Synthesis of modified nucleotide polymers by the poly(U) polymerase Cid1: Application to direct RNA sequencing on nanopores.

2021 ◽  
Author(s):  
Jenny Vo ◽  
Logan Mulroney ◽  
Jen Quick-Cleveland ◽  
Miten Jain ◽  
Mark Akeson ◽  
...  
Keyword(s):  
Nucleic Acids ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Rna Sequencing ◽  
Rna Molecules ◽  
C Elegans ◽  
Current Trace ◽  
Detection And Quantification

Understanding transcriptomes requires documenting the structures, modifications, and abundances of RNAs as well as their proximity to other molecules. The methods that make this possible depend critically on enzymes (including mutant derivatives) that act on nucleic acids for capturing and sequencing RNA. We tested two 3′ nucleotidyl transferases, S. cerevisiae poly(A) polymerase and C. elegans Cid1, for the ability to add base and sugar modified rNTPs to free RNA 3′ ends, eventually focusing on Cid1. Although unable to polymerize ΨTP or 1meΨTP, Cid1 can use 5meUTP and 4thioUTP. Surprisingly, Cid1 can use inosine triphosphate to add poly(I) to the 3′ ends of a wide variety of RNA molecules. Most poly(A) mRNAs efficiently acquire a uniform tract of about 50 inosine residues from Cid1, whereas non-poly(A) RNAs acquire longer, more heterogeneous tails. Here we test these activities for use in direct RNA sequencing on nanopores, and find that Cid1-mediated poly(I)-tailing permits detection and quantification of both mRNAs and non-poly(A) RNAs simultaneously, as well as enabling the analysis of nascent RNAs associated with RNA polymerase II. Poly(I) produces a different current trace than poly(A), enabling recognition of native RNA 3′ end sequence lost by in vitro poly(A) addition. Addition of poly(I) by Cid1 offers a broadly useful alternative to poly(A) capture for direct RNA sequencing on nanopores.

scholarly journals The Ras/PKA Signaling Pathway May Control RNA Polymerase II Elongation via the Spt4p/Spt5p Complex in Saccharomyces cerevisiae

Genetics ◽  
2003 ◽  
Vol 165 (3) ◽  
pp. 1059-1070
Author(s):  
Susie C Howard ◽  
Arelis Hester ◽  
Paul K Herman
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Cell Growth ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Signaling Pathway ◽  
Elongation Factor ◽  
Ras Signaling ◽  
Elongation Step ◽  
Rna Polymerase Ii Transcription

Abstract The Ras signaling pathway in Saccharomyces cerevisiae controls cell growth via the cAMP-dependent protein kinase, PKA. Recent work has indicated that these effects on growth are due, in part, to the regulation of activities associated with the C-terminal domain (CTD) of the largest subunit of RNA polymerase II. However, the precise target of these Ras effects has remained unknown. This study suggests that Ras/PKA activity regulates the elongation step of the RNA polymerase II transcription process. Several lines of evidence indicate that Spt5p in the Spt4p/Spt5p elongation factor is the likely target of this control. First, the growth of spt4 and spt5 mutants was found to be very sensitive to changes in Ras/PKA signaling activity. Second, mutants with elevated levels of Ras activity shared a number of specific phenotypes with spt5 mutants and vice versa. Finally, Spt5p was efficiently phosphorylated by PKA in vitro. Altogether, the data suggest that the Ras/PKA pathway might be directly targeting a component of the elongating polymerase complex and that this regulation is important for the normal control of yeast cell growth. These data point out the interesting possibility that signal transduction pathways might directly influence the elongation step of RNA polymerase II transcription.

scholarly journals Spt4 Facilitates the Movement of RNA Polymerase II through the +2 Nucleosomal Barrier

2021 ◽  
Author(s):  
Ülkü Uzun ◽  
Thomas Brown ◽  
Harry Fischl ◽  
Andrew Angel ◽  
Jane Mellor
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Elongation Factor ◽  
Nucleosome Positioning ◽  
Gene Body ◽  
Precise Position ◽  
Transcription Elongation Factor

AbstractSpt4 is a transcription elongation factor, with homologues in organisms with nucleosomes. Structural and in vitro studies implicate Spt4 in transcription through nucleosomes, yet the in vivo function of Spt4 is unclear. Here we assessed the precise position of Spt4 during transcription and the consequences of loss of Spt4 on RNA polymerase II (RNAPII) dynamics and nucleosome positioning in Saccharomyces cerevisiae. In the absence of Spt4, the spacing between gene-body nucleosomes increases and RNAPII accumulates upstream of the nucleosomal dyad, most dramatically at nucleosome +2. Spt4 associates with elongating RNAPII early in transcription and its association dynamically changes depending on nucleosome positions. Together, our data show that Spt4 regulates early elongation dynamics, participates in co-transcriptional nucleosome positioning, and promotes RNAPII movement through the gene-body nucleosomes, especially the +2 nucleosome.

RNA polymerase II subunit composition, stoichiometry, and phosphorylation

1990 ◽  
Vol 10 (5) ◽  
pp. 1915-1920 ◽  
Author(s):  
P A Kolodziej ◽  
N Woychik ◽  
S M Liao ◽  
R A Young
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Rna Synthesis ◽  
Subunit Composition ◽  
Subunit Gene ◽  
Cell Extracts ◽  
Alpha Amanitin

RNA polymerase II subunit composition, stoichiometry, and phosphorylation were investigated in Saccharomyces cerevisiae by attaching an epitope coding sequence to a well-characterized RNA polymerase II subunit gene (RPB3) and by immunoprecipitating the product of this gene with its associated polypeptides. The immunopurified enzyme catalyzed alpha-amanitin-sensitive RNA synthesis in vitro. The 10 polypeptides that immunoprecipitated were identical in size and number to those previously described for RNA polymerase II purified by conventional column chromatography. The relative stoichiometry of the subunits was deduced from knowledge of the sequence of the subunits and from the extent of labeling with [35S]methionine. Immunoprecipitation from 32P-labeled cell extracts revealed that three of the subunits, RPB1, RPB2, and RPB6, are phosphorylated in vivo. Phosphorylated and unphosphorylated forms of RPB1 could be distinguished; approximately half of the RNA polymerase II molecules contained a phosphorylated RPB1 subunit. These results more precisely define the subunit composition and phosphorylation of a eucaryotic RNA polymerase II enzyme.

scholarly journals Amplification of RNA by an RNA polymerase ribozyme

2016 ◽  
Vol 113 (35) ◽  
pp. 9786-9791 ◽  
Author(s):  
David P. Horning ◽  
Gerald F. Joyce
Keyword(s):  
Nucleic Acids ◽  
Rna Polymerase ◽  
Genetic Information ◽  
Rna World ◽  
In Vitro Evolution ◽  
Rna Molecules ◽  
Encoded Proteins ◽  
Rna Genes ◽  
Functional Rna

In all extant life, genetic information is stored in nucleic acids that are replicated by polymerase proteins. In the hypothesized RNA world, before the evolution of genetically encoded proteins, ancestral organisms contained RNA genes that were replicated by an RNA polymerase ribozyme. In an effort toward reconstructing RNA-based life in the laboratory, in vitro evolution was used to improve dramatically the activity and generality of an RNA polymerase ribozyme by selecting variants that can synthesize functional RNA molecules from an RNA template. The improved polymerase ribozyme is able to synthesize a variety of complex structured RNAs, including aptamers, ribozymes, and, in low yield, even tRNA. Furthermore, the polymerase can replicate nucleic acids, amplifying short RNA templates by more than 10,000-fold in an RNA-catalyzed form of the PCR. Thus, the two prerequisites of Darwinian life—the replication of genetic information and its conversion into functional molecules—can now be accomplished with RNA in the complete absence of proteins.

scholarly journals RNA polymerase II subunit composition, stoichiometry, and phosphorylation.

1990 ◽  
Vol 10 (5) ◽  
pp. 1915-1920 ◽  
Author(s):  
P A Kolodziej ◽  
N Woychik ◽  
S M Liao ◽  
R A Young
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Rna Synthesis ◽  
Subunit Composition ◽  
Subunit Gene ◽  
Cell Extracts ◽  
Alpha Amanitin

RNA polymerase II subunit composition, stoichiometry, and phosphorylation were investigated in Saccharomyces cerevisiae by attaching an epitope coding sequence to a well-characterized RNA polymerase II subunit gene (RPB3) and by immunoprecipitating the product of this gene with its associated polypeptides. The immunopurified enzyme catalyzed alpha-amanitin-sensitive RNA synthesis in vitro. The 10 polypeptides that immunoprecipitated were identical in size and number to those previously described for RNA polymerase II purified by conventional column chromatography. The relative stoichiometry of the subunits was deduced from knowledge of the sequence of the subunits and from the extent of labeling with [35S]methionine. Immunoprecipitation from 32P-labeled cell extracts revealed that three of the subunits, RPB1, RPB2, and RPB6, are phosphorylated in vivo. Phosphorylated and unphosphorylated forms of RPB1 could be distinguished; approximately half of the RNA polymerase II molecules contained a phosphorylated RPB1 subunit. These results more precisely define the subunit composition and phosphorylation of a eucaryotic RNA polymerase II enzyme.

scholarly journals Identification of a Saccharomyces cerevisiae DNA-binding protein involved in transcriptional regulation.

1990 ◽  
Vol 10 (4) ◽  
pp. 1743-1753 ◽  
Author(s):  
H Wang ◽  
P R Nicholson ◽  
D J Stillman
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Dna Binding ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Binding Protein ◽  
Dna Binding Protein ◽  
Rrna Gene ◽  
Yeast Saccharomyces Cerevisiae ◽  
Yeast Genes

A DNA-binding protein has been identified from extracts of the budding yeast Saccharomyces cerevisiae which binds to sites present in the promoter regions of a number of yeast genes transcribed by RNA polymerase II, including SIN3 (also known as SDI1), SWI5, CDC9, and TOP1. This protein also binds to a site present in the enhancer for the 35S rRNA gene, which is transcribed by RNA polymerase I, and appears to be identical to the previously described REB1 protein (B. E. Morrow, S. P. Johnson, and J. R. Warner, J. Biol. Chem. 264:9061-9068, 1989). When oligonucleotides containing a REB1-binding site are placed between the CYC1 upstream activating sequence and TATA box, transcription by RNA polymerase II in vivo is substantially reduced, suggesting that REB1 acts as a repressor of RNA polymerase II transcription. The in vitro levels of the REB1 DNA-binding activity are reduced in extracts prepared from strains bearing a mutation in the SIN3 gene. A greater reduction in REB1 activity is observed if the sin3 mutant strain is grown in media containing galactose as a carbon source.

scholarly journals Isolation and characterization of temperature-sensitive RNA polymerase II mutants of Saccharomyces cerevisiae.

1987 ◽  
Vol 7 (6) ◽  
pp. 2155-2164 ◽  
Author(s):  
H J Himmelfarb ◽  
E M Simpson ◽  
J D Friesen
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Temperature Sensitive ◽  
Isolation And Characterization ◽  
Type Gene ◽  
Rnap Ii ◽  
Cloned Gene

Three independent, recessive, temperature-sensitive (Ts-) conditional lethal mutations in the largest subunit of Saccharomyces cerevisiae RNA polymerase II (RNAP II) have been isolated after replacement of a portion of the wild-type gene (RPO21) by a mutagenized fragment of the cloned gene. Measurements of cell growth, viability, and total RNA and protein synthesis showed that rpo21-1, rpo21-2, and rpo21-3 mutations caused a slow shutoff of RNAP II activity in cells shifted to the nonpermissive temperature (39 degrees C). Each mutant displayed a distinct phenotype, and one of the mutant enzymes (rpo21-1) was completely deficient in RNAP II activity in vitro. RNAP I and RNAP III in vitro activities were not affected. These results were consistent with the notion that the genetic lesions affect RNAP II assembly or holoenzyme stability. DNA sequencing revealed that in each case the mutations involved nonconservative amino acid substitutions, resulting in charge changes. The lesions harbored by all three rpo21 Ts- alleles lie in DNA sequence domains that are highly conserved among genes that encode the largest subunits of RNAP from a variety of eucaryotes; one mutation lies in a possible Zn2+ binding domain.

scholarly journals Rsp5 Ubiquitin-Protein Ligase Mediates DNA Damage-Induced Degradation of the Large Subunit of RNA Polymerase II in Saccharomyces cerevisiae

1999 ◽  
Vol 19 (10) ◽  
pp. 6972-6979 ◽  
Author(s):  
Sylvie L. Beaudenon ◽  
Maria R. Huacani ◽  
Guangli Wang ◽  
Donald P. McDonnell ◽  
Jon M. Huibregtse
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Dna Damage ◽  
Rna Polymerase ◽  
Rna Polymerase Ii ◽  
Large Subunit ◽  
26S Proteasome ◽  
Regulatory Subunit ◽  
Ubiquitin Protein Ligase

ABSTRACT Rsp5 is an E3 ubiquitin-protein ligase of Saccharomyces cerevisiae that belongs to the hect domain family of E3 proteins. We have previously shown that Rsp5 binds and ubiquitinates the largest subunit of RNA polymerase II, Rpb1, in vitro. We show here that Rpb1 ubiquitination and degradation are induced in vivo by UV irradiation and by the UV-mimetic compound 4-nitroquinoline-1-oxide (4-NQO) and that a functional RSP5 gene product is required for this effect. The 26S proteasome is also required; a mutation ofSEN3/RPN2 (sen3-1), which encodes an essential regulatory subunit of the 26S proteasome, partially blocks 4-NQO-induced degradation of Rpb1. These results suggest that Rsp5-mediated ubiquitination and degradation of Rpb1 are components of the response to DNA damage. A human WW domain-containing hect (WW-hect) E3 protein closely related to Rsp5, Rpf1/hNedd4, also binds and ubiquitinates both yeast and human Rpb1 in vitro, suggesting that Rpf1 and/or another WW-hect E3 protein mediates UV-induced degradation of the large subunit of polymerase II in human cells.

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