Helicase

From Proteopedia

(Difference between revisions)

Revision as of 12:47, 8 July 2018

1 Function
2 What is a Helicase?
3 PcrA a Simple Model for Helicases
4 PcrA Biochemistry
5 PcrA Helicase Mechanism : The Mexican Wave
6 The Superfamily 1 (SF1)

Function

Helicase (Hel) is a motor protein which separates nucleic acid strands like DNA double helix or self-annealed RNA. They use ATP hydrolysis for energy. Hel falls into 5 superfamilies (SF1-SF5). Some Hel contain a Helicase and RNase D C terminal Domain (HRDC). The α-thalassemia and mental retardation X-linked syndrome helicase (ATRX ), contains an ATRX-Dnmt3-Dnmt3L (ADD) domain in which many disease-related mutations are found. ATP-dependent helicase Rho is a protein involved in termination of transcription in prokaryotes. Rho binds to the transcription terminator site on single-stranded RNA. Rho forms a ring-shaped hexamer and advances along the mRNA until it reaches the RNA polymerase and causing it to dissociate from the DNA and end transcription.

For details of PcrA helicase see

For ATP-dependent helicase Rho see

Transcription Termination Factor Rho.

For ATP-dependent helicase Q see

Human RecQ-Like protein 1.

For ATP-dependent helicase RecG see

RecG Bound to Three-Way DNA Junction.

For ATP-dependent helicase HepA see

RapA, a Swi2/Snf2 protein.

For DEAD box ATP-dependent RNA helicase see

For helicase XPD see

XPD Helicase (3CRV)

What is a Helicase?

Helicases are nucleic acid–dependent ATP-ases that are capable of unwinding DNA [1] or RNA [2] duplex substrates. As a consequence, they play roles in almost every process in cells that involves nucleic acids, including DNA replication and repair, transcription, translation, ribosome synthesis (1).

PcrA a Simple Model for Helicases

PcrA_Structure

PcrA is part of the replication machinery of the Geobacillus stearothermophilusa gram (+) bacteria, This helicase is part of the superfamily I of Helicases. Monomeric protein that is mainly has the Rec domians. This helicase was reported as a mutation in the gen PcrA from "Stapphylococcus aerous", this mutation was related to a deficiency in the replication of a reporter plasmid.[3]

PcrA Biochemistry

PcrA is has an ATPas activityt which directionality is from 3' to 5' helicase strand separation reaction. The enzyme shows a specificity for the DNA substrate in gel mobility assays with the preferred substrate being one containing both single and double stranded regions of DNA. In contrast to Rep and UvrD from E. coli, there is not evidence for dimerisation of the enzyme using gel filtration, or by crosslinking in the presence of combinations of Mg2+, nucleotides and DNA. Moreover, kcat for ATP hydrolysis is constant over a large range of protein concentrations. Therefore, the protein appears to be monomeric under all conditions tested, including in the structure of two crystal forms of PcrA.[4]

PcrA Helicase Mechanism : The Mexican Wave

Professor Dale B. Wigley' group in 1996-1999 was able to crystalize the intermediate states from PcrA, giving solution to the controversy of what kind of mechanism this helicase has. [5] Two crystal form of the enzyma, one couple with a 10 mer DNA and a non hydrolizable form of ATP (ATPnP) (pdb id: 3pjr, and another a truncated form embebed in sulfate (pdb id: 2pjr, give a light in a model for how ATP hydrolysis results in motor movement along ssDNA. In the figure below step 1 (top) is the ATP free (product) ssDNA conformation. The DNA bases are labelled arbitrarily. On binding ATP, F626 creates a new binding pocket for base 6. Likewise, F64 destroys an acceptor pocket for base 2, forcing it to move to the position occupied by base 1. After ATP hydrolysis, the grip on base 6 is released. When the Y257 pocket is re-opened due to movement of F64, bases 3-6 can now flip through the acceptor pockets to their new positions. This model predicts that each ATP hydrolysis event will advance PcrA one base along ssDNA.[6]

Inchworm or Mexicanwave model

PcrA Movie

The link below show a movie with the principal characteristics of this protain as long with the inchworm mode. Pcr4 Helicase and Mexican Wave

The Superfamily 1 (SF1)

PcrA share structural domains with the Rec helicases, like UvrD (2is1) and RepD (1uaa) from E. coli, Superfamily 1 (SF1) helicases are probably the best characterized class, certainly from a structural perspective. All members characterized to date are bona fide helicases and α enzymes. Indeed, from their mode of translocation via the bases it is difficult to envisage how they could translocate along a duplex. However, they can have either A or B directional polarity.

3D structures of helicase

Updated on 08-July-2018

References

Crystal structure of a DExx box DNA helicase., Subramanya HS, Bird LE, Brannigan JA, Wigley DB, Nature. 1996 Nov 28;384(6607):379-83. PMID:8934527
^ Johnson DS, Bai L, Smith BY, Patel SS, Wang MD (2007). "Single-molecule studies reveal dynamics of DNA unwinding by the ring-shaped t7 helicase". Cell 129 (7): 1299–309. doi:10.1016/j.cell.2007.04.038. PMID 17604719.
^ a b "Researchers solve mystery of how DNA strands separate" (2007-07-03). Retrieved on 2007-07-05.
^ Dumont S, Cheng W, Serebrov V, Beran RK, Tinoco Jr I, Pylr AM, Bustamante C, "RNA Translocation and Unwinding Mechanism of HCV NS3 Helicase and its Coordination by ATP", Nature. 2006 Jan 5; 439: 105-108. Anand SP, Zheng H, Bianco PR, Leuba SH, Khan SA. DNA helicase activity of PcrA is not required for displacement of RecA protein from DNA or inhibition of RecA-mediated DNA strand exchange. Journal of Bacteriology (2007) 189 (12):4502-4509.
Bird L, Subramanya HS, Wigley DB, "Helicases: a unifying structural theme?", Current Opinion in Structural Biology. 1998 Feb; 8 (1): 14-18.
Betterton MD, Julicher F, "Opening of nucleic-acid double strands by helicases: active versus passive opening.", Physical Review E. 2005 Jan; 71 (1): 011904.

Sengoku T, Nureki O, Nakamura A, Kobayashi S, Yokoyama S. Structural basis for RNA unwinding by the DEAD-box protein Drosophila Vasa. Cell. 2006 Apr 21;125(2):287-300. PMID:16630817 doi:10.1016/j.cell.2006.01.054
Sengoku T, Nureki O, Dohmae N, Nakamura A, Yokoyama S. Crystallization and preliminary X-ray analysis of the helicase domains of Vasa complexed with RNA and an ATP analogue. Acta Crystallogr D Biol Crystallogr. 2004 Feb;60(Pt 2):320-2. Epub 2004, Jan 23. PMID:14747711 doi:10.1107/S0907444903025897

Content Donators

Created with the participation of Luis E Ramirez-Tapia, Wayne Decatur.

Proteopedia Page Contributors and Editors (what is this?)

Michal Harel, Alexander Berchansky, Wayne Decatur, Joel L. Sussman

Retrieved from "http://52.214.119.220/wiki/index.php/Helicase"

@@ Line 47: / Line 47: @@
 ==PcrA Helicase Mechanism : The Mexican Wave==
 Professor Dale B. Wigley' group in 1996-1999 was able to crystalize the intermediate states from PcrA, giving solution to the controversy of what kind of mechanism this helicase has. [http://www.ncbi.nlm.nih.gov/pubmed/10199404ordinalpos=39&itool=EntrezSystem2.PEntrez.Pubmed.Pubmed_ResultsPanel.Pubmed_DefaultReportPanel.Pubmed_RVDocSum]
-Two crystal form of the enzyma, one couple with a 10 mer DNA and a non hydrolizable form of ATP (ATPnP) (pdb id: [[3pjr]], <scene name='User:Luis_E_Ramirez-Tapia/Sandbox_2/3pjrinitial/1'> (Enzyme Subtrate Structure) </scene>and another a truncated form embebed in sulfate (pdb id: [[2pjr]]<scene name='User:Luis_E_Ramirez-Tapia/Sandbox_2/2pjrinitial/1'> (Enzyme Product Structure)</scene>, give a light in a model for how ATP hydrolysis results in motor movement along ssDNA. In the figure below step 1 (top) is the ATP free (product) ssDNA conformation. The DNA bases are labelled arbitrarily. On binding ATP, F626 creates a new binding pocket for base 6. Likewise, F64 destroys an acceptor pocket for base 2, forcing it to move to the position occupied by base 1. After ATP hydrolysis, the grip on base 6 is released. When the Y257 pocket is re-opened due to movement of F64, bases 3-6 can now flip through the acceptor pockets to their new positions. This model predicts that each ATP hydrolysis event will advance PcrA one base along ssDNA.[http://www.icnet.uk/labs/wigley/projects/helicase/35.html]
+Two crystal form of the enzyma, one couple with a 10 mer DNA and a non hydrolizable form of ATP (ATPnP) (pdb id: [[3pjr]], <scene name='User:Luis_E_Ramirez-Tapia/Sandbox_2/3pjrinitial/1'> (Enzyme Substrate Structure) </scene>and another a truncated form embebed in sulfate (pdb id: [[2pjr]]<scene name='User:Luis_E_Ramirez-Tapia/Sandbox_2/2pjrinitial/1'> (Enzyme Product Structure)</scene>, give a light in a model for how ATP hydrolysis results in motor movement along ssDNA. In the figure below step 1 (top) is the ATP free (product) ssDNA conformation. The DNA bases are labelled arbitrarily. On binding ATP, F626 creates a new binding pocket for base 6. Likewise, F64 destroys an acceptor pocket for base 2, forcing it to move to the position occupied by base 1. After ATP hydrolysis, the grip on base 6 is released. When the Y257 pocket is re-opened due to movement of F64, bases 3-6 can now flip through the acceptor pockets to their new positions. This model predicts that each ATP hydrolysis event will advance PcrA one base along ssDNA.[http://www.icnet.uk/labs/wigley/projects/helicase/35.html]
 [[Image:Mexicanwave.jpg|thumb|170px|left|Inchworm or Mexicanwave model]]
 [[Image:Snapshot_2008-12-03_14-11-31.jpg|thumb|400px|center|PcrA Movie]]

Helicase

From Proteopedia

Revision as of 12:47, 8 July 2018

Contents

Function

What is a Helicase?

PcrA a Simple Model for Helicases

PcrA Biochemistry

PcrA Helicase Mechanism : The Mexican Wave

The Superfamily 1 (SF1)

3D structures of helicase

References

Content Donators

Proteopedia Page Contributors and Editors (what is this?)

Views

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