Iron In Pyruvate Kinase Deficiency

Would not this article point to a PREdisease iron loading Pyruvate Kinase Deficiency .. ?
It seems to say the IRON itself CAUSES the deficiency.
It would then again evidence the possibility of a 'long term transfusion independent remission' by going LOWER than that one might think they 'need' to in order to generate the remission .. ?
Iron loading found in those with sickle-cell and now to Pyruvate Kinase Deficiency .. ?

Iron-Dependent Oxidative Inactivation with Affinity Cleavage of
Pyruvate Kinase.
Biol Trace Elem Res. 2009 Jan 24.
Murakami K, Tsubouchi R, Fukayama M, Qiao S, Yoshino M.
Department of Biochemistry, Aichi Medical University School of
Medicine,
Nagakute, Aichi, 480-1195, Japan.

Treatment of rabbit muscle pyruvate kinase with iron/ascorbate caused
an inactivation with the cleavage of peptide bond.
The inactivation or fragmentation of the enzyme was prevented by
addition of Mg(2+), catalase, and mannitol, but ADP and PEP the
substrates did not show any effect.
Protective effect of catalase and mannitol suggests that hydroxyl
radical produced through the ferrous ion-dependent reduction of oxygen
is responsible for the inactivation/fragmentation of the enzyme.
SDS-PAGE and TOF-MS analysis confirmed five pairs of fragments, which
were determined to result from the cleavage of the Lys114-Gly115,
Glu117-Ile118, Asp177-Gly178, Gly207-Val208, and Phe243-Ile244 bonds
of the enzyme by amino-terminal sequencing analysis.
Protection of the enzyme by Mg(2+) implies the identical binding sites
of Fe(2+) and Mg(2+), but the cleavage sites were discriminated from
the cofactor Mg(2+)-binding sites.
Considering amino acid residues interacting with metal ions and
tertiary structure, Fe(2+) ion may bind to Asp177 neighboring to
Gly207 and Glu117 neighboring to Lys114 and Phe243, causing the
peptide cleavage by hydroxyl radical.
Iron-dependent oxidative inactivation/fragmentation of pyruvate kinase
can explain the decreased glycolytic flux under aerobic conditions.
Intracellular free Mg(2+) concentrations are responsible for the
control of cellular respiration and glycolysis.

PMID: 19169653
---------------------

Lower Ferritin Concentrations Are Associated with Decreased Hemolysis
in Sickle Cell Disease Children without Iron Overload.
Blood (ASH Annual Meeting Abstracts) 2009 114: Abstract 2571
Oswaldo L Castro, MD1, Mehdi Nouraie, M.D., Ph.D.*,1, Lori Luchtman-
Jones, MD2, Xiaomei Niu, M.D.*,1, Caterina Minniti, M.D.*,3, Andrew D.
Campbell, MD4, Sohail R Rana, MD*,5, Gregory J. Kato, MD6, Mark
Gladwin, MD7 and Victor R. Gordeuk, MD1
1 Center for Sickle cell Disease, Howard University, Washington, DC,
USA,
2 Children's National Medical Center, Washington, DC, USA,
3 Vascular Medicine Branch, NHLBI, Bethesda, MD, USA,
4 Pediatric Hematology/Oncology, Univ. of Michigan Med. Ctr., Ann
Arbor, MI, USA,
5 Department of Pediatric and Child Health, Howard University
Hospital, Washington, DC,
6 Pulmonary and Vascular Medicine Branch, National Heart, Lung, and
Blood Institute, National Institutes of Health, Bethesda, MD, USA,
7 Division of Pulmonary, Allergy and Critical Care Medicine,
University of Pittsburgh Medical Center, Pittsburgh, PA, USA


Abstract 2571

Poster Board II-548

The role of iron in the pathophysiology of sickle cell disease
(SCD) is complex and not fully understood.
Iron overload is associated with disease severity primarily
because multiple transfusions are linked to a severe SCD
clinical course.
Additionally, hemolysis, also associated with disease severity,
increases iron absorption.
Iron deficiency decreases red cell MCHC, which lowers Hb S
polymerization and thus may improve the clinical manifestations
of SCD.
Such a hypothesis is supported by our recent observation of a
homozygous SCD adult with iron deficiency anemia and a very low
hemolytic rate that increased dramatically with iron
supplementation.
This experience and similar case reports from the literature led
us to examine the relationship of ferritin levels with hemolysis
and other laboratory and clinical parameters in a group of non-iron
overloaded children with sickle cell disease.
All subjects in this analysis were enrolled in a prospective study
of the prevalence and significance of pulmonary hypertension in
children with SCD (PUSH).
Because of the known association of high serum ferritin with
multiple transfusions and with a severe clinical course in this
and other SCD populations, we excluded children who had ferritin
concentrations of 242 ng/ml or higher.
This cut-off value is 3 SDs above the geometric mean of the
ferritin concentrations in a group of 42 age, sex, and ethnicity
matched control children without SCD.
Hence the group of sickle cell children with ferritin levels of
< 242 ng/ml should include only those with iron deficiency or
with normal iron stores.

In this group of non-iron overloaded SCD children and
adolescents (median age 12 y, range 3–20 y), lower
serum ferritin was related to higher serum transferrin
and to lower serum iron and MCV, documenting that serum
ferritin was reflective of iron status.
Hemolytic parameters such as reticulocyte count and the
hemolytic component were significantly lower with lower
ferritin levels.
In multivariable analysis these relationships remained
statistically significant (P for MCV and ferritin: 0.003,
P for hemolytic component and ferritin: 0.044) even after
correcting for alpha-thalassemia, which is known to also
lower MCV and hemolysis, and for markers of inflammation
(WBC) and liver disease (ALT), which could increase the
ferritin level regardless of iron stores.
Ferritin was significantly lower in older subjects, probably
as a result of growth-related red cell mass expansion in the
presence of marginal iron stores.
Our results thus suggest that low iron stores are independently
associated with decreased hemolysis.
Low hemolysis is likely to be beneficial in SCD by reducing
hemolysis-related vasculopathy, which in adult SCD patients
predicts an increased risk of pulmonary hypertension, leg
ulcers, priapism, and death.
Whether iron status per se plays a role in the pathogenesis
of SCD vasculopathy is not known.
In non-SCD adults, decreasing iron stores by frequent blood
donation has beneficial effects on endothelial function and
cardiovascular disease even within the normal range for iron
stores.
Hence, lowering iron stores could benefit SCD subjects by
an additional, hemolysis-independent mechanism.
Therapeutic iron depletion is not an option for children
because of their need for adequate iron stores for optimal
physical and neuro-psychological development.
However, carefully controlled studies should be considered to
reduce iron stores and so decrease the hemolytic rate in
adults with SCD.
It may be possible to achieve levels of iron reduction that
lower hemolysis but do not worsen the anemia: in our study
subjects, low iron stores were not associated with increased
anemia and the red cell counts were actually higher with
lower ferritin levels.

Disclosures: Gordeuk: TRF Pharma: Research Funding; Merck:
Research Funding; Biomarin pharmaceutical company:
Research Funding; Novartis: Speakers Bureau.


© 2009 American Society of Hematology

As for the first article: could you please transform it into human being languague?
However, I have such feeling that this article was based on bodybuilders who take the supplement 'pyruvate'. Or am I the only who is completely nuts? 

I think it says they INDUCED the pyruvate kinase deficiency BY giving the mouse iron and vitamin C .. ?
THAT is what leads me to the conclusion that an iron and/or vitamin C seems to CAUSE a deficiency of pyruvate kinase / pyruvate kinase deficiency and I assume all its' baggage.
This part is what I found interesting .. "Protective effect of catalase and mannitol".
Mannitol and catalase are both iron chelators.

Quote: Mannitol and catalase are both iron chelators.

Some will argue catalase does NOT work BY iron chelation BUT this snip COMPARES all these and they RESULT in the SAME .. ie: reduced oxidation ..

"2–2′-dipyridyl is an iron chelator that prevents the Fenton-mediated hydroxyl radical formation. A knockout of iscS substantially impairs iron sulfur cluster synthesis capability and therefore it prevents the Fenton reaction . Here we show that similarly to catalase and superoxide dismutase, 2–2′-dipyridyl  and a knockout of iscS prevented mazEF-mediated cell death triggered by inhibitors of transcription and/or translation, but not by antibiotics causing DNA damage."

http://www.plosbiology.org/article/info:doi/10.1371/journal.pbio.0060319#pbio-0060319-g001

I am sorry, I dont get it. Why can iron and vit C has such effect? We don't have any pyrvate, so what's the sense? I still want to ask the expert, but I have such thought that some patients has a little pyruvate in their body. I don't know.

As to an opinion from an 'expert' they may believe they know the precise ins and outs of the science of it but MUST leave preconceived notions out of it because preconceived notions is what stops some from proceeding in a manner which may bring about a treatment or two.
Being untrained I am able to DO that / preconceived notions because I was never taught the wrong things.
I have attempted to open doors which NORMAL PEOPLE / experts would not even think of trying to open BECAUSE they already KNOW what IS behind the door.
As an investigator one .. must .. try to open every door even though someone may try to tell you what is behind the door / what they were taught.
I find oxidation / rust .
Coincidentally precisely what is causing pretty much every disease according to Linus Pauling AND just like what the article is saying is causing the deficiency of pyruvate kinase.
Pyruvate kinase deficiency is second only to Glucose-6-phosphate dehydrogenase deficiency.
This oxidation is also a model of glucose 6-phosphate dehydrogenase deficiency.
Oxidation excess .. ?
Quartz is notorious for containing iron.
------

Quartz Inhibits Glucose 6-Phosphate Dehydrogenase in Murine Alveolar
Macrophages.
Chem Res Toxicol 2008 Mar 28.
Polimeni M, Gazzano E, Ghiazza M, Fenoglio I, Bosia A, Fubini B,
Ghigo
D

Crystalline silica is well-known to induce oxidative stress as a
consequence of both surface-derived generation of free radicals and
intracellular production of reactive oxygen species upon
phagocytosis;
the mechanism of the latter is still partially unknown.
In this study, we report that in murine alveolar MH-S macrophages, a
24 h incubation with quartz particles (80 microg/cm (2)) inhibits the
glucose 6-phosphate dehydrogenase (G6PD) (1) activity by 70% and the
pentose phosphate pathway by 30%.
Such effects are accompanied by a 50% decrease of intracellular
glutathione, a 35% increase of thiobarbituric acid reactive products
(index of lipoperoxidation), and a 5-fold increase of leakage of
lactate dehydrogenase in the extracellular medium (index of
cytotoxicity).
Quartz inhibits G6PD but not other oxidoreductases, and such
inhibition is fully prevented by glutathione, suggesting that silica
exerts on G6PD an oxidative damage.
Our data provide a new additional mechanism by which silica may
induce
oxidative stress, that is, by inhibiting the pentose phosphate
pathway, one of the main antioxidant metabolic pathways of the cell.

Chemical research in toxicology [Chem Res Toxicol]

This is ANOTHER disease which seems to have iron loading BEFORE the
onset of the disease.
Porphyria.

--------------------


http://www.jci.org/articles/view/110866/files/pdf


Porphyria


A transient decrease in activity of ALA dehydrase
was observed after iron loading, in five separate
experiments, although there was some variability in
the maximal degree of the decrease (50-80%) and
the time after iron treatment at which the nadir
occurred (12-20 h).
The effect of decreased activity of ALA dehydrase
on heme synthesis in vivo is further complicated since
ALA and PBG can leak out of hepatocytes, especially
when hepatic production and accumulation are increased.
This leakage occurs in human acute porphyrias,
in certain experimental porphyrias (3, 5) and in
cultured liver cells (25).


------------------

I know all the disease very well. My apologies.... Andy, could you please help me??!!!???!!

@ironjustice: could you please use simple easy language. If you just said that there is a cure, then I don't believe you. Because there isn't and there won't be.

Quote: Because there isn't and there won't be.

What I am saying is what studies are beginning to show.
In some sickle cell patients they have shown long term transfusion free remission.
In some sickle cell patients they have shown PREdisease iron LOADING.
In some sickle cell patients they have shown long term symptom free remission BY keeping iron levels LOW lower than what was / is considered to BE what one might think to be low ENOUGH.

The most striking of studies I believe is one in which researchers found their mice were 'catching' porphyria and they narrowed it down to the chow the researchers had purchased. They replaced the chow with they made themselves and they found their mice didn't catch porphyria.
Now looking closely at the chows .. one contains meat .. the other it doesn't.
WHETHER it is the HIGH absorption rate of the iron from the meat / chow which was / is CAUSING the porphyria .. ? .. and therefore possibly OTHER .. prediseaseloadingiron .. syndromes.. ?

THAT is all I'm saying .. and as to the possibility of cures ... others HAVE shown what one might consider to be genetic disorders treated successfully as of late ..

I had the same thought when noticing how many responses there are about PKD in dogs. Could this be set off by their diets? Dogs eat far more meat than is natural due to the meat heavy dog foods on the market. It did make me wonder if the amount of iron in their diets is what sets off the PKD caused anemia.

I see. Thank you for sending the clouds away from your story.
As for dogs; there are also many cats. So I always search without those dogs and cats. I think I have somewhere an emailaddress from one of the expert who do research into this. Should I give it a try and include Andy's guess in it?

  [thinking]

PS I am glad you were albe to find those articles. How did you do that? At the moment I try to train my search skills for a subject I call pc trouble. (That's what it caused by me)

Quote: Could this be set off by their diets?

They did a study of working dogs in Europe and found 50% have siderosis.

"haemosiderosis (47% of animals)"

Renal pathology in working dogs in the South African National Defence Force.   
J S Afr Vet Assoc 1999 Dec;70(4):158-60   
Short RP, Lobetti RG, Nesbit JW   
South African Military Health Service Headquarters, Centurion.     
Urine analysis, serum biochemical profile and a cortical wedge biopsy   for
histopathological examination was performed on 42 South African   National
Defence Force (SANDF) dogs from around the country.
The only   significant finding on urine analysis and serum biochemistry was a   
relatively large number (16/42) of dogs with elevated serum inorganic   
phosphate levels.
Histopathology revealed that only 9 of the animals   had normal kidneys
reflected in the wedge biopsy material, with over   50% of them showing signs
of glomerular pathology (primarily   mesangioproliferative glomerulonephritis).
Other conditions detected   histopathologically were haemosiderosis (47% of
animals), focal   nephrosis (2.4%), membranoproliferative glomerulonephritis
(2.4%),   focal interstitial nephritis (4.7%) and acute tubular nephrosis   
(4.7%).
The lesions observed were of limited distribution and extent;   this
histopathological finding may account for the absence of   significant
abnormalities on urine analysis or serum biochemistry   profiles.
It appears from these results that a large percentage of the   SANDF
population would be expected to have mild renal lesions, but   that
these lesions are not severe enough to lead to clinical signs.   
The findings of this study are similar to those of randomly selected   
populations of non-military dogs performed in other areas of the   
world, which also demonstrated an unexpectedly high incidence of   
histopathological renal pathology in dogs considered healthy.
These   lesions may well, however, play a role in later life, and it is   
recommended that military veterinarians maintain an index of suspicion   
for renal disease, particularly glomerular disease.
The aetiology of   the histopathological lesions is unknown.     
PMID: 10855840, UI: 20312548

I'm surprised the iron overload didn't set off alarms. The hearts of the animals should also be checked. Dogs in captivity eat a diet far different from what wild dogs eat. Wild dogs eat more vegetation directly and indirectly, through the stomachs of the small rodents that make up much of their diet. They do not eat commercial beef or chicken as do dogs fed by humans.

There is much to be said for a more natural diet for pets and their owners alike.

This seems to say they now BELIEVE there IS a connection to hemochromatosiis genetically and iron overload in untransfused hemolytic anemia is common.
They say now the same with thalassemia .

http://www.springerlink.com/content/g53709l567112666/

Hemochromatosis and pyruvate kinase deficiency
Report of a case and review of the literature
Annals of Hematology
Volume 62, Number 5 / May, 1991
M. De Braekeleer1   , C. St-Pierre2, A. Vigneault1, H. Simard3 and E. de Medicis2
(1)  Human Genetics, Department of Human Sciences, Université du Quebec a Chicoutimi, Chicoutimi, Quebec
(2)  Département de Biochimie, Faculté de Médecine, Université de Sherbrooke, Sherbrooke, Quebec
(3)  Département d'Hematologie, Hôpital de Chicoutimi, Chicoutimi, Quebec

Received: 10 December 1990  Accepted: 12 February 1991 

Summary  Hemochromatosis has been reported in several patients with chronic hemolytic anemia due to pyruvate kinase deficiency. We describe here a further patient with such an association and review the literature on the subject. We hypothesize that iron overload may occur in patients with pyruvate kinase deficiency who are also carriers of the hereditary hemochromatosis gene.
Key words  Hemochromatosis - Pyruvate kinase deficiency - Hereditary anemia - Genetics

This work was supported in part by a grant from theFonds de la Recherche en Sante de Quebec. C. St-Pierre was supported by a summer research scholarship from theFonds de la Recherche en Santé du Quebec
Publisher Springer Berlin / Heidelberg
ISSN 0939-5555 (Print) 1432-0584 (Online)
Case Report
DOI 10.1007/BF01703147
Pages 188-189
Subject Collection Medicine
SpringerLink Date Tuesday, June 14, 2005

These two studies show how they found by replacing the chow they
didn't develope the porphyria.
They show that vitamin C can prevent BUT **only** when the iron levels
are low .

"Ascorbate suppresses porphyria at low, but not high hepatic iron
levels"

Effect of iron and ascorbate on uroporphyria in ascorbate-requiring
mice as a model for porphyria cutanea tarda.
Gorman N, Zaharia A, Trask HS, Szakacs JG, Jacobs NJ, Jacobs JM,
Balestra D, Sinclair JF, Sinclair PR
Hepatology. 2006 Dec 22; 45(1): 187-194
Excess hepatic iron is known to enhance both porphyria cutanea tarda
(PCT) and experimental uroporphyria.
Since previous studies have suggested a role for ascorbate (AA) in
suppressing uroporphyria in AA-requiring rats (in the absence of
excess
iron), the present study investigated whether AA could suppress
uroporphyria produced by excess hepatic iron.
Hepatic URO accumulation was produced in AA-requiring Gulo(-/-) mice
by treatment with 3,3’,4,4’,5-pentachlorbiphenyl, an inducer of
CYP1A2,
and 5-aminolevulinic acid.
Mice were administered either sufficient AA (1000 ppm) in the
drinking
water to maintain near normal hepatic AA levels or a lower intake
(75 ppm) that resulted in 70 % lower hepatic AA levels.
The higher AA intake suppressed hepatic URO accumulation in the
absence of administered iron, but not when iron dextran (300-500 mg Fe/
kg)
was administered.
This effect of iron was not due to hepatic AA depletion since hepatic
AA
content was not decreased.
The effect of iron to prevent AA suppression of hepatic URO
accumulation was not observed until a high hepatic iron threshold was
exceeded.
At both low and high AA intakes, hepatic malondialdehyde (MDA), an
indicator of oxidative stress, was increased three-fold by high doses
of iron
dextran.
MDA was considerably increased even at low iron dextran doses, but
without any increase in URO accumulation.
The level of hepatic CYP1A2 was unaffected by either AA intake.
Conclusion:
In this mouse model of PCT, AA suppresses hepatic URO accumulation at
low, but not high hepatic iron levels.
These results may have implications for the management of PCT.


(HEPATOLOGY 2007;45:187-194.).
Abstract · PubMed FullText · SFX · GS Clip Export InterDB ·
Terms Related · Graph Tag · Scopus · Cites 10.1002/hep.21474
----------------


Effect of an oral iron chelator or iron-deficient diets on
uroporphyria in a murine model of porphyria cutanea tarda.
Hepatology. 2007 Sep 13;
Gorman N, Zaharia A, Trask HS, Szakacs JG, Jacobs NJ, Jacobs JM,
Balestra D, Sinclair JF, Sinclair PR.
Veterans Affairs Medical Center, White River Junction, VT.


Porphyria cutanea tarda is a liver disease characterized by elevated
hepatic iron and excessive production of uroporphyrin (URO).
Phlebotomy is an effective treatment that probably acts by reducing
hepatic iron.
Here we used Hfe(-/-) mice to compare the effects on hepatic URO
accumulation of two different methods of hepatic iron depletion: iron
chelation using deferiprone (L1) versus iron-deficient diets.
Hfe(-/-) mice in a 129S6/SvEvTac background were fed
5- aminolevulinic acid (ALA), which results in hepatic URO
accumulation,
and increasing doses of L1 in the drinking water.
Hepatic URO accumulation was completely prevented at low L1 doses,
which partially depleted hepatic nonheme iron.
By histological assessment, the decrease in hepatic URO accumulation
was associated with greater depletion of iron from hepatocytes than
from Kupffer cells.
The L1 treatment had no effect on levels of hepatic cytochrome
P4501A2
(CYP1A2). L1 also effectively decreased hepatic URO accumulation in
C57BL/6 Hfe(-/-) mice treated with ALA and a CYP1A2 inducer.
ALA- treated mice maintained on defined iron-deficient diets, rather
than
chow diets, did not develop uroporphyria, even when the animals were
iron-supplemented either directly in the diet or by iron dextran
injection.
Conclusion:
The results suggest that dietary factors other than iron are involved
in the development of uroporphyria and that a modest depletion of
hepatocyte iron by L1 is sufficient to prevent URO accumulation.


(HEPATOLOGY 2007.).
PMID: 17854053
­——