ISOLATION AND CHARACTERIZATION OF THE FOUR ARABIDOPSIS THALIANA POLY(A) POLYMERASE GENES

Meeks, Lisa Renee

01 January 2005

Poly(A) tail addition to pre-mRNAs is a highly coordinated and essential step in mRNA maturation involving multiple cis- and trans-acting factors. The trans-acting factor, poly(A) polymerase (PAP) plays an essential role in the polyadenylation of mRNA precursors. The Arabidopsis thaliana genome contains four putative PAP genes. We have found, using in silico analysis and transgenic plants expressing GUS under the control of the four PAP promoters, that each of these genes is expressed in overlapping, yet unique patterns. This gives rise to the possibility that these genes are not redundant and may be essential for plant survival. To further test this, inducible RNAi and T-DNA mutagenized plants were obtained and analyzed. Plants lacking all, or most, of each PAP gene product, due to RNAi induction, were not viable at any of the stages of plant growth tested. Furthermore, T-DNA PCR analysis determined that no plants containing a homozygous mutation, were viable. This data reveals that lack of any of the four PAP gene products has a significant effect on the plants ability of survive, thus indicating that each PAP gene is essential. Finally, transient expression experiments with each of the full length PAP cDNAs fused to GFP showed that the PAP I, PAP II and PAP IV gene products are localized throughout the nucleus and within nuclear speckles. The cellular localization of PAP III could not be determined.

Regulation of Mammalian Poly(A) Polymerase Activity

Thuresson, Ann-Charlotte

January 2002

<p>Poly(A) polymerase (PAP) is the enzyme catalyzing the synthesis of the adenine tail to the 3’-end of mRNA. This A-tail is present on the majority of the primary RNA transcripts of protein-coding genes, and is important for mRNA stability, export to the cytoplasm and translation. Therefore, PAP is a key regulator of eukaryotic gene expression. This thesis describes the heterogeneity of PAP and the functional significance of multiple isoforms of PAP. </p><p>PAP exists in many different isoforms generated by three different mechanisms, gene duplication, alternative mRNA processing and post-translational modification. In HeLa cell extracts three different forms of PAP being 90, 100 and 106 kDa in size have been detected, where the 106 kDa isoform is a phosphorylated version of the 100 kDa species. It is shown that the N-terminal region of PAP contains a region required for catalysis, while the C-terminal end is important for the interaction with the cleavage and polyadenylation specificity factor (CPSF). Interestingly, it was found that also the extreme N-terminal end is important for the interaction with CPSF. This region is post-translationally modified by phosphorylation. Five alternatively spliced forms of PAP mRNAs are encoded by the PAPOLA gene while one unique species is encoded by the PAPOLG gene. The analysis showed that the exact structure of the alternatively spliced C-terminal end of PAP played an important role for catalytic efficiency. Thus, the C-terminal end contains a region important for modulating the catalytic efficiency of PAP.</p><p>Aminoglycoside antibiotics inhibit PAP activity, most likely by displacement of catalytically important divalent metal ions. Data shows that different aminoglycosides inhibit PAP activity by different mechanisms suggesting that the binding sites for the different aminoglycosides do not completely overlap. It is concluded that aminoglycosides interfere with enzymes important for housekeeping functions in mammalian cell, which may explain some of the toxic side effects caused by aminoglycoside antibiotics in clinical practice.</p>

Biomedicine

poly(A) polymerase

PAP

polyadenylation

isoforms

phosphorylation

alternative splicing

CPSF interaction

aminoglycosides

Biomedicin

Microbiology

Mikrobiologi

Regulation of Mammalian Poly(A) Polymerase Activity

Thuresson, Ann-Charlotte

January 2002

Poly(A) polymerase (PAP) is the enzyme catalyzing the synthesis of the adenine tail to the 3’-end of mRNA. This A-tail is present on the majority of the primary RNA transcripts of protein-coding genes, and is important for mRNA stability, export to the cytoplasm and translation. Therefore, PAP is a key regulator of eukaryotic gene expression. This thesis describes the heterogeneity of PAP and the functional significance of multiple isoforms of PAP. PAP exists in many different isoforms generated by three different mechanisms, gene duplication, alternative mRNA processing and post-translational modification. In HeLa cell extracts three different forms of PAP being 90, 100 and 106 kDa in size have been detected, where the 106 kDa isoform is a phosphorylated version of the 100 kDa species. It is shown that the N-terminal region of PAP contains a region required for catalysis, while the C-terminal end is important for the interaction with the cleavage and polyadenylation specificity factor (CPSF). Interestingly, it was found that also the extreme N-terminal end is important for the interaction with CPSF. This region is post-translationally modified by phosphorylation. Five alternatively spliced forms of PAP mRNAs are encoded by the PAPOLA gene while one unique species is encoded by the PAPOLG gene. The analysis showed that the exact structure of the alternatively spliced C-terminal end of PAP played an important role for catalytic efficiency. Thus, the C-terminal end contains a region important for modulating the catalytic efficiency of PAP. Aminoglycoside antibiotics inhibit PAP activity, most likely by displacement of catalytically important divalent metal ions. Data shows that different aminoglycosides inhibit PAP activity by different mechanisms suggesting that the binding sites for the different aminoglycosides do not completely overlap. It is concluded that aminoglycosides interfere with enzymes important for housekeeping functions in mammalian cell, which may explain some of the toxic side effects caused by aminoglycoside antibiotics in clinical practice.

Biomedicine

poly(A) polymerase

PAP

polyadenylation

isoforms

phosphorylation

alternative splicing

CPSF interaction

aminoglycosides

Biomedicin

Microbiology

Mikrobiologi

CHARACTERIZATION OF PLANT POLYADENYLATION TRANSACTING FACTORS-FACTORS THAT MODIFY POLY(A) POLYMERSE ACTIVITY

Forbes, Kevin Patrick

01 January 2005

Plant polyadenylation factors have proven difficult to purify and characterize, owing to the presence of excessive nuclease activity in plant nuclear extracts, thereby precluding the identification of polyadenylation signal-dependent processing and polyadenylation in crude extracts. As an alternative approach to identifying such factors, a screen was conducted for activities that inhibit the non-specific activity of plant poly(A) polymerases (PAP). One such factor (termed here as Putative Polyadenylation Factor B, or PPF-B) was identified in a screen of DEAE-Sepharose column fractions using a partially purified preparation of a plant nuclear poly(A) polymerase. This factor was purified to near homogeneity. Surprisingly, in addition to being an effective inhibitor of the nuclear PAP, PPF-B inhibited the activity of a chloroplast PAP. In contrast, this factor stimulated the activity of the yeast PAP. Direct assays of ATPase, proteinase, and nuclease activities indicated that inhibition of PAP activity was not due to depletion of substrates or degradation of products of the PAP reaction. The major polypeptide component of PPF-B proved to be a novel linker histone (RSP), which copurified with inhibitory activity by affinity chromatography on DNA-cellulose. The association of inhibitory activity with a linker histone and the spectrum of inhibitory activity, raise interesting possibilities regarding the role of PPF-B in nuclear RNA metabolism. These include a link between DNA damage and polyadenylation, as well as a role for limiting the polyadenylation of stable RNAs in the nucleus and nucleolus. The Arabidopsis genome possesses genes encoding probable homologs of most of the polyadenylation subunits that have been identified in mammals and yeast. Two of these reside on chromosome III and V and have the potential to encode a protein that is related to the yeast and mammalian Fip1 subunit (AtFip1-III and AtFip1-V). These genes are universally expressed in Arabidopsis tissues. AtFip1-V stimulates the non-specific activity of at least one Arabidopsis nuclear PAP, binds RNA, and interacts with other polyadenylation homologs AtCstF77 and AtCPSF30. These studies suggest that AtFip1- V is an authentic polyadenylation factor that coordinates other subunits and plays a role in regulating the activityof PAP in plants.

Molecular Mechanism of the TRAMP Complex

Jia, Huijue

January 2011

No description available.

Biochemistry

RNA helicase

RNA duplex unwinding

poly(A) polymerase

polyadenylation

TRAMP

Mtr4

Ded1

ATP analog

Analysis of the Arabidopsis Polyadenylation Factors PAP1, CstF64 and CstF77 and their characteristic inter-relationship

Bandyopadhyay, Amrita

01 January 2009

3’-end modification by polyadenylation is a ubiquitous feature of almost all eukaryotic mRNA species and is catalyzed by a consortium of enzymes, the polyadenylation factors. Poly(A) polymerase (PAP), the enzyme catalyzing the addition of adenosine residues during the polyadenylation stage, exists in four isoforms within Arabidopsis. In silico and yeast two-hybrid studies showed that PAP1 has unique expression and interaction pattern in Arabidopsis, suggesting non-canonical functions of PAP1. Its exclusive interaction with PAP4 has not been reported in other living systems until now and hints at a difference in polyadenylation in plants with respect to mammals and yeast. Cleavage Stimulation Factor (CstF), a heterotrimeric complex of the polyadenylation factors CstF50, CstF64 and CstF77, plays a role largely in cleavage of pre-mRNA. This study highlights some aspects of the Arabidopsis homologs of CstF64 and CstF77, central to various cellular processes other than nuclear polyadenylation. In silico studies showed an elevated expression of CstF64 in the pollen while that of CstF77 remained fairly low. Yeast two-hybrid assays indicated a novel kind of interaction of CstF64 with Fip1(V). It is also speculated from sub-cellular localization techniques by agroinfiltration in tobacco leaves that CstF64 localizes in the cytoplasm and CstF77 in the nucleus, as found for the orthologs of CstF77 in other systems.

Plant Sciences

Functional Significance of Multiple Poly(A) Polymerases (PAPs)

Nordvarg, Helena

January 2002

<p>3’ end cleavage and polyadenylation are important steps in the maturation of eukaryotic mRNAs. Poly(A) polymerase (PAP), the enzyme catalysing the addition of adenosine residues, exists in multiple isoforms. In this study the functional significance of multiple poly(A) polymerases have been investigated. It is concluded (i) that at least three mechanisms generate the multiple isoforms i.e. gene duplication, post-translational modification and alternative mRNA processing and (ii) that the different isoforms of poly(A) polymerases have different catalytic properties. The study highlights regulation of poly(A) polymerase activity through modulation of its affinity for the substrate as visualised by the K_M parameter. We suggest that trans-acting factors modulating the K_M of poly(A) polymerase will play important roles in regulating its activity.</p><p>A new human poly(A) polymerase (PAPγ) encoded by the PAPOLG gene was identified. PAPγ is 65% homologous to the previously identified PAP. In human cells three isoforms of poly(A) polymerases being 90, 100 and 106 kDa in sizes are present. These native isoforms were purified. The PAPOLA gene encoded the 100 and 106 kDa isoforms while the 90 kDa isoform was encoded by the PAPOLG gene. Native PAPγ was found to be more active than 100 kDa PAP while the hyperphosphorylated 106 kDa PAP isoform was comparably inactive due to a 500-fold decrease in affinity for the RNA substrate. </p><p>The PAPOLG gene was shown to encode one unique mRNA while the PAPOLA gene generated five different PAP mRNAs by alternative splicing of the last three exons. The PAPOLA encoded mRNAs were divided into two classes based on the composition of the last three exons. Poly(A) polymerases from the two classes were shown to differ in polyadenylation activities. These differences revealed two novel regulatory motifs in the extreme C-terminal end of PAP, one being inactivating and the other activating for polyadenylation activity.</p>

Genetics

poly(A) polymerase

PAP

phosphorylation

isoforms

alternative splicing

kinetic parameters

hyperphosphorylation

regulation

Genetik

Poly(A) polymeras

PAP

fosforylering

isoformer

alternativ splitsning

kinetiska parametrar

reglering

Clinical genetics

Klinisk genetik

Functional Significance of Multiple Poly(A) Polymerases (PAPs)

Nordvarg, Helena

January 2002

3’ end cleavage and polyadenylation are important steps in the maturation of eukaryotic mRNAs. Poly(A) polymerase (PAP), the enzyme catalysing the addition of adenosine residues, exists in multiple isoforms. In this study the functional significance of multiple poly(A) polymerases have been investigated. It is concluded (i) that at least three mechanisms generate the multiple isoforms i.e. gene duplication, post-translational modification and alternative mRNA processing and (ii) that the different isoforms of poly(A) polymerases have different catalytic properties. The study highlights regulation of poly(A) polymerase activity through modulation of its affinity for the substrate as visualised by the KM parameter. We suggest that trans-acting factors modulating the KM of poly(A) polymerase will play important roles in regulating its activity. A new human poly(A) polymerase (PAPγ) encoded by the PAPOLG gene was identified. PAPγ is 65% homologous to the previously identified PAP. In human cells three isoforms of poly(A) polymerases being 90, 100 and 106 kDa in sizes are present. These native isoforms were purified. The PAPOLA gene encoded the 100 and 106 kDa isoforms while the 90 kDa isoform was encoded by the PAPOLG gene. Native PAPγ was found to be more active than 100 kDa PAP while the hyperphosphorylated 106 kDa PAP isoform was comparably inactive due to a 500-fold decrease in affinity for the RNA substrate. The PAPOLG gene was shown to encode one unique mRNA while the PAPOLA gene generated five different PAP mRNAs by alternative splicing of the last three exons. The PAPOLA encoded mRNAs were divided into two classes based on the composition of the last three exons. Poly(A) polymerases from the two classes were shown to differ in polyadenylation activities. These differences revealed two novel regulatory motifs in the extreme C-terminal end of PAP, one being inactivating and the other activating for polyadenylation activity.

Genetics

poly(A) polymerase

PAP

phosphorylation

isoforms

alternative splicing

kinetic parameters

hyperphosphorylation

regulation

Genetik

Poly(A) polymeras

PAP

fosforylering

isoformer

alternativ splitsning

kinetiska parametrar

reglering

Clinical genetics

Klinisk genetik

Analýza regulace komplexů cytoplazmatických poly(A) polymeráz / Analýza regulace komplexů cytoplazmatických poly(A) polymeráz

Novák, Jakub

January 2011

The regulation of gene expression is achieved at many levels. Chromatin-based gene regulation has been the central focus of many decades of research; however, posttranscriptional control mechanisms are emerging as a fundamental complement to direct protein synthesis. This thesis is focused on a specific mechanism of posttranscriptional control - the translational regulation of mRNAs in the cell cytoplasm. This control is a consequence of the balance between translational repression and activation and hinges on the selective recognition of regulated mRNAs by RNA-binding proteins and their ability to recruit RNA modifying proteins. In this thesis, Caenorhabditis elegans germline was used to study translational control of the germ cell-enriched gene, gld-2. Mutants of known RNA-binding proteins of the PUF and CPB protein families were analyzed by performing Western blots, using anti-GLD-2 antibodies. Yeast 3-Hybrid system was used to identify the cis-regulatory sites in the gld-2 mRNA conferring translational regulation by members of PUF and CPB protein families. Potential autoregulatory loop of gld-2 gene expression was also investigated. This thesis shows that FBF proteins positively regulate expression of gld-2 and bind to a conserved sequence in the 3'UTR of its mRNA. Mutations of gld-2 negatively affect...