Heterologous expression of the mammalian microtubule associated proteins (MAPs), TAU, MAP2C and MAP4 in the fission yeast schizosaccharomyces pombe

Bezbaruah, Supriya

January 1999

No description available.

572.8

The Mitochondrial S7 Ribosomal Protein Gene: Impact of DNA Rearrangements on RNA Expression in Grasses

Byers, Evan

10 January 2012

Frequent rearrangements, typically through homologous recombination in plant mitochondrial genomes often result in different upstream and downstream sequences for the same gene among a number of species. Transcription and RNA processing signals are therefore different, even among closely related plants. To evaluate the impact of DNA rearrangements on gene expression I conducted a comparative analysis of the S7 ribosomal protein gene (rps7) among a number of grasses: wheat, rice, maize, barley, rye, brome, Lolium and oats (grasses whose evolutionary divergence times range from about 5 to 60 Mya). Using circularized-RT-PCR to simultaneously map rps7 transcript termini I found that 3’ends for various RNA species are homogeneous, mapping to conserved sequences among plants. 5’ termini are more complex and can be both discrete and heterogeneous for different transcripts, both within and among plants. Genome rearrangements upstream of the rps7 start codon for some but not all species has led to plant-specific signals for both rps7 transcription and RNA processing. Termini for rps7 precursor species in wheat and Lolium are very discrete and likely use different upstream tRNAs as processing signals for end-cleavage. A number of potential stem-loop structures have also been identified at or near 5’ and 3’ termini which may function in maturation of transcript ends or provide transcript stability and protection from degradation by ribonucleases. C-to-U RNA editing of non-coding sequences, a rare event, was observed at multiple sites within the 5’ and 3’UTRs among plants. Some sites may even be developmentally regulated as CR-RT-PCR experiments were conducted using mitochondrial RNA isolated from seedlings and germinating embryos. Taken together, my observations demonstrate the frequency of upstream DNA rearrangements and the variety of signals used for expression of rps7 among grasses, providing new insights into the complexities of mRNA production in plant mitochondria.

Mitochondria

Ribosomal protein

RNA processing

Editing

Grasses

The Mitochondrial S7 Ribosomal Protein Gene: Impact of DNA Rearrangements on RNA Expression in Grasses

Byers, Evan

10 January 2012

Frequent rearrangements, typically through homologous recombination in plant mitochondrial genomes often result in different upstream and downstream sequences for the same gene among a number of species. Transcription and RNA processing signals are therefore different, even among closely related plants. To evaluate the impact of DNA rearrangements on gene expression I conducted a comparative analysis of the S7 ribosomal protein gene (rps7) among a number of grasses: wheat, rice, maize, barley, rye, brome, Lolium and oats (grasses whose evolutionary divergence times range from about 5 to 60 Mya). Using circularized-RT-PCR to simultaneously map rps7 transcript termini I found that 3’ends for various RNA species are homogeneous, mapping to conserved sequences among plants. 5’ termini are more complex and can be both discrete and heterogeneous for different transcripts, both within and among plants. Genome rearrangements upstream of the rps7 start codon for some but not all species has led to plant-specific signals for both rps7 transcription and RNA processing. Termini for rps7 precursor species in wheat and Lolium are very discrete and likely use different upstream tRNAs as processing signals for end-cleavage. A number of potential stem-loop structures have also been identified at or near 5’ and 3’ termini which may function in maturation of transcript ends or provide transcript stability and protection from degradation by ribonucleases. C-to-U RNA editing of non-coding sequences, a rare event, was observed at multiple sites within the 5’ and 3’UTRs among plants. Some sites may even be developmentally regulated as CR-RT-PCR experiments were conducted using mitochondrial RNA isolated from seedlings and germinating embryos. Taken together, my observations demonstrate the frequency of upstream DNA rearrangements and the variety of signals used for expression of rps7 among grasses, providing new insights into the complexities of mRNA production in plant mitochondria.

Mitochondria

Ribosomal protein

RNA processing

Editing

Grasses

Ribosomal Protein Mutations in Hematopoiesis and Zebrafish Development

Taylor, Allison

January 2012

The focus of this thesis is the role of ribosomal proteins in hematopoiesis and development. Ribosomal proteins are mutated in patients with Diamond Blackfan anemia (DBA). These mutations primarily affect blood tissues, as DBA patients have a macrocytic anemia. We have identified hematopoietic defects in zebrafish with a mutation in ribosomal protein S29 (rps29). \(Rps29^{-/-}\) embryos have defects in hematopoietic stem cell formation, aorta specification, and hemoglobinization. Embryos also have increased numbers of apoptotic cells, and microarray analysis reveals up-regulation of a p53 gene signature. All of the hematopoietic phenotypes are rescued by p53 mutation, demonstrating that p53 activation induced by ribosomal protein knockdown is mediating the \(rps29^{-/-}\) mutant phenotype. In addition, polysome profiles of mutant embryos identify a decrease in 80s monosome and polysome fractions. Preliminary RNA sequencing analysis of the polysome fractions suggested a shift in genes being translated in the mutant. We performed a chemical screen on rps29 embryos. Using embryo morphology and vascular expression patterns as read-outs, 600 compounds of known bioactivity were screened. One compound, A-3, improves embryo morphology, and a structurally related compound, W-7, rescues the vasculature defect. These compounds are calmodulin inhibitors, and A-3 can also rescue the hemoglobin defect in \(rps29^{-/-}\) embryos. To elucidate the compounds’ mechanism of action, A549 and \(CD34^+\) cells with RPS19 knocked down by shRNA were treated with chemical hits. In these cells, calmodulin inhibitors cause a decrease of p21 even with p53 induction. These data support a model where calmodulin inhibition can inhibit the p53 pathway upon ribosomal protein knockdown. In parallel to our zebrafish studies, we generated induced pluripotent stem (iPS) cells from DBA patient fibroblasts as a part of a large-scale collaboration. Three iPS lines are validated, and a total of 27 lines will be generated from patients with mutations in RPS19, RPL5, and RPL11. Testing for defects in blood differentiation and determining the role of p53 in these lines will enable validation of this system as a model of DBA. The iPS lines can subsequently be used for chemical and genetic screening to identify novel DBA pathways and potential therapies.

Diamond Blackfan anemia

hematopoiesis

ribosomal protein

genetics

The Mitochondrial S7 Ribosomal Protein Gene: Impact of DNA Rearrangements on RNA Expression in Grasses

Byers, Evan

10 January 2012

Frequent rearrangements, typically through homologous recombination in plant mitochondrial genomes often result in different upstream and downstream sequences for the same gene among a number of species. Transcription and RNA processing signals are therefore different, even among closely related plants. To evaluate the impact of DNA rearrangements on gene expression I conducted a comparative analysis of the S7 ribosomal protein gene (rps7) among a number of grasses: wheat, rice, maize, barley, rye, brome, Lolium and oats (grasses whose evolutionary divergence times range from about 5 to 60 Mya). Using circularized-RT-PCR to simultaneously map rps7 transcript termini I found that 3’ends for various RNA species are homogeneous, mapping to conserved sequences among plants. 5’ termini are more complex and can be both discrete and heterogeneous for different transcripts, both within and among plants. Genome rearrangements upstream of the rps7 start codon for some but not all species has led to plant-specific signals for both rps7 transcription and RNA processing. Termini for rps7 precursor species in wheat and Lolium are very discrete and likely use different upstream tRNAs as processing signals for end-cleavage. A number of potential stem-loop structures have also been identified at or near 5’ and 3’ termini which may function in maturation of transcript ends or provide transcript stability and protection from degradation by ribonucleases. C-to-U RNA editing of non-coding sequences, a rare event, was observed at multiple sites within the 5’ and 3’UTRs among plants. Some sites may even be developmentally regulated as CR-RT-PCR experiments were conducted using mitochondrial RNA isolated from seedlings and germinating embryos. Taken together, my observations demonstrate the frequency of upstream DNA rearrangements and the variety of signals used for expression of rps7 among grasses, providing new insights into the complexities of mRNA production in plant mitochondria.

Mitochondria

Ribosomal protein

RNA processing

Editing

Grasses

The Mitochondrial S7 Ribosomal Protein Gene: Impact of DNA Rearrangements on RNA Expression in Grasses

Byers, Evan

January 2012

Frequent rearrangements, typically through homologous recombination in plant mitochondrial genomes often result in different upstream and downstream sequences for the same gene among a number of species. Transcription and RNA processing signals are therefore different, even among closely related plants. To evaluate the impact of DNA rearrangements on gene expression I conducted a comparative analysis of the S7 ribosomal protein gene (rps7) among a number of grasses: wheat, rice, maize, barley, rye, brome, Lolium and oats (grasses whose evolutionary divergence times range from about 5 to 60 Mya). Using circularized-RT-PCR to simultaneously map rps7 transcript termini I found that 3’ends for various RNA species are homogeneous, mapping to conserved sequences among plants. 5’ termini are more complex and can be both discrete and heterogeneous for different transcripts, both within and among plants. Genome rearrangements upstream of the rps7 start codon for some but not all species has led to plant-specific signals for both rps7 transcription and RNA processing. Termini for rps7 precursor species in wheat and Lolium are very discrete and likely use different upstream tRNAs as processing signals for end-cleavage. A number of potential stem-loop structures have also been identified at or near 5’ and 3’ termini which may function in maturation of transcript ends or provide transcript stability and protection from degradation by ribonucleases. C-to-U RNA editing of non-coding sequences, a rare event, was observed at multiple sites within the 5’ and 3’UTRs among plants. Some sites may even be developmentally regulated as CR-RT-PCR experiments were conducted using mitochondrial RNA isolated from seedlings and germinating embryos. Taken together, my observations demonstrate the frequency of upstream DNA rearrangements and the variety of signals used for expression of rps7 among grasses, providing new insights into the complexities of mRNA production in plant mitochondria.

Mitochondria

Ribosomal protein

RNA processing

Editing

Grasses

Evolutionary Status of Mitochondrial Ribosomal Protein Genes rps19 and rpl2 and their Transfer to the Nucleus in Grasses

Atluri, Sruthi

January 2015

Massive mitochondrial gene transfer to the nucleus occurred very early during eukaryotic evolution following endosymbiosis, and is still ongoing in plants. Tracking recent gene transfer events can give us insight into the evolutionary processes by which a transferred gene becomes functional in the nucleus and how its protein gets targeted back into the mitochondrion, where it is needed. Rps19 and rpl2 are two such ribosomal protein genes that are known to have been transferred to the nucleus, many times independently during flowering plant evolution. My research project focusses on determining the status and expression of rps19 and rpl2 in the mitochondrion and nucleus of selected grasses and in particular brome (close relative to agronomically important crops such as wheat, rye and barley). My results at the level of DNA and RNA (PCR and RT-PCR, respectively) show that the mitochondrial brome rpl2 copy is a pseudogene while its functional gene is in the nucleus. The brome mitochondrial genome has a copy of rps19 which is transcribed and C-U edited. Surprisingly, the brome nuclear genome also has functional copies of rps19.The targeting sequence for the nuclear rps19 gene was acquired from duplication of mitochondrial targeting heat shock protein (hsp70) presequence. Comparative analysis strongly suggests that a functional rps19 gene was transferred to the nucleus before rice and maize lineages split and now that brome rps19 has been found to be present in both compartments, this implies a transition stage of about 60 million years. Oats was found to have a functional rps19 copy in the nucleus and has a novel presequence due to lineage specific rearrangements and exon shuffling. Functional paralogous copies were found in wheat, and maize while barley lost one of the copy. Thus, following transfer, duplication of rps19 gene must have occurred in the ancestor of barley and wheat clade. Maize might have had a recent duplication or gene conversion events along its lineage as its paralogous copies are very similar to each other. More information is needed to determine if this duplication event extends to wheat-brome, wheat-oats or even before rice and maize split. Barley was also found to have a recent independent DNA mediated transfer in addition to the common transfer, as it possesses an unedited nuc-mt rps19 in its nuclear genome. This suggests that barley must also have had a transition stage for ~60MY and lost its mitochondrial copy very recently.

Gene transfer

Ribosomal protein

Mitochondria

Brome

Grasses

Identification and Characterization of Novel Ribosomal Protein-binding RNA motifs in Bacteria

Fu, Yang

January 2014

Thesis advisor: Michelle M. Meyer / As the factory responsible for producing proteins, ribosomes are of great importance. In bacteria, ribosomes are composed of three ribosomal RNAs (rRNA) of different sizes, and around 50 ribosomal proteins (r-protein). During ribosome biogenesis in bacteria, synthesis of rRNAs and r-proteins are both tightly regulated and coordinated to ensure robust growth. In particular, a group of cis-regulatory RNA elements located in the 5' untranslated regions or the intergenic regions in r-protein operons are responsible for the regulation of r-protein biosynthesis. Based on the fact that RNA-regulated r-protein biosynthesis is essential and universal in bacteria, such unique and varied regulatory RNAs could provide new targets for antibacterial purpose. In this thesis, we report and experimentally verify a novel r-protein L1 regulation model that contains dual L1-binding RNA motif, and for the first time, a S6:S18 dimer-binding RNA structure in the S6 operon. We also describe Escherichia coli-based and Schizosaccharomyces pombe-based reporter systems for in vivo characterization of RNA-protein interactions. So far, both in vivo systems failed to report RNA-protein interactions, and thus need further tuning. In addition, we performed phage-display to select for regulatory RNA-binding small peptides and examined their effects on bacteria viability. One selected peptide, N-TVNFKLY-C, caused defective growth when overexpressed in E. coli. Yet, further studies must be conducted to verify the possibility that bacteria were killed by direct RNA-peptide interaction that disrupted the native r-protein regulation. / Thesis (MS) — Boston College, 2014. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

Bacteria

cis-regulatory

L1

Ribosomal protein

RNA

S6

Characterization of the four genes encoding cytoplasmic ribosomal protein S15a in Arabidopsis thaliana

Hulm, Jacqueline Louise

31 March 2008

Eukaryotic cytosolic ribosomes are composed of two distinct subunits consisting of four individual ribosomal RNAs and, in Arabidopsis thaliana, 81 ribosomal proteins. Functional subunit assembly is dependent on the production of each ribosomal component. Arabidopsis thaliana r-protein genes exist in multi-gene families ranging in size from two to seven transcriptionally active members. The cytosolic RPS15a gene family consists of four members (RPS15aA, -C, -D and -F) that, at the amino acid level, share 87-100% identity. Using semi-quantitative RT-PCR I have shown that RPS15aC is not expressed and that transcript abundance differs both spatially and temporally among the remaining RPS15a genes in non-treated Arabidopsis tissues and in seedlings following a variety of abiotic stresses. A comprehensive analysis of the RPS15a 5' regulatory regions (RRs) using a series of deletion constructs was used to determine the minimal region required for gene expression and identify putative cis-regulatory elements. Transcription start site mapping using 5' RACE indicated multiple sites of initiation for RPS15aA and -F and only a single site for RPS15aD while all three genes contain a leader intron upstream of the start codon. Analysis of reporter gene activity in transgenic Arabidopsis containing a series of 5' RR deletion::GUS fusions showed that, similar to previous RT-PCR results, there was a trend for mitotically active tissues to stain for GUS activity. Putative cis-elements including the TELO box, PCNA Site II motif and pollen specific elements were identified. However, there was not always a clear correlation between the presence of a putative element and RPS15a transcript abundance or GUS activity. Although variation in transcriptional activity of each RPS15a gene has been observed, subcellular localization of both RPS15aA and -D in the nucleolus has been confirmed in planta by confocal microscopy. The results of this thesis research suggest while all three active RPS15a genes are transcriptionally regulated, additional post-transcriptional and/or translational regulation may be responsible for final RPS15a levels while differential isoform incorporation into ribosomal subunits may be the final point of r-protein regulation.

gene expression

transcriptional regulation

Arabidopsis

S15a

ribosomal protein

ribosome

Characterization of the two genes encoding cytoplasmic ribosomal protein L23a in <i>Arabidopsis thaliana</i>

McIntosh, Kerri Bryn

23 November 2005

<p>RPL23a is one of the ~80 ribosomal proteins (r-proteins) of the cytoplasmic ribosome in the model plant <i>Arabidopsis thaliana</i>. The objectives of this research were to establish Arabidopsis RPL23a as a functional r-protein, characterize expression patterns for the two genes (RPL23aA and B) encoding RPL23a using reverse transcription PCR (RT-PCR), and identify regulatory elements controlling the expression of RPL23aA and B. Complementation of a yeast l25 mutant with AtRPL23aA demonstrated that AtRPL23aA can fulfill all the essential functions of L25 in vivo. A survey of various Arabidopsis tissue types showed that, while RPL23aA and B expression patterns both showed increased transcript abundance in mitotically active tissues, RPL23aB transcript levels were generally lower than those of RPL23aA and responded differently to abiotic stresses. In order to determine cis regulatory elements controlling RPL23aA and B expression, the 5 regulatory region (RR) of each gene was characterized via plants carrying a series of 5 RR deletion fragments upstream of a reporter. Transcript start sites and 5 untranslated regions (UTRs) for both RPL23aA and B were also characterized using primer extension, and transcripts from 5 deletion transgenics were amplified using RT-PCR. No correlation was observed between putative cis-acting elements and the expression patterns from the RPL23aA and B deletion transgenics, although a 102 bp sequence in the RPL23aB 5 RR was found to contain pollen-specific elements. 5 leader introns were found in each RPL23a gene, and amplification of transgene transcripts from deletion series plants indicated the importance of post-transcriptional and translational regulation in RPL23aA and B expression. This thesis work is the first demonstration of a plant RPL23a protein as a functional member of the L23/L25 (L23p) conserved r-protein family, and is one of the few in-depth studies of the regulation of r-protein genes in plants. While the majority of previous research on plant r-protein gene expression has focused solely on transcript levels, I show herein that post-transcriptional mechanisms have a critical role in regulating these genes, and thus plant r-protein genes more strongly resemble their mammalian counterparts than those of yeast in terms of structure and regulation.

regulatory region

yeast complemetation

ribosome

ribosomal protein

Arabidopsis

gene expression