Transcriptional pausing and stalling causes multiple clustered mutations by human activation‐induced deaminase

Transcription of the rearranged immunoglobulin gene and expression of the enzyme activation‐induced deaminase (AID) are essential for somatic hypermutations of this gene during antibody maturation. While AID acts as a single‐strand DNA‐cytosine deaminase creating U · G mispairs that lead to mutations, the role played by transcription in this process is less clear. We have used in vitro transcription of the kan gene by the T7 RNA polymerase (RNAP) in the presence of AID and a genetic reversion assay for kanamycin‐resistance to investigate the causes of multiple clustered mutations (MCMs) during somatic hypermutations. We find that, depending on transcription conditions, AID can cause single‐base substitutions or MCMs. When wild‐type RNAP is used for transcription at physiologically relevant concentrations of ribonucleoside triphosphates (NTPs), few MCMs are found. In contrast, slowing the rate of elongation by reducing the NTP concentration or using a mutant RNAP increases several‐fold the percent of revertants containing MCMs. Arresting the elongation complexes by a quick removal of NTPs leads to formation of RNA‐DNA hybrids (R‐loops). Treatment of these structures with AID results in a high percentage of KanR revertants with MCMs. Furthermore, selecting for transcription elongation complexes stalled near the codon that suffers mutations during acquisition of kanamycin‐resistance results in an overwhelming majority of revertants with MCMs. These results show that if RNAP II pauses or stalls during transcription of immunoglobulin gene, AID is likely to promote MCMs. As changes in physiological conditions such as occurrence of certain DNA primary or secondary structures or DNA adducts are known to cause transcriptional pausing and stalling in mammalian cells, this process may cause MCMs during somatic hypermutation.—Canugovi, C., Samaranayake, M., Bhagwat, A. S. Transcriptional pausing and stalling causes multiple clustered mutations by human activation‐induced deaminase. FASEB J. 23, 34‐44 (2009)

[1]  F. Alt,et al.  Antisense transcripts from immunoglobulin heavy-chain locus V(D)J and switch regions , 2008, Proceedings of the National Academy of Sciences.

[2]  M. Lieber,et al.  Sequence Dependence of Chromosomal R-Loops at the Immunoglobulin Heavy-Chain Sμ Class Switch Region , 2007, Molecular and Cellular Biology.

[3]  M. Goodman,et al.  DNA deaminases AID and APOBEC3G act processively on single-stranded DNA. , 2007, DNA Repair.

[4]  Svend K. Petersen-Mahrt,et al.  The nuclear DNA deaminase AID functions distributively whereas cytoplasmic APOBEC3G has a processive mode of action. , 2007, DNA repair.

[5]  Alberto Martin,et al.  Detection of chromatin-associated single-stranded DNA in regions targeted for somatic hypermutation , 2007, The Journal of experimental medicine.

[6]  R. Landick The regulatory roles and mechanism of transcriptional pausing. , 2006, Biochemical Society transactions.

[7]  D. Nicolae,et al.  Somatic Hypermutation and Class Switch Recombination in Msh6−/−Ung−/− Double-Knockout Mice1 , 2006, The Journal of Immunology.

[8]  M. Neuberger,et al.  The in vivo pattern of AID targeting to immunoglobulin switch regions deduced from mutation spectra in msh2 −/− ung −/− mice , 2006, The Journal of experimental medicine.

[9]  F. Papavasiliou,et al.  The Transcription Elongation Complex Directs Activation-Induced Cytidine Deaminase-Mediated DNA Deamination , 2006, Molecular and Cellular Biology.

[10]  M. Carpenter,et al.  Evaluation of molecular models for the affinity maturation of antibodies: roles of cytosine deamination by AID and DNA repair. , 2006, Chemical reviews.

[11]  U. Storb,et al.  Targeting of the Activation-Induced Cytosine Deaminase Is Strongly Influenced by the Sequence and Structure of the Targeted DNA , 2005, Molecular and Cellular Biology.

[12]  Nikhil S. Joshi,et al.  Deoxyuridine Is Generated Preferentially in the Nontranscribed Strand of DNA from Cells Expressing Activation-Induced Cytidine Deaminase , 2005, The Journal of Immunology.

[13]  M. Lieber,et al.  Fine-Structure Analysis of Activation-Induced Deaminase Accessibility to Class Switch Region R-Loops , 2005, Molecular and Cellular Biology.

[14]  C. Kang,et al.  Sequential multiple functions of the conserved sequence in sequence-specific termination by T7 RNA polymerase. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[15]  Oleg Laptenko,et al.  Bacterial transcription elongation factors: new insights into molecular mechanism of action , 2004, Molecular microbiology.

[16]  Myron F. Goodman,et al.  Biochemical Analysis of Hypermutational Targeting by Wild Type and Mutant Activation-induced Cytidine Deaminase* , 2004, Journal of Biological Chemistry.

[17]  M. Neuberger,et al.  Mismatch recognition and uracil excision provide complementary paths to both Ig switching and the A/T-focused phase of somatic mutation. , 2004, Molecular cell.

[18]  N. Maizels,et al.  Intracellular transcription of G-rich DNAs induces formation of G-loops, novel structures containing G4 DNA. , 2004, Genes & development.

[19]  A. Shilatifard Transcriptional elongation control by RNA polymerase II: a new frontier. , 2004, Biochimica et biophysica acta.

[20]  A. Bhagwat DNA-cytosine deaminases: from antibody maturation to antiviral defense. , 2004, DNA repair.

[21]  Y. Yokota,et al.  Transcription-Coupled Events Associating with Immunoglobulin Switch Region Chromatin , 2003, Science.

[22]  M. Goodman,et al.  Processive AID-catalysed cytosine deamination on single-stranded DNA simulates somatic hypermutation , 2003, Nature.

[23]  A. Bhagwat,et al.  Human activation-induced cytidine deaminase causes transcription-dependent, strand-biased C to U deaminations. , 2003, Nucleic acids research.

[24]  F. Papavasiliou,et al.  AID Mediates Hypermutation by Deaminating Single Stranded DNA , 2003, The Journal of experimental medicine.

[25]  Jeffrey H. Miller,et al.  Use of the rpoB gene to determine the specificity of base substitution mutations on the Escherichia coli chromosome. , 2003, DNA repair.

[26]  M. Nussenzweig,et al.  Transcription enhances AID-mediated cytidine deamination by exposing single-stranded DNA on the nontemplate strand , 2003, Nature Immunology.

[27]  M. Lieber,et al.  R-loops at immunoglobulin class switch regions in the chromosomes of stimulated B cells , 2003, Nature Immunology.

[28]  F. Alt,et al.  Transcription-targeted DNA deamination by the AID antibody diversification enzyme , 2003, Nature.

[29]  M. Goodman,et al.  Activation-induced cytidine deaminase deaminates deoxycytidine on single-stranded DNA but requires the action of RNase , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[30]  T. Ushiki,et al.  Molecular Visualization of Immunoglobulin Switch Region RNA/DNA Complex by Atomic Force Microscope* , 2003, The Journal of Biological Chemistry.

[31]  T. Honjo,et al.  AID Enzyme-Induced Hypermutation in an Actively Transcribed Gene in Fibroblasts , 2002, Science.

[32]  K.,et al.  Biochemistry of Deoxyribonucleic Acid-defective Amber Mutants of Bacteriophage T4 , 2002 .

[33]  Toshiro Matsuda,et al.  Somatic mutation hotspots correlate with DNA polymerase η error spectrum , 2001, Nature Immunology.

[34]  C. Martin,et al.  Fluorescence characterization of the transcription bubble in elongation complexes of T7 RNA polymerase. , 2001, Journal of molecular biology.

[35]  V. Gray-Schopfer,et al.  Increased Transcription Levels Induce Higher Mutation Rates in a Hypermutating Cell Line1 , 2001, The Journal of Immunology.

[36]  T. Honjo,et al.  Class Switch Recombination and Hypermutation Require Activation-Induced Cytidine Deaminase (AID), a Potential RNA Editing Enzyme , 2000, Cell.

[37]  A Grigoriev,et al.  Mutations induced by bacteriophage T7 RNA polymerase and their effects on the composition of the T7 genome. , 2000, Journal of molecular biology.

[38]  A. Bhagwat,et al.  The Role of the Escherichia coli Mug Protein in the Removal of Uracil and 3,N 4-Ethenocytosine from DNA* , 1999, The Journal of Biological Chemistry.

[39]  M. Dreyfus,et al.  NTP concentration effects on initial transcription by T7 RNAP indicate that translocation occurs through passive sliding and reveal that divergent promoters have distinct NTP concentration requirements for productive initiation. , 1998, Journal of molecular biology.

[40]  U. Storb,et al.  A Hypermutable Insert in an Immunoglobulin Transgene Contains Hotspots of Somatic Mutation and Sequences Predicting Highly Stable Structures in the RNA Transcript , 1998, The Journal of experimental medicine.

[41]  C. Milstein,et al.  Hot spot focusing of somatic hypermutation in MSH2-deficient mice suggests two stages of mutational targeting. , 1998, Immunity.

[42]  T. Kunkel,et al.  Altered spectra of hypermutation in antibodies from mice deficient for the DNA mismatch repair protein PMS2. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[43]  J. Hackett,et al.  Cis‐acting sequences that affect somatic hypermutation of Ig genes , 1998, Immunological reviews.

[44]  M. Neuberger,et al.  Multiple sequences from downstream of the Jκ cluster can combine to recruit somatic hypermutation to a heterologous, upstream mutation domain , 1998, European journal of immunology.

[45]  W. Mcallister,et al.  Rapid mutagenesis and purification of phage RNA polymerases. , 1997, Protein expression and purification.

[46]  A. Bhagwat,et al.  Transcription-induced mutations: increase in C to T mutations in the nontranscribed strand during transcription in Escherichia coli. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[47]  U. Storb,et al.  The molecular basis of somatic hypermutation of immunoglobulin genes. , 1996, Current opinion in immunology.

[48]  R. Conaway,et al.  The RNA polymerase II elongation complex , 1995, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[49]  M. Lieber,et al.  RNA:DNA complex formation upon transcription of immunoglobulin switch regions: implications for the mechanism and regulation of class switch recombination. , 1995, Nucleic acids research.

[50]  R. Sousa,et al.  Characterization of a set of T7 RNA polymerase active site mutants. , 1994, The Journal of biological chemistry.

[51]  J. Lebowitz,et al.  Transcription induces the formation of a stable RNA.DNA hybrid in the immunoglobulin alpha switch region. , 1994, The Journal of biological chemistry.

[52]  M. Wyszynski,et al.  Cytosine deaminations catalyzed by DNA cytosine methyltransferases are unlikely to be the major cause of mutational hot spots at sites of cytosine methylation in Escherichia coli. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[53]  D. Patra,et al.  Mutations in T7 RNA polymerase that support the proposal for a common polymerase active site structure. , 1992, The EMBO journal.

[54]  C. Mathews Biochemistry of deoxyribonucleic acid-defective amber mutants of bacteriophage T4. 3. Nucleotide pools. , 1972, The Journal of biological chemistry.

[55]  J. Gallant,et al.  The control of ribonucleic acid synthesis in Escherichia coli. 3. The functional relationship between purine ribonucleoside triphosphate pool sizes and the rate of ribonucleic acid accumulation. , 1969, The Journal of biological chemistry.

[56]  J. Gallant,et al.  The control of ribonucleic acid synthesis in Escherichia coli. II. Stringent control of energy metabolism. , 1969, The Journal of biological chemistry.