The pgaABCD operon of Escherichia coli is required for production of the biofilm adhesin poly--1,6-Nacetyl-D-glucosamine (PGA). We establish here that NhaR, a DNA-binding protein of the LysR family of transcriptional regulators, activates transcription of this operon. Disruption of the nhaR gene decreased biofilm formation without affecting planktonic growth. PGA production was undetectable in an nhaR mutant strain. Expression of a pgaA-lacZ translational fusion was induced by NaCl and alkaline pH, but not by CaCl 2 or sucrose, in an nhaR-dependent fashion. Primer extension and quantitative real-time reverse transcription-PCR analyses further revealed that NhaR affects the steady-state level of pga mRNA. A purified recombinant NhaR protein bound specifically and with high affinity within the pgaABCD promoter region; one apparent binding site overlaps the ؊35 element, and a second site lies immediately upstream of the first. This protein was necessary and sufficient for activation of in vitro transcription from the pgaA promoter. These results define a novel mechanism for regulation of biofilm formation in response to environmental conditions and suggest an expanded role for NhaR in promoting bacterial survival.
Human single-stranded DNA binding protein 1 (hSSB1) plays a critical role in responding to DNA damage and maintaining genome stability. However, the regulation of hSSB1 remains poorly studied. Here, we determined that hSSB1 acetylation at K94 mediated by the acetyltransferase p300 and the deacetylases SIRT4 and HDAC10 impaired its ubiquitin-mediated degradation by proteasomes. Moreover, we demonstrated that the hSSB1-K94R mutant had reduced cell survival in response to DNA damage by radiation or chemotherapy drugs. Furthermore, the p300/CBP inhibitor C646 significantly enhanced the sensitivity of cancer cells to chemotherapy drugs, and a positive correlation between hSSB1 and p300 level was observed in clinical colorectal cancer samples. Acetylation, a novel regulatory modification of hSSB1, is crucial for its function under both physiological and pathological conditions. This finding supports the notion that the combination of chemotherapy drugs with acetylation inhibitors may benefit cancer patients.
Pseudorabies virus (PRV), the etiological pathogen of Aujeszky's disease, belongs to the Alphaherpesvirus subfamily. Large latency transcript (LLT), the most abundant PRV transcript, harbors a ~ 4.6 kb microRNA (miRNA) cluster-encoding intron. To investigate the function of the LLT miRNA cluster during the life cycle of PRV, we generated a miRNA cluster mutation virus (PRV-∆miR cluster) and revertant virus. Analysis of the growth kinetics of PRV-ΔmiR cluster-infected cells revealed significantly smaller plaques and lower titers than the wild-type and revertant viruses. The mutation virus exhibited increased IE180 and decreased EP0 expression. The clinical symptoms observed in mice infected with PRV-ΔmiR cluster revealed that the miRNA cluster is involved in the pathogenesis of PRV. Physical parameters, virus shedding assays, and the SN titers revealed that the miRNA cluster enhances PRV virulence in pigs. Collectively, our findings suggest that the full-length miRNA cluster is involved in PRV replication and virulence.
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