Right, back to links from Mary Rogge's paper on the role of impaired mitochondrial fatty acid oxidation in the obese.
She links to Ruderman's mini review, which we will come back to in some detail in future, and there we find this excellent graph:
I rather like this graph, although it could theoretically be reduced to one line of text. The bit I like best about it is that you can play Pin the Donkey Tail on it. We'll play later.
The graph shows that lipid oxidation, as indicated by respiratory quotient, is well below normal in both pre-obese and post-obese people.
But not in the obese.
No, the RQ of an obese person is, from the graph, somewhere around 0.825, ie an obese person actually runs their whole body metabolism slightly more using fat vs carbohydrate than a non obese person, who has their RQ at around 8.5 when on a mixed diet.
It is only the pre-obese or post-obese who run their metabolism on carbohydrate (poorly) and fail to oxidise fat, their RQ panning out up at 0.875.
If we ignore causes of mitochondrial dysfunction for the time being, we can look at these situations logically. I'm loathe to use analogies but they are useful on occasions. Here's one, highly factual and probably quite relevant:
Take a type 1 diabetic with complete failure to produce any pancreatic insulin. Ask them to volunteer to skip their exogenous insulin, become both profoundly hypoinsulinaemic and markedly hyperglycaemic. Then use a tracer to measure their glucose metabolism. Can they use glucose? Of course they can. This was done back in 1978 and the results are quite clear cut. Acute hypoinsulinaemia can be compensated for by acute hyperglycaemia.
Now, the question is whether there is a situation existing at the mitochondrial surface, as relates to fatty acids, which is analogous to that at the cell membrane surface as regards glucose. Glucose uptake is controlled at the cell surface. Fatty acid uptake is (predominantly) controlled at the mitochondrial surface.
Can we increase intracellular free fatty acid derivatives to the point where energy production can be forced back up to a semblance of normality in the abnormal mitochondria of a pre-obese person?
The graph of RQs suggests to me that this can indeed be done.
However it requires an increase in FFA delivery to the tissues well in excess of what a normal person might oxidise. There needs to be enough of an increase in FFA delivery to the tissues to reach the point where FFA derivatives can be "pushed" down an adequate concentration gradient in to mitochondria to restore adequate ATP production.
The cost of this maneuver is in increased FFA intermediary-derived insulin resistance and even greater failure to use glucose.
If you are having even more problems using glucose because you have managed to get your fat oxidation up by increased lipid derivatives within the cytosol, where would you expect your RQ to be compared to someone who has free choice in metabolic substrate utilisation? More fat, less glucose. So the RQ will be.....
Lower of course. Somewhere around 0.825 I would guess, looking at the graph.
You can see why I like this graph...
So we know that the pre-obese and post-obese have problems burning fatty acids in their mitochondria. We know the currently-obese have corrected this defect by increasing fatty acid delivery to their mitochondria at the cost of worsening insulin resistance.
How do we increase fatty acid delivery to the cytosol? Fatty acid delivery is primarily controlled at the adipocyte level. Insulin, acting on normal adipocytes, inhibits lipolysis. Have I ever said that before?
Adipocyte insulin resistance is the direct equivalent of relative hypoinsulinaemia. If we simply stretch our adipocytes to the point where they no longer listen adequately to insulin we can increase FFAs delivery to the blood stream and so increase their delivery to cytosol and get to work pushing them in to whatever mitochondria we have.
In the state of established obesity energy production is, in fact, normalised.
Let's just set this out:
Mitochondrial dysfunction leads to cytosolic fatty acid derivative accumulation.
This leads to chronic hyperinsulinaemia via insulin resistance.
This leads to adipocyte distension.
This leads to adipocyte insulin resistance.
This leads to increased plasma FFA delivery at a given level of insulin.
This leads to increased cytosolic FFA derivatives.
This leads to mitochondrial ATP production being normalised.
The cost is increased insulin resistance. Oh, and the MECHANISM for improved ATP production is OBESITY. Call this a cost if you wish.
BTW: Of course there is a second set of discussions related to adipocyte mitochondrial dysfunction but I'll leave that out to keep it simple here.
Okaaaaaay.
Time to play Pin the Donkey Tail.
Everybody needs a drawing pin (thumb tack?). And a piece of string attached to it to represent the donkey's tail. It is traditional to have a picture of a tail-less donkey taped to a cork board and to try and pin the tail in the correct place, while blindfolded. I'll let everyone off of the blindfold and we can have this nice blue balloon as a substitute for the picture of the tail-less donkey.
It would be very helpful, if you are doing this at home, to write "Adipostat Hypothesis" on the balloon, most easily done before you inflate it. I couldn't be *rsed to do this, as always.
Now pin the tail, using the thumb tack, on to the balloon.
Pop!
Oops. Did you just pop the set point hypothesis of obesity? Clumsy of you, but easily done.
Obesity is a method of normalising ATP production. The concept of an adipose tissue "set point" is an artefact of how much adipocyte distension-induced insulin resistance is needed to normalise tissue ATP production at a given level of mitochondrial dysfunction.
Confession time. I never meant anyone to pop a real balloon. You don't have to actually do it. What I really wanted everyone to do was to pin a hypothetical donkey tail to the graph at the top of the post.
You need to guess what the respiratory quotient is for a person who, for the last seven days, has been eating a diet which included less that 20 grams per day of carbohydrate, around 60 grams of protein and as much butter as they like.
All you have to oxidise outside of your brain is fat. Your RQ will plummet to the lowest value possible short of full starvation. FFA delivery to non neural tissue will rocket. Glucose delivery will be irrelevant and the role of insulin in energy production will be sidelined. Cytosolic FFA derivatives will sky rocket too, to keep you alive using physiological insulin resistance, dontcha-no.
Perhaps you will normalise your ATP production?
Might you normalise your appetite too as you normalise your ATP production? It happens for many who try it...
Peter
I think ATP, AMP and AMPK might be an interesting subject to move on to next.
Wednesday, October 12, 2011
Thursday, October 06, 2011
Adipocyte insulin resistance
It was in late 2007 that I first blogged about the concept of adipocyte insulin resistance and of course it is back in my mind while I work through ideas on metabolic flexibility and insulin resistance in general. It is a very simple concept that the fatter adipocytes become (using whatever delivery system you like, ASP if you must) the harder it becomes to push more fat in to them. And certainly the harder it becomes to keep it there once it is installed. So this idea of adipocyte insulin resistance limiting fat gain is very intuitive and probably correct. How big adipocytes can get is probably determined by how strong your pancreas is combined with how responsive your adipocytes are to insulin as they swell. A pancreas of steel and relatively insulin-resistance resistant (no typo) adipocytes combine to get you to the over 200kg mark. This came up in comments on the last post. Is this true?
A rather nice paper was published back in the 1960s showing this very clearly. I have seen it cited as purporting to show that elevated fasting insulin is a consequence of obesity, rather than a cause. This is a fascinating and rather counter intuitive concept, so you just have to go have a look see at the paper. Luckily it's free access.
It does show, very convincingly, that adipocyte size correlates with adipocyte insulin resistance on the adipocyte cellular level. I rather like that.
It also demonstrates quite clearly that forced, brutal adipocyte size reduction by a couple of months on a 600kcal/d diet improves adipocyte insulin sensitivity as adipocyte size shrinks.
There are two core concepts which need to be taken away from this paper.
The first is that as adipocytes swell they become progressively less able to respond to insulin. This obviously translates in to insulin resistance of adipocytes ultimately limiting fat gain within the limits of the pancreas to secrete or hypersecrete insulin. That is if you accept that insulin is in any way involved in fat storage.
Now. What does this mean for the carbohydrate hypothesis of fat gain?
It is the RESISTANCE of adipocytes to insulin which limits fat gain.
And the corollary is??? Sensitivity to insulin drives fat gain. You can't have one conclusion without the other.
Anyone telling you that adipocyte insulin resistance limits fat gain and yet insulin per se has nothing to do with fat gain... Well, you decide. I have.
Although the group measured many, many things the only information we get about fasting insulin levels and post challenge insulin levels are these five paired graphs:
There is nothing in the text or tables giving any numeric data about insulin levels in obese individuals and no details at all from the normal groups. I don't mind this too much as the study was really aimed at adipocyte size and adipocyte glucose metabolism in response to exogenous insulin. This was the main drive of the paper. Note that they didn't look at adipocyte beta oxidation, no one had any idea this might be compromised back in the 1960s, so we get no idea about the ability of adipocytes to carry out this essential function.
Look, fasting insulin in five obese people is not generally elevated, it's reported as being only slightly elevated in two out of the five obese patients. This obviously implies that elevated fasting insulin does not predict weight gain. There we go. Time to pack up and go home.
Ah yes, but which fasting insulin are we looking at? Remember that group of starved obese folk we chatted about previously who had three different fasting insulin levels? One level on their normal (obesogenic) diet, one on a calorie and carbohydrate limited diet and another on the full starvation non-diet (ie complete carbohydrate restriction): 45 or 38 or 15-20 microIU/ml.
In obese people (but not in people who have normal metabolic flexibility) you can simply dial fasting insulin by carbohydrate intake. The question we cannot answer from Hirsch's study is what the fasting (and the 24h AUC) insulin values were for the five obese participants while they were free living on their normal obesogenic (high carbohydrate, you can bet) diet and slowly gaining weight? Remember we only need an average of 5g/d adipose tissue accumulation for long term obesity.
We are given an insulin value during phase I on a weight stability diet with a carbohydrate intake fixed at 45% of not-quite-enough-for-comfort calories. This is not what a given individual would normally choose to eat. In real life these people would not be on a weight stable diet. They certainly would not have been limiting their carbohydrate to 45% of calories. So we have no idea what their fasting insulin level would have been before stabilisation on phase I, but is certainly going to have been higher than the graphs show.
After massive weight loss during phase II of the study (on 600kcal/d for several months, probably only bearable because carbohydrate was limited to around 50-55g/d and the doors were locked [jk!]) we go in to phase III and get our second set of curves. Here we are now maintaining weight stability at a markedly reduced body weight with a smaller portion size of a still 45% carbohydrate diet, so total carbohydrate intake will be a bit lower. Hence the slightly reduced fasting insulin... But of course none of this represents the life which led to the enrolment in the study.
Subjects will be hungry.
While ever they stay hungry and limit carbohydrate to 45% of their never-quite-enough calorie intake, their insulin levels will stay low and they will, hungrily, stay slim.
Four of the five patients managed this for quite some time. Kudos to them and their willpower. You have to wonder about the fifth patient. Lost to follow up? Not lost to follow up but fatter than pre study? Just got fed up with people sticking needles in their butt?
How effective for long term weight control is chronic caloric restriction? Answers on a postage stamp to...
Are these people fixed? Their adipocytes certainly have scope to respond better to insulin and will inhibit lipolysis more effectively than during obesity. This limits FFA leakage due to insulin resistance which decreases FFA delivery to muscles and so allows muscles to take up glucose better, so both glucose and insulin curves improve. But are they really, really fixed? Will they will simply regain their lost weight, unless they enjoy being hungry all the time? Especially if they increase their total carbohydrate intake? And why are they hungry? Another post in this series there.
Addendum: Running through the methods section of Petersen's paper it is actually worth noting that fasting insulin and simple derivatives of fasting insulin plus glucose, such as the HOMA score, are rather blunt instruments for picking up insulin resistance. The more complex insulin sensitivity index is better but even this failed to pick out two out of twelve apparently insulin sensitive participants who turned out to be insulin resistant on the hyperinsulinaemic clamp, the current gold standard for picking out insulin resistant subjects. So, while insulin resistance is core, simple fasting insulin has to be accepted as a blunt instrument. Clamps, unfortunately, are not simple to perform. End addendum.
Of course you cannot dial fasting insulin by carbohydrate intake in normal individuals. So all you have to do is include enough normal people in your longditudinal studies and there will be no significant correlation between fasting insulin and subsequent weight gain. What would you expect?
Anyhoo, back to adipocyte insulin resistance. Stretching adipocytes appears to have effects on their sensitivity to insulin. As adipocytes stretch this translates in to progressive pathology as the adipocytes are running out of their ability to function normally. As they get fatter they leak more FFAs at a given level of insulin. This is important. Very important.
Before we go on to the next post: Is there any other form of adipocyte insulin resistance, other than that due to fat distension?
I rather like physiological insulin resistance. It keeps me alive. Simple carbohydrate restriction or a couple of days of frank starvation produces whole body insulin resistance to spare glucose for brain use. You know what I mean. Take a young fit healthy human and starve him for three days and he will immediately become intensely insulin resistant on a whole body basis. If not he would become intensely dead. Are adipocytes part of this physiological insulin resistance response, in the same way as muscle cells are?
We get a partial answer to this when Hirsch cites Tucker's study and suggests that the reason she found no difference between the adipocytes of obese and slim rats was because both were maximally insulin resistant after a 20 hour fast, even those from skinny rats...
"However, these studies were performed upon tissue from animals fasted for 20 hr, a manipulation known to decrease the insulin response of adipose tissue in vitro."
Ad hoc number 3523, but highly plausible. Every body knows this... Physiological insulin resistance mimics pathological insulin resistance. The mechanism through FFAs is likely to be the same.
This would again be logical as you do not want rats in starvation hanging on to their adipocyte energy stores or to be allowing precious glucose in to adipocytes (however little glucose adipocytes use) and so allowing it to be "wasted" when needed by the brain.
Is there a third factor affecting adipocyte insulin sensitivity?
Well, of course adipocytes have mitochondria. Are they breakable? Probably.
If you break them I would assume that they behave much like those in muscle tissue and they do the best they can with pyruvate while leaving the FFA derivatives in the cytosol, ie adipocytes should become insulin resistant if they have broken mitochondria. But this insulin resistance is not stretch related and it's not physiological. It's a mitochondrial break and could happen at any stage of distension of adipocytes. So mitochondrial failure should lead to adipocytes leaking FFAs when glucose and insulin are elevated. Possibly at minimal distension size, ie while you are still slim.
This would worsen whatever state of insulin resistance the muscles were in from their own mitochondrial problems. If the pancreas is not up to overcoming the supplementary FFA-induced insulin resistance (due to its own mitochondrial problems as suggested by Petersen et al) then hyperglycaemia will result and you get that label of T2DM... Possibly while still slim.
The plateau in your weight here might be mistakenly attributed to the satiating effects of insulin on your brain finally kicking in, somewhat belatedly, after 50 years or so of hunger.
If you have an unbroken pancreas of steel you can still argue with the broken adipocyte mitochondria and you can still get even fatter. Ditto if you have T2DM due to insulin resistance and some joker gives you a bottle of injectable insulin plus some syringes. Especially if they also tell you to eat a ton of bagels and cover the hyperglycaemia with a ton of exogenous insulin. And chide you for overeating.
Peter
Summary: Adipocytes become fatter under the influence of insulin. Resistance to insulin by adipocytes limits fat storage and hence eventually limits weight gain. It also elevates FFA supply. Important.
A rather nice paper was published back in the 1960s showing this very clearly. I have seen it cited as purporting to show that elevated fasting insulin is a consequence of obesity, rather than a cause. This is a fascinating and rather counter intuitive concept, so you just have to go have a look see at the paper. Luckily it's free access.
It does show, very convincingly, that adipocyte size correlates with adipocyte insulin resistance on the adipocyte cellular level. I rather like that.
It also demonstrates quite clearly that forced, brutal adipocyte size reduction by a couple of months on a 600kcal/d diet improves adipocyte insulin sensitivity as adipocyte size shrinks.
There are two core concepts which need to be taken away from this paper.
The first is that as adipocytes swell they become progressively less able to respond to insulin. This obviously translates in to insulin resistance of adipocytes ultimately limiting fat gain within the limits of the pancreas to secrete or hypersecrete insulin. That is if you accept that insulin is in any way involved in fat storage.
Now. What does this mean for the carbohydrate hypothesis of fat gain?
It is the RESISTANCE of adipocytes to insulin which limits fat gain.
And the corollary is??? Sensitivity to insulin drives fat gain. You can't have one conclusion without the other.
Anyone telling you that adipocyte insulin resistance limits fat gain and yet insulin per se has nothing to do with fat gain... Well, you decide. I have.
Although the group measured many, many things the only information we get about fasting insulin levels and post challenge insulin levels are these five paired graphs:
There is nothing in the text or tables giving any numeric data about insulin levels in obese individuals and no details at all from the normal groups. I don't mind this too much as the study was really aimed at adipocyte size and adipocyte glucose metabolism in response to exogenous insulin. This was the main drive of the paper. Note that they didn't look at adipocyte beta oxidation, no one had any idea this might be compromised back in the 1960s, so we get no idea about the ability of adipocytes to carry out this essential function.
Look, fasting insulin in five obese people is not generally elevated, it's reported as being only slightly elevated in two out of the five obese patients. This obviously implies that elevated fasting insulin does not predict weight gain. There we go. Time to pack up and go home.
Ah yes, but which fasting insulin are we looking at? Remember that group of starved obese folk we chatted about previously who had three different fasting insulin levels? One level on their normal (obesogenic) diet, one on a calorie and carbohydrate limited diet and another on the full starvation non-diet (ie complete carbohydrate restriction): 45 or 38 or 15-20 microIU/ml.
In obese people (but not in people who have normal metabolic flexibility) you can simply dial fasting insulin by carbohydrate intake. The question we cannot answer from Hirsch's study is what the fasting (and the 24h AUC) insulin values were for the five obese participants while they were free living on their normal obesogenic (high carbohydrate, you can bet) diet and slowly gaining weight? Remember we only need an average of 5g/d adipose tissue accumulation for long term obesity.
We are given an insulin value during phase I on a weight stability diet with a carbohydrate intake fixed at 45% of not-quite-enough-for-comfort calories. This is not what a given individual would normally choose to eat. In real life these people would not be on a weight stable diet. They certainly would not have been limiting their carbohydrate to 45% of calories. So we have no idea what their fasting insulin level would have been before stabilisation on phase I, but is certainly going to have been higher than the graphs show.
After massive weight loss during phase II of the study (on 600kcal/d for several months, probably only bearable because carbohydrate was limited to around 50-55g/d and the doors were locked [jk!]) we go in to phase III and get our second set of curves. Here we are now maintaining weight stability at a markedly reduced body weight with a smaller portion size of a still 45% carbohydrate diet, so total carbohydrate intake will be a bit lower. Hence the slightly reduced fasting insulin... But of course none of this represents the life which led to the enrolment in the study.
Subjects will be hungry.
While ever they stay hungry and limit carbohydrate to 45% of their never-quite-enough calorie intake, their insulin levels will stay low and they will, hungrily, stay slim.
Four of the five patients managed this for quite some time. Kudos to them and their willpower. You have to wonder about the fifth patient. Lost to follow up? Not lost to follow up but fatter than pre study? Just got fed up with people sticking needles in their butt?
How effective for long term weight control is chronic caloric restriction? Answers on a postage stamp to...
Are these people fixed? Their adipocytes certainly have scope to respond better to insulin and will inhibit lipolysis more effectively than during obesity. This limits FFA leakage due to insulin resistance which decreases FFA delivery to muscles and so allows muscles to take up glucose better, so both glucose and insulin curves improve. But are they really, really fixed? Will they will simply regain their lost weight, unless they enjoy being hungry all the time? Especially if they increase their total carbohydrate intake? And why are they hungry? Another post in this series there.
Addendum: Running through the methods section of Petersen's paper it is actually worth noting that fasting insulin and simple derivatives of fasting insulin plus glucose, such as the HOMA score, are rather blunt instruments for picking up insulin resistance. The more complex insulin sensitivity index is better but even this failed to pick out two out of twelve apparently insulin sensitive participants who turned out to be insulin resistant on the hyperinsulinaemic clamp, the current gold standard for picking out insulin resistant subjects. So, while insulin resistance is core, simple fasting insulin has to be accepted as a blunt instrument. Clamps, unfortunately, are not simple to perform. End addendum.
Of course you cannot dial fasting insulin by carbohydrate intake in normal individuals. So all you have to do is include enough normal people in your longditudinal studies and there will be no significant correlation between fasting insulin and subsequent weight gain. What would you expect?
Anyhoo, back to adipocyte insulin resistance. Stretching adipocytes appears to have effects on their sensitivity to insulin. As adipocytes stretch this translates in to progressive pathology as the adipocytes are running out of their ability to function normally. As they get fatter they leak more FFAs at a given level of insulin. This is important. Very important.
Before we go on to the next post: Is there any other form of adipocyte insulin resistance, other than that due to fat distension?
I rather like physiological insulin resistance. It keeps me alive. Simple carbohydrate restriction or a couple of days of frank starvation produces whole body insulin resistance to spare glucose for brain use. You know what I mean. Take a young fit healthy human and starve him for three days and he will immediately become intensely insulin resistant on a whole body basis. If not he would become intensely dead. Are adipocytes part of this physiological insulin resistance response, in the same way as muscle cells are?
We get a partial answer to this when Hirsch cites Tucker's study and suggests that the reason she found no difference between the adipocytes of obese and slim rats was because both were maximally insulin resistant after a 20 hour fast, even those from skinny rats...
"However, these studies were performed upon tissue from animals fasted for 20 hr, a manipulation known to decrease the insulin response of adipose tissue in vitro."
Ad hoc number 3523, but highly plausible. Every body knows this... Physiological insulin resistance mimics pathological insulin resistance. The mechanism through FFAs is likely to be the same.
This would again be logical as you do not want rats in starvation hanging on to their adipocyte energy stores or to be allowing precious glucose in to adipocytes (however little glucose adipocytes use) and so allowing it to be "wasted" when needed by the brain.
Is there a third factor affecting adipocyte insulin sensitivity?
Well, of course adipocytes have mitochondria. Are they breakable? Probably.
If you break them I would assume that they behave much like those in muscle tissue and they do the best they can with pyruvate while leaving the FFA derivatives in the cytosol, ie adipocytes should become insulin resistant if they have broken mitochondria. But this insulin resistance is not stretch related and it's not physiological. It's a mitochondrial break and could happen at any stage of distension of adipocytes. So mitochondrial failure should lead to adipocytes leaking FFAs when glucose and insulin are elevated. Possibly at minimal distension size, ie while you are still slim.
This would worsen whatever state of insulin resistance the muscles were in from their own mitochondrial problems. If the pancreas is not up to overcoming the supplementary FFA-induced insulin resistance (due to its own mitochondrial problems as suggested by Petersen et al) then hyperglycaemia will result and you get that label of T2DM... Possibly while still slim.
The plateau in your weight here might be mistakenly attributed to the satiating effects of insulin on your brain finally kicking in, somewhat belatedly, after 50 years or so of hunger.
If you have an unbroken pancreas of steel you can still argue with the broken adipocyte mitochondria and you can still get even fatter. Ditto if you have T2DM due to insulin resistance and some joker gives you a bottle of injectable insulin plus some syringes. Especially if they also tell you to eat a ton of bagels and cover the hyperglycaemia with a ton of exogenous insulin. And chide you for overeating.
Peter
Summary: Adipocytes become fatter under the influence of insulin. Resistance to insulin by adipocytes limits fat storage and hence eventually limits weight gain. It also elevates FFA supply. Important.
Tuesday, October 04, 2011
Denmark purchased using Flora profits?
Ali prompted me to put up this link and I see Barry Groves has something up about it too.
I think it was Iain Banks who wrote about corporate interests or massive personal wealth buying up a small country in the Himalayas, can't remember which novel it was. Fiction anyway.
Unilever appears to have bought Denmark. Where next for corporate take over? Hint, probably the UK, we're dumb enough. Probably not Hungary. At least the worst aspects of the Hungarian tax can be corrected with the shake of a salt cellar.
Peter
I think it was Iain Banks who wrote about corporate interests or massive personal wealth buying up a small country in the Himalayas, can't remember which novel it was. Fiction anyway.
Unilever appears to have bought Denmark. Where next for corporate take over? Hint, probably the UK, we're dumb enough. Probably not Hungary. At least the worst aspects of the Hungarian tax can be corrected with the shake of a salt cellar.
Peter
Saturday, October 01, 2011
HOW MANY bananas a day?
Our daughter eats everything. Her ultimate favourite food so far is a purée of pig heart casseroled in red wine. We tried her on a banana, head to head with 90% cocoa chocolate. My wife filmed the encounter.
The vocals at 19 seconds from the start sum it up.
Help was needed with the chocolate as it glues itself down to the tray, especially when well sucked!
Peter
The vocals at 19 seconds from the start sum it up.
Help was needed with the chocolate as it glues itself down to the tray, especially when well sucked!
Peter