Thymosin: Difference between revisions
Bradley Monk (talk | contribs) (Created page with "See also: Actin") |
Bradley Monk (talk | contribs) No edit summary |
||
| Line 1: | Line 1: | ||
See also: [[Actin]] | See also: [[Actin]] | ||
==Articles== | |||
<!-- * {{PopFig|[[File:Dot.png]]|<html><video src="XXXXXX" controls></video> <br> <div style='color:white; width:400px'> XXXXX </div></html>||<big>SI video1 </big>}} --> | |||
{{Article|Honkura, Matsuzaki, Noguchi, Ellis-Davies, Kasai|2008|Cell • [http://www.sciencedirect.com/science/article/pii/S0896627308000743 FullText]|18341992|The subspine organization of actin fibers regulates the structure and plasticity of dendritic spines.}} | |||
<mediaplayer image='http://www.bradleymonk.com/w/images/d/da/Kasai_GluUncaging_S7.png' width='500' height='300'>http://www.bradleymonk.com/w/images/1/18/Kasai_GluUncaging_S7.mov</mediaplayer> | |||
{{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/1/18/Kasai_GluUncaging_S7.mov" controls></video> <br> <div style='color:white; width:400px'> Movie S7. | |||
Two-photon imaging of the confinement of PAGFP-actin fluorescence after repetitive photoactivation and uncaging of MNI-glutamate (60 pulses of 0.6 ms duration at 1 Hz) at a point (square) distal to the apex of the spine shown in Figure 5D. The 2D images were acquired every 10 s for 7 min. Photoactivation was induced at the moment when the white square turns red. Scale bar, 1 μm. </div></html>||<big>SI video1 </big>}} | |||
<mediaplayer image='http://www.bradleymonk.com/w/images/0/06/Kasai_GluUncaging_S8.png' width='500' height='300'>http://www.bradleymonk.com/w/images/6/64/Kasai_GluUncagingLat_S8.mov</mediaplayer> | |||
{{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/6/64/Kasai_GluUncagingLat_S8.mov" controls></video> <br> <div style='color:white; width:400px'> Movie S8. | |||
Two-photon imaging of PAGFP-actin fluorescence after repetitive photoactivation and uncaging of MNI-glutamate (60 pulses of 0.6 ms duration at 1 Hz) at a point (square) distal to the apex of the spine shown in Figure 5G in the presence of Lat A (0.1 μM). The 2D images were acquired every 15 s for 10 min. Photoactivation was induced at the moment when the white square turns red. Scale bar, 1 μm. </div></html>||<big>SI video1 </big>}} | |||
{{Article|Fischer, Kaech, Knutti, Matus|1998|Cell • [http://www.ncbi.nlm.nih.gov/pubmed/9620690 FullText]|9620690|Rapid actin-based plasticity in dendritic spines.}} | |||
;Hover mouse over icon to expand supplementary movies: | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/5/5e/Mmc2.mov" controls></video> <br> <div style='color:white; width:400px'> Visualization of actin dynamics in migrating fibroblasts. A rat embryo fibroblast transiently transfected with EGFP was recorded crawling from top right to bottom left of the frame. In addition to the actin dynamics associated with membrane ruffles, note the reorientation of stress fibers as the cell turns slightly toward the left from its initial direction. Time marker shows hours, minutes, and seconds. | |||
</div></html>||<big>SI video1 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/a/ab/Mmc4.mov" controls></video> <br> <div style='color:white; width:400px'> Growth cone on a 48-hr-old hippocampal neuron transfected with GFP-actin. In addition to the concentration of actin in the “palm” of the growth cone, local concentrations are associated with spots and lateral filopodia from the shaft of the neurite. Time marker shows hours, minutes, and seconds. | |||
</div></html>||<big>SI video2 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/f/fb/Mmc6.mov" controls></video> <br> <div style='color:white; width:400px'> A large field from a GFP-actin expressing hippocampal neuron is shown at low magnification (40X objective lens). As well as showing the widespread nature of spine motility, this sequence also indicates the extent to which actin is concentrated in spines compared to the shaft domain of dendrites. Time marker shows hours, minutes, and seconds. | |||
</div></html>||<big>SI video3 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/e/e0/Mmc8.mov" controls></video> <br> <div style='color:white; width:400px'> Dynamics in motile spines recorded at higher magnification (100X objective lens) from a GFP-actin transfected cell in another culture. Over these short recording times the actin-driven changes are limited to spine shape and involve the growth and shrinkage of miniature protrusions. Time marker shows hours, minutes, and seconds. | |||
</div></html>||<big>SI video4 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/7/7e/Mmc10.mov" controls></video> <br> <div style='color:white; width:400px'> Even over the brief duration of this recording (90 s) in a GFP-actin transfected neuron, continuous changes in the configuration of spine actin are visible. Time marker shows minutes and seconds. | |||
</div></html>||<big>SI video5 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/1/13/Mmc12.mov" controls></video> <br> <div style='color:white; width:400px'> The cell shown in Figure 2a was recorded during an experiment to examine the susceptibility of spine motility to the actin polymerization inhibitor cytochalasin D. At the point indicated, medium containing the drug flowed into the observation chamber. Time marker shows hours, minutes, and seconds.</div></html>||<big>SI video6 </big>}} | |||
{{Article|Lang|2004|PNAS • [http://www.pnas.org/content/101/47/16665.full FullText]|15542587|Transient expansion of synaptically connected dendritic spines upon induction of hippocampal long-term potentiation.}} | |||
We find that induction of long-term potentiation (LTP) of synaptic transmission in acute hippocampal slices of adult mice evokes a reliable, transient expansion in spines that are synaptically activated, as determined with calcium imaging. Similar to LTP, transient spine expansion requires N-methyl- D-aspartate (NMDA) receptor-mediated Ca2 influx and actin polymerization. Moreover, like the early phase of LTP induced by the stimulation protocol, spine expansion does not require Ca2 influx through L-type voltage-gated Ca2 channels nor does it require protein synthesis. Thus, transient spine expansion is a characteristic feature of the initial phases of plasticity at mature synapses and so may contribute to synapse remodeling important for LTP. | |||
;Hover mouse over icon to expand supplementary movies: | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/2/2b/Lang2004S1Actin.mov" controls></video> <br> <span style='color:white;'>Typical transient expansion. <br>Movie of a spine exhibiting typical transient expansion corresponding to Fig. 1B <br> (12 frames acquired every 0.5 min, viewed at 4 frames/s). <br> The appearance of the red circle represents stimulation with a 1-s, 100-Hz tetanus.</span></html>||<big> video1 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/b/b8/Lang2004S2Actin.mov" controls></video> <br> <span style='color:white;'>Movie 2. Asymmetric transient expansion. <br> Movie of a spine exhibiting asymmetric transient expansion <br> corresponding to Fig. 1D (12 frames acquired every 0.5 min, viewed at 4 frames/s). <br> The appearance of the red circle represents stimulation with a 1-s, 100-Hz tetanus.</span></html>|| <big> video2 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/a/a1/Lang2004S3Actin.mov" controls></video> <br> <span style='color:white;'>Movie 3. Transient spine expansion on large- and small-diameter dendritic branches. <br>Movie of three dendritic branches with shafts of varying diameter from a single <br> CA1 pyramidal neuron exhibiting many spines undergoing transient expansion <br>(12 frames acquired every 0.5 min, viewed at 4 frames/s). <br>The appearance of the red circle represents stimulation with a 1-s, 100-Hz tetanus.</html>||<big> video3 </big>}} | |||
<!-- ###################################### --> | |||
{{Article|Fujiwara, Vavylonis, Pollard|2007|PNAS • [http://www.pnas.org/content/104/21/8827 FullText]|PMC1885587|Polymerization kinetics of ADP- and ADP-Pi-actin determined by fluorescence microscopy}} | |||
;Hover mouse over icon to expand supplementary movies: | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/b/b6/Pollard2007SI1.mov" controls></video> <br> <span style='color:white;'>SI Movie 1. Time lapse (230´) movie of the elongation of actin filaments by 3 mM Mg-ADP-actin <br>(30% Alexa-Green label) in polymerization buffer with 0.2 mM ADP, <br>viewed in a flow chamber coated with 50 nM NEM-myosin and 1% BSA.</span></html>||<big> SI movie1 </big>}} | |||
* {{PopFig|[[File:Dot.png]]|<html><video src="http://www.bradleymonk.com/w/images/e/e7/Pollard2007SI2.mov" controls></video> <br> <span style='color:white;'>Time lapse (225) movie of the elongation and depolymerization of ADP-actin filaments (30% Alexa label). <br>The movie begins with filaments elongating in 5 mM Mg-ADP-actin in polymerization buffer. <br>At the point indicated by WASHOUT, free actin monomers were washed out of the <br>chamber with polymerization buffer with 0.2 mM ADP to allow depolymerization.</span></html>||<big> SI movie2 </big>}} | |||
<!-- ###################################### --> | |||
{{Article|Koskinen and Hotulainen|2014|Frontiers • [http://journal.frontiersin.org/article/10.3389/fnana.2014.00074/abstract FullText]|PMC4122166|Measuring F-actin properties in dendritic spines}} | |||
Measurements of actin turnover in dendritic spines: | |||
Fitting the data from individual measurements resulted in a mean stable component size of 18% as well as mean time constants of 51 sec for the dynamic component and 840 sec for the stable component. | |||
<!-- ###################################### --> | |||
{{Article|Bindschadler, Osborn, Dewey, McGrath|2004|BiophysicalJ • [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1304143/ PMC]|PMC1304143|A Mechanistic Model of the Actin Cycle}} | |||
Actin polymerization proceeds until only a small concentration (~0.1 µM) of unpolymerized actin (Gactin) remains. This ‘‘critical concentration’’ is also the minimum concentration required to form filaments (F-actin). | |||
Both regulated and unregulated actin binding proteins modify the actin cycle in cells (Fig. 1). Barbed-end binding proteins block the assembly of G-actin at filament-barbed ends. The most abundant barbed-end binding proteins, <big>capping protein (CP)</big> and <big>gelsolin</big> (Isenberg et al., 1980; Yin et al., 1981), are inactivated by PIP2 and other polyphosphoinositides (Heiss and Cooper, 1991; Janmey and Stossel, 1987). Gelsolin, which also severs actin filaments (Yin and Stossel, 1979), requires micromolar calcium for its activity. CP, gelsolin, and Arp2/3 complex (Mullins et al., 1998), can nucleate new actin filaments. The processes of severing and nucleation help determine the number and length of actin filaments. <big>Arp2/3 complex</big> can also cap pointed ends (Mullins et al., 1998). Arp2/ 3 complex activities are greatly enhanced by the GTPase binding protein N-WASp (Machesky et al., 1999; Yarar et al., 1999). Inhibited by phosphorylation (Morgan et al., 1993), the ADF/cofilin family proteins bind preferentially to ADP containing subunits (Carlier et al., 1997). <big>Cofilin</big> destabilizes filaments by severing them (Maciver et al., 1991), by accelerating the rate of ADP subunit disassembly (Carlier et al., 1997), and by enhancing the rate of Pi release (Blanchoin and Pollard, 1999). Unregulated proteins of the '''<big>b4-thymosin family</big> bind actin monomers to maintain unpolymerized actin at hundreds of times the critical concentration ''' (Safer et al., 1990). Unlike b4-thymosin, the monomer binding protein <big>profilin</big> has catalytic functions. Profilin accelerates the exchange of ADP for ATP on actin monomer 140-fold (Selden et al., 1999). Also unlike actin complexed with b4-thymosin, profilin-bound G-actin assembles at barbed ends but not pointed ends (Pollard and Cooper, 1984), releasing unbound profilin (Pantaloni and Carlier, 1993). | |||
[[File:Bindschadler2004.png]] | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
<!-- ###################################### --> | |||
Revision as of 04:46, 2 October 2016
See also: Actin
Articles
Honkura, Matsuzaki, Noguchi, Ellis-Davies, Kasai • 2008 • Cell • FullText
<mediaplayer image='http://www.bradleymonk.com/w/images/d/da/Kasai_GluUncaging_S7.png' width='500' height='300'>http://www.bradleymonk.com/w/images/1/18/Kasai_GluUncaging_S7.mov</mediaplayer>
SEE POPUP{{#info: 
SI video1 }}
<mediaplayer image='http://www.bradleymonk.com/w/images/0/06/Kasai_GluUncaging_S8.png' width='500' height='300'>http://www.bradleymonk.com/w/images/6/64/Kasai_GluUncagingLat_S8.mov</mediaplayer>
SEE POPUP{{#info: SI video1 }}
Fischer, Kaech, Knutti, Matus • 1998 • Cell • FullText
- Hover mouse over icon to expand supplementary movies
- SEE POPUP{{#info:
SI video1 }}
- SEE POPUP{{#info: SI video2 }}
- SEE POPUP{{#info: SI video3 }}
- SEE POPUP{{#info: SI video4 }}
- SEE POPUP{{#info: SI video5 }}
- SEE POPUP{{#info: SI video6 }}
Lang • 2004 • PNAS • FullText
We find that induction of long-term potentiation (LTP) of synaptic transmission in acute hippocampal slices of adult mice evokes a reliable, transient expansion in spines that are synaptically activated, as determined with calcium imaging. Similar to LTP, transient spine expansion requires N-methyl- D-aspartate (NMDA) receptor-mediated Ca2 influx and actin polymerization. Moreover, like the early phase of LTP induced by the stimulation protocol, spine expansion does not require Ca2 influx through L-type voltage-gated Ca2 channels nor does it require protein synthesis. Thus, transient spine expansion is a characteristic feature of the initial phases of plasticity at mature synapses and so may contribute to synapse remodeling important for LTP.
- Hover mouse over icon to expand supplementary movies
- SEE POPUP{{#info: video1 }}
- SEE POPUP{{#info: video2 }}
- SEE POPUP{{#info: video3 }}
Fujiwara, Vavylonis, Pollard • 2007 • PNAS • FullText
- Hover mouse over icon to expand supplementary movies
- SEE POPUP{{#info: SI movie1 }}
- SEE POPUP{{#info: SI movie2 }}
Koskinen and Hotulainen • 2014 • Frontiers • FullText
Measurements of actin turnover in dendritic spines: Fitting the data from individual measurements resulted in a mean stable component size of 18% as well as mean time constants of 51 sec for the dynamic component and 840 sec for the stable component.
Bindschadler, Osborn, Dewey, McGrath • 2004 • BiophysicalJ • PMC
Actin polymerization proceeds until only a small concentration (~0.1 µM) of unpolymerized actin (Gactin) remains. This ‘‘critical concentration’’ is also the minimum concentration required to form filaments (F-actin).
Both regulated and unregulated actin binding proteins modify the actin cycle in cells (Fig. 1). Barbed-end binding proteins block the assembly of G-actin at filament-barbed ends. The most abundant barbed-end binding proteins, capping protein (CP) and gelsolin (Isenberg et al., 1980; Yin et al., 1981), are inactivated by PIP2 and other polyphosphoinositides (Heiss and Cooper, 1991; Janmey and Stossel, 1987). Gelsolin, which also severs actin filaments (Yin and Stossel, 1979), requires micromolar calcium for its activity. CP, gelsolin, and Arp2/3 complex (Mullins et al., 1998), can nucleate new actin filaments. The processes of severing and nucleation help determine the number and length of actin filaments. Arp2/3 complex can also cap pointed ends (Mullins et al., 1998). Arp2/ 3 complex activities are greatly enhanced by the GTPase binding protein N-WASp (Machesky et al., 1999; Yarar et al., 1999). Inhibited by phosphorylation (Morgan et al., 1993), the ADF/cofilin family proteins bind preferentially to ADP containing subunits (Carlier et al., 1997). Cofilin destabilizes filaments by severing them (Maciver et al., 1991), by accelerating the rate of ADP subunit disassembly (Carlier et al., 1997), and by enhancing the rate of Pi release (Blanchoin and Pollard, 1999). Unregulated proteins of the b4-thymosin family bind actin monomers to maintain unpolymerized actin at hundreds of times the critical concentration (Safer et al., 1990). Unlike b4-thymosin, the monomer binding protein profilin has catalytic functions. Profilin accelerates the exchange of ADP for ATP on actin monomer 140-fold (Selden et al., 1999). Also unlike actin complexed with b4-thymosin, profilin-bound G-actin assembles at barbed ends but not pointed ends (Pollard and Cooper, 1984), releasing unbound profilin (Pantaloni and Carlier, 1993).
