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DJ-1: Deglycation 40,000x faster than FN3K

dj-1deglycation glycation fructosamine-3- kinases fn3k

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#1 Logic

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Posted 22 February 2016 - 05:06 PM


DESCRIPTION The inventors have found that the enzymes of the invention display protein and nucleic acid deglycase activities, which has never been disclosed. Indeed, although an alleged glyoxalase activity had been proposed for the DJ-1 protein and for bacterial Hsp31 (Lee et al. , Hum Mol Genet. , 21 (1 ): 3215-25, 2012, Subedi et al. , Mol. Microbiol. 81 , 926-936), it was never suggested nor demonstrated that neither the DJ-1 protein, nor its bacterial homologs Hsp31 , YhbO and YajL, actually harbor a deglycase activity.
 
The enzymes of the invention are early protein deglycases which can notably use substrates such as aminocarbinols formed by reaction of arginines and lysines residues with methylglyoxal and glyoxal , and hemithioacetals formed by reaction of cysteines residues with methylglyoxal or glyoxal (as demonstrated in the experimental part herein). Moreover, the inventors have found that the enzymes of the invention can also use as substrates the aminocarbinols formed by reaction of nucleotides aminogroups with glyoxals.
 
Interestingly, the enzymes of the invention catalyse deglycation at the second time- level, which means that they are about 40,000-fold faster than fructosamine-3- kinases (FN3K), and also impressively faster than FN3K-related proteins. The enzymes of the invention can act at the hemithioacetal step (for glycated cysteines), or the aminocarbinol step (for glycated lysines, arginines and nucleotides), and release the repaired amino acid, protein or nucleotide/nucleic acid and an acid-alcohol (lactate from methylglyoxal and glycolate from glyoxal).
 
The enzymes of the invention can thus act as instant deglycases, on the first glycation intermediates (hemithioacetals and aminocarbinols), and thus prevent formation of late intermediates, including AGEs. Indeed, there is a precursor-product relationship between early glycation products (including hemithioacetals and aminocarbinols which can be deglycated by deglycases of the invention) and late intermediates (i.e. late glycation products), including AGEs.
 
Moreover, the inventors have shown that the enzymes of the invention, by the way of their deglycase activity, can restore the activity of glycated proteins and enzymes such as bovine serum albumin, glyceraldehyde-3-phosphate dehydrogenase, fructose biphosphate aldolase and aspartate transaminase, i.e. proteins with cysteine or lysine and/or arginine residue in their active site. The enzymes of the invention can therefore be used to either to prevent or to reverse glycation on free lysine, arginine and lysine, and on lysyl-, arginyl- and cysteinyl residues of proteins, as well as on amino groups of free nucleic acids (particularly guanine residues, which are most prone to glycation (Voulgaridou et al. Mutation Res. 71 1 , 13-27), and polynucleotides which has never been shown for any enzyme.
http://www.sumobrain...15140348A2.html


Boosting your body's on glycation removal or deglycases seems like one of the best ways of stopping and reversing AGEs and the increase in bad NF-kB and short telomeres etc that come with it.
 
I hope the better qualified and experienced members here will read this patent and post their thoughts.

For us amature enthusiasts:
 

The invention thus further pertains to the use of DJ-1 inducers, preferably isothiocyanates, such as sulforaphane for example, or plant extracts, such as those from Butea frondosa or Butea monosperma for instance (Sujith et al. Asian J. of Pharmaceut. And Clin. Res. 4, 93).

 

The inventors have already shown that sulforaphane induces 3-fold the expression of Hsp31 and YhbO in bacterial cells (Figure 10B-C), and it is likely that it induces similarly DJ-1 in eukaryotic cells. Morover, it has been reported that sulforaphane induces Nrf2 (Kerns et al. PNAS 104, 14460, Xue et al. Diabetes, 57, 2809)) and also induces glyosalase

 

we tried to induce the deglycases with sulforaphane, a naturally occurring isothiocyanate derived from cruciferous vegetables, which is a potent inducer of phase 2 cytoprotective enzymes and protects cells against electrophiles, oxidative stress and inflammation (42) (sulforaphane likely acts by stabilization of Nrf2, which results in the induction of oxidative and electrophile stress resistance genes). As shown in Figure 10 B, C, sulforaphane, at micromolar concentrations which did not affect bacterial growth, induced Hsp31 and YhbO expression by 3 to 4-fold.

 
http://www.longecity...nable-efficacy/
 
https://cse.google.c....q=sulforaphane
 
ANTIDIABETIC ACTIVITY OF METHANOLIC EXTRACT OF BUTEA FRONDOSA LEAVES WITH ITS POSSIBLE MECHANISM OF ACTION
http://www.ajpcr.com...4Issue3/380.pdf
 
Examine.com
https://examine.com/...tea-monosperma/


Edited by Logic, 22 February 2016 - 05:27 PM.

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#2 niner

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Posted 23 February 2016 - 12:02 AM

The patent claims that DJ-1 can reduce the early steps of glycation, but once a complete crosslink is formed, I don't think it will do anything to it.  If it can be induced in humans through the consumption of sulforaphane or other isothiocyanates, then that would be yet another reason to eat your vegies.  It should hypothetically slow down the rate of crosslink formation, but it doesn't look like it would do anything to existing crosslinks.


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#3 Logic

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Posted 24 February 2016 - 10:02 PM

The patent claims that DJ-1 can reduce the early steps of glycation, but once a complete crosslink is formed, I don't think it will do anything to it.  If it can be induced in humans through the consumption of sulforaphane or other isothiocyanates, then that would be yet another reason to eat your vegies.  It should hypothetically slow down the rate of crosslink formation, but it doesn't look like it would do anything to existing crosslinks.

 

 

Thx for replying Niner.

I know patents are often 'pie in the sky', but this one seems well researched and referenced.
As AGEs are slowly cleared naturally and if DJ-1 is able to deglycate proteins 40,000 X faster than FN3K etc; this stuff might just lead to a slow decrease in AGEs?

 

I'd hate to see a good lead go unnoticed!



#4 Steve H

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Posted 24 February 2016 - 10:28 PM

Agree with niner. If you want me to test this in mice and confirm I can if costs are met.
Agree with niner. If you want me to test this in mice and confirm I can if costs are met.

#5 Steve H

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Posted 24 February 2016 - 10:36 PM

Ditto if you want me to obtain glucosepane from David Spiegel and get it tested. Most likely enzymes are the solution and David is making progress. This is likely one of the growing list of things that slow down cross linking but do nothing to stable cross links once formed

#6 corb

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Posted 25 February 2016 - 01:51 AM

Ditto if you want me to obtain glucosepane from David Spiegel and get it tested. Most likely enzymes are the solution and David is making progress. This is likely one of the growing list of things that slow down cross linking but do nothing to stable cross links once formed

 

I think a test with just glucosepane would be more helpful in the long run.
There are myriads of papers looking at pentosidine and glucosepane and their correlation to pathology.
There hasn't been a single one as far as I know looking at or trying to prove causation.
 



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#7 Logic

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Posted 25 February 2016 - 11:53 AM

Ditto if you want me to obtain glucosepane from David Spiegel and get it tested. Most likely enzymes are the solution and David is making progress. This is likely one of the growing list of things that slow down cross linking but do nothing to stable cross links once formed

 

I know its just a patent but:

"Moreover, the inventors have shown that the enzymes of the invention, by the way of their deglycase activity, can restore the activity of glycated proteins and enzymes such as bovine serum albumin, glyceraldehyde-3-phosphate dehydrogenase, fructose biphosphate aldolase and aspartate transaminase, i.e. proteins with cysteine or lysine and/or arginine residue in their active site. The enzymes of the invention can therefore be used to either to prevent or to reverse glycation on free lysine, arginine and lysine, and on lysyl-, arginyl- and cysteinyl residues of proteins, as well as on amino groups of free nucleic acids (particularly guanine residues, which are most prone to glycation (Voulgaridou et al. Mutation Res. 71 1 , 13-27), and polynucleotides which has never been shown for any enzyme."

 

The patent holders may be interested in 'meeting costs' and that would be a good measure of how sure they are of their claims.
If it works as claimed; You will also need them for the inevitable startup company as they already hold the patent..!  :)



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#8 niner

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Posted 26 February 2016 - 01:31 AM

The problem is that when a protein is first glycated, it sits around in a repairable state for a day or two.  This is the state where a Lys, Arg, or Cys has reacted with a sugar molecule or some other glycating agent, but it has not yet formed a crosslink. It's this state that the enzyme in the patent can repair.  If you could somehow maintain a high enough level of the enzyme in your system at all times, then perhaps these glycations could be repaired before the next step happens.  It's the next step that's the real problem-- That's the step where the glycated residues react with a different protein, or perhaps a different residue on the same protein, and form a stable crosslink, typically a glucosepane linkage in humans.  It's this final step that is the biological disaster, and we don't at present have a way to break those bonds.  I think that if DJ-1 could cleave a glucosepane linkage, that would be pretty big news, but I don't see them claiming to do this.  Now that the Spiegel lab has developed their breakthrough synthesis of glucosepane, we're finally on the road to a solution for this problem, but I don't think it will be quick or easy.


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Also tagged with one or more of these keywords: dj-1deglycation, glycation, fructosamine-3- kinases, fn3k

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