A constitutively expressed, truncated umuDC operon regulates the recA-dependent DNA damage induction of a gene in Acinetobacter baylyi strain ADP1

In response to environmentally caused DNA damage, SOS genes are up-regulated due to RecA-mediated relief of LexA repression. In Escherichia coli, the SOS umuDC operon is required for DNA damage checkpoint functions and for replicating damaged DNA in the error-prone process called SOS mutagenesis. In the model soil bacterium Acinetobacter baylyi strain ADP1, however, the content, regulation, and function of the umuDC operon are unusual. The umuC gene is incomplete, and a remnant of an ISEhe3-like transposase has replaced the middle 57% of the umuC coding region. The umuD open reading frame is intact, but it is 1.5 times the size of other umuD genes and has an extra 5' region that lacks homology to known umuD genes. Analysis of a umuD::lacZ fusion showed that umuD was expressed at very high levels in both the absence and presence of mitomycin C and that this expression was not affected in a recA-deficient background. The umuD mutation did not affect the growth rate or survival after UV-induced DNA damage. However, the UmuD-like protein found in ADP1 (UmuDAb) was required for induction of an adjacent DNA damage-inducible gene, ddrR. The umuD mutation specifically reduced the DNA damage induction of the RecA-dependent DNA damage-inducible ddrR locus by 83% (from 12.9-fold to 2.3-fold induction), but it did not affect the 33.9-fold induction of benA, an unrelated benzoate degradation gene. These data suggest that the response of the ADP1 umuDC operon to DNA damage is unusual and that UmuDAb specifically regulates the expression of at least one DNA damage-inducible gene.     

SOS and Mayday: multiple inducible mutagenic pathways in Escherichia coli

Environmental and physiological stress conditions can transiently alter the fidelity of DNA replication. The DNA damage-mediated SOS response in Escherichia coli is the best-known example of such an 'inducible mutagenesis' or 'transient mutator' pathway. Emerging evidence suggests the existence of a number of other stress-inducible pathways that also affect the fidelity of replication. Among the more provocative recent findings are UVM, an SOS-independent damage-inducible mutagenic pathway, and a new recA -dependent but umuD/C -independent pathway that appears to be provoked by translational stress. These findings alter our view of inducible mutagenesis, and anticipate the existence of previously unrecognized links between protein synthesis and DNA replication.     

Yeast omnipotent supressor SUP1 (SUP45): nucleotide sequence of the wildtype and a mutant gene.

The primary structures of the yeast recessive omnipotent suppressor gene SUP1 (SUP45) and one of its mutant alleles (sup1-ts36) was determined. The gene codes for a protein of 49 kD. The mutant protein differs from the wildtype form in one amino acid residue (Ser instead of Leu) in the N-terminal part. The codon usage differs significantly from that of yeast ribosomal protein genes. However, an upstream element resembling a conserved oligonucleotide in the region 5' to ribosomal protein genes in S. cerevisiae has been found. A DNA probe internal to the SUP1 gene does not exhibit detectable homology to genomic DNA neither from higher eucaryotes nor from eu- or archaebacteria. The hypothetical function of this protein in control of translational fidelity is discussed.     

SOS-inducible DNA polymerase II of E coli is homologous to replicative DNA polymerase of eukaryotes

The polB gene of Escherichia coli encodes DNA polymerase II whose role in vivo is not defined. The polB gene has been cloned and shown to be identical to a DNA damage-inducible gene dinA which is regulated by the LexA repressor. Nucleotide sequencing of polB reveals that E coli DNA polymerase II is highly homologous to replicative DNA polymerases of eukaryotes which include human DNA polymerase alpha and Saccharomyces cerevisiae DNA polymerases I, II and III. The polB gene is not required for growth, UV-repair and UV-mutagenesis.     

A role for DNA polymerase V in G --> T mutations from the major benzo[a]pyrene N2-dG adduct when studied in a 5'-TGT sequence in E. coli

Benzo[a]pyrene (B[a]P), a potent mutagen/carcinogen, is metabolically activated to (+)-anti-B[a]PDE, which induces a full spectrum of mutations (e.g. GC --> TA, GC --> AT, etc.) principally via its major adduct [+ta]-B[a]P-N2-dG. Recent findings suggest that different lesion bypass DNA polymerases may be involved in different mutagenic pathways, which is the subject of this report. [+ta]-B[a]P-N2-dG built into a plasmid in a 5'-TGT sequence gives approximately equal numbers of G --> T and G --> A mutations when host E. coli are UV irradiated prior to transformation, so this sequence context was chosen to investigate what DNA polymerases are involved in G --> T versus G --> A mutations. G --> T mutations decline (>10-fold) if E. coli either are not UV-irradiated or are deficient in DNA polymerase V ((delta)umuD/C), demonstrating a role for damage-inducible DNA Pol V in a G --> T pathway. G --> T mutations are not affected by transformation into E. coli deficient in either DNA polymerases II or IV. While the work herein was in progress, Lenne-Samuel et al. [Mol. Microbiol. 38 (2000) 299] built the same adduct into a plasmid in a 5'-GGA sequence, and showed that the frequency of G --> T mutations was similar in UV-irradiated and unirradiated host E. coli cells, suggesting no involvement by damage-inducible, lesion bypass DNA polymerases (i.e., not II, IV or V); furthermore, a role for DNA Pol V was explicitly ruled out. The easiest way to reconcile the findings of Lenne-Samuel et al. with the findings herein is if two G --> T mutagenic pathways exist for [+ta]-B[a]P-N2-dG, where sequence context dictates which pathway is followed. In contrast to the G --> T mutations, herein G --> A mutations from [+ta]-B[a]P-N2-dG in the 5'-TGT sequence context are shown not to be affected by UV-irradiation of host E. coli, and are not dependent on DNA Pol V, or Pol II, Pol IV, or the damage-inducible, but SOS-independent UVM system. Published studies, however, have shown that G --> A mutations are usually enhanced by UV-irradiation of host E. coli prior to the introduction of plasmids either site-specifically modified with [+ta]-B[a]P-N2-dG or randomly adducted with (+)-anti-B[a]PDE; both findings imply the involvement of a lesion-bypass DNA polymerase. These disparate results suggest the existence of two G --> A mutagenic pathways for [+ta]-B[a]P-N2-dG as well, although confirmation of this awaits further study. In conclusion, a comparison between the evidence presented herein and published findings suggests the existence of two distinct mutagenic pathways for both G --> T and G --> A mutations from [+ta]-B[a]P-N2-dG, where in each case one pathway is not damage-inducible and not dependent on a lesion-bypass DNA polymerase, while the second pathway is damage-inducible and dependent on a lesion-bypass DNA polymerase. Furthermore, DNA sequence context appears to dictate which pathway (as defined by the involvement of different DNA polymerases) is followed in each case.     

Roles of CHOP/GADD153 in endoplasmic reticulum stress

Endoplasmic reticulum (ER) is the site of synthesis and folding of secretory proteins. Perturbations of ER homeostasis affect protein folding and cause ER stress. ER can sense the stress and respond to it through translational attenuation, upregulation of the genes for ER chaperones and related proteins, and degradation of unfolded proteins by a quality-control system. However, when the ER function is severely impaired, the organelle elicits apoptotic signals. ER stress has been implicated in a variety of common diseases such as diabetes, ischemia and neurodegenerative disorders. One of the components of the ER stress-mediated apoptosis pathway is C/EBP homologous protein (CHOP), also known as growth arrest- and DNA damage-inducible gene 153 (GADD153). Here, we summarize the current understanding of the roles of CHOP/GADD153 in ER stress-mediated apoptosis and in diseases including diabetes, brain ischemia and neurodegenerative disease.     

A Constitutively Expressed, Truncated umuDC Operon Regulates the recA-Dependent DNA Damage Induction of a Gene in Acinetobacter baylyi Strain ADP1

In response to environmentally caused DNA damage, SOS genes are up-regulated due to RecA-mediated relief of LexA repression. In Escherichia coli, the SOS umuDC operon is required for DNA damage checkpoint functions and for replicating damaged DNA in the error-prone process called SOS mutagenesis. In the model soil bacterium Acinetobacter baylyi strain ADP1, however, the content, regulation, and function of the umuDC operon are unusual. The umuC gene is incomplete, and a remnant of an ISEhe3-like transposase has replaced the middle 57% of the umuC coding region. The umuD open reading frame is intact, but it is 1.5 times the size of other umuD genes and has an extra 5′ region that lacks homology to known umuD genes. Analysis of a umuD::lacZ fusion showed that umuD was expressed at very high levels in both the absence and presence of mitomycin C and that this expression was not affected in a recA-deficient background. The umuD mutation did not affect the growth rate or survival after UV-induced DNA damage. However, the UmuD-like protein found in ADP1 (UmuDAb) was required for induction of an adjacent DNA damage-inducible gene, ddrR. The umuD mutation specifically reduced the DNA damage induction of the RecA-dependent DNA damage-inducible ddrR locus by 83% (from 12.9-fold to 2.3-fold induction), but it did not affect the 33.9-fold induction of benA, an unrelated benzoate degradation gene. These data suggest that the response of the ADP1 umuDC operon to DNA damage is unusual and that UmuDAb specifically regulates the expression of at least one DNA damage-inducible gene.     

Effects of modifying topoisomerase II levels on cellular recovery from radiation damage

Effects of Modifying Topoisomerase II Levels on Cellular Recovery from Radiation Damage. Experiments were performed with the budding yeast, Saccharomyces cerevisiae, to test whether DNA topoisomerase II is involved in repair of DNA damage induced by ionizing radiation. Topoisomerase II was inactivated by use of a temperature-sensitive mutation. Enzyme inactivation increased cellular radiosensitivity, blocked the restitution of broken chromosomes, assayed by pulsed-field gel electrophoresis, and prolonged the induction of a DNA damage-inducible gene (RNR3). Overexpression of the topoisomerase II gene did not alter cellular radiosensitivity. The data support a role for topoisomerase II in the repair of DNA strand breaks.