Duohong Sheng

The in vitro activity of a Rad55 homologue from Sulfolobus tokodaii, a candidate mediator in RadA-catalyzed homologous recombination

Archaea have recombination proteins similar to those of eukaryote, but many have not been characterized. Here, the characterization of a Rad55 homologue from Sulfolobus tokodaii (stRad55A) was reported. StRad55A protein preferred binding to ssDNA and had ssDNA-dependent ATPase activity. In addition, UV light could induce the expression of this protein, which was different from RadB, a RadA paralog found in euryarchaeota. Most importantly, stRad55A could release the suppression of excessive stSSB (single strand DNA binding protein from S. tokodaii) on the strand exchange catalyzed by stRadA (RadA homologue from S. tokodaii), by interacting directly with both stRadA and stSSB. StRad55A may function as a mediator to accelerate the displacement of stSSB by stRadA.

Dissection of the functional domains of an archaeal Holliday junction helicase

Helicases and nucleases form complexes that play very important roles in DNA repair pathways some of which interact with each other at Holliday junctions. In this study, we present in vitro and in vivo analysis of Hjm and its interaction with Hjc in Sulfolobus. In vitro studies employed Hjm from the hyperthermophilic archaeon Sulfolobus tokodaii (StoHjm) and its truncated derivatives, and characterization of the StoHjm proteins revealed that the N-terminal module (residues 1-431) alone was capable of ATP hydrolysis and DNA binding, while the C-terminal one (residues 415-704) was responsible for regulating the helicase activity. The region involved in StoHjm-StoHjc (Hjc from S. tokodaii) interaction was identified as part of domain II, domain III (Winged Helix motif), and domain IV (residues 366-645) for StoHjm. We present evidence supporting that StoHjc regulates the helicase activity of StoHjm by inducing conformation change of the enzyme. Furthermore, StoHjm is able to prevent the formation of Hjc/HJ high complex, suggesting a regulation mechanism of Hjm to the activity of Hjc. We show that Hjm is essential for cell viability using recently developed genetic system and mutant propagation assay, suggesting that Hjm/Hjc mediated resolution of stalled replication forks is of crucial importance in archaea. A tentative pathway with which Hjm/Hjc interaction could have occurred at stalled replication forks is discussed.

Single-stranded DNA binding activity of XPBI, but not XPBII, from Sulfolobus tokodaii causes double-stranded DNA melting

XPB helicase is the largest subunit of transcription factor IIH (TFIIH), a ten-subunit protein complex essential for transcription initiation and nucleotide excision repair (NER) in Eukarya. Two XPB homologues (XPBI and XPBII) are present in the genome of most crenarchaeota, one of the two major phyla of archaea; however, the biochemical properties have not been fully characterized and their cellular roles have not been clearly defined. Here, we report that XPBI from the hyperthermophilic crenarchaeon Sulfolobus tokodaii (StoXPBI) is able to destabilize double-stranded DNA (dsDNA) helix independent of ATP (designated as dsDNA melting activity). This activity is inhibited by single-stranded DNA (ssDNA) and relies on the unique N-terminal domain of StoXPBI, which is also likely responsible for the intrinsic strong ssDNA binding activity of StoXPBI as revealed by deletion analysis. We demonstrate that the ATPase activity of StoXPBII is remarkably stimulated by StoBax1, a nuclease partner of StoXPBII. The role of the unique dsDNA melting activity of XPBI in NER in archaea was discussed.

Sulfolobus tokodaii RadA paralog, stRadC2, is involved in DNA recombination via interaction with RadA and Hjc

Rad51/RadA paralogs found in eukaryotes and euryarchaea play important roles during recombination and repair, and mutations in one of the human Rad51 paralogs, Rad51C, are associated with breast and ovarian cancers. The hyperthermophilic crenarchaeon Sulfolobus tokodaii encodes four putative RadA paralogs and studies on these proteins may assist in understanding the functions of human Rad51 paralogs. Here, we report the biochemical characterization of stRadC2, a S. tokodaii RadA paralog. Pull-down assays revealed that the protein was able to interact with the recombinase, RadA, and the Holliday junction endonuclease, Hjc. stRadC2 inhibited the strand exchange activity of RadA and facilitated Hjc-mediated Holliday junction DNA cleavage in vitro. RT-PCR analysis revealed that stRadC2 transcription was immediately reduced after UV irradiation, but was restored to normal levels at the late stages of DNA repair. Our results suggest that stRadC2 may act as an antirecombination factor in DNA recombinational repair in S. tokodaii.

Spatial subunit distribution and in vitro functions of the novel trimeric PCNA complex from Sulfolobus tokodaii.

The relationships among three PCNA (proliferating cell nuclear antigen) subunits in the hyperthermophilic archaeon Sulfolobus tokodaii (StoPCNAs) were analyzed and the effects of two PCNA complexes on the activities of the DNA helicase Hjm, DNA Ligase I, and Holliday junction specific endonuclease Hjc were tested. There was no strong self-interaction of each StoPCNA. StoPCNA1 and StoPCNA3 interacted with each other, so did StoPCNA2 and StoPCNA3, but no interaction between StoPCNA1 and StoPCNA2 was observed. Two trimeric complexes (designed StoPCNA123 and StoPCNA323) were formed in vitro and it was determined that StoPCNA323 was composed of one StoPCNA2 and two StoPCNA3 subunits, with StoPCNA2 bridging the two StoPCNA3 subunits. Both complexes inhibited the unwinding activity of Hjm and the ligation activity of DNA Ligase I. In contrast, both stimulated the Holliday junction cleavage activity of Hjc. Our results provide further evidence that in crenarchaea, the PCNAs exhibit diversity in subunit interaction and complex formation.

The carboxyl terminal of the archaeal nuclease NurA is involved in the interaction with single-stranded DNA-binding protein and dimer formation

The nuclease NurA is present in all known thermophilic archaea and has been implicated to facilitate efficient DNA double-strand break end processing in Mre11/Rad50-mediated homologous recombinational repair. To understand the structural and functional relationship of this enzyme, we constructed five site-directed mutants of NurA from Sulfolobus tokodaii (StoNurA), D56A, E114A, D131A, Y291A, and H299A, at the conserved motifs, and four terminal deletion mutants, StoNurAΔN (19–331), StoNurAΔNΔC (19–303), StoNurAΔC (1–281), and StoNurAΔC (1–303), and characterized the proteins biochemically. We found that mutation at the acidic residue, D56, E114, D131, or at the basic residue, H299, abolishes the nuclease activity, while mutation at the aromatic residue Y291 only impairs the activity. Interestingly, by chemical cross-linking assay, we found that the mutant Y291A is unable to form stable dimer. Additionally, we demonstrated that deletion of the C-terminal amino acid residues 304–331 of StoNurA results in loss of the physical and functional interaction with the single-stranded DNA-binding protein (StoSSB). These results established that the C-terminal conserved aromatic residue Y291 is involved in dimer formation and the C-terminal residues 304–331 of NurA are involved in the interaction with single-stranded DNA-binding protein.

RecX is involved in the switch between DNA damage response and normal metabolism in D. radiodurans.

Apart from inhibiting RecA activity through protein-protein interactions, Deinococcus radiodurans RecX inhibits the expression of RecA and two other anti-oxidant proteins. To identify the repertoire of proteins regulated by RecX, comparative proteomic studies were undertaken on a wild-type strain (R1) and recX null mutant (RecX(-)). Two-dimensional electrophoresis followed by MALDI-TOF identification revealed 35 differentially expressed proteins, including 12 up-regulated and 23 down-regulated proteins in the mutant. The 12 up-regulated proteins are DNA repair proteins, stress response proteins, and metabolism-related proteins. Most of these have been previously characterized as ionizing radiation-induced proteins. The 23 down-regulated proteins are mainly involved in cellular metabolism, and some of these are key enzymes in the metabolic pathway. Thus, RecX is suggested to be involved in the switch between DNA damage response and normal metabolism in D. radiodurans.

Repression of recA Induction by RecX Is Independent of the RecA Protein in Deinococcus radiodurans

Besides inhibiting RecA activity at the protein level, Deinococcus radiodurans RecX can suppress RecA induction at the transcriptional level. The regulation of RecX on recA induction is independent of RecA activity, and its N terminus is involved in this process.

SCO5351 is a pleiotropic factor that impacts secondary metabolism and morphological development in Streptomyces coelicolor

The genome of Streptomyces coelicolor encodes hundreds of putative regulatory proteins, most of which are of unknown function, including SCO5351. In this study, we determined that deletion of sco5351 largely abrogates production of actinorhodin (ACT) and reduces production of the calcium-dependent antibiotic (CDA). Comprehensive transcriptional analyses indicated that transcription of genes of the ACT pathway, including the pathway-specific regulator actII-orf4 and those involved in the building of the chemical compound, was markedly lower in Δsco5351 in the late growth phase. However, transcription of genes in the CDA cluster was notably reduced in Δsco5351 only in the early growth phase, suggesting that SCO5351 has a regulatory role throughout growth. Similar to the observations with Δsco5351, ACT production was blocked by mutagenesis of three conserved amino acids potentially involved in dimerization of SCO5351, indicating that protein dimerization is critical to the function of SCO5351. In addition, disruption of sco5351 delayed the formation of aerial mycelium and spores under the conditions tested and, consistent with this, transcription of developmental genes associated with spore formation was reduced in Δsco5351, implying that SCO5351 is involved in developmental control. Our findings reveal SCO5351 as a pleiotropic regulator with roles in both secondary metabolism and morphological development in S. coelicolor.