Your search keyword '"Polynucleotide Adenylyltransferase chemistry"' showing total 4 results

1. Structural basis for the activation of the C. elegans noncanonical cytoplasmic poly(A)-polymerase GLD-2 by GLD-3.

Author

Nakel K, Bonneau F, Eckmann CR, and Conti E

Subjects

Animals, Caenorhabditis elegans Proteins chemistry, Crystallography, X-Ray, Models, Molecular, Pancreatitis-Associated Proteins, Polynucleotide Adenylyltransferase chemistry, Protein Conformation, RNA-Binding Proteins chemistry, Caenorhabditis elegans enzymology, Caenorhabditis elegans Proteins metabolism, Cytoplasm enzymology, Polynucleotide Adenylyltransferase metabolism, RNA-Binding Proteins metabolism

Abstract

The Caenorhabditis elegans germ-line development defective (GLD)-2-GLD-3 complex up-regulates the expression of genes required for meiotic progression. GLD-2-GLD-3 acts by extending the short poly(A) tail of germ-line-specific mRNAs, switching them from a dormant state into a translationally active state. GLD-2 is a cytoplasmic noncanonical poly(A) polymerase that lacks the RNA-binding domain typical of the canonical nuclear poly(A)-polymerase Pap1. The activity of C. elegans GLD-2 in vivo and in vitro depends on its association with the multi-K homology (KH) domain-containing protein, GLD-3, a homolog of Bicaudal-C. We have identified a minimal polyadenylation complex that includes the conserved nucleotidyl-transferase core of GLD-2 and the N-terminal domain of GLD-3, and determined its structure at 2.3-Å resolution. The structure shows that the N-terminal domain of GLD-3 does not fold into the predicted KH domain but wraps around the catalytic domain of GLD-2. The picture that emerges from the structural and biochemical data are that GLD-3 activates GLD-2 both indirectly by stabilizing the enzyme and directly by contributing positively charged residues near the RNA-binding cleft. The RNA-binding cleft of GLD-2 has distinct structural features compared with the poly(A)-polymerases Pap1 and Trf4. Consistently, GLD-2 has distinct biochemical properties: It displays unusual specificity in vitro for single-stranded RNAs with at least one adenosine at the 3' end. GLD-2 thus appears to have evolved specialized nucleotidyl-transferase properties that match the 3' end features of dormant cytoplasmic mRNAs.

Published

2015

2. Reengineering CCA-adding enzymes to function as (U,G)- or dCdCdA-adding enzymes or poly(C,A) and poly(U,G) polymerases.

Author

Cho HD, Verlinde CL, and Weiner AM

Subjects

Binding Sites, Hydrogen Bonding, Polynucleotide Adenylyltransferase chemistry, Polynucleotide Adenylyltransferase physiology, RNA Nucleotidyltransferases chemistry, Poly A metabolism, Poly C metabolism, Poly G metabolism, Poly U metabolism, Protein Engineering methods, RNA Nucleotidyltransferases physiology

Abstract

CCA-adding enzymes build and repair the 3'-terminal CCA sequence of tRNA. These unusual RNA polymerases use either a ribonucleoprotein template (class I) or pure protein template (class II) to form mock base pairs with the Watson-Crick edges of incoming CTP and ATP. Guided by the class II Bacillus stearothermophilus CCA-adding enzyme structure, we introduced mutations designed to reverse the polarity of hydrogen bonds between the nucleobases and protein template. We were able to transform the CCA-adding enzyme into a (U,G)-adding enzyme that incorporates UTP and GTP instead of CTP and ATP; we transformed the related Aquifex aeolicus CC- and A-adding enzymes into UU- and G-adding enzymes and Escherichia coli poly(A) polymerase into a poly(G) polymerase; and we transformed the B. stearothermophilus CCA-adding enzyme into a poly(C,A) polymerase by mutations in helix J that appear, based on the apoenzyme structure, to sterically limit addition to CCA. We also transformed the B. stearothermophilus CCA-adding enzyme into a dCdCdA-adding enzyme by mutating an arginine that interacts with the incoming ribose 2' hydroxyl. Most importantly, we found that mutations in helix J can affect the specificity of the nucleotide binding site some 20 A away, suggesting that the specificity of both class I and II enzymes may be dictated by an intricate network of hydrogen bonds involving the protein, incoming nucleotide, and 3' end of the tRNA. Collaboration between RNA and protein in the form of a ribonucleoprotein template may help to explain the evolutionary diversity of the nucleotidyltransferase family.

Published

2007

3. Mammalian GLD-2 homologs are poly(A) polymerases.

Author

Kwak JE, Wang L, Ballantyne S, Kimble J, and Wickens M

Subjects

Animals, Humans, Kinetics, Mice, Models, Molecular, Nucleotidyltransferases genetics, Phylogeny, Plasmids, Poly A metabolism, Polynucleotide Adenylyltransferase chemistry, Protein Biosynthesis, Protein Conformation, RNA, Messenger genetics, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Transcription, Genetic, Nucleotidyltransferases metabolism, Polynucleotide Adenylyltransferase genetics, Polynucleotide Adenylyltransferase metabolism

Abstract

GLD-2 is a cytoplasmic poly(A) polymerase present in the Caenorhabditis elegans germ line and embryo. It is a divergent member of the DNA polymerase beta nucleotidyl transferase superfamily, which includes CCA-adding enzymes, DNA polymerases and eukaryotic nuclear poly(A) polymerases. The polyadenylation activity of GLD-2 is stimulated by physical interaction with an RNA binding protein, GLD-3. To test whether GLD-3 might stimulate GLD-2 by recruiting it to RNA, we tethered C. elegans GLD-2 to mRNAs in Xenopus oocytes by using MS2 coat protein. Tethered GLD-2 adds poly(A) and stimulates translation of the mRNA, demonstrating that recruitment is sufficient to stimulate polyadenylation activity. We use the same tethered assay to identify human and mouse poly(A) polymerases related to GLD-2. This may provide entrees to previously uncharacterized modes of polyadenylation in mammalian cells.

Published

2004

4. Identification of the coding region for a second poly(A) polymerase in Escherichia coli.

Author

Cao GJ, Pogliano J, and Sarkar N

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, Escherichia coli genetics, Inclusion Bodies enzymology, Kinetics, Molecular Sequence Data, Peptide Fragments chemistry, Polynucleotide Adenylyltransferase chemistry, Protein Conformation, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Sequence Tagged Sites, Escherichia coli enzymology, Polynucleotide Adenylyltransferase biosynthesis, Polynucleotide Adenylyltransferase genetics

Abstract

We had earlier identified the pcnB locus as the gene for the major Escherichia coli poly(A) polymerase (PAP I). In this report, we describe the disruption and identification of a candidate gene for a second poly(A) polymerase (PAP II) by an experimental strategy which was based on the assumption that the viability of E. coli depends on the presence of either PAP I or PAP II. The coding region thus identified is the open reading frame f310, located at about 87 min on the E. coli chromosome. The following lines of evidence support f310 as the gene for PAP II: (i) the deduced peptide encoded by f310 has a molecular weight of 36,300, similar to the molecular weight of 35,000 estimated by gel filtration of PAP II; (ii) the deduced f310 product is a relatively hydrophobic polypeptide with a pI of 9.4, consistent with the properties of partially purified PAP II; (iii) overexpression of f310 leads to the formation of inclusion bodies whose solubilization and renaturation yields poly(A) polymerase activity that corresponds to a 35-kDa protein as shown by enzyme blotting; and (iv) expression of a f310 fusion construct with hexahistidine at the N-terminus of the coding region allowed purification of a poly(A) polymerase fraction whose major component is a 36-kDa protein. E. coli PAP II has no significant sequence homology either to PAP I or to the viral and eukaryotic poly(A) polymerases, suggesting that the bacterial poly(A) polymerases have evolved independently. An interesting feature of the PAP II sequence is the presence of sets of two paired cysteine and histidine residues that resemble the RNA binding motifs seen in some other proteins.

Published

1996