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Tuesday, 25 October 2016

Regulation of the Arachidonic Acid (AA) Cascade to treat Inflammatory Disease via aspirin, diet, lithium or better still calcium channels

A rather simpler type of cascade

Today’s post was really to explain why for some people with autism their GI problems disappear when they take the calcium channel blocker verapamil.  Along the way, we will see that a similar mechanism is behind the effectiveness of both low dose aspirin and even high doses of omega 3 oil, when combined with lower dietary intake of omega 6.
There have been several studies regarding omega 3 oil in autism, but overall they are not very conclusive.  A small number of people with autism and ADHD seem to benefit.
Low dose aspirin is now very commonly prescribed to people at risk of a heart attack.
In essence you can say that too much of the omega-6 fatty acid arachidonic acid (AA) is potentially bad for you;  it allows for the body to become inflamed, but more important seems to be the AA cascade which determines whether the AA is converted to prostaglandins or leukotrienes.  Fortunately prostaglandins and leukotrienes tend to act locally rather than circulate throughout your body because they degrade quickly.
You can inhibit this cascade for therapeutic benefit.
In inflammatory bowel disease (IBD), prostaglandins are mucosal protective whereas leukotrienes are pro-inflammatory.
IBD and IBS are common in autism.  In some people with autism it appears that too much arachidonic acid in the gut is being converted to leukotrienes and too little to prostaglandins, the result is inflammation.
The calcium channel blocker, verapamil, has a mucosal-protective effect that occurs as a consequence of reduced mucosal leukotriene synthesis and increased prostaglandin synthesis.
This very likely explains why some people’s chronic GI problems disappear when they take verapamil.
Arachidonic acid (AA) is also present in the brain and it appears to be dysfunctional in many neurological conditions, including autism, bipolar and Alzheimer’s.
We already know that some people with autism or bipolar respond well to verapamil.
We also know that mood stabilizing drugs, like lithium, work by affecting the arachidonic acid cascade in the brain.  
Aspirin enters the brain and inhibits the AA metabolism.  Aspirin is now being trialed as an add-on therapy in bipolar to decrease inflammation suggested to be present in the brain.  Some people do not tolerate aspirin.
In research models a diet high in omega 3 and low in omega 6 oils has been shown to reduce brain AA metabolism.  This would suggest eating fish and olive oil and avoiding junk food.
Modern western diets typically have ratios of omega 6 to omega 3 in excess of 10 to 1, the average ratio of omega 6 to omega 3 in the Western diet is 15:1.  Humans are thought to have evolved with a diet of a 1-to-1 ratio of omega-6 to omega 3 and the optimal ratio is thought to be 4 to 1 or lower.
The source of excessive omega-6 for most people is vegetable oil (corn, sunflower etc.) in junk food.
Most people eat so much omega 6, that buying some expensive omega 3 capsules is going to have minimal impact.  Maybe time to embrace a more Mediterranean diet?
For those trying to influence the AA cascade, you have plenty of choices.  I am happy with verapamil, and plenty of olive oil.

Conclusion
Treating IBS/IBD with a calcium channel blocker looks an interesting avenue for some researcher to develop.  It would be an extremely cheap therapy, so I do not see anyone rushing in that direction.
The many people giving their child expensive omega 3 supplements for autism or ADHD, might want to start by reducing excessive omega 6 consumed in fried food and processed food. 
If you have IBS/IBD yourself and a relative with autism you might well benefit from occasional use of moderate dose verapamil.
You might wonder how come so many things respond to verapamil; it seems that dysfunctional calcium signaling is at the core of many conditions including autism.  You will see in a later post that even autophagy/mitophagy, the cellular garbage collection service, that is dysfunctional in autism, can be treated via calcium channels.

The science
For those interested in the science here follows the more complicated part.

Arachidonic acid (AA) is a polyunsaturated omega-6 fatty acid.  It is abundant in the brain and performs very important roles.  docosahexaenoic acid (DHA) is present in the brain in similar quantities.



AA then undergoes a cascade forming so-called eicosanoids this happens by either producing prostaglandins or leukotrienes.  These eicosanoids have various roles in inflammation, fever, regulation of blood pressure, blood clotting, immune system modulation, control of reproductive processes and tissue growth, and regulation of the sleep/wake cycle.
Eicosanoids, derived from arachidonic acid, are formed when your cells are damaged or are under threat of damage. This stimulus activates enzymes that transform the arachidonic acid into eicosanoids such as prostaglandin, thromboxane and leukotrienes. Eicosanoids cause inflammation. Therefore, the more arachidonic acid that is present, the greater capacity your body has to become inflamed. Eicosanoids tend to act locally rather than circulate throughout your body because they degrade quickly. 
Corticosteroids are anti-inflammatory because they prevent inducible Phospholipase A2 expression, reducing AA release
Non-steroidal anti-inflammatory drugs (NSAIDs), such as aspirin and derivatives of ibuprofen, inhibit Cyclooxygenase activity of PGH2 Synthase. They inhibit formation of prostaglandins involved in fever, pain and inflammation. They inhibit blood clotting by blocking thromboxane formation in blood platelets.

Arachidonic Acid and the Brain
In adults, the disturbed metabolism of ARA contributes to neurological disorders such as Alzheimer's disease and Bipolar disorder. This involves significant alterations in the conversion of arachidonic acid to other bioactive molecules (overexpression or disturbances in the ARA enzyme cascade).


Altered arachidonic acid cascade enzymes in postmortem brain from bipolar disorder patients

Mood stabilizers that are approved for treating bipolar disorder (BD), when given chronically to rats, decrease expression of markers of the brain arachidonic metabolic cascade, and reduce excitotoxicity and neuroinflammation-induced upregulation of these markers. These observations, plus evidence for neuroinflammation and excitotoxicity in BD, suggest that arachidonic acid (AA) cascade markers are upregulated in the BD brain. To test this hypothesis, these markers were measured in postmortem frontal cortex from 10 BD patients and 10 age-matched controls. Mean protein and mRNA levels of AA-selective cytosolic phospholipase A2 (cPLA2) IVA, secretory sPLA2 IIA, cyclooxygenase (COX)-2 and membrane prostaglandin E synthase (mPGES) were significantly elevated in the BD cortex. Levels of COX-1 and cytosolic PGES (cPGES) were significantly reduced relative to controls, whereas Ca2+-independent iPLA2VIA, 5-, 12-, and 15-lipoxygenase, thromboxane synthase and cytochrome p450 epoxygenase protein and mRNA levels were not significantly different. These results confirm that the brain AA cascade is disturbed in BD, and that certain enzymes associated with AA release from membrane phospholipid and with its downstream metabolism are upregulated. As mood stabilizers downregulate many of these brain enzymes in animal models, their clinical efficacy may depend on suppressing a pathologically upregulated cascade in BD. An upregulated cascade should be considered as a target for drug development and for neuroimaging in BD

Lithium and the other mood stabilizers effective in bipolar disorder target the rat brain arachidonic acid cascade.


This Review evaluates the arachidonic acid (AA, 20:4n-6) cascade hypothesis for the actions of lithium and other FDA-approved mood stabilizers in bipolar disorder (BD). The hypothesis is based on evidence in unanesthetized rats that chronically administered lithium, carbamazepine, valproate, or lamotrigine each downregulated brain AA metabolism, and it is consistent with reported upregulated AA cascade markers in post-mortem BD brain. In the rats, each mood stabilizer reduced AA turnover in brain phospholipids, cyclooxygenase-2 expression, and prostaglandin E2 concentration. Lithium and carbamazepine also reduced expression of cytosolic phospholipase A2 (cPLA2) IVA, which releases AA from membrane phospholipids, whereas valproate uncompetitively inhibited in vitro acyl-CoA synthetase-4, which recycles AA into phospholipid. Topiramate and gabapentin, proven ineffective in BD, changed rat brain AA metabolism minimally. On the other hand, the atypical antipsychotics olanzapine and clozapine, which show efficacy in BD, decreased rat brain AA metabolism by reducing plasma AA availability. Each of the four approved mood stabilizers also dampened brain AA signaling during glutamatergic NMDA and dopaminergic D2receptor activation, while lithium enhanced the signal during cholinergic muscarinic receptor activation. In BD patients, such signaling effects might normalize the neurotransmission imbalance proposed to cause disease symptoms. Additionally, the antidepressants fluoxetine and imipramine, which tend to switch BD depression to mania, each increased AA turnover and cPLA2 IVA expression in rat brain, suggesting that brain AA metabolism is higher in BD mania than depression. The AA hypothesis for mood stabilizer action is consistent with reports that low-dose aspirin reduced morbidity in patients taking lithium, and that high n-3 and/or low n-6 polyunsaturated fatty acid diets, which in rats reduce brain AA metabolism, were effective in BD and migraine patients.

3.1. Low Dose Aspirin

In a pharmacoepidemiological study of patients taking lithium for an average duration of 847 days, patients receiving low-dose (30 or 80 mg/day) acetylsalicylic acid (aspirin) were significantly less likely to have a “medication event” (evidence of disease worsening) than patients on lithium alone, independently of use duration.44 High dose aspirin given for short periods of time, nonselective COX inhibitors, selective COX-2 inhibitors, or glucocorticoids were not beneficial. As low dose aspirin does not increase serum lithium,52aspirin’s synergistic effect with lithium likely was centrally mediated, particularly because it can enter the brain and inhibit AA metabolism.53 Clinical trials with aspirin in BD currently are underway.54
A central positive effect of aspirin in BD is consistent with a report that aspirin given to men undergoing coronary angiography reduced depression and anxiety.55 Of relevance, the COX-2 inhibitor celecoxib, although having low brain penetrability,56 showed significant positive effects as adjunctive therapy in BD patients experiencing depressive or mixed episodes, and in depressed patients.57
The clinical data are consistent with the AA cascade hypothesis. Acetylation of COX-2 by aspirin reduces the ability of the enzyme to convert AA to pro-inflammatory PGE2. Additionally, acylated COX-2 can convert AA to anti-inflammatory mediators such as lipoxin A4 and 15-epi-lipoxin A4, as well as DHA to anti-inflammatory 17-(R)-OH-DHA.43a Lithium similarly reduces rat brain COX-2 activity and PGE2concentration (Table 2), while increasing brain concentrations of 17-hydroxy-DHA and other potential DHA-derived anti-inflammatory metabolites.43b

3.2. Changing Dietary PUFA Composition Can Suppress Brain Arachidonic Acid Cascade

Brain concentrations of AA and DHA can be altered reciprocally by changing dietary PUFA concentrations, since brain AA and DHA concentrations depend on dietary intake and hepatic elongation from nutritionally essential LA and α-LNA, respectively.49 Furthermore, decreases in dietary LA and increases in dietary α-LNA have been reported to be neuroprotective in animal models. In rats, reducing dietary α-LNA below a level considered to be PUFA “adequate” reduces brain DHA concentration and uptake, expression of DHA-selective iPLA2 VIA, and of brain derived growth factor (BDNF) critical for neuronal integrity,58 while it increases AA-metabolizing cPLA2 IVA, sPLA2 IIA and COX-2 activities. In contrast, reducing dietary LA below the “adequate” level reduces brain AA concentration, kinetics and enzyme expression, while reciprocally increasing corresponding DHA parameters.59
While data are controversial with regard to dietary intervention in the clinic, a cross-national study did identify a significant relation between greater DHA-containing seafood consumption and lower prevalence rates of BD.60 Also, a review of clinical trials reported that increased dietary n-3 PUFA in combination with standard treatment improved bipolar depression, even taking into account sample bias.61 In the future, one might maximize effects of dietary intervention by combining dietary n-3 PUFA supplementation with reduced dietary n-6 PUFA, which when compared to a standard diet was effective in a phase III trial in patients with migraine.62 Migraine occurs in 30% of BD patients.63

Inhibitors of the Arachidonic Acid Cascade: Interfering with Multiple Pathways


Modulators of the arachidonic acid cascade have been in the focus of research for treatments of inflammation and pain for several decades. Targeting this complex pathway experiences a paradigm change towards the design and development of multi-target inhibitors, exhibiting improved efficacy and less undesired side effects. This minireview summarizes recent developments in the field of designed multi-target ligands of the arachidonic acid cascade. In addition to the well-known dual inhibitors of 5-lipoxygenase and cyclooxygenase-2 such as licofelone, very recent developments are discussed. Especially, multi-target inhibitors interfering with the cytochrome P450 pathway via inhibition of soluble epoxide hydrolase seem to offer a novel opportunity for development of novel anti-inflammatory drugs.




  

Low-dose aspirin(acetylsalicylate) prevents increases in brain PGE2, 15-epi-lipoxinA4 and 8-isoprostane concentrations in 9 month-old HIV-1 transgenic rats, a model for HIV-1 associated neurocognitive disorders

Conclusion

Chronic low-dose ASA reduces AA-metabolite markers of neuroinflammation and oxidative stress in a rat model for HAND.


Aspirin:a review of its neurobiological properties and therapeutic potential for mentalillness

There is compelling evidence to support an aetiological role for inflammation, oxidative and nitrosative stress (O&NS), and mitochondrial dysfunction in the pathophysiology of major neuropsychiatric disorders, including depression, schizophrenia, bipolar disorder, and Alzheimer's disease (AD). These may represent new pathways for therapy. Aspirin is a non-steroidal anti-inflammatory drug that is an irreversible inhibitor of both cyclooxygenase (COX)-1 and COX-2, It stimulates endogenous production of anti-inflammatory regulatory 'braking signals', including lipoxins, which dampen the inflammatory response and reduce levels of inflammatory biomarkers, including C-reactive protein, tumor necrosis factor-α and interleukin (IL)--6, but not negative immunoregulatory cytokines, such as IL-4 and IL-10. Aspirin can reduce oxidative stress and protect against oxidative damage. Early evidence suggests there are beneficial effects of aspirin in preclinical and clinical studies in mood disorders and schizophrenia, and epidemiological data suggests that high-dose aspirin is associated with a reduced risk of AD. Aspirin, one of the oldest agents in medicine, is a potential new therapy for a range of neuropsychiatric disorders, and may provide proof-of-principle support for the role of inflammation and O&NS in the pathophysiology of this diverse group of disorders.


Inflammation, particularly the M1 macrophage response, is accompanied by increased levels of free radicals and O&NS, creating a state in which levels of available antioxidants are reduced. Activation of the immune-inflammatory and O&NS pathways and lowered levels of antioxidants are key phenomena in clinical depression (both unipolar and bipolar), autism, and schizophrenia [2, 3, 4]. Indeed, there is now strong evidence of the involvement of a progressive neuropathologic process in these conditions, with stage-related structural and neurocognitive changes well described for each. Incorporation of these wider factors into traditional monoamine neurotransmitter-system models has facilitated a more comprehensive model of disease, capable of explaining the observed process of neuroprogression. This understanding has facilitated the identification of new therapeutic targets and treatments that have the potential to interrupt the identified neurotoxic cascades [5, 6, 7, 8]. The neuroprotective potential is one of the key promises of agents that target the components of the cascade.

Working mechanisms of aspirin

Aspirin is a non-steroidal anti-inflammatory drug (NSAID), and an irreversible inhibitor of both COX-1 and COX-2. It is more potent in its inhibition of COX-1 than COX-2, and targeting COX-2 alone may be a less viable therapeutic approach in neuropsychiatric disorders such as depression [102]. COX-2 inhibitors may theoretically cause neuroinflammatory reactions, and potentially might augment the Th1 predominance, increase O&NS levels and O&NS-induced damage, decrease antioxidant defenses, and even aggravate neuroprogression [102]. In addition, COX-2 inhibition may interfere with the resolution of inflammation [103]. Thus, COX-2 inhibition decreases the production of prostaglandin E2 (PGE2), which drives the negative immunoregulatory effects on ongoing inflammatory responses. In autoimmune arthritis, for example, PGE2 is part of a negative-feedback mechanism that attenuates the chronic inflammatory response [103]. Therefore, in order to understand the clinical efficacy of aspirin in neuropsychiatric disorders such as depression and schizophrenia, it is more important to consider how its inhibition of COX-1 affects the five aforementioned pathways. This is supported by data suggesting lower response rates to antidepressants in people receiving NSAIDs [104], but is at odds with some recent studies suggesting a benefit for celecoxib, a COX-2 inhibitor, in several disorders including autism and depression [105, 106]. In the following sections, we will discuss the effects of aspirin on these pathways. 
 Arachidonic acid is a type of omega-6 fatty acid that is involved in inflammation. Like other omega-6 fatty acids, arachidonic acid is essential to your health. Omega-6 fatty acids help maintain your brain function and regulate growth. Eating a diet that has a combination of omega-6 and omega-3 fatty acids will lower your risk of developing heart disease. Arachidonic acid in particular helps regulate neuronal activity, the American College of Neuropsychopharmacology explains.

Arachidonic Acid and Eicosanoids

Eicosanoids, derived from arachidonic acid, are formed when your cells are damaged or are under threat of damage. This stimulus activates enzymes that transform the arachidonic acid into eicosanoids such as prostaglandin, thromboxane and leukotrienes. Eicosanoids cause inflammation. Therefore, the more arachidonic acid that is present, the greater capacity your body has to become inflamed. Eicosanoids tend to act locally rather than circulate throughout your body because they degrade quickly.

Other Functions

Arachidonic acid and its metabolites help regulate neurotransmitter release, the American College of Neuropsychopharmacology writes. Arachidonic acid is metabolized so that it may be used to modulate ion channel activities, protein kinases and neurotransmitter uptake systems. Arachidonic acid acts as a substrate that is changed to useful metabolites.
   

Arachidonic Acid and the Gut

In inflammatory bowel disease, prostaglandins are mucosal protective whereas leukotrienes are proinflammatory.
   

Irritable bowel syndrome (IBS) is a highly prevalent functional bowel disorder routinely encountered by healthcare providers. Although not life-threatening, this chronic disorder reduces patients’ quality of life and imposes a significant economic burden to the healthcare system. IBS is no longer considered a diagnosis of exclusion that can only be made after performing a battery of expensive diagnostic tests. Rather, IBS should be confidently diagnosed in the clinic at the time of the first visit using the Rome III criteria and a careful history and physical examination. Treatment options for IBS have increased in number in the past decade and clinicians should not be limited to using only fiber supplements and smooth muscle relaxants. Although all patients with IBS have symptoms of abdominal pain and disordered defecation, treatment needs to be individualized and should focus on the predominant symptom. This paper will review therapeutic options for the treatment of IBS using a tailored approach based on the predominant symptom. Abdominal pain, bloating, constipation and diarrhea are the four main symptoms that can be addressed using a combination of dietary interventions and medications. Treatment options include probiotics, antibiotics, tricyclic antidepressants, selective serotonin reuptake inhibitors and agents that modulate chloride channels and serotonin. Each class of agent will be reviewed using the latest data from the literature

The efficacy of the calcium channel blocker verapamil was prospectively studied in a group of 129 nonconstipated IBS patients meeting Rome II criteria [Quigley et al. 2007]. In this double-blind study, 12-week study, patients were randomized to receive either placebo or the r-enantiomer of verapamil. Doses were adjusted at 4-week intervals, increasing from 20 mg p.o. t.i.d. to 80 mg p.o. t.i.d. as tolerated. The authors reported that the medication was generally well tolerated, without any significant adverse events being reported. Intention-to-treat analysis showed a significant improvement for the r-verapamil group for both primary efficacy variables compared with control, including global symptom scores (p¼0.0057) and abdominal pain/discomfort (p ¼ 0.05). Although not discussed in this preliminary report, verapamil may improve symptoms by modulating smooth muscle function in the gastrointestinal tract. Further studies are forthcoming from this active research group.



Verapamil alters eicosanoid synthesis and accelerates healing during experimental colitis inrats.


In inflammatory bowel disease, prostaglandins are mucosal protective whereas leukotrienes are proinflammatory. Recent evidence suggests that the formation and action of leukotrienes are calcium-dependent, whereas the formation and action of prostaglandins are not. To examine the possibility that, because of differential regulation of arachidonic acid metabolism, calcium channel blockade might alter mucosal eicosanoid synthesis and accelerate healing during inflammatory bowel disease, we treated a 4% acetic acid-induced colitis model with verapamil and/or misoprostol and determined the effects on colonic macroscopic injury, mucosal inflammation as measured by myeloperoxidase activity, in vivo intestinal fluid absorption, and mucosal prostaglandin E2 and leukotriene B4 (LTB4) levels as measured by in vivo rectal dialysis. In colitic animals, verapamil treatment significantly improved colonic fluid absorption and macroscopic ulceration. This mucosal-protective effect of verapamil occurred in the presence of a twofold reduction in mucosal LTB4 synthesis. In noncolitic animals, verapamil alone had no effect on in vivo fluid absorption, macroscopic ulceration, or myeloperoxidase activity but did induce a threefold reduction in LTB4 synthesis in addition to shifting arachidonic acid metabolism towards a sixfold stimulation of prostaglandin E2 synthesis. Our results show that, when administered before the experimental induction of colitis, the calcium channel blocker, verapamil, has a mucosal-protective effect that occurs as a consequence of reduced mucosal leukotriene synthesis and increased prostaglandin synthesis. This differential regulation of arachidonic acid metabolism may play an important role in the development of novel therapeutic agents for inflammatory bowel disease.





Background/aims: In this study two calcium channel blockers (CCB), diltiazem and verapamil, which demonstrate their effects on two different receptor blockage mechanisms, were assessed comparatively in an experimental colitis model regarding the local and systemic effect spectrum. Methods: Eighty male Swiss albino rats were divided into eight groups (n:10 each): Group I) colitis was induced with 1 ml 4% acetic acid without any medication. Group II) Sham group. Group III) Intra-muscular (IM) diltiazem was administered daily for five days before inducing colitis. Group IV) IM verapamil was administered daily for five days before inducing colitis. Group V) Transrectal (TR) diltiazem was administered with enema daily for two days before inducing colitis. Group VI) TR saline was administered four hours before inducing colitis. Group VII) TR diltiazem was administered with enema four hours before inducing colitis. Group VIII) TR verapamil was administered with enema four hours before inducing colitis. All subjects were sacrified 48 hours after the colitis induction. The distal colon segment was assessed macroscopically and microscopically for the grade of damage, and myeloperoxidase (MPO) activity was measured. Results: All the data of the control colitis group (group I), including the microscopic, macroscopic and MPO activity measurements, were significantly higher than in the groups in which verapamil and diltiazem were administered over seven days (3.100±0.7379 to 1.300+0.9487 and 1.600±0.9661) (p


Background Gastrointestinal inflammation significantly affects the electrical excitability of smooth muscle cells. Considerable progress over the last few years have been made to establish the mechanisms by which ion channel function is altered in the setting of gastrointestinal inflammation. Details have begun to emerge on the molecular basis by which ion channel function may be regulated in smooth muscle following inflammation. These include changes in protein and gene expression of the smooth muscle isoform of L-type Ca2+ channels and ATP-sensitive K+ channels. Recent attention has also focused on post-translational modifications as a primary means of altering ion channel function in the absence of changes in protein/gene expression. Protein phosphorylation of serine/theronine or tyrosine residues, cysteine thiol modifications, and tyrosine nitration are potential mechanisms affected by oxidative/nitrosative stress that alter the gating kinetics of ion channels. Collectively, these findings suggest that inflammation results in electrical remodeling of smooth muscle cells in addition to structural remodeling. Purpose The purpose of this review is to synthesize our current understanding regarding molecular mechanisms that result in altered ion channel function during gastrointestinal inflammation and to address potential areas that can lead to targeted new therapies.

CONCLUSIONS AND FUTURE DIRECTIONS Inflammation induced changes in electrical excitability of gastrointestinal smooth muscle cells were first established over twenty years ago by sharp microelectrode studies in whole tissue segments.74 We now know of specific changes in both protein expression and post-translational modifications of ion channels that results in electrical remodeling in pathophysiological settings. Important questions still remain with regard to identifying these changes in human GI smooth muscle cells, and what alterations occur in the acute vs. the chronic phases of inflammation. Studies to delineate the pathways for membrane trafficking and ion channel degradation and the influence of inflammation need to be established. It is important to note that each individual ion channel may be modulated at various sites by different ‘oxidative’ elements. Although oxidative stress has been recognized as a key component in gastrointestinal inflammation and alterations in endogenous anti-oxidants have been reported in inflammatory bowel disease, antioxidant therapy still remains in its infancy.  The focus of this review was to highlight the possible mechanisms involved in altered ion channel activity and the different facets of post-translational modifications. The latter also brings into question the role of various endogenous anti-oxidant mechanisms. For example, de-nitrosylation requires specific thioredoxins, oxidation of cysteine residues may be reduced by ascorbate and glutathione, while S-sulfhydration appears to be more stable. Recent studies have also addressed the potential of a ‘denitrase’ which may allow for recovery of tyrosine nitrated proteins. A combination that takes into account the various antioxidant mechanisms could provide an important therapeutic approach in the treatment of gastrointestinal inflammatory disorders particularly towards restoring cellular excitability



Arachidonic Acid and Asthma

Arachidonic acid metabolites: mediators of inflammation in asthma.



Asthma is increasingly recognized as a mediator-driven inflammatory process in the lungs. The leukotrienes (LTs) and prostaglandins (PGs), two families of proinflammatory mediators arising via arachidonic acid metabolism, have been implicated in the inflammatory cascade that occurs in asthmatic airways. The PG pathway normally maintains a balance in the airways; both PGD2 and thromboxane A2 are bronchoconstrictors, whereas PGE2 and prostacyclin are bronchoprotective. The actions of the LTs, however, appear to be exclusively proinflammatory in nature. The dihydroxy-LT, LTB4, may play an important role in attracting neutrophils and eosinophils into the airways, whereas the sulfidopeptide leukotrienes (LTC4, LTD4, and LTE4) produce effects that are characteristic of asthma, such as potent bronchoconstriction, increased endothelial membrane permeability leading to airway edema, and enhanced secretion of thick, viscous mucus. Given the significant role of the inflammatory process in asthma, newer pharmacologic agents, such as the sulfidopeptide-LT antagonists, zafirlukast, montelukast, and pranlukast and the 5-lipoxygenase (5-LO) inhibitor, zileuton, have been developed with the goal of targeting specific elements of the inflammatory cascade. These drugs appear to represent improvements to the existing therapeutic armamentarium. In addition, the results of clinical trials with these agents have helped to expand our understanding of the pathogenesis of asthma.


Arachidonic Acid metabolites and inflammation generally

Prostaglandins and Inflammation



Prostanoids can promote or restrain acute inflammation. Products of COX-2 in particular may also contribute to resolution of inflammation in certain settings. Presently, we have little information on which products of COX-2 might subserve this role or indeed if the dominant factors reflect rediversion of the arachidonic acid substrate to other metabolic pathways consequent to deletion or inhibition of COX-2. As with cyclopentanone prostanoids, many arachidonate derivatives, including transcellular products, when synthesized and administered as exogenous compounds, can promote resolution in models of inflammation. However, rigorous physico-chemical evidence for the formation of the endogenous species in relevant quantities to subserve this role in vivo is limited. Elucidation of whether and how prostanoids might restrain inflammation and how substrate modification, such as with fish oils, might exploit this understanding is currently a focus of much research from which novel therapeutic strategies are likely to emerge.






Thursday, 20 October 2016

Clinical Trial of Mega-dose Folinic Acid in Autism



The common form of Leucovorin Calcium is for injection, but it exists in 
tablet form. Maybe another opportunity for intra-nasal delivery?


As pointed out by Tyler, Richard Frye has published his trial on the effect of mega-dose folinic acid in children with autism and language impairment.

FRAA (folate receptor-αautoantibody) status was predictive of response to treatment.  This means that people who are FRAA positive are likely to really benefit from folinic acid treatment.

There are different types of folinic acid.  Dr Frye uses Calcium Leucovorin (Calcium Folinate), which is used in chemotherapy.  It is given by intramuscular injection or orally.

Dr Frye uses the oral form.

Folinic acid should be distinguished from folic acid (vitamin B9). However, folinic acid is a vitamer for folic acid, and has the full vitamin activity of this vitamin.

The dose is huge by normal standards of vitamin B9.  It was 2mg/kg per day (maximum 50mg per day) in two equally divided doses with half of the target dose given during the first 2 weeks. 

Biomarkers
Two folate-related biomarkers were investigated. FRAA titers, both blocking and binding, were analyzed. Plasma free reduced-to-oxidized glutathione redox ratio was determined. Folate-related vitamins and minerals were measured. Serum total folate and vitamin B12 were measured 

Of 93 children with ASD, 60% and 44% were positive for blocking and binding FRAAs, respectively.
  




We sought to determine whether high-dose folinic acid improves verbal communication in children with non-syndromic autism spectrum disorder (ASD) and language impairment in a double-blind placebo control setting. Forty-eight children (mean age 7 years 4 months; 82% male) with ASD and language impairment were randomized to receive 12 weeks of high-dose folinic acid (2mgkg−1 per day, maximum 50mg per day; n=23) or placebo (n=25). Children were subtyped by glutathione and folate receptor-αautoantibody (FRAA) status. Improvement in verbal communication, as measured by a ability-appropriate standardized instrument, was significantly greater in participants receiving folinic acid as compared with those receiving placebo, resulting in an effect of 5.7 (1.0,10.4) standardized points with a medium-to-large effect size (Cohen’s d=0.70). FRAA status was predictive of response to treatment. For FRAA-positive participants, improvement in verbal communication was significantly greater in those receiving folinic acid as compared with those receiving placebo, resulting in an effect of 7.3 (1.4,13.2) standardized points with a large effect size (Cohen’s d=0.91), indicating that folinic acid treatment may be more efficacious in children with ASD who are FRAA positive. Improvements in subscales of the Vineland Adaptive Behavior Scale, the Aberrant Behavior Checklist, the Autism Symptom Questionnaire and the Behavioral Assessment System for Children were significantly greater in the folinic acid group as compared with the placebo group. There was no significant difference in adverse effects between treatment groups. Thus, in this small trial of children with non-syndromic ASD and language impairment, treatment with high-dose folinic acid for 12 weeks resulted in improvement in verbal communication as compared with placebo, particularly in those participants who were positive for FRAAs.

Separate analyses were conducted for each biomarker of folate metabolism (Table 2A). In general, improvement in verbal communication was significantly greater in participants on folinic acid as compared with those on placebo for participants with abnormal folate metabolism (i.e., FRAA positive, low glutathione redox ratio). For participants with biomarkers indicating more normal folate metabolism (i.e., FRAA negative, high glutathione redox ratio) improvement in verbal communication was not significantly different between groups.

This study suggests that FRAAs predict response to high-dose folinic acid treatment. This is consistent with the notion that children with ASD and FRAAs may represent a distinct subgroup.61 Other factors such as genetic polymorphisms in folate-related genes or mitochondrial dysfunction may be important in determining treatment response but were not examined in this study. When methylcobalamin was combined with folinic acid, improvement in communication as well as glutathione redox status was found.48 Indeed, future studies will be needed to define factors that predict response to treatment, investigate optimal dosing and help understand whether other compounds could work synergistically with folinic acid.


Conclusion

This study, and previous ones, suggest that > 50% of people tested have what Frye is calling positive Folate Receptor Antibody Status.  This combined with oxidative stress, as measured by low glutathione redox ratio, looks a like a good predictor of who will benefit from Calcium Folinate.

Clearly using tablets, as opposed to the usual injections, means that less of the folinic acid actually reaches the brain.  As was discussed in an earlier post, there are other forms of folate, like Metafolin, that are OTC.

Can Metafolin perform the same function as  Calcium Leucovorin?

It would be useful to know how much Metafolin = 2mg/kg of Calcium Leucovorin.  

The only way to find out would be to ask someone taking Calcium Leucovorin.


Metafolin® is a proprietary ingredient directly usable by the human organism, involved in lowering homocysteine blood levels, and the only form of folate able to cross the blood-brain barrier. In addition, Metafolin® does not mask a vitamin B12-deficiency and presents no risk of an accumulation of unmodified folic acid in the body.”



I suppose readers will now want to measure Folate Receptor Antibody (FRA) status and look for Calcium Leucovorin.  Our regular reader Roger may want to give his insights; perhaps he wants to see if Metafolin can do the job of Calcium Leucovorin?


Any side effects, Roger, after long term use of Calcium Leucovorin?








Thursday, 13 October 2016

Multigenerational Epigenetic Change Stimulating Inflammatory Disease



Multigenerational transmission of nicotine-induced effects. The diagram illustrates the experimental design and findings of Rehan et al. [4]. Pregnant dams (F0 generation) are injected with nicotine or nicotine + rosiglitazone. The lungs and gonads of both male and female offspring (F1 generation) of nicotine-treated dams exhibit epigenetic changes, and the lungs show an asthma-like functional phenotype (blue nicotine-induced changes). These nicotine effects are not seen in the offspring of animals treated with nicotine + rosiglitazone. Offspring of F1 mated pairs (F2 generation) exhibit the same nicotine-induced changes to lung function as their parents, even though they were not exposed to drug.


Today’s post is again filling in some gaps in this blog to date.

A big question in autism is whether the incidence is increasing or not.  According to the now best-selling autism author Silberman, incidence is not increasing at all; it is just that diagnosis is much better than it was half a century ago.  So it is not an “autism epidemic”, rather a “diagnosis epidemic”.

I did not buy Siberman’s book and while I would like to believe he has accurately assessed the facts, in this case he really has not.

Psychiatrists have done none of us any favours by constantly changing the definition of autism and clinicians have never adequately collated data on those who match those criteria.

It does actually matter whether or not incidence of autism is increasing, because this would then stimulate research as to why.  In time this better understanding would lead to therapeutic avenues.

Being neither a professional researcher, nor a best-selling author, my level of evidence can be a little lower.  In earlier posts we saw incidence of ASD (autism, Asperger’s and PDD-NOS) is around one percent of both the child and adult population.  Many adults with Asperger’s and milder dysfunctions were never diagnosed as children, because they did not have speech delay or great cognitive difficulties.

The autism figures are always of low quality, but there is an opinion that underlying them is a real increase in severe autism, as well as the increased diagnosis of milder autism due to lowering of the diagnostic threshold.

The data I would like to see is the incidence of severe autism over the last few decades, but it does not exist.  All we have is anecdotes.

I remember asking my retired doctor mother how many patients had autism in her medical practice of about 10,000, where she saw all the children.  They did not have any and apparently until the Wakefield autism-MMR business nobody even talked about autism.

Hidden away in a group of 10,000 there “should be” about 100 with some degree of autism.  About 30 might have quite severe autism, many with MR/ID and epilepsy. 30 sounds a lot, but it is only one or two births a year.  People with severe autism live half as long as typical people, so you would not see many past middle age. I suppose it was easy to just diagnose mental retardation and then put the child into “care” when the parents could not cope.  

When a friend of mine from graduate school asked our alumni group of 200 how many had a child with autism there were six responses.  None were Asperger’s, all were strictly defined autism (SDA).

Some disease surprisingly does correlate with educational level.  I recently read that IBS/IBD is much more common among more educated people.

So my take is that hidden in all those poor quality statistics is a rise in the incidence of strictly defined autism (SDA).  Just as it is known that there has been a rise in inflammatory disease like asthma.

Asthma and COPD are really well researched and we know at least some of the reason why they have become more common.  I think the same general mechanism is behind the increase in SDA.

By understanding this mechanism you can then try and reverse it.  This is already being done in COPD research and some of the single gene autisms like Pitt Hopkins.

The mechanism is epigenetics, where you can modify when genes turn on, or turn off.  COPD is a severe disease because an environmental factor (normally smoking) has caused the body's oxidative stress response genes to be turned off.  Pitt Hopkins is caused by an insufficient expression of the TCF4 gene.  This was unlikely to have been caused by epigenetic changes, but could potentially be treated by using epigenetics to turn on the TCF4 gene.

Today’s post highlights pretty convincing research that shows how an environmental factor, smoking in this case, can cause heritable epigenetic changes.  It shows how a Grandparent smoking increases asthma incidence in the grandchildren.

Other than sending the message that smoking can affect the health of your future grandchildren, it becomes clear that many other environmental insults could also be heritable.  The accumulation of these insults over generations affects the incidence of certain diseases, particularly those complex ones often caused by multiple hits (cancer, autism etc.).
  
This makes me recall how it is theorized that epilepsy can develop as an acquired channelopathy.  We saw how the threshold for a person’s first seizure is quite high, but after the first seizure the threshold falls.  The proposed mechanism is called an acquired channelopathy.  This means that one of the many ion channels whose dysfunction is known to lead to epilepsy has been permanently disturbed.  The ion channel can now behave aberrantly with little provocation,

Ion channel diseases are classified as ‘acquired’ or ‘genetic’. Genetic ion channel disorders of the brain generally manifest as epilepsy, migraine, paroxysmal dyskinesia or episodic ataxia.

Acquired channelopathies can be caused by antibodies which target specific ion channels or by toxins which block voltage-gated ion channels. Altered transcription of ion channels may contribute to many acquired neurological ion channel disorders.

Mutations in genes which encode subunits of CNS sodium, potassium, calcium channels, GABAA and nicotinic receptors have been reported in association with various epilepsy syndromes.

While genetic (inherited) ion channel disorders may be the cause of most people’s epilepsy, it is suggested that acquired channelopathies are also involved.  Perhaps both are present?



 the “acquired channelopathy” hypothesis suggests that proepileptic channel characteristics develop during epilepsy.

In summary, cell type-specific information on epilepsy-related ion channel modifications can explain and support AED strategies. Precisely those inhibitory ion channels which appear to be effective AED targets in preclinical tests are the ones upregulated in DG GCs during TLE. These data indicate that cell-endogenous ion channel homeostasis mechanisms could be used as “channelacoid” archetypes in the search of antiepileptic strategies. In particular, the enhancement of static shunt via combined K/Cl/cation leak channel support appears to be a promising strategy.


The science, though complex, is still in its infancy.  You do wonder if acquired channelopathy cannot be caused by epigenetic changes to the genes encoding the ion channel.



Nicotine, your genes and those of your heirs

Finally, the subject of today’s post, the research showing the epigenetic effects of nicotine. In place of nicotine you could likely substitute other environment damage such as intense air pollution in cities like Beijing.  Another example below is lead pollution. 

 First the easier to read article:-


"Our results therefore indicate that the increased disease risk associated with smoking is partly caused by epigenetic changes. A better understanding of the molecular mechanism behind diseases and reduced body function might lead to improved drugs and therapies in the future," 


Now the more interesting study that shows how the effect of nicotine is passed down the generations to non-smokers.






Multigenerational transmission of nicotine-induced effects. The diagram illustrates the experimental design and findings of Rehan et al. [4]. Pregnant dams (F0 generation) are injected with nicotine or nicotine + rosiglitazone. The lungs and gonads of both male and female offspring (F1 generation) of nicotine-treated dams exhibit epigenetic changes, and the lungs show an asthma-like functional phenotype (blue nicotine-induced changes). These nicotine effects are not seen in the offspring of animals treated with nicotine + rosiglitazone. Offspring of F1 mated pairs (F2 generation) exhibit the same nicotine-induced changes to lung function as their parents, even though they were not exposed to drug.

A recent preclinical study has shown that not only maternal smoking but also grandmaternal smoking is associated with elevated pediatric asthma risk. Using a well-established rat model of in utero nicotine exposure, Rehan et al. have now demonstrated multigenerational effects of nicotine that could explain this 'grandmother effect'. F1 offspring of nicotine-treated pregnant rats exhibited asthma-like changes to lung function and associated epigenetic changes to DNA and histones in both lungs and gonads. These alterations were blocked by co-administration of the peroxisome proliferator-activated receptor-γ agonist, rosiglitazone, implicating downregulation of this receptor in the nicotine effects. F2 offspring of F1 mated animals exhibited similar changes in lung function to that of their parents, even though they had never been exposed to nicotine. Thus epigenetic mechanisms appear to underlie the multigenerational transmission of a nicotine-induced asthma-like phenotype. These findings emphasize the need for more effective smoking cessation strategies during pregnancy, and cast further doubt on the safety of using nicotine replacement therapy to reduce tobacco use in pregnant women.


More on epigenetic changes related to heart disease.





Finally the effect down the generations of lead, a known neurotoxin.



We report that the DNA methylation profile of a child’s neonatal whole blood can be significantly influenced by his or her mother’s neonatal blood lead levels (BLL). We recruited 35 mother-infant pairs in Detroit and measured the whole blood lead (Pb) levels and DNA methylation levels at over 450,000 loci from current blood and neonatal blood from both the mother and the child. We found that mothers with high neonatal BLL correlate with altered DNA methylation at 564 loci in their children’s neonatal blood. Our results suggest that Pb exposure during pregnancy affects the DNA methylation status of the fetal germ cells, which leads to altered DNA methylation in grandchildren’s neonatal dried blood spots. This is the first demonstration that an environmental exposure in pregnant mothers can have an epigenetic effect on the DNA methylation pattern in the grandchildren.



Conclusion

As regards autism, heritable epigenetic changes could well explain the increase in strictly defined autism (SDA) that cannot be explained away in terms of widening diagnostic criteria and awareness.

With respect to many diseases it is hardly surprising that they are becoming more prevalent if we accumulate the environmental insults experienced by our ancestors, via heritable epigenetic changes.  Where this will lead in future generations?

There are further studies looking at the role of PPAR gamma agonists (the rosiglitazone given to protect the mouse from epigenetic change) and HDAC inhibitors, which together can do very clever things regarding epigenetics.

You may recall the broccoli sprout extract being given by John Hopkins researchers to protect Beijing residents from the effects of severe air pollution.  The sulforaphane produced is an HDAC inhibitor.  

The mouse studies showed how to protect a mouse from epigenetic change occurring, what would be more interesting would be studies looking at reversing that change, once it has already occurred.

The only bad thing in the Mediterranean diet/lifestyle is smoking; just imagine how healthy the Greeks would be without smoking 2,000 cigarettes per adult per year, compared to 1,000 in the US.