Project description:Yeast DNA polymerase (Pol) delta, essential for DNA replication, is comprised of 3 subunits, Pol3, Pol31, and Pol32. Of these, the catalytic subunit Pol3 and the second subunit Pol31 are essential, whereas the Pol32 subunit is not essential for DNA replication. Although Pol32 is an integral component of Pol delta, it is also required for translesion synthesis (TLS) by Pol zeta. To begin to decipher the bases of Pol32 involvement in Pol zeta-mediated TLS, here we examine whether Pol32 physically interacts with Pol zeta or its associated proteins and provide evidence for the physical interaction of Pol32 with Rev1. Rev1 plays an indispensable structural role in Pol zeta-mediated TLS and it binds the Rev3 catalytic subunit of Pol zeta. Here, we show that although Pol32 does not directly bind Pol zeta, Pol32 can bind the Rev1-Pol zeta complex through its interaction with Rev1. We find that Pol32 binding has no stimulatory effect on DNA synthesis either by Rev1 in the Rev1-Pol32 complex or by Pol zeta in the Pol zeta-Rev1-Pol32 complex, irrespective of whether proliferating cell nuclear antigen has been loaded onto DNA or not. We discuss evidence for the biological significance of Rev1 binding to Pol32 for Pol zeta function in TLS and suggest a structural role for Rev1 in modulating the binding of Pol zeta with Pol32 in Pol delta stalled at a lesion site.

Project description:Replication through a diverse array of DNA lesions occurs by the sequential action of two translesion synthesis (TLS) DNA polymerases (Pols), in which one inserts the nucleotide opposite the lesion and the other carries out the subsequent extension. By extending from the nucleotide inserted by another Pol, Pol? plays an indispensable role in mediating lesion bypass. Pol? comprises the Rev3 catalytic and Rev7 accessory subunits. Pol32, a subunit of the replicative polymerase Pol?, is also required for Pol?-dependent TLS, but how this Pol? subunit contributes to Pol? function in TLS has remained unknown. Here we show that yeast Pol? is a four-subunit enzyme containing Rev3, Rev7, Pol31, and Pol32; in this complex, association with Pol31/Pol32 is mediated via binding of the Rev3 C terminus to Pol31. The functional requirement of this complex is supported by evidence that mutational inactivation of Rev3's ability to bind Pol31 abrogates Pol?'s role in TLS in yeast cells. These findings identify an unexpected role of Pol31 and Pol32 as two essential subunits of Pol?, and clarify why these proteins are required for Pol?-dependent TLS, but not for TLS mediated by Pol? in yeast cells. To distinguish the four-subunit complex from the two-subunit Pol?, we designate the four-subunit enzyme "Pol?-d," where "-d" denotes the Pol31/Pol32 subunits of Pol?.

Project description:Common fragile sites (CFS) are chromosomal regions that exhibit instability during DNA replication stress. Although the mechanism of CFS expression has not been fully elucidated, one known feature is a severely delayed S-phase. We used an in vitro primer extension assay to examine the progression of DNA synthesis through various sequences within FRA16D by the replicative human DNA polymerases delta and alpha, and with human cell-free extracts. We found that specific cis-acting sequence elements perturb DNA elongation, causing inconsistent DNA synthesis rates between regions on the same strand and complementary strands. Pol delta was significantly inhibited in regions containing hairpins and microsatellites, [AT/TA](24) and [A/T](19-28), compared with a control region with minimal secondary structure. Pol delta processivity was enhanced by full length Werner Syndrome protein (WRN) and by WRN fragments containing either the helicase domain or DNA-binding C-terminal domain. In cell-free extracts, stalling was eliminated at smaller hairpins, but persisted in larger hairpins and microsatellites. Our data support a model whereby CFS expression during cellular stress is due to a combination of factors--density of specific DNA secondary-structures within a genomic region and asymmetric rates of strand synthesis.

Project description:We used electron microscopy to examine the structure of human DNA pol gamma, the heterotrimeric mtDNA replicase implicated in certain mitochondrial diseases and aging models. Separate analysis of negatively stained preparations of the catalytic subunit, pol gammaA, and of the holoenzyme including a dimeric accessory factor, pol gammaB(2), permitted unambiguous identification of the position of the accessory factor within the holoenzyme. The model explains protection of a partial chymotryptic cleavage site after residue L(549) of pol gammaA upon binding of the accessory subunit. This interaction region is near residue 467 of pol gammaA, where a disease-related mutation has been reported to impair binding of the B subunit. One pol gammaB subunit dominates contacts with the catalytic subunit, while the second B subunit is largely exposed to solvent. A model for pol gamma is discussed that considers the effects of known mutations in the accessory subunit and the interaction of the enzyme with DNA.

Project description:Phosphorylase kinase (PhK) is a hexadecameric (????)(4) complex that regulates glycogenolysis in skeletal muscle. Activity of the catalytic ? subunit is regulated by allosteric activators targeting the regulatory ?, ?, and ? subunits. Three-dimensional EM reconstructions of PhK show it to be two large (????)(2) lobes joined with D(2) symmetry through interconnecting bridges. The subunit composition of these bridges was unknown, although indirect evidence suggested the ? subunits may be involved in their formation. We have used biochemical, biophysical, and computational approaches to not only address the quaternary structure of the ? subunits within the PhK complex, i.e. whether they compose the bridges, but also their secondary and tertiary structures. The secondary structure of ? was determined to be predominantly helical by comparing the CD spectrum of an ??? subcomplex with that of the native (????)(4) complex. An atomic model displaying tertiary structure for the entire ? subunit was constructed using chemical cross-linking, MS, threading, and ab initio approaches. Nearly all this model is covered by two templates corresponding to glycosyl hydrolase 15 family members and the A subunit of protein phosphatase 2A. Regarding the quaternary structure of the ? subunits, they were directly determined to compose the four interconnecting bridges in the (????)(4) kinase core, because a ?(4) subcomplex was observed through both chemical cross-linking and top-down MS of PhK. The predicted model of the ? subunit was docked within the bridges of a cryoelectron microscopic density envelope of PhK utilizing known surface features of the subunit.

Project description:Replication of eukaryotic genomes relies on the family B DNA polymerases Pol α, Pol δ, and Pol ε. All of these enzymes coordinate an iron-sulfur (FeS) cluster, but the function of this cofactor has remained largely unclear. Here, we show that the FeS cluster in the catalytic subunit of human Pol δ is coordinated by four invariant cysteines of the C-terminal CysB motif. FeS cluster loss causes a partial destabilisation of the four-subunit enzyme, a defect in double-stranded DNA binding, and compromised polymerase and exonuclease activities. Importantly, complex stability, DNA binding, and enzymatic activities are restored in the presence of proliferating cell nuclear antigen. We further show that also more subtle changes to the FeS cluster-binding pocket that do not abolish FeS cluster binding can have repercussions on the distant exonuclease domain and render the enzyme error prone. Our data hence suggest that the FeS cluster in human Pol δ is an important co-factor that despite its C-terminal location has an impact on both DNA polymerase and exonuclease activities, and can influence the fidelity of DNA synthesis.

Project description:Eukaryotic DNA polymerase ? (pol ?) plays a crucial role in chromosomal DNA replication and various DNA repair processes. It is thought to consist of p125, p66 (p68), p50 and p12 subunits. However, rigorous isolation of mammalian pol ? from natural sources has usually yielded two-subunit preparations containing only p125 and p50 polypeptides. While recombinant pol ? isolated from infected insect cells have some problems of consistency in the quality of the preparations, and the yields are much lower. To address these deficiencies, we have constructed recombinant BmNPV baculoviruses using MultiBac system. This method makes the generation of recombinant forms of pol ? containing mutations in any one of the subunits or combinations thereof extremely facile. From about 350 infected larvae, we obtained as much as 4 mg of pol ? four-subunit complex. Highly purified enzyme behaved like the one of native form by rigorous characterization and comparison of its activities on poly(dA)/oligo(dT) template-primer and singly primed M13 DNA, and its homogeneity on FPLC gel filtration. In vitro base excision repair (BER) assays showed that pol ? plays a significant role in uracil-intiated BER and is more likely to mediate LP BER, while the trimer lacking p12 is more likely to mediate SN BER. It seems likely that loss of p12 modulates the rate of SN BER and LP BER during the repair process. Thus, this work provides a simple, fast, reliable and economic way for the large-scale production of human DNA polymerase ? with a high activity and purity, setting up a new platform for our further research on the biochemical properties of pol ?, its regulation and the integration of its functions, and how alterations in pol ? function could contribute to the etiology of human cancer or other diseases that can result from loss of genomic stability.

Project description:Human DNA polymerase ? (Pol ?) is involved in various DNA damage responses in addition to its central role in DNA replication. The Pol ?4 holoenzyme consists of four subunits, p125, p50, p68 and p12. It has been established that the p12 subunit is rapidly degraded in response to DNA damage by UV leading to the in vivo conversion of Pol ?4 to Pol ?3, a trimeric form lacking the p12 subunit. We provide the first analysis of the time-dependent recruitment of the individual Pol ? subunits to sites of DNA damage produced by UV irradiation through 5 ?m polycarbonate filters by immunofluorescence microscopy and laser scanning cytometry (LSC). Quantitative analysis demonstrates that the recruitments of the three large subunits was near complete by 2 h and did not change significantly up to 4 h after UV exposure. However, the recruitment of p12 was incomplete even at 4 h, with about 70% of the Pol ? lacking the p12 subunit. ChIP analysis of Pol ? after global UV irradiation further demonstrates that only p125, p50 and p68 were present. Thus, Pol ?3 is the predominant form of Pol ? at sites of UV damage as a result of p12 degradation. Using LSC, we have further confirmed that Pol ? was recruited to CPD damage sites in all phases of the cell cycle. Collectively, our results show that Pol ? at the DNA damage site is the Pol ? trimer lacking p12 regardless of the cell cycle phase.

Project description:Here we report the crystal structure of the human mitochondrial RNA polymerase (mtRNAP) transcription elongation complex, determined at 2.65-Å resolution. The structure reveals a 9-bp hybrid formed between the DNA template and the RNA transcript and one turn of DNA both upstream and downstream of the hybrid. Comparisons with the distantly related RNA polymerase (RNAP) from bacteriophage T7 indicates conserved mechanisms for substrate binding and nucleotide incorporation but also strong mechanistic differences. Whereas T7 RNAP refolds during the transition from initiation to elongation, mtRNAP adopts an intermediary conformation that is capable of elongation without refolding. The intercalating hairpin that melts DNA during T7 RNAP initiation separates RNA from DNA during mtRNAP elongation. Newly synthesized RNA exits toward the pentatricopeptide repeat (PPR) domain, a unique feature of mtRNAP with conserved RNA-recognition motifs.

Project description:RNA polymerase III (Pol III) transcribes essential structured small RNAs, such as tRNAs, 5S rRNA and U6 snRNA. The transcriptional activity of Pol III is tightly controlled and its dysregulation is associated with human diseases, such as cancer. Human Pol III has two isoforms with difference only in one of its subunits RPC7 (α and β). Despite structural studies of yeast Pol III, structure of human Pol III remains unsolved. Here, we determined the structures of 17-subunit human Pol IIIα complex in the backtracked and post-translocation states, respectively. Human Pol III contains a generally conserved catalytic core, similar to that of yeast counterpart, and structurally unique RPC3-RPC6-RPC7 heterotrimer and RPC10. The N-ribbon of TFIIS-like RPC10 docks on the RPC4-RPC5 heterodimer and the C-ribbon inserts into the funnel of Pol III in the backtracked state but is more flexible in the post-translocation state. RPC7 threads through the heterotrimer and bridges the stalk and Pol III core module. The winged helix 1 domain of RPC6 and the N-terminal region of RPC7α stabilize each other and may prevent Maf1-mediated repression of Pol III activity. The C-terminal FeS cluster of RPC6 coordinates a network of interactions that mediate core-heterotrimer contacts and stabilize Pol III. Our structural analysis sheds new light on the molecular mechanism of human Pol IIIα-specific transcriptional regulation and provides explanations for upregulated Pol III activity in RPC7α-dominant cancer cells.