Mevalonate inhibition

Mevalonate inhibition

Mevalonate inhibition is used to define the effects of medicines based on HMG-CoA reductase enzyme inhibitors to control the products of the mevalonate pathway. This term addresses the effects of long-term restriction of mevalonate production in cell membranes by the inhibition of the membrane attached enzyme HMG-CoA reductase. Such inhibitors are also known as the statins. They exert their effect at the very beginning of the mevalonate pathway, the location of this key reductase step, and thereby reduce the de-novo availability of a range of terpenoid and steroid products in cell membrane. The consequences of long-term statin use are classified below according to the depletion of a mevalonate product,[1] e.g. de novo membrane cholesterol.[2] and Co-enzyme Q10 [3][4]

There are also less direct impacts from mevalonate product depletions e.g. those affecting the synthesis of Tau proteins and Rho family of GTPases to consider here. [5]

Contents

Cholesterol depletion in cholesterol-rich lipid rafts

Neuron A (transmitting) to neuron B (receiving)
1. Mitochondrion
2. synaptic vesicle with neurotransmitters
3. Autoreceptor
4. Synapse with neurotransmitter released (serotonin)
5. Postsynaptic receptors activated by neurotransmitter (induction of a postsynaptic potential)
6. Calcium channel
7. Exocytosis of a vesicle
8. Recaptured neurotransmitter
The membranes in the vesicles and synapses are very dependent on additional glial sourced cholesterol[6]

Cholesterol produced and found in the membranes of eukaryotic cells where it is facilitates their form and function. A key example is the is glial cell cholesterol synthesis [6] in our brains vital for memory function and cognition.

Cholesterol also is the substrate for our most important hormones: aldosterone, cortisone, estrogen, progesterone and testosterone as well as the quasi-hormone, vitamin D (calciferol). The body itself produces all the cholesterol it needs and there is no requirement for any dietary cholesterol intake.

Cholesterol's vital role in eukaryote biomembrane structure and function and lipid raft formation, makes it of critical importance in vesicle formation, exocytosis [2], endocytosis, lipid trafficking [7] cell signalling, cell communication and immune defense.

Potential adverse effects of glial cell inhibition of de novo cholesterol synthesis include amnesia, forgetfulness, confusion, disorientation and increased senility. [8]. [9]
An oligodendrocyte runs numerous processes to continuously replace oxidised cholesterol (Oxycholesterol) in the myelin sheathing of up to 40 neurons. Treatments that lower LDL cholesterols such as (APOE), by mevalonate inhibition are known to impair myelin maintenance in oligodendrocytes, leading to Neurodegeneration and dementia. [10][11][12][13]

CoQ10 ( Ubiquinone ) Inhibition

Coenzyme Q10 (CoQ10) also known Ubiquinone is an isoprenoid made from mevalonate units and found primarily in the miochondria. It is depleted by inhibiting the supply of mevalonate. This leads to depleted anti-oxidant activity as well as its important role in Electron transfer phosphorylation in the cellular respiration. Golomb et al.[14] have extensively reviewed and documented the role of statin side effects and very strongly associated them with CoQ10 depletion. A direct causative biochemical link has been in the long term use HMG-CoA reductase and the depletion of the mevalonate required for the biosynthesis of mitochondrial CoQ10.

The correction of this deficiency is discussed in the documentation supporting two US patent applications (Nos.4,933,165 and 4,929,437) for the inclusion of CoQ10 in statin medication both filed in 1990.[3][4]

A citizen's petition for improved guidance on CoQ10 supplementation was undertaken by a journal of the Life Extension Foundation in 2002 and remains unresolved. [15]

Mitochondrial Damage, Permanent Neuropathy, Permanent Myopathy, Neurodegeneration[16] [17]

Dolichol Inhibition

Dolichols are isoprenoids synthesised from mevalonate. They are vital to the process of Glycoprotein formation in the endoplasmic reticulum of cells. In this capacity it is critical to the formation of the Glycoproteins involved in neuropeptides, cell identification, cell messaging and Immunodefence. Reduced bioavailability of dolichols can affect every cellular process in the body. [18] [19] [20]

Potential side effects from altered glycoprotein synthesis include impairment of DNA error correction, dysfunction of almost any cellular process, altered cell identification, altered cell messaging, and altered immunodefense. [16] [21]

Abnormal phosphorylation of Tau protein

Meske V et al. have shown that when normal phosphorylation is interfered with by mevalonate blockade[22], our[who?] cells increase the production of tau protein. Tau is the protein substance of the neurofibrillary tangles common to Alzheimer's disease and other neurodegenerative diseases.

Abnormal tau phosphorylation and deposition in neurons and glial cells is one of the major features in tauopathies. The tauopathies are a group of neurodegenerative disorders characterized by the presence of filamentous deposits, consisting of hyperphosphorylated tau protein, in neurons and glia. Major neurodegenerative tauopathies includes sporadic and hereditary neurodegenerative diseases characterized by filamentous tau deposits in brain and spinal cord.

In prototypical tauopathies, glial and neuronal tau inclusions are the sole or predominant CNS lesions. They include

Section References:[21] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [34]
Alzheimer's and Parkinson Disease 9Th International Conference

Selenoprotein

Only recently have selenoproteins been discovered and the effects of statin use to blockade of the mevalonate pathway on their role in human physiology are just emerging. Deficiency of selenoproteins has been proven to result in various types of Myopathies formerly seen only in Selenium deficiency - ( a Trace element). Additionally some forms of cognitive dysfunction are associated with Selenium deficiency.[35]

Nuclear factor-kappa B NF-κB

The benefit of statin drugs in cardiovascular disease control is in their ability to inhibit this vital transcriptase. The anti-inflammatory and immunomodulation effect of statins might be mediated by such statin inhibition of NF-κB. Repoerted improvement in atherosclerosis may result from such inhibition of the key inflammatory elements: smooth muscle migration. lymphocyte adhesion, macrophage attraction and platelet activation has been associated with inhibition of NF-κB. The immunodefense system is also keyed to NF-κB, possibly explaining associative connections with changing patterns of certain infections and cancers. [36] [37]

References

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  2. ^ a b Salaün C, James DJ & Chamberlain LH. Lipid rafts and the regulation of exocytosis. Traffic (2004) 5: pp. 255–264
  3. ^ a b Brown MS. Coenzyme q.sub.10 with hmg-coa reductase inhibitors. United States Patent (1990) 4,933,165
  4. ^ a b Tobert JA. Coenzyme q.sub.10 with hmg-coa reductase inhibitors. United States Patent (1990) 4,929,437:
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  19. ^ Selected Medical Biochemistry Pages of Michael King PhD, Indiana State University http://themedicalbiochemistrypage.org/glycoproteins.html
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Further reading

External links

  • MeSH NF-kappa+B
  • Collected Videos on Cholesterol and Statins [1]
  • The Wonder of Cholesterol [2]
  • Headingley Cafe Scientifique - 6 July 2009 - Long Term Cholesterol Therapy
    Meeting Report[3] Presentation Slideshow[4]
  • Duane Graveline MD MPH aka Spacedoc [5]
  • Long Term Cholesterol Reducing Therapy a research review

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