Post questions to the researchers below.
Please give them some time to answer- want the scientists focussed on the science, not browsing forums all day.
Posted 20 September 2013 - 12:29 AM
Posted 26 September 2013 - 01:16 AM
Posted 28 September 2013 - 08:45 PM
Edited by Elus, 28 September 2013 - 09:11 PM.
Posted 28 September 2013 - 10:24 PM
Posted 28 September 2013 - 11:25 PM
Assuming that the ultimate therapy would involve transfecting every cell, how feasible is this? I'm thinking that if you only get 90 or 95% transfection, then although there will be a lot of healthy mitochondria, there will still be a significant fraction of potentially sick mitochondria that might wreak all manner of havoc. Am I off base with this thinking?
Edited by Elus, 28 September 2013 - 11:31 PM.
Posted 30 September 2013 - 08:25 AM
Assuming that the ultimate therapy would involve transfecting every cell, how feasible is this? I'm thinking that if you only get 90 or 95% transfection, then although there will be a lot of healthy mitochondria, there will still be a significant fraction of potentially sick mitochondria that might wreak all manner of havoc. Am I off base with this thinking?
I wonder this too. Aubrey speaks of the selective advantage that "broken" mitochondria have - they do not incur oxidative damage to their membrane because of impaired OXPHOS, impairing the ability of the cell to discard these broken mitochondria which have high membrane fidelity (allowing them to to evade proteases) but low ATP production.
Perhaps by introducing this therapy, the mitochondrial population within the majority of cells will be maintained above some critical threshold such that disease does not occur.
Also, once transcribed from the nucleus, it appears that this mRNA isn't capable of differentiating between a broken mitochondrion and a healthy one (unless I'm mistaken). Would extra copies of mitochondrial mRNA enhance the function of healthy mitochondria above their normal capacity?
Edited by mitomutant, 30 September 2013 - 08:26 AM.
Posted 30 September 2013 - 01:23 PM
Can´t find the paper now but targeting defective mitochondria and inducing death on them would be a much more effective way to treat mitochondrial diseases. The "threshold effect" is key here: You "only" need to maintain a healthy ratio of wild-type/mutant mitochondria to keep the clinical symptons at bay. In fact, "genetic shifting" - in this case by increasing wild-type population via satellite cell activation - is a proposed therapy to treat mitochondrial diseases.
This is my opinion for treating mitochondrial diseases. I understand that SENS is not about treating diseases.
Posted 03 October 2013 - 06:29 PM
Posted 03 October 2013 - 09:28 PM
So why did you pick CyB and ATP8 as the two genes to work on here? Was that a fortuitous happenstance in terms of a suitable source of mutant cells to work with?
Posted 09 October 2013 - 09:42 PM
Edited by Oki, 09 October 2013 - 09:50 PM.
Posted 10 October 2013 - 08:23 AM
Assuming that the ultimate therapy would involve transfecting every cell, how feasible is this? I'm thinking that if you only get 90 or 95% transfection, then although there will be a lot of healthy mitochondria, there will still be a significant fraction of potentially sick mitochondria that might wreak all manner of havoc. Am I off base with this thinking?
Assuming that the ultimate therapy would involve transfecting every cell, how feasible is this? I'm thinking that if you only get 90 or 95% transfection, then although there will be a lot of healthy mitochondria, there will still be a significant fraction of potentially sick mitochondria that might wreak all manner of havoc. Am I off base with this thinking?
I wonder this too. Aubrey speaks of the selective advantage that "broken" mitochondria have - they do not incur oxidative damage to their membrane because of impaired OXPHOS, impairing the ability of the cell to discard these broken mitochondria which have high membrane fidelity (allowing them to to evade proteases) but low ATP production.
Perhaps by introducing this therapy, the mitochondrial population within the majority of cells will be maintained above some critical threshold such that disease does not occur.
Also, once transcribed from the nucleus, it appears that this mRNA isn't capable of differentiating between a broken mitochondrion and a healthy one (unless I'm mistaken). Would extra copies of mitochondrial mRNA enhance the function of healthy mitochondria above their normal capacity?
Posted 10 October 2013 - 01:45 PM
Posted 10 October 2013 - 04:42 PM
Can´t find the paper now but targeting defective mitochondria and inducing death on them would be a much more effective way to treat mitochondrial diseases. The "threshold effect" is key here: You "only" need to maintain a healthy ratio of wild-type/mutant mitochondria to keep the clinical symptons at bay. In fact, "genetic shifting" - in this case by increasing wild-type population via satellite cell activation - is a proposed therapy to treat mitochondrial diseases.
This is my opinion for treating mitochondrial diseases. I understand that SENS is not about treating diseases.
Edited by Michael, 15 October 2013 - 11:49 PM.
Posted 10 October 2013 - 04:48 PM
Are there any supplements that might promote natural mitochondrial transfer?
Posted 10 October 2013 - 05:14 PM
A safe live-replicating viral vector would be awesome, but I think we are a long way away from approval for one since it is so hard to safely control a replicating virus. Those suckers have a nasty tendency to evolve and spread!
Posted 10 October 2013 - 05:32 PM
SENS Research Foundation is, in fact, 100% dedicated to curing all of the diseases of aging. We are also working on connecting the research that we do to ways in which it can help people with rare disease. For example, I have been in contact with the United Mitochondrial Disease Foundation and they have expressed interest in the potential of my approach for treating inherited and spontaneous mitochondrial disease.proposed therapy[/url] to treat mitochondrial diseases.
This is my opinion for treating mitochondrial diseases. I understand that SENS is not about treating diseases.
Edited by Michael, 15 October 2013 - 11:48 PM.
Posted 10 October 2013 - 05:34 PM
Are there any supplements that might promote natural mitochondrial transfer?
In short, no. What we are doing is completely artificial and highly engineered. There are many topics on the longecity forums that discuss supplements and drugs that might help improve mitochondrial function, but nothing other than an engineered solution can fix a mitochondria that has lost 100% of its ability to synthesize its own proteins.
Mitochondrial transfer between cells can rescue aerobic respiration
We report here that mitochondria are more dynamic than previously considered: mitochondria or mtDNA can move between cells. The active transfer from adult stem cells and somatic cells can rescue aerobic respiration in mammalian cells with nonfunctional mitochondria...In this article, we ask whether stem/progenitor cells or other somatic cells can repair cells with nonfunctional mitochondria by transfer of functional mitochondria or mtDNA.
Posted 11 October 2013 - 08:29 PM
UMDF is a great organization for patient care and family support, but consider contacting Foundation for Mitochondrial Medicine and JDM Fund for mitochondrial research. The are much more focused on funding projects like yours. For example, JDM helped to fund the latest Dr. Moraes research with TALE nucleases to target and destroy mutant mitochondria.
Posted 15 October 2013 - 07:42 PM
Posted 16 October 2013 - 05:54 AM
Which of the "13" mitochondrial proteins have you already done? And which haven't you started on yet? How much more is there still to do before you can show that all "13" proteins can be individually imported successfully? Are there any that you expect to have difficulties with?
And what about the 14th mitochondrial DNA encoded protein? Are you going to do anything about Humanin? It appears to protect neurons. I haven't heard anything from SENS about it. Fortunately, even though it is encoded by mitochondrial DNA, it doesn't seem to need importing into the mitochondria, since it acts on both the inside and the outside of cells. And fortunately, other people have already made circular DNA of it that the nucleus can process, and that is effective in rejuvenating neurons.
(In case you are wondering where the genes for another protein are hiding... it's in the rRNA of MT-RNR2... the ribosome has to translate part of another ribosome)
Posted 17 October 2013 - 04:43 PM
Posted 18 October 2013 - 01:46 AM
Posted 28 October 2013 - 04:09 AM
Edited by Elus, 28 October 2013 - 04:16 AM.
Posted 02 December 2013 - 07:40 AM
Posted 06 December 2013 - 01:27 AM
Edited by olaf.larsson, 06 December 2013 - 01:30 AM.
Posted 06 December 2013 - 01:58 AM
Apologies if I have got this wrong, I am no scientist, but what is to stop the dysfunctional proteins produced by the damaged genes in the mitchondria completing with the corrected imported proteins?
And how do you know that this isn't a prion Huntington style disease where a misfolded protein is wrecking havock (but only within the mtichondria)?
Posted 21 December 2013 - 12:17 AM
Thanks for the reply Matthew.
I'm sure you've seen this recent research on Mtichondrial dysfunction which seems to suggested aging is caused by a breakdown in communication between the nucleus' genome and the mtiochondrial genomes (decreased NAD decreases the ability of SIRT1 to keep HIF-1 in check, leading to a breakdown in communication).
What implications (if any) does this have for your group's research?
Edited by jiminbrizzy, 21 December 2013 - 12:18 AM.
Posted 19 December 2015 - 01:03 AM
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