The Ubc13 protein was recently identified for its unique role in ubiquitin (Ub) chain assembly at the Ub Lys-63 residue instead of the conventional Lys-48 residue. This activity requires Ubc13 to form a complex with Mms2 and indeed ubc13 and mms2 mutations have been shown elsewhere to be epistatic with respect to UV sensitivity. The MMS2 gene is known to be a member of the error-free DNA postreplication repair (PRR) pathway. By contrast, the Ub Lys-63 residue has been previously implicated in the error-prone PRR pathway, since yeast cells carrying the ubiK63R mutation are defective in UV-induced mutagenesis. In the present study, we attempted to define the role of UBC13 within the PRR pathway. We found that the ubc13 mutation is epistatic to mms2 and rad6, confirming that UBC13 belongs to the PRR-pathway. We also found that ubc13 is synergistic to the error-prone PRR pathway mutation rev3, indicating that UBC13 is in a pathway alternative to REV3 mutagenesis. The ubc13 mutant displays up to a 30-fold increase in the spontaneous mutation rate, and this increase is largely REV3 dependent. In addition, UV-induced mutagenesis is fully functional in the ubc13 mutant. These results together demonstrate that UBC13 is a member of the error-free PRR pathway. The involvement of UBC13 in cellular tolerance to DNA-damage is further implicated by our finding that the UBC13 transcript level is increased up to 6-fold in response to DNA-damage.
SUMMARYS45A, a double recessive mutant at both the BnMs1 and BnMs2 loci in Brassica napus, produces no pollen in mature anthers and no seeds by self-fertilization. The BnMs1 and BnMs2 genes, which have redundant functions in the control of male fertility, are positioned on linkage groups N7 and N16, respectively, and are located at the same locus on Arabidopsis chromosome 1 based on collinearity between Arabidopsis and Brassica. Complementation tests indicated that one candidate gene, BnCYP704B1, a member of the cytochrome P450 family, can rescue male sterility. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) of the developing anther showed that pollen-wall formation in the mutant was severely compromised, with a lack of sporopollenin or exine. The phenotype was first evident at the tetrad stage (stage 7) of anther development, coinciding with the maximum BnCYP704B1 mRNA accumulation observed in tapetal cells at stages 7-8 (haploid stage). TEM also suggested that development of the tapetum was seriously defective due to the disturbed lipid metabolism in the S45A mutant. A TUNEL assay indicated that the pattern of programmed cell death in the tapetum of the S45A mutant was defective. Lipid analysis showed that the total fatty acid content was reduced in the S45A mutant, indicating that BnCYP704B1 is involved in lipid metabolism. These data suggest that BnCYP704B1 participates in a vital tapetum-specific metabolic pathway that is not only involved in exine formation but is also required for basic tapetal cell development and function.
Bacteria employ a coordinated SOS response to DNA damage by enhancing transcription, translesion synthesis, and recombination; a similar phenomenon has not been reported in eukaryotes. Here, we demonstrate that the ubiquitination complex Rad6-Rad18 is required for the increased transcription of a large number of yeast genes in response to DNA damage. Rad6-Rad18 promotes DNA-damage-dependent transcriptional induction as well as checkpoint functions by catalyzing monoubiquitination at the K197 residue of the Rad17 subunit of the 9-1-1 complex. Rad17 ubiquitination invokes both DNA damage responsive pathways by promoting efficient Rad53 phosphorylation, possibly through the recruitment or maintenance of the 9-1-1 clamp at sites of lesions. Taken together, the Rad6-Rad18 complex is involved in the control of global gene regulation in a way reminiscent of the bacterial SOS response and plays key roles in coordinating several DNA damage response pathways through ubiquitination of two DNA clamps, PCNA and 9-1-1.
1. Modulation of Ca(2+)-channel currents by phorbol-12-myristate-13-acetate (PMA) was investigated in acutely dissociated adult rat superior cervical ganglion neurons using the whole cell variant of the patch-clamp technique. 2. PMA (500 nM) increased the current amplitudes, accelerated the inactivation of step currents, retarded the deactivation of tail currents, and shifted the tail current activation to more negative potentials. 3. The effects of PMA were concentration and voltage dependent and mediated through activation of protein kinase C (PKC). PMA also increased Ca2+ currents recorded with the perforated patch technique. 4. PMA affected the N-type Ca2+ channels and an omega-conotoxin GVIA-resistant current component. Ca2+ currents affected by PMA were not sensitive to omega-agatoxin IVA or nimodipine. 5. PMA not only attenuated Ca(2+)-channel inhibition induced by alpha 2-adrenoceptor agonist, which modulates Ca2+ channels via a pertussis toxin (PTX)-sensitive pathway, but also attenuated current inhibition by vasoactive intestinal polypeptide, which modulates Ca2+ channels via a PTX-insensitive but cholera toxin-sensitive pathway. 6. PMA reversed Ca(2+)-channel inhibition induced by tonic activation of G-protein in the absence of neurotransmitter (even in neurons pretreated with PTX) or induced by activation of G-proteins with guanosine 5'-O-(3-thiotriphosphate) (GTP)-gamma-S. 7. Inhibition of phosphatase by okadaic acid or substitution of Ba2+ for Ca2+ in the external solutions accelerated the PMA effect. 8. Our results suggest that activation of PKC antagonizes G-protein mediated inhibition of Ca2+ channels by shifting Ca2+ channels from the "reluctant" state to the "willing" state. The G-proteins and, more likely, the N-type Ca2+ channels may be the target of PKC phosphorylation. Protein phosphatases may be involved in counteracting the PKC phosphorylation in rat sympathetic neurons.
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