Your search keyword '"Finger LD"' showing total 33 results

1. Cellularly active N-hydroxyurea FEN1 inhibitors block substrate entry to the active site

Author

Exell, JC, Thompson, MJ, Finger, LD, Shaw, SJ, Debreczeni, J, Ward, TA, McWhirter, C, Siöberg, CLB, Molina, DM, Abbott, WM, Jones, CD, Nissink, JWM, Durant, ST, and Grasby, JA

Abstract

The structure-specific nuclease human flap endonuclease-1 (hFEN1) plays a key role in DNA replication and repair and may be of interest as an oncology target. We present the crystal structure of inhibitor-bound hFEN1, which shows a cyclic N-hydroxyurea bound in the active site coordinated to two magnesium ions. Three such compounds had similar IC50 values but differed subtly in mode of action. One had comparable affinity for protein and protein–substrate complex and prevented reaction by binding to active site catalytic metal ions, blocking the necessary unpairing of substrate DNA. Other compounds were more competitive with substrate. Cellular thermal shift data showed that both inhibitor types engaged with hFEN1 in cells, and activation of the DNA damage response was evident upon treatment with inhibitors. However, cellular EC50 values were significantly higher than in vitro inhibition constants, and the implications of this for exploitation of hFEN1 as a drug target are discussed.

Published

2016

2. FEN1 (flap structure-specific endonuclease 1)

Author

Finger, LD, primary and Shen, B, additional

Published

2011

3. Efficient Synthesis of DNA Duplexes Containing Reduced Acetaldehyde Interstrand Cross-Links.

Author

Morton SB, Finger LD, van der Sluijs R, Mulcrone WD, Hodskinson M, Millington CL, Vanhinsbergh C, Patel KJ, Dickman MJ, Knipscheer P, Grasby JA, and Williams DM

Subjects

Cross-Linking Reagents, DNA Replication, DNA Repair, DNA Damage, Acetaldehyde, DNA metabolism

Abstract

DNA interstrand cross-links (ICLs) prevent DNA replication and transcription and can lead to potentially lethal events, such as cancer or bone marrow failure. ICLs are typically repaired by proteins within the Fanconi Anemia (FA) pathway, although the details of the pathway are not fully established. Methods to generate DNA containing ICLs are key to furthering the understanding of DNA cross-link repair. A major route to ICL formation in vivo involves reaction of DNA with acetaldehyde, derived from ethanol metabolism. This reaction forms a three-carbon bridged ICL involving the amino groups of adjacent guanines in opposite strands of a duplex resulting in amino and imino functionalities. A stable reduced form of the ICL has applications in understanding the recognition and repair of these types of adducts. Previous routes to creating DNA duplexes containing these adducts have involved lengthy post-DNA synthesis chemistry followed by reduction of the imine. Here, an efficient and high-yielding approach to the reduced ICL using a novel N 2 -(( R )-4-trifluoroacetamidobutan-2-yl)-2'-deoxyguanosine phosphoramidite is described. Following standard automated DNA synthesis and deprotection, the ICL is formed overnight in over 90% yield upon incubation at room temperature with a complementary oligodeoxyribonucleotide containing 2-fluoro-2'-deoxyinosine. The cross-linked duplex displayed a melting transition 25 °C higher than control sequences. Importantly, we show using the Xenopus egg extract system that an ICL synthesized by this method is repaired by the FA pathway. The simplicity and efficiency of this methodology for preparing reduced acetaldehyde ICLs will facilitate access to these DNA architectures for future studies on cross-link repair.

Published

2023

4. Flap Endonuclease 1 Mutations A159V and E160D Cause Genomic Instability by Slowing Reaction on Double-Flap Substrates.

Author

Algasaier SI, Finger LD, Bennet IA, and Grasby JA

Subjects

Amino Acid Substitution, Animals, Catalytic Domain genetics, DNA chemistry, DNA metabolism, Flap Endonucleases metabolism, Fluorescence Resonance Energy Transfer, Genomic Instability, Kinetics, Mice, Models, Molecular, Mutagenesis, Site-Directed, Nucleic Acid Conformation, Substrate Specificity, Flap Endonucleases chemistry, Flap Endonucleases genetics

Abstract

Flap endonuclease 1 (FEN1) is a structure-selective nuclease best known for its roles in the penultimate steps of Okazaki fragment maturation, long-patch base excision repair and ribonucleotide excision repair. To better understand the role of FEN1 in genome maintenance in yeast and mammals, FEN1 active site mutations (A159V and E160D) have been used as tools to dissect its involvement in DNA metabolic pathways. However, discrepancies concerning the biochemistry and molecular etiology of genomic instability when FEN1 function is altered exist. Here, a detailed biochemical and biophysical characterization of mouse FEN1 and mutants is presented. Kinetic measurements showed that the active site mutants A159V and E160D reduce the rates of hydrolysis under multiple- and single-turnover conditions on all substrates. Consistent with their dominant negative effects in heterozygotes, neither mutation affects the adoption of the substrate duplex arms in the bent conformation on the enzyme surface, although decreases in substrate binding affinity are observed. The ability of the mutants to induce the requisite local DNA conformational change near the scissile phosphate is adversely affected, suggesting that the ability to place the scissile phosphate optimally in the active site causes the reduction in rates of phosphate diester hydrolysis. Further analysis suggests that the A159V mutation causes the chemistry of phosphate diester hydrolysis to become rate-limiting, whereas the wild-type and E160D proteins are likely rate-limited by a conformational change. On the basis of these results, the proposed roles of FEN1 in genome maintenance derived from studies involving these mutations are reassessed.

Published

2018

5. Regional conformational flexibility couples substrate specificity and scissile phosphate diester selectivity in human flap endonuclease 1.

Author

Bennet IA, Finger LD, Baxter NJ, Ambrose B, Hounslow AM, Thompson MJ, Exell JC, Shahari NNBM, Craggs TD, Waltho JP, and Grasby JA

Subjects

Catalytic Domain, Cations, Divalent chemistry, DNA chemistry, DNA metabolism, Flap Endonucleases metabolism, Fluorescence Resonance Energy Transfer, Humans, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Phosphates chemistry, Protein Conformation, Protein Structure, Secondary, Substrate Specificity, Flap Endonucleases chemistry

Abstract

Human flap endonuclease-1 (hFEN1) catalyzes the divalent metal ion-dependent removal of single-stranded DNA protrusions known as flaps during DNA replication and repair. Substrate selectivity involves passage of the 5'-terminus/flap through the arch and recognition of a single nucleotide 3'-flap by the α2-α3 loop. Using NMR spectroscopy, we show that the solution conformation of free and DNA-bound hFEN1 are consistent with crystal structures; however, parts of the arch region and α2-α3 loop are disordered without substrate. Disorder within the arch explains how 5'-flaps can pass under it. NMR and single-molecule FRET data show a shift in the conformational ensemble in the arch and loop region upon addition of DNA. Furthermore, the addition of divalent metal ions to the active site of the hFEN1-DNA substrate complex demonstrates that active site changes are propagated via DNA-mediated allostery to regions key to substrate differentiation. The hFEN1-DNA complex also shows evidence of millisecond timescale motions in the arch region that may be required for DNA to enter the active site. Thus, hFEN1 regional conformational flexibility spanning a range of dynamic timescales is crucial to reach the catalytically relevant ensemble.

Published

2018

6. Corrigendum: Phosphate steering by Flap Endonuclease 1 promotes 5'-flap specificity and incision to prevent genome instability.

Author

Tsutakawa SE, Thompson MJ, Arvai AS, Neil AJ, Shaw SJ, Algasaier SI, Kim JC, Finger LD, Jardine E, Gotham VJB, Sarker AH, Her MZ, Rashid F, Hamdan SM, Mirkin SM, Grasby JA, and Tainer JA

Abstract

[This corrects the article DOI: 10.1038/ncomms15855.].

Published

2017

7. Human Exonuclease 1 Threads 5'-Flap Substrates through Its Helical Arch.

Author

Shaw SJ, Finger LD, and Grasby JA

Subjects

Flap Endonucleases chemistry, Humans, Kinetics, Protein Structure, Secondary, DNA chemistry, DNA Repair, DNA Repair Enzymes chemistry, Exodeoxyribonucleases chemistry, Models, Chemical

Abstract

Human exonuclease 1 (hEXO1) is a member of the 5'-nuclease superfamily and plays important roles in DNA repair. Along with acting as a 5'-exonuclease on blunt, gapped, nicked, and 3'-overhang DNAs, hEXO1 can also act as an endonuclease removing protruding 5'-single-stranded flaps from duplex ends. How hEXO1 and related 5'-nuclease human flap endonuclease 1 (hFEN1) are specific for discontinuous DNA substrates like 5'-flaps has been controversial. Here we report the first functional data that imply that hEXO1 threads the 5'-flap through a hole in the protein known as the helical arch, thereby excluding reactions of continuous single strands. Conjugation of bulky 5'-streptavidin that would "block" threading through the arch drastically slowed the hEXO1 reaction. In contrast, addition of streptavidin to a preformed hEXO1 5'-biotin flap DNA complex trapped a portion of the substrate in a highly reactive threaded conformation. However, another fraction behaves as if it were "blocked" and decayed very slowly, implying there were both threaded and unthreaded forms of the substrate present. The reaction of an unmodified hEXO1-flap DNA complex did not exhibit marked biphasic kinetics, suggesting a fast re-equilibration occurs that produces more threaded substrate when some decays. The finding that a threading mechanism like that used by hFEN1 is also used by hEXO1 unifies the mode of operation for members of the 5'-nuclease superfamily that act on discontinuous substrates. As with hFEN1, intrinsic disorder of the arch region of the protein may explain how flaps can be threaded without a need for a coupled energy source.

Published

2017

8. Phosphate steering by Flap Endonuclease 1 promotes 5'-flap specificity and incision to prevent genome instability.

Author

Tsutakawa SE, Thompson MJ, Arvai AS, Neil AJ, Shaw SJ, Algasaier SI, Kim JC, Finger LD, Jardine E, Gotham VJB, Sarker AH, Her MZ, Rashid F, Hamdan SM, Mirkin SM, Grasby JA, and Tainer JA

Subjects

Amino Acid Sequence, Binding Sites, Catalytic Domain, DNA chemistry, DNA metabolism, DNA Repair, DNA Replication, Flap Endonucleases chemistry, Flap Endonucleases genetics, Humans, Mutation, Phosphates chemistry, Sequence Alignment, Substrate Specificity, DNA genetics, Flap Endonucleases metabolism, Genomic Instability, Phosphates metabolism

Abstract

DNA replication and repair enzyme Flap Endonuclease 1 (FEN1) is vital for genome integrity, and FEN1 mutations arise in multiple cancers. FEN1 precisely cleaves single-stranded (ss) 5'-flaps one nucleotide into duplex (ds) DNA. Yet, how FEN1 selects for but does not incise the ss 5'-flap was enigmatic. Here we combine crystallographic, biochemical and genetic analyses to show that two dsDNA binding sites set the 5'polarity and to reveal unexpected control of the DNA phosphodiester backbone by electrostatic interactions. Via 'phosphate steering', basic residues energetically steer an inverted ss 5'-flap through a gateway over FEN1's active site and shift dsDNA for catalysis. Mutations of these residues cause an 18,000-fold reduction in catalytic rate in vitro and large-scale trinucleotide (GAA) n repeat expansions in vivo, implying failed phosphate-steering promotes an unanticipated lagging-strand template-switch mechanism during replication. Thus, phosphate steering is an unappreciated FEN1 function that enforces 5'-flap specificity and catalysis, preventing genomic instability.

Published

2017

9. Cellularly active N-hydroxyurea FEN1 inhibitors block substrate entry to the active site.

Author

Exell JC, Thompson MJ, Finger LD, Shaw SJ, Debreczeni J, Ward TA, McWhirter C, Siöberg CL, Martinez Molina D, Abbott WM, Jones CD, Nissink JW, Durant ST, and Grasby JA

Subjects

Catalytic Domain drug effects, Cell Line, Tumor, Dose-Response Relationship, Drug, Enzyme Inhibitors chemistry, Flap Endonucleases chemistry, Humans, Models, Molecular, Molecular Structure, Structure-Activity Relationship, Temperature, Enzyme Inhibitors pharmacology, Flap Endonucleases antagonists & inhibitors, Flap Endonucleases metabolism

Abstract

The structure-specific nuclease human flap endonuclease-1 (hFEN1) plays a key role in DNA replication and repair and may be of interest as an oncology target. We present the crystal structure of inhibitor-bound hFEN1, which shows a cyclic N-hydroxyurea bound in the active site coordinated to two magnesium ions. Three such compounds had similar IC50 values but differed subtly in mode of action. One had comparable affinity for protein and protein-substrate complex and prevented reaction by binding to active site catalytic metal ions, blocking the necessary unpairing of substrate DNA. Other compounds were more competitive with substrate. Cellular thermal shift data showed that both inhibitor types engaged with hFEN1 in cells, and activation of the DNA damage response was evident upon treatment with inhibitors. However, cellular EC50 values were significantly higher than in vitro inhibition constants, and the implications of this for exploitation of hFEN1 as a drug target are discussed.

Published

2016

10. DNA and Protein Requirements for Substrate Conformational Changes Necessary for Human Flap Endonuclease-1-catalyzed Reaction.

Author

Algasaier SI, Exell JC, Bennet IA, Thompson MJ, Gotham VJ, Shaw SJ, Craggs TD, Finger LD, and Grasby JA

Subjects

Circular Dichroism, DNA chemistry, DNA Repair, Fluorescence Resonance Energy Transfer, Humans, Nucleic Acid Conformation, Substrate Specificity, DNA metabolism, Flap Endonucleases metabolism

Abstract

Human flap endonuclease-1 (hFEN1) catalyzes the essential removal of single-stranded flaps arising at DNA junctions during replication and repair processes. hFEN1 biological function must be precisely controlled, and consequently, the protein relies on a combination of protein and substrate conformational changes as a prerequisite for reaction. These include substrate bending at the duplex-duplex junction and transfer of unpaired reacting duplex end into the active site. When present, 5'-flaps are thought to thread under the helical cap, limiting reaction to flaps with free 5'-terminiin vivo Here we monitored DNA bending by FRET and DNA unpairing using 2-aminopurine exciton pair CD to determine the DNA and protein requirements for these substrate conformational changes. Binding of DNA to hFEN1 in a bent conformation occurred independently of 5'-flap accommodation and did not require active site metal ions or the presence of conserved active site residues. More stringent requirements exist for transfer of the substrate to the active site. Placement of the scissile phosphate diester in the active site required the presence of divalent metal ions, a free 5'-flap (if present), a Watson-Crick base pair at the terminus of the reacting duplex, and the intact secondary structure of the enzyme helical cap. Optimal positioning of the scissile phosphate additionally required active site conserved residues Tyr(40), Asp(181), and Arg(100)and a reacting duplex 5'-phosphate. These studies suggest a FEN1 reaction mechanism where junctions are bound and 5'-flaps are threaded (when present), and finally the substrate is transferred onto active site metals initiating cleavage., (© 2016 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2016

11. Proline scanning mutagenesis reveals a role for the flap endonuclease-1 helical cap in substrate unpairing.

Author

Patel N, Exell JC, Jardine E, Ombler B, Finger LD, Ciani B, and Grasby JA

Subjects

Amino Acid Substitution, Calcium metabolism, DNA genetics, DNA metabolism, Flap Endonucleases genetics, Flap Endonucleases metabolism, Humans, Mutagenesis, Site-Directed, Mutation, Missense, Proline, Protein Structure, Secondary, Calcium chemistry, DNA chemistry, Flap Endonucleases chemistry

Abstract

The prototypical 5'-nuclease, flap endonuclease-1 (FEN1), catalyzes the essential removal of single-stranded flaps during DNA replication and repair. FEN1 hydrolyzes a specific phosphodiester bond one nucleotide into double-stranded DNA. This specificity arises from double nucleotide unpairing that places the scissile phosphate diester on active site divalent metal ions. Also related to FEN1 specificity is the helical arch, through which 5'-flaps, but not continuous DNAs, can thread. The arch contains basic residues (Lys-93 and Arg-100 in human FEN1 (hFEN1)) that are conserved by all 5'-nucleases and a cap region only present in enzymes that process DNAs with 5' termini. Proline mutations (L97P, L111P, L130P) were introduced into the hFEN1 helical arch. Each mutation was severely detrimental to reaction. However, all proteins were at least as stable as wild-type (WT) hFEN1 and bound substrate with comparable affinity. Moreover, all mutants produced complexes with 5'-biotinylated substrate that, when captured with streptavidin, were resistant to challenge with competitor DNA. Removal of both conserved basic residues (K93A/R100A) was no more detrimental to reaction than the single mutation R100A, but much less severe than L97P. The ability of protein-Ca(2+) to rearrange 2-aminopurine-containing substrates was monitored by low energy CD. Although L97P and K93A/R100A retained the ability to unpair substrates, the cap mutants L111P and L130P did not. Taken together, these data challenge current assumptions related to 5'-nuclease family mechanism. Conserved basic amino acids are not required for double nucleotide unpairing and appear to act cooperatively, whereas the helical cap plays an unexpected role in hFEN1-substrate rearrangement.

Published

2013

12. Observation of unpaired substrate DNA in the flap endonuclease-1 active site.

Author

Finger LD, Patel N, Beddows A, Ma L, Exell JC, Jardine E, Jones AC, and Grasby JA

Subjects

2-Aminopurine chemistry, Catalytic Domain, DNA chemistry, Flap Endonucleases genetics, Flap Endonucleases metabolism, Humans, Models, Molecular, Mutation, Nucleic Acid Conformation, DNA metabolism, Flap Endonucleases chemistry

Abstract

The structure- and strand-specific phosphodiesterase flap endonuclease-1 (FEN1), the prototypical 5'-nuclease, catalyzes the essential removal of 5'-single-stranded flaps during replication and repair. FEN1 achieves this by selectively catalyzing hydrolysis one nucleotide into the duplex region of substrates, always targeting the 5'-strand. This specificity is proposed to arise by unpairing the 5'-end of duplex to permit the scissile phosphate diester to contact catalytic divalent metal ions. Providing the first direct evidence for this, we detected changes induced by human FEN1 (hFEN1) in the low-energy CD spectra and fluorescence lifetimes of 2-aminopurine in substrates and products that were indicative of unpairing. Divalent metal ions were essential for unpairing. However, although 5'-nuclease superfamily-conserved active-site residues K93 and R100 were required to produce unpaired product, they were not necessary to unpair substrates. Nevertheless, a unique arrangement of protein residues around the unpaired DNA was detected only with wild-type protein, suggesting a cooperative assembly of active-site residues that may be triggered by unpaired DNA. The general principles of FEN1 strand and reaction-site selection, which depend on the ability of juxtaposed divalent metal ions to unpair the end of duplex DNA, may also apply more widely to other structure- and strand-specific nucleases.

Published

2013

13. Interstrand disulfide crosslinking of DNA bases supports a double nucleotide unpairing mechanism for flap endonucleases.

Author

Beddows A, Patel N, Finger LD, Atack JM, Williams DM, and Grasby JA

Subjects

Disulfides chemistry, Humans, Hydrolysis, Oxidation-Reduction, Substrate Specificity, Thioguanine chemistry, Thiouracil chemistry, DNA metabolism, Flap Endonucleases metabolism, Thioguanine metabolism, Thiouracil metabolism

Abstract

Flap endonucleases (FENs) are proposed to select their target phosphate diester by unpairing the two terminal nucleotides of duplex. Interstrand disulfide crosslinks, introduced by oxidation of thiouracil and thioguanine bases, abolished the specificity of human FEN1 for hydrolysis one nucleotide into the 5'-duplex.

Published

2012

14. Flap endonucleases pass 5'-flaps through a flexible arch using a disorder-thread-order mechanism to confer specificity for free 5'-ends.

Author

Patel N, Atack JM, Finger LD, Exell JC, Thompson P, Tsutakawa S, Tainer JA, Williams DM, and Grasby JA

Subjects

Amino Acid Sequence, Biocatalysis, DNA metabolism, Flap Endonucleases metabolism, Humans, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Streptavidin metabolism, Substrate Specificity, DNA chemistry, Flap Endonucleases chemistry

Abstract

Flap endonucleases (FENs), essential for DNA replication and repair, recognize and remove RNA or DNA 5'-flaps. Related to FEN specificity for substrates with free 5'-ends, but controversial, is the role of the helical arch observed in varying conformations in substrate-free FEN structures. Conflicting models suggest either 5'-flaps thread through the arch, which when structured can only accommodate single-stranded (ss) DNA, or the arch acts as a clamp. Here we show that free 5'-termini are selected using a disorder-thread-order mechanism. Adding short duplexes to 5'-flaps or 3'-streptavidin does not markedly impair the FEN reaction. In contrast, reactions of 5'-streptavidin substrates are drastically slowed. However, when added to premixed FEN and 5'-biotinylated substrate, streptavidin is not inhibitory and complexes persist after challenge with unlabelled competitor substrate, regardless of flap length or the presence of a short duplex. Cross-linked flap duplexes that cannot thread through the structured arch react at modestly reduced rate, ruling out mechanisms involving resolution of secondary structure. Combined results explain how FEN avoids cutting template DNA between Okazaki fragments and link local FEN folding to catalysis and specificity: the arch is disordered when flaps are threaded to confer specificity for free 5'-ends, with subsequent ordering of the arch to catalyze hydrolysis.

Published

2012

15. Unpairing and gating: sequence-independent substrate recognition by FEN superfamily nucleases.

Author

Grasby JA, Finger LD, Tsutakawa SE, Atack JM, and Tainer JA

Subjects

Amino Acid Sequence, Animals, Catalytic Domain, DNA chemistry, DNA metabolism, DNA Repair, Endonucleases chemistry, Endonucleases metabolism, Exodeoxyribonucleases chemistry, Exodeoxyribonucleases metabolism, Flap Endonucleases metabolism, Humans, Molecular Sequence Data, Protein Conformation, RNA Interference, Substrate Specificity, Flap Endonucleases chemistry

Abstract

Structure-specific 5'-nucleases form a superfamily of evolutionarily conserved phosphodiesterases that catalyse a precise incision of a diverse range of DNA and RNA substrates in a sequence-independent manner. Superfamily members, such as flap endonucleases, exonuclease 1, DNA repair protein XPG, endonuclease GEN1 and the 5'-3'-exoribonucleases, play key roles in many cellular processes such as DNA replication and repair, recombination, transcription, RNA turnover and RNA interference. In this review, we discuss recent results that highlight the conserved architectures and active sites of the structure-specific 5'-nucleases. Despite substrate diversity, a common gating mechanism for sequence-independent substrate recognition and incision emerges, whereby double nucleotide unpairing of substrates is required to access the active site., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2012

16. The wonders of flap endonucleases: structure, function, mechanism and regulation.

Author

Finger LD, Atack JM, Tsutakawa S, Classen S, Tainer J, Grasby J, and Shen B

Subjects

Animals, DNA genetics, DNA metabolism, DNA Ligases chemistry, DNA Ligases genetics, DNA Ligases metabolism, DNA Polymerase III chemistry, DNA Polymerase III genetics, DNA Polymerase III metabolism, Flap Endonucleases genetics, Humans, Proliferating Cell Nuclear Antigen chemistry, Proliferating Cell Nuclear Antigen genetics, Proliferating Cell Nuclear Antigen metabolism, Structure-Activity Relationship, DNA biosynthesis, DNA chemistry, DNA Replication physiology, Flap Endonucleases chemistry, Flap Endonucleases metabolism

Abstract

Processing of Okazaki fragments to complete lagging strand DNA synthesis requires coordination among several proteins. RNA primers and DNA synthesised by DNA polymerase α are displaced by DNA polymerase δ to create bifurcated nucleic acid structures known as 5'-flaps. These 5'-flaps are removed by Flap Endonuclease 1 (FEN), a structure-specific nuclease whose divalent metal ion-dependent phosphodiesterase activity cleaves 5'-flaps with exquisite specificity. FENs are paradigms for the 5' nuclease superfamily, whose members perform a wide variety of roles in nucleic acid metabolism using a similar nuclease core domain that displays common biochemical properties and structural features. A detailed review of FEN structure is undertaken to show how DNA substrate recognition occurs and how FEN achieves cleavage at a single phosphate diester. A proposed double nucleotide unpairing trap (DoNUT) is discussed with regards to FEN and has relevance to the wider 5' nuclease superfamily. The homotrimeric proliferating cell nuclear antigen protein (PCNA) coordinates the actions of DNA polymerase, FEN and DNA ligase by facilitating the hand-off intermediates between each protein during Okazaki fragment maturation to maximise through-put and minimise consequences of intermediates being released into the wider cellular environment. FEN has numerous partner proteins that modulate and control its action during DNA replication and is also controlled by several post-translational modification events, all acting in concert to maintain precise and appropriate cleavage of Okazaki fragment intermediates during DNA replication.

Published

2012

17. The DNA repair endonuclease XPG interacts directly and functionally with the WRN helicase defective in Werner syndrome.

Author

Trego KS, Chernikova SB, Davalos AR, Perry JJ, Finger LD, Ng C, Tsai MS, Yannone SM, Tainer JA, Campisi J, and Cooper PK

Subjects

Binding Sites, DNA Helicases, DNA Repair, DNA Replication, DNA-Binding Proteins physiology, Endonucleases physiology, Exodeoxyribonucleases physiology, Humans, Nuclear Proteins physiology, Protein Binding, RecQ Helicases physiology, S Phase, Transcription Factors physiology, Werner Syndrome Helicase, Xeroderma Pigmentosum, DNA-Binding Proteins metabolism, Endonucleases metabolism, Exodeoxyribonucleases metabolism, Nuclear Proteins metabolism, RecQ Helicases metabolism, Transcription Factors metabolism, Werner Syndrome enzymology

Abstract

XPG is a structure-specific endonuclease required for nucleotide excision repair (NER). XPG incision defects result in the cancer-prone syndrome xeroderma pigmentosum, whereas truncating mutations of XPG cause the severe postnatal progeroid developmental disorder Cockayne syndrome. We show that XPG interacts directly with WRN protein, which is defective in the premature aging disorder Werner syndrome, and that the two proteins undergo similar subnuclear redistribution in S phase and colocalize in nuclear foci. The co-localization was observed in mid- to late S phase, when WRN moves from nucleoli to nuclear foci that have been shown to contain both protein markers of stalled replication forks and telomeric proteins. We mapped the interaction between XPG and WRN to the C-terminal domains of each, and show that interaction with the C-terminal domain of XPG strongly stimulates WRN helicase activity. WRN also possesses a competing DNA single-strand annealing activity that, combined with unwinding, has been shown to coordinate regression of model replication forks to form Holliday junction/chicken foot intermediate structures. We tested whether XPG stimulated WRN annealing activity, and found that XPG itself has intrinsic strand annealing activity that requires the unstructured R- and C-terminal domains but not the conserved catalytic core or endonuclease activity. Annealing by XPG is cooperative, rather than additive, with WRN annealing. Taken together, our results suggest a novel function for XPG in S phase that is, at least in part, performed coordinately with WRN, and which may contribute to the severity of the phenotypes that occur upon loss of XPG.

Published

2011

18. Human flap endonuclease structures, DNA double-base flipping, and a unified understanding of the FEN1 superfamily.

Author

Tsutakawa SE, Classen S, Chapados BR, Arvai AS, Finger LD, Guenther G, Tomlinson CG, Thompson P, Sarker AH, Shen B, Cooper PK, Grasby JA, and Tainer JA

Subjects

Amino Acid Sequence, Catalytic Domain, DNA metabolism, DNA Mutational Analysis, Exodeoxyribonucleases chemistry, Exodeoxyribonucleases metabolism, Humans, Models, Molecular, Molecular Sequence Data, Sequence Alignment, Substrate Specificity, Flap Endonucleases chemistry, Flap Endonucleases metabolism

Abstract

Flap endonuclease (FEN1), essential for DNA replication and repair, removes RNA and DNA 5' flaps. FEN1 5' nuclease superfamily members acting in nucleotide excision repair (XPG), mismatch repair (EXO1), and homologous recombination (GEN1) paradoxically incise structurally distinct bubbles, ends, or Holliday junctions, respectively. Here, structural and functional analyses of human FEN1:DNA complexes show structure-specific, sequence-independent recognition for nicked dsDNA bent 100° with unpaired 3' and 5' flaps. Above the active site, a helical cap over a gateway formed by two helices enforces ssDNA threading and specificity for free 5' ends. Crystallographic analyses of product and substrate complexes reveal that dsDNA binding and bending, the ssDNA gateway, and double-base unpairing flanking the scissile phosphate control precise flap incision by the two-metal-ion active site. Superfamily conserved motifs bind and open dsDNA; direct the target region into the helical gateway, permitting only nonbase-paired oligonucleotides active site access; and support a unified understanding of superfamily substrate specificity., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

19. Functional regulation of FEN1 nuclease and its link to cancer.

Author

Zheng L, Jia J, Finger LD, Guo Z, Zer C, and Shen B

Subjects

Animals, Flap Endonucleases metabolism, Humans, Mice, Flap Endonucleases genetics, Flap Endonucleases physiology, Neoplasms genetics

Abstract

Flap endonuclease-1 (FEN1) is a member of the Rad2 structure-specific nuclease family. FEN1 possesses FEN, 5'-exonuclease and gap-endonuclease activities. The multiple nuclease activities of FEN1 allow it to participate in numerous DNA metabolic pathways, including Okazaki fragment maturation, stalled replication fork rescue, telomere maintenance, long-patch base excision repair and apoptotic DNA fragmentation. Here, we summarize the distinct roles of the different nuclease activities of FEN1 in these pathways. Recent biochemical and genetic studies indicate that FEN1 interacts with more than 30 proteins and undergoes post-translational modifications. We discuss how FEN1 is regulated via these mechanisms. Moreover, FEN1 interacts with five distinct groups of DNA metabolic proteins, allowing the nuclease to be recruited to a specific DNA metabolic complex, such as the DNA replication machinery for RNA primer removal or the DNA degradosome for apoptotic DNA fragmentation. Some FEN1 interaction partners also stimulate FEN1 nuclease activities to further ensure efficient action in processing of different DNA structures. Post-translational modifications, on the other hand, may be critical to regulate protein-protein interactions and cellular localizations of FEN1. Lastly, we also review the biological significance of FEN1 as a tumor suppressor, with an emphasis on studies of human mutations and mouse models.

Published

2011

20. The 3'-flap pocket of human flap endonuclease 1 is critical for substrate binding and catalysis.

Author

Finger LD, Blanchard MS, Theimer CA, Sengerová B, Singh P, Chavez V, Liu F, Grasby JA, and Shen B

Subjects

Base Sequence, Catalysis, Flap Endonucleases physiology, Humans, Hydrolysis, Kinetics, Molecular Sequence Data, Nucleic Acid Conformation, Phosphorylation, Potassium Chloride chemistry, Protein Binding, Protein Structure, Secondary, Substrate Specificity, Thermodynamics, Flap Endonucleases chemistry, Flap Endonucleases genetics

Abstract

Flap endonuclease 1 (FEN1) proteins, which are present in all kingdoms of life, catalyze the sequence-independent hydrolysis of the bifurcated nucleic acid intermediates formed during DNA replication and repair. How FEN1s have evolved to preferentially cleave flap structures is of great interest especially in light of studies wherein mice carrying a catalytically deficient FEN1 were predisposed to cancer. Structural studies of FEN1s from phage to human have shown that, although they share similar folds, the FEN1s of higher organisms contain a 3'-extrahelical nucleotide (3'-flap) binding pocket. When presented with 5'-flap substrates having a 3'-flap, archaeal and eukaryotic FEN1s display enhanced reaction rates and cleavage site specificity. To investigate the role of this interaction, a kinetic study of human FEN1 (hFEN1) employing well defined DNA substrates was conducted. The presence of a 3'-flap on substrates reduced Km and increased multiple- and single turnover rates of endonucleolytic hydrolysis at near physiological salt concentrations. Exonucleolytic and fork-gap-endonucleolytic reactions were also stimulated by the presence of a 3'-flap, and the absence of a 3'-flap from a 5'-flap substrate was more detrimental to hFEN1 activity than removal of the 5'-flap or introduction of a hairpin into the 5'-flap structure. hFEN1 reactions were predominantly rate-limited by product release regardless of the presence or absence of a 3'-flap. Furthermore, the identity of the stable enzyme product species was deduced from inhibition studies to be the 5'-phosphorylated product. Together the results indicate that the presence of a 3'-flap is the critical feature for efficient hFEN1 substrate recognition and catalysis.

Published

2009

21. Comprehensive mapping of the C-terminus of flap endonuclease-1 reveals distinct interaction sites for five proteins that represent different DNA replication and repair pathways.

Author

Guo Z, Chavez V, Singh P, Finger LD, Hang H, Hegde ML, and Shen B

Subjects

Amino Acid Sequence, Binding Sites, Cell Cycle Proteins chemistry, DNA Damage, DNA-(Apurinic or Apyrimidinic Site) Lyase chemistry, Endodeoxyribonucleases chemistry, Exodeoxyribonucleases chemistry, Exonucleases chemistry, Flap Endonucleases genetics, Humans, Molecular Sequence Data, Mutation, Protein Binding, Protein Interaction Domains and Motifs, Protein Interaction Mapping, RecQ Helicases chemistry, Werner Syndrome Helicase, DNA Repair, DNA Replication, Flap Endonucleases chemistry, Models, Molecular

Abstract

Flap endonuclease-1 (FEN-1) is a multifunctional and structure-specific nuclease that plays a critical role in maintaining human genome stability through RNA primer removal, long-patch base excision repair, resolution of DNA secondary structures and stalled DNA replication forks, and apoptotic DNA fragmentation. How FEN-1 is involved in multiple pathways, of which some are seemingly contradictory, is of considerable interest. To date, at least 20 proteins are known to interact with FEN-1; some form distinct complexes that affect one or more FEN-1 activities presumably to direct FEN-1 to a particular DNA metabolic pathway. FEN-1 consists of a nuclease core domain and a C-terminal extension. While the core domain harbors the nuclease activity, the C-terminal extension may be important for protein-protein interactions. Here, we have truncated or mutated the C-terminus of FEN-1 to identify amino acid residues that are critical for interaction with five proteins representing roles in different DNA replication and repair pathways. We found with all five proteins that the C-terminus is important for binding and that each protein uses a subset of amino acid residues. Replacement of one or more residues with an alanine in many cases leads to the complete loss of interaction, which may consequently lead to severe biological defects in mammals.

Published

2008

22. The DNA-protein interaction modes of FEN-1 with gap substrates and their implication in preventing duplication mutations.

Author

Liu R, Qiu J, Finger LD, Zheng L, and Shen B

Subjects

Amino Acid Sequence, Binding Sites, DNA chemistry, DNA metabolism, DNA Helicases metabolism, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Exodeoxyribonucleases metabolism, Flap Endonucleases genetics, Humans, Kinetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutation, Nucleic Acid Conformation, Protein Binding, RecQ Helicases, Substrate Specificity, Werner Syndrome Helicase, Flap Endonucleases chemistry, Flap Endonucleases metabolism

Abstract

Flap endonuclease-1 (FEN-1) is a structure-specific nuclease best known for its involvement in RNA primer removal and long-patch base excision repair. This enzyme is known to possess 5'-flap endo- (FEN) and 5'-3' exo- (EXO) nuclease activities. Recently, FEN-1 has been reported to also possess a gap endonuclease (GEN) activity, which is possibly involved in apoptotic DNA fragmentation and the resolution of stalled DNA replication forks. In the current study, we compare the kinetics of these activities to shed light on the aspects of DNA structure and FEN-1 DNA-binding elements that affect substrate cleavage. By using DNA binding deficient mutants of FEN-1, we determine that the GEN activity is analogous to FEN activity in that the single-stranded DNA region of DNA substrates interacts with the clamp region of FEN-1. In addition, we show that the C-terminal extension of human FEN-1 likely interacts with the downstream duplex portion of all substrates. Taken together, a substrate-binding model that explains how FEN-1, which has a single active center, can have seemingly different activities is proposed. Furthermore, based on the evidence that GEN activity in complex with WRN protein cleaves hairpin and internal loop substrates, we suggest that the GEN activity may prevent repeat expansions and duplication mutations.

Published

2006

23. Structure of the Tetrahymena thermophila telomerase RNA helix II template boundary element.

Author

Richards RJ, Theimer CA, Finger LD, and Feigon J

Subjects

Animals, Base Sequence, Conserved Sequence, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Nucleic Acid Conformation, Regulatory Sequences, Ribonucleic Acid, Templates, Genetic, Tetrahymena thermophila genetics, Models, Molecular, RNA chemistry, Telomerase chemistry, Tetrahymena thermophila enzymology

Abstract

Telomere addition by telomerase requires an internal templating sequence located in the RNA subunit of telomerase. The correct boundary definition of this template sequence is essential for the proper addition of the nucleotide repeats. Incorporation of incorrect telomeric repeats onto the ends of chromosomes has been shown to induce chromosomal instability in ciliate, yeast and human cells. A 5' template boundary defining element (TBE) has been identified in human, yeast and ciliate telomerase RNAs. Here, we report the solution structure of the TBE element (helix II) from Tetrahymena thermophila telomerase RNA. Our results indicate that helix II and its capping pentaloop form a well-defined structure including unpaired, stacked adenine nucleotides in the stem and an unusual syn adenine nucleotide in the loop. A comparison of the T.thermophila helix II pentaloop with a pentaloop of the same sequence found in the 23S rRNA of the Haloarcula marismortui ribosome suggests possible RNA and/or protein interactions for the helix II loop within the Tetrahymena telomerase holoenzyme.

Published

2006

24. Multiple but dissectible functions of FEN-1 nucleases in nucleic acid processing, genome stability and diseases.

Author

Shen B, Singh P, Liu R, Qiu J, Zheng L, Finger LD, and Alas S

Subjects

Amino Acid Motifs, Animals, Cell Nucleus metabolism, DNA chemistry, DNA Primers chemistry, Endonucleases metabolism, Exonucleases metabolism, Flap Endonucleases chemistry, Humans, Models, Biological, Models, Genetic, Muscular Diseases metabolism, Nucleic Acids chemistry, Phenotype, Proliferating Cell Nuclear Antigen metabolism, Protein Binding, Protein Processing, Post-Translational, RNA chemistry, Structure-Activity Relationship, Flap Endonucleases physiology, Genome

Abstract

Flap EndoNuclease-1 (FEN-1) is a multifunctional and structure-specific nuclease involved in nucleic acid processing pathways. It plays a critical role in maintaining human genome stability through RNA primer removal, long-patch base excision repair and resolution of dinucleotide and trinucleotide repeat secondary structures. In addition to its flap endonuclease (FEN) and nick exonuclease (EXO) activities, a new gap endonuclease (GEN) activity has been characterized. This activity may be important in apoptotic DNA fragmentation and in resolving stalled DNA replication forks. The multiple functions of FEN-1 are regulated via several means, including formation of complexes with different protein partners, nuclear localization in response to cell cycle or DNA damage and post-translational modifications. Its functional deficiency is predicted to cause genetic diseases, including Huntington's disease, myotonic dystrophy and cancers. This review summarizes the knowledge gained through efforts in the past decade to define its structural elements for specific activities and possible pathological consequences of altered functions of this multirole player., (Copyright (c) 2005 Wiley Periodicals, Inc.)

Published

2005

25. Structure determination of protein/RNA complexes by NMR.

Author

Wu H, Finger LD, and Feigon J

Subjects

Nucleic Acid Conformation, Protein Structure, Tertiary, Magnetic Resonance Spectroscopy methods, RNA chemistry, RNA metabolism, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism

Abstract

Structure determination of protein?RNA complexes in solution provides unique insights into factors that are involved in protein/RNA recognition. Here, we review the methodology used in our laboratory to overcome the challenges of protein?RNA structure determination by nuclear magnetic resonance (NMR). We use as two examples complexes recently solved in our laboratory, the nucleolin RBD12/b2NRE and Rnt1p dsRBD/snR47h complexes. Topics covered are protein and RNA preparation, complex formation, identification of the protein/RNA interface, protein and RNA resonance assignment, intermolecular NOE assignment, and structure calculation and analysis.

Published

2005

26. Contributions of the RNA-binding and linker domains and RNA structure to the specificity and affinity of the nucleolin RBD12/NRE interaction.

Author

Finger LD, Johansson C, Rinaldi B, Bouvet P, and Feigon J

Subjects

Amino Acid Sequence, Animals, Base Sequence, Binding Sites, Consensus Sequence, Cricetinae, Fluorescence Polarization, Kinetics, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Nucleic Acid Conformation, Phosphoproteins chemistry, Phosphoproteins genetics, Protein Binding, Protein Conformation, Protein Structure, Tertiary, RNA genetics, RNA metabolism, RNA-Binding Proteins chemistry, RNA-Binding Proteins genetics, Nucleolin, Phosphoproteins metabolism, RNA chemistry, RNA Precursors metabolism, RNA-Binding Proteins metabolism

Abstract

Nucleolin is a multidomain phosphoprotein involved in ribosome biogenesis. In vitro selection and binding studies with pre-rRNA fragments have shown that the first two RNA-binding domains (RBDs) in nucleolin (RBD12) recognize the consensus sequence (U/G)CCCG(A/G) in the context of a stem-loop structure (nucleolin-recognition element = NRE). Structural studies of nucleolin RBD12 in complex with an in vitro selected NRE (sNRE) and a natural pre-rRNA NRE (b2NRE) have revealed that sequence-specific binding of the consensus NRE is achieved in a similar manner in both complexes using residues in both RBDs as well as the linker connecting them. Using fluorescence anisotropy (FA) and nuclear magnetic resonance (NMR), we demonstrate the importance of the linker for NRE affinity by showing that only the individual RBDs with the linker attached retain the ability to specifically bind, albeit weakly, to sNRE and b2NRE. Binding of RBD1 and RBD2 to the NREs in trans is not detected even when one of the RBDs has the linker attached, which suggests that the linker also contributes to the affinity by tethering the two RBDs. To determine if binding of nucleolin RBD12 to natural NREs is dependent on a specific RNA stem-loop structure, as was the case for the sNRE, we conducted FA and NMR binding assays with nucleolin RBD12 and a single-stranded NRE. The results show that nucleolin RBD12 sequence-specifically binds a single-stranded NRE with an affinity similar to that for b2NRE, indicating that a stem-loop structure is not required for the nucleolin RBD12/pre-rRNA NRE interaction.

Published

2004

27. Solution structure of the complex formed by the two N-terminal RNA-binding domains of nucleolin and a pre-rRNA target.

Author

Johansson C, Finger LD, Trantirek L, Mueller TD, Kim S, Laird-Offringa IA, and Feigon J

Subjects

Animals, Computational Biology, Cricetinae, Kinetics, Nucleic Acid Conformation, Protein Structure, Tertiary, RNA, Ribosomal metabolism, Nucleolin, Phosphoproteins metabolism, RNA Precursors metabolism, RNA-Binding Proteins metabolism

Abstract

Nucleolin is a 70 kDa multidomain protein involved in several steps of eukaryotic ribosome biogenesis. In vitro selection in combination with mutagenesis and structural analysis identified binding sites in pre-rRNA with the consensus (U/G)CCCG(A/G) in the context of a hairpin structure, the nucleolin recognition element (NRE). The central region of the protein contains four tandem RNA-binding domains (RBDs), of which the first two are responsible for the RNA-binding specificity and affinity for NREs. Here, we present the solution structure of the 28 kDa complex formed by the two N-terminal RNA-binding domains of nucleolin (RBD12) and a natural pre-rRNA target, b2NRE. The structure demonstrates that the sequence-specific recognition of the pre-rRNA NRE is achieved by intermolecular hydrogen bonds and stacking interactions involving mainly the beta-sheet surfaces of the two RBDs and the linker residues. A comparison with our previously determined NMR structure of RBD12 in complex with an in vitro selected RNA target, sNRE, shows that although the sequence-specific recognition of the loop consensus nucleotides is the same in the two complexes, they differ in several aspects. While the protein makes numerous specific contacts to the non-consensus nucleotides in the loop E motif (S-turn) in the upper part of the sNRE stem, nucleolin RBD12 contacts only consensus nucleotides in b2NRE. The absence of these upper stem contacts from the RBD12/b2NRE complex results in a much less stable complex, as demonstrated by kinetic analyses. The role of the loop E motif in high-affinity binding is supported by gel-shift analyses with a series of sNRE mutants. The less stable interaction of RBD12 with the natural RNA target is consistent with the proposed role of nucleolin as a chaperone that interacts transiently with pre-rRNA to prevent misfolding.

Published

2004

28. YNMG tetraloop formation by a dyskeratosis congenita mutation in human telomerase RNA.

Author

Theimer CA, Finger LD, and Feigon J

Subjects

Humans, Nuclear Magnetic Resonance, Biomolecular, Nucleic Acid Denaturation, RNA chemistry, Thermodynamics, Dyskeratosis Congenita genetics, Mutation, Nucleic Acid Conformation, RNA genetics, Telomerase genetics

Abstract

Autosomal dominant dyskeratosis congenita (DKC) has been linked to mutations in the RNA component of telomerase, the ribonucleoprotein responsible for telomere maintenance. Recent studies have investigated the role of the GC (107-108) --> AG mutation in the conserved P3 helix in the pseudoknot domain of human telomerase RNA. The mutation was found to significantly destabilize the pseudoknot conformation, resulting in a shift in the thermodynamic equilibrium to favor formation of a P2b hairpin intermediate. In the wild-type sequence, the hairpin intermediate was found to form a novel sequence of pyrimidine base pairs in a continuous stem capped by a structured pentaloop. The DKC mutant hairpin was observed to be slightly more stable than the wild-type hairpin, further shifting the pseudoknot-hairpin equilibrium to favor the mutant P2b hairpin. Here we examined the solution structure of the DKC mutant hairpin to identify the reason for this additional stability. We found that the mutant hairpin forms the same stem structure as wild-type and that the additional stabilization observed using optical melting can be explained by the formation of a YNMG-type tetraloop structure, with the last nucleotide of the pentaloop bulged out into the major groove. Our results provide a structural explanation for the increased stability of the mutant hairpin and further our understanding of the effect of this mutation on the structure and stability of the dominant conformation of the pseudoknot domain in this type of DKC.

Published

2003

29. Solution structures of stem-loop RNAs that bind to the two N-terminal RNA-binding domains of nucleolin.

Author

Finger LD, Trantirek L, Johansson C, and Feigon J

Subjects

Base Sequence, Binding Sites, Fluorescence Polarization, Magnetic Resonance Spectroscopy, Oligoribonucleotides chemistry, Oligoribonucleotides metabolism, Phosphoproteins metabolism, Protein Binding, RNA genetics, RNA metabolism, RNA-Binding Proteins metabolism, Solutions, Nucleolin, Nucleic Acid Conformation, Phosphoproteins chemistry, RNA chemistry, RNA-Binding Proteins chemistry

Abstract

Nucleolin, a multi-domain protein involved in ribosome biogenesis, has been shown to bind the consensus sequence (U/G)CCCG(A/G) in the context of a hairpin loop structure (nucleolin recognition element; NRE). Previous studies have shown that the first two RNA-binding domains in nucleolin (RBD12) are responsible for the interaction with the in vitro selected NRE (sNRE). We have previously reported the structures of nucleolin RBD12, sNRE and nucleolin RBD12-sNRE complex. A comparison of free and bound sNRE shows that the NRE loop becomes structured upon binding. From this observation, we hypothesized that the disordered hairpin loop of sNRE facilitates conformational rearrangements when the protein binds. Here, we show that nucleolin RBD12 is also sufficient for sequence- specific binding of two NRE sequences found in pre-rRNA, b1NRE and b2NRE. Structural investigations of the free NREs using NMR spectroscopy show that the b1NRE loop is conformationally heterogeneous, while the b2NRE loop is structured. The b2NRE forms a hairpin capped by a YNMG-like tetraloop. Comparison of the chemical shifts of sNRE and b2NRE in complex with nucleolin RBD12 suggests that the NRE consensus nucleotides adopt a similar conformation. These results show that a disordered NRE consensus sequence is not a prerequisite for nucleolin RBD12 binding.

Published

2003

30. Mutations linked to dyskeratosis congenita cause changes in the structural equilibrium in telomerase RNA.

Author

Theimer CA, Finger LD, Trantirek L, and Feigon J

Subjects

Base Sequence, Humans, Molecular Sequence Data, Nucleic Acid Conformation, Thermodynamics, Dyskeratosis Congenita genetics, Mutation, RNA chemistry, Telomerase chemistry

Abstract

Autosomal dominant dyskeratosis congenita (DKC), as well as aplastic anemia, has been linked to mutations in the RNA component of telomerase, the ribonucleoprotein responsible for telomere maintenance. Here we examine the effect of the DKC mutations on the structure and stability of human telomerase RNA pseudoknot and CR7 domains by using NMR and thermal melting. The CR7 domain point mutation decreases stability and alters a conserved secondary structure thought to be involved in human telomerase RNA accumulation in vivo. We find that pseudoknot constructs containing the conserved elements of the pseudoknot domain are in equilibrium with a hairpin conformation. The solution structure of the wild-type hairpin reveals that it forms a continuous helix containing a novel run of three consecutive U.U and a U.C base pairs closed by a pentaloop. The six base pairs unique to the hairpin conformation are phylogenetically conserved in mammals, suggesting that this conformation is also functionally important. The DKC mutation in the pseudoknot domain results in a shift in the equilibrium toward the hairpin form, primarily due to destabilization of the pseudoknot. Our results provide insight into the effect of these mutations on telomerase structure and suggest that the catalytic cycle of telomerase involves a delicate interplay between RNA conformational states, alteration of which leads to the disease state.

Published

2003

31. Recognition of pre-formed and flexible elements of an RNA stem-loop by nucleolin.

Author

Bouvet P, Allain FH, Finger LD, Dieckmann T, and Feigon J

Subjects

Animals, Base Pairing, Base Sequence, Binding Sites, Consensus Sequence genetics, Humans, Mice, Models, Molecular, Mutation genetics, Nuclear Magnetic Resonance, Biomolecular, Nucleotides chemistry, Nucleotides genetics, Nucleotides metabolism, Pliability, Protein Binding, Protein Structure, Tertiary, RNA Precursors chemistry, RNA Precursors genetics, RNA Precursors metabolism, RNA Stability, RNA, Ribosomal genetics, Regulatory Sequences, Nucleic Acid genetics, Substrate Specificity, Thermodynamics, Titrimetry, Nucleolin, Nucleic Acid Conformation, Phosphoproteins chemistry, Phosphoproteins metabolism, RNA, Ribosomal chemistry, RNA, Ribosomal metabolism, RNA-Binding Proteins chemistry, RNA-Binding Proteins metabolism

Abstract

Nucleolin is an abundant nucleolar protein which is essential for ribosome biogenesis. The first two of its four tandem RNA-binding domains (RBD12) specifically recognize a stem-loop structure containing a conserved UCCCGA sequence in the loop called the nucleolin-recognition element (NRE). We have determined the structure of the consensus SELEX NRE (sNRE) by NMR spectroscopy. In both the free and bound RNA the top part of the stem forms a loop E (or S-turn) motif. In the absence of protein, the structure of the hairpin loop is not well defined due to conformational heterogeneity, and appears to be in equilibrium between two families of conformations. Titrations of RBD1, RBD2, and RBD12 with the sNRE show that specific binding requires RBD12. In complex with RBD12, the hairpin loop interacts specifically with the protein and adopts a well-defined structure which shares some of the features of the free form. The loop E motif also has specific interactions with the protein. Implications of these findings for the mechanism of recognition of RNA structures by modular proteins are discussed., (Copyright 2001 Academic Press.)

Published

2001

32. Solution nuclear magnetic resonance probing of cation binding sites on nucleic acids.

Author

Feigon J, Butcher SE, Finger LD, and Hud NV

Subjects

Base Sequence, Binding Sites, Cations, Monovalent, DNA chemistry, Hydrogen-Ion Concentration, Models, Molecular, Molecular Structure, Nucleic Acid Conformation, Quaternary Ammonium Compounds, RNA chemistry, RNA, Catalytic chemistry, Solutions, Temperature, Thallium, Thermodynamics, Nuclear Magnetic Resonance, Biomolecular methods, Nucleic Acids chemistry

Published

2001

33. Enzymatic synthesis of a quorum-sensing autoinducer through use of defined substrates.

Author

Moré MI, Finger LD, Stryker JL, Fuqua C, Eberhard A, and Winans SC

Subjects

3-Oxoacyl-(Acyl-Carrier-Protein) Synthase antagonists & inhibitors, 3-Oxoacyl-(Acyl-Carrier-Protein) Synthase metabolism, Acyl Carrier Protein metabolism, Agrobacterium tumefaciens metabolism, Base Sequence, Cerulenin pharmacology, Chromatography, Gel, Chromatography, High Pressure Liquid, Cloning, Molecular, DNA Primers, Escherichia coli, Escherichia coli Proteins, Fatty Acids metabolism, Homoserine biosynthesis, Malonyl Coenzyme A metabolism, Molecular Sequence Data, NADP metabolism, Plasmids, S-Adenosylmethionine metabolism, Agrobacterium tumefaciens genetics, DNA Helicases metabolism, Gene Expression Regulation, Bacterial drug effects, Homoserine analogs & derivatives

Abstract

Many bacteria, including several pathogens of plants and humans, use a pheromone called an autoinducer to regulate gene expression in a cell density-dependent manner. Agrobacterium autoinducer [AAI, N-(3-oxo-octanoyl)-L-homoserine lactone] of A. tumefaciens is synthesized by the Tral protein, which is encoded by the tumor-inducing plasmid. Purified hexahistidinyl-Tral (H6-Tral) used S-adenosylmethionine to make the homoserine lactone moiety of AAI, but did not use related compounds. H6-Tral used 3-oxo-octanoyl-acyl carrier protein to make the 3-oxo-octanoyl moiety of AAI, but did not use 3-oxo-octanoyl-coenzyme A. These results demonstrate the enzymatic synthesis of an autoinducer through the use of purified substrates.

Published

1996