C-JUN: Difference between revisions

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== Introduction ==
== Introduction ==


The c-Jun protein is a member of transcription factors which consist of a basic region leucine zipper region  <ref name="one">PMID:8662824</ref>.  Originally identified by its homology to v-jun, the oncogene from the avian sarcomoa virus <ref name="four"/> Bossy-Wetzel, E., Bakiri, L., Yaniv, M.  (1997).  Induction of apoptosis by the transcription factor c-Jun.  EMO Journal.  Vol.16;7.  1695-1709 </ref>.    All these leucine zipper factors bind to DNA in one of two states: homo or heterodimers  <ref>PMID:8662824</ref>.  In conjunction with the c-Fos protein these two proteins bind to specific regions of DNA strands.  Together these two proteins form the c-fos/c-jun complex which help regulate cell growth and differentiation <ref name="one">.  the members of the jun and fos families include three Jun proteins and four Fos proteins  (c-Jun, JunB, JunD,c-Fos, Fos-B, Fra1, and Fra2) <ref name="one">.  Regulation of the complex iteslf is done by interactions between the protein and DNA in addition to the protein-protein  interactions between each of the leucine zipper domains <ref name="one">.           
The c-Jun protein is a member of transcription factors which consist of a basic region leucine zipper region  <ref name="one">PMID:8662824</ref>.  Originally identified by its homology to v-jun, the oncogene from the avian sarcomoa virus <ref name="four"> Bossy-Wetzel, E., Bakiri, L., Yaniv, M.  (1997).  Induction of apoptosis by the transcription factor c-Jun.  EMO Journal.  Vol.16;7.  1695-1709 </ref>.    All these leucine zipper factors bind to DNA in one of two states: homo or heterodimers  <ref name="two">PMID:8662824</ref>.  In conjunction with the c-Fos protein these two proteins bind to specific regions of DNA strands.  Together these two proteins form the c-fos/c-jun complex which help regulate cell growth and differentiation <ref name="one">.  the members of the jun and fos families include three Jun proteins and four Fos proteins  (c-Jun, JunB, JunD,c-Fos, Fos-B, Fra1, and Fra2) <ref name="one">.  Regulation of the complex iteslf is done by interactions between the protein and DNA in addition to the protein-protein  interactions between each of the leucine zipper domains <ref name="one">.           
    
    
== Structure Overview ==
== Structure Overview ==
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The structure of c-Jun is comprised of a leucine zipper as previously stated.  This dimerization motif may be in one of two classes, both of which are required for DNA-binding transcription factors; the basic-domain leucine zipper proteins (bZIP) and the basic helix loop-helix-leucine zipper proteins(bHLH-ZIP) <ref name="ref2"/> A Junius, F.K., Mackay, J.P., Bubb, W.A., Jensen, S.A., Weiss, A.S., King, G.F.  2006.  Nuclear Magnetic Resonance Characterization of the Jun Leucine Zipper Domain:  Unusual Properties of Coiled-Coil Interfacial Polar Residues?</ref>.  As can be been in the figure XXXXX, the strand becomes an elongated coiled coil.  This is formed by residues at the a and d positions in each of the two monomers, whereby they create hydrophobic centers which conform to the "knobs into holes" model by Crick.  <ref name="ref2"/>.  amino acids at these a and d positions are each surrounded by 4 additional residues from adjacent a-helix monomer <ref name="ref2"/>.
The structure of c-Jun is comprised of a leucine zipper as previously stated.  This dimerization motif may be in one of two classes, both of which are required for DNA-binding transcription factors; the basic-domain leucine zipper proteins (bZIP) and the basic helix loop-helix-leucine zipper proteins(bHLH-ZIP) <ref name="two"/> A Junius, F.K., Mackay, J.P., Bubb, W.A., Jensen, S.A., Weiss, A.S., King, G.F.  2006.  Nuclear Magnetic Resonance Characterization of the Jun Leucine Zipper Domain:  Unusual Properties of Coiled-Coil Interfacial Polar Residues?</ref>.  As can be been in the figure XXXXX, the strand becomes an elongated coiled coil.  This is formed by residues at the a and d positions in each of the two monomers, whereby they create hydrophobic centers which conform to the "knobs into holes" model by Crick.  <ref name="two"/>.  amino acids at these a and d positions are each surrounded by 4 additional residues from adjacent a-helix monomer <ref name="two"/>.


the a and d residues each exhibit varying types of packing in terms of this "knobs into holes" theory.  According to Harbury et al.(24) the leucines at the a positions are packed "parallel" in such a way that the C-alpha-C-beta bond vector lies in a parallel manner to the C-alpha-C-alpha vector at the base of the acceptor hole on adjacent helix <ref name="one">.  Whereas the opposite is true for the leucines in the d positions.  Here the residues are packed in a "perpendicular" nature <ref name="one">.  The bond vector of the C-alpha-C-beta pack approximately perpendicular to the C-alpha-C-alpha vector at the base of the hole of the second helix in which it packs <ref name="one">.  therefore only the leucine side chains in the a positions, which point away from the boundary, make van der Waals interactions <ref name="one">.         
the a and d residues each exhibit varying types of packing in terms of this "knobs into holes" theory.  According to Harbury et al.(24) the leucines at the a positions are packed "parallel" in such a way that the C-alpha-C-beta bond vector lies in a parallel manner to the C-alpha-C-alpha vector at the base of the acceptor hole on adjacent helix <ref name="one">.  Whereas the opposite is true for the leucines in the d positions.  Here the residues are packed in a "perpendicular" nature <ref name="one">.  The bond vector of the C-alpha-C-beta pack approximately perpendicular to the C-alpha-C-alpha vector at the base of the hole of the second helix in which it packs <ref name="one">.  therefore only the leucine side chains in the a positions, which point away from the boundary, make van der Waals interactions <ref name="one">.         
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== Protein Function ==
== Protein Function ==


The primary function of c-Jun is in regards to DNA transcription.  Specifically, the protein is involved in proliferation, apoptosis, oncogenic transformation and various cellular processes <ref name="ref3"/>.  for instance cells which lack an allele for c-jun show stunted growth both in vitro and in vivo <ref name="ref4"/>.  whereas a prolonged and therefore strong induction of c-jun has been in response to such things as tumor necrosis factor, stress inducing stimuli such as UV <ref name="ref4"/>.         
The primary function of c-Jun is in regards to DNA transcription.  Specifically, the protein is involved in proliferation, apoptosis, oncogenic transformation and various cellular processes <ref name="three">PMID:12798298</ref>.  for instance cells which lack an allele for c-jun show stunted growth both in vitro and in vivo <ref name="four"/>.  whereas a prolonged and therefore strong induction of c-jun has been in response to such things as tumor necrosis factor, stress inducing stimuli such as UV <ref name="four"/>.         


== Protein Regulation ==
== Protein Regulation ==

Revision as of 09:45, 1 April 2010

Andrew Rebeyka

C-JUNC-JUN


1JUN

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IntroductionIntroduction

The c-Jun protein is a member of transcription factors which consist of a basic region leucine zipper region [1]. Originally identified by its homology to v-jun, the oncogene from the avian sarcomoa virus [2]. All these leucine zipper factors bind to DNA in one of two states: homo or heterodimers [3]. In conjunction with the c-Fos protein these two proteins bind to specific regions of DNA strands. Together these two proteins form the c-fos/c-jun complex which help regulate cell growth and differentiation Cite error: Closing </ref> missing for <ref> tag. As can be been in the figure XXXXX, the strand becomes an elongated coiled coil. This is formed by residues at the a and d positions in each of the two monomers, whereby they create hydrophobic centers which conform to the "knobs into holes" model by Crick. [3]. amino acids at these a and d positions are each surrounded by 4 additional residues from adjacent a-helix monomer [3].

the a and d residues each exhibit varying types of packing in terms of this "knobs into holes" theory. According to Harbury et al.(24) the leucines at the a positions are packed "parallel" in such a way that the C-alpha-C-beta bond vector lies in a parallel manner to the C-alpha-C-alpha vector at the base of the acceptor hole on adjacent helix Cite error: Closing </ref> missing for <ref> tag. for instance cells which lack an allele for c-jun show stunted growth both in vitro and in vivo [2]. whereas a prolonged and therefore strong induction of c-jun has been in response to such things as tumor necrosis factor, stress inducing stimuli such as UV [2].

Protein RegulationProtein Regulation

Changes made in the phosphorylation state of specific amino acids is one means by which c-Jun regulates transcription [4] PMID:8165146 </ref>. To date two seperate sites of phosphorylation have been identified. at the N-terminal end are the amino acids Ser63 and Ser73, which are phosphorylated in response to ras expression. When ras is expressed, and Ser63 and Ser73 are phosphorylated, transcriptional activity of c-Jun increases. the second site is located at the C-terminal which is very close in proximity to the DNA binding domain. Here the residues are Thr214, Ser226, and Ser 232 [4]. Unlike the two serines at the N-terminal end, phosphorylation at the C-terminal end inhibits DNA binding to c-Jun [4]. therefore with the expression of such oncogenes as ras lead to dephsphorylation of these three residues.

Psychological InfluencesPsychological Influences

The stress-induced signalling cascade may also active c-Jun by phosphorylation. the N-ternminal protein kinase phosphorylates Ser63 and Ser73 [5] PMID:10064599 </ref> . Another mechanism for the activation however is interestingly through intracellular calcium concentrations. increasing these concentrations by opening the L-type voltage gated calcium channels It was found that the N-terminus contains both calcium and stress-regulated transcriptional activation domains [5]. According to the study,distinct mechanisms of c-Jun control function by calcium and stress signals [5].



ReferencesReferences

  1. Junius FK, O'Donoghue SI, Nilges M, Weiss AS, King GF. High resolution NMR solution structure of the leucine zipper domain of the c-Jun homodimer. J Biol Chem. 1996 Jun 7;271(23):13663-7. PMID:8662824
  2. 2.0 2.1 2.2 Bossy-Wetzel, E., Bakiri, L., Yaniv, M. (1997). Induction of apoptosis by the transcription factor c-Jun. EMO Journal. Vol.16;7. 1695-1709
  3. 3.0 3.1 3.2 Junius FK, O'Donoghue SI, Nilges M, Weiss AS, King GF. High resolution NMR solution structure of the leucine zipper domain of the c-Jun homodimer. J Biol Chem. 1996 Jun 7;271(23):13663-7. PMID:8662824
  4. 4.0 4.1 4.2 Cite error: Invalid <ref> tag; no text was provided for refs named ref6
  5. 5.0 5.1 5.2 Cite error: Invalid <ref> tag; no text was provided for refs named ref5

Proteopedia Page Contributors and Editors (what is this?)Proteopedia Page Contributors and Editors (what is this?)

Andrea Gorrell, Andrew Rebeyka, David Canner, Michal Harel, Alexander Berchansky
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