Just a brief respite from mitochondria:
Adipotide is a drug which targets the blood vessels supplying adipose tissue. It causes impressive fat loss by killing fat cells. Anon posted these two links on the last post.
There are other processes which can produce adipocyte destruction. We've discussed both acquired and congenital lipodystrophes in the past. They produce whole body fat loss with progressively deteriorating glucose tolerance because fatty acids have no adipocytes to enter, so end up accumulating in all tissues, producing pathological insulin resistance and diabetes. This is basic physiology and exactly what you would expect.
Adipotide is different. It produces fat loss with improving metabolic conditions and decreased hunger. How come a dead adipocyte is good from Adipotide and bad from auto immune attack?
Alex emailed me the full text. Here is the snippet from the email conversation which was my initial take on what might be happening:
"How does the drug get any improvement? You'd need to see the data and how they generated it but if the drug preferentially targets abdominal fat there would be an improvement in systemic insulin resistance until enough total [whole body] fat cells were lost for the overall for deterioration in insulin sensitivity due to muscle lipid accumulation to precipitate diabetes.
Of course during lipolysis you would have FFA release acting like an obese fat cell becoming insulin resistant and sending FFAs systemically to most non CNS mitochondria... Reduced need for food and increased ATP for activity from the metabolic flexibility perspective..."
Look here: Surgical removal of visceral fat improves peripheral insulin sensitivity (there's a lot I could write about this paper but no time). This paper looks OK, other papers by this group are very dubious.
Visceral fat seems quite important, here's an early brief review.
And here is the only quote we need from the Adipotide paper (thank you Alex for the full text):
"MRI and DEXA imaging confirmed that weight loss in the rhesus monkeys occurred primarily because of visceral fat loss."
Now, that's all hunky dory. What is the question we need to ask? Actually, there are a few:
Why is visceral fat Bad Fat? Why do we make it? If we get rid of the Bad Fat, will health be Good for ever? Did we evolve Bad Fat to kill ourselves? Is there a survival benefit from Bad Fat if we continue to drink >30% of our calories from fructose based drinks? Would having our omentum removed do good or bad things long term if we continue to mainline fructose? Would we need to get rid of our Bad Fat if we poured the Fanta down the urinal rather than down our throats?
I rather like Bad Fat. It opens all sorts of avenues of thought. There's so much about it that fits together but no more time to blog at the moment.
Peter
Monday, November 21, 2011
Thursday, November 10, 2011
LIRKO mice (3) The MCQ
**************EDIT - This is serious**************
It has been pointed out that this post is a deliberate intention to mislead. I would like to deny this categorically. The allegation is based around my personal error relating to the renal glycosuria threshold of rats. I have never treated a rat for diabetes. Apparently they do not become glycosuric until blood glucose exceeds around 400mg/dl, somewhat above the glycaemic level of LIRKO mice and waaaay above the cat, dog or human threshold.
They are still functionally diabetic, despite the lack of glycosuria, in terms of hyperglycaemia. But it appears that YOU CANNOT MAKE JAM from their urine.
I would really like to say I hope Dr Guyenet did not waste too much time trying to get his rather watery jam to set. But I just can't. I guess he spent a lot of hours.
Mea culpa.
Sorry to anyone other than Dr G who tried this. Better buy your jam ready made.
******************END EDIT******************
I see the LIRKO mouse has resurfaced as a destructor of the role of insulin in obesity yet again. I've posted on the LIRKO mouse in the past so this little quizz should be quite straight forward. I skipped the questions about leptin because I felt like it.
WARNING some of the questions may have more than one correct answer.
Q1. What is the blood glucose of a LIRKO mouse after a mouthfull of chow?
a. 400mg/dl
b. 400mg/dl
c. 400mg/dl
d. WTF, no one told me LIRKO mice are intensely diabetic.
Q2. What is the urine glucose concentration of a LIRKO mouse?
a. Some
b. Quite a lot
c. More than quite a lot
d. Obesity researchers boil it down to make jam.
Q3. The liver of a LIRKO mouse has no access to glucose. Where does it source it's energy?
a. Not from glucose
b. Definitely not from glucose
c. Absolutely, definitely not from glucose
d. Where's the fat?
Q4. How much fat is there in mouse diet F9?
a. Not a lot.
b. Not a lot
e. Not a lot
d. 10%, just about enough to run the liver on, rather badly, giving early onset cirrhosis and death.
Q5. How much de novo lipogenesis (DNL) from glucose is done in the liver of a LIRKO mouse?
a. None
b. Zero
c. Zilch
d. LIRKO mouse liver can't take up glucose for anything because it has no insulin receptors. Ha ha, gotcha, this is a trick question.
Q6. If the dietary fat is used to run the liver and there is no DNL, where does the fat in adipose tissue fat come from?
a. Thin air.
b. Spontaneous generation
c. Beamed in from The Enterprise
d. A small nuclear reactor
e. It doesn't, you can't put in what you haven't got. OK, there is a smidge of DNL in adipocytes.
Q7. If a LIRKO mouse at the gym is losing more calories down the urinals (where glucose is collected for making jam) than it burns on the treadmill, why doesn't it eat more?
a. Blood glucose is 400mg/dl
b. Blood insulin is 80ng/ml
c. Both.
d. Yeugh, is that really how they make jam?
Q8. The LIRKO mouse is hyperinsulinaemic. By how much does this lower plasma free fatty acids?
a. By 40%
b. By 40%
c. By 40%
d. By only 40% because adipocytes, like the rest of the mouse, are intensely insulin resistant.
e. WTF, no one told me they had depressed FFAs.
Q9. How would the LIRKO mouse cope with a saturated fat based, intensely ketogenic diet?
a. Well
b. Really well
c. Really, really well
d. Don't ask, don't even think about it.
Q10. Obesity researchers trot out the LIRKO mouse because:
a. They want to share
b. They want to share
c. They want to share
d. Shut up and eat your carbohydrate. You need insulin to get slim. Mmmm LIRKO jam...
Peter
It has been pointed out that this post is a deliberate intention to mislead. I would like to deny this categorically. The allegation is based around my personal error relating to the renal glycosuria threshold of rats. I have never treated a rat for diabetes. Apparently they do not become glycosuric until blood glucose exceeds around 400mg/dl, somewhat above the glycaemic level of LIRKO mice and waaaay above the cat, dog or human threshold.
They are still functionally diabetic, despite the lack of glycosuria, in terms of hyperglycaemia. But it appears that YOU CANNOT MAKE JAM from their urine.
I would really like to say I hope Dr Guyenet did not waste too much time trying to get his rather watery jam to set. But I just can't. I guess he spent a lot of hours.
Mea culpa.
Sorry to anyone other than Dr G who tried this. Better buy your jam ready made.
******************END EDIT******************
I see the LIRKO mouse has resurfaced as a destructor of the role of insulin in obesity yet again. I've posted on the LIRKO mouse in the past so this little quizz should be quite straight forward. I skipped the questions about leptin because I felt like it.
WARNING some of the questions may have more than one correct answer.
Q1. What is the blood glucose of a LIRKO mouse after a mouthfull of chow?
a. 400mg/dl
b. 400mg/dl
c. 400mg/dl
d. WTF, no one told me LIRKO mice are intensely diabetic.
Q2. What is the urine glucose concentration of a LIRKO mouse?
a. Some
b. Quite a lot
c. More than quite a lot
d. Obesity researchers boil it down to make jam.
Q3. The liver of a LIRKO mouse has no access to glucose. Where does it source it's energy?
a. Not from glucose
b. Definitely not from glucose
c. Absolutely, definitely not from glucose
d. Where's the fat?
Q4. How much fat is there in mouse diet F9?
a. Not a lot.
b. Not a lot
e. Not a lot
d. 10%, just about enough to run the liver on, rather badly, giving early onset cirrhosis and death.
Q5. How much de novo lipogenesis (DNL) from glucose is done in the liver of a LIRKO mouse?
a. None
b. Zero
c. Zilch
d. LIRKO mouse liver can't take up glucose for anything because it has no insulin receptors. Ha ha, gotcha, this is a trick question.
Q6. If the dietary fat is used to run the liver and there is no DNL, where does the fat in adipose tissue fat come from?
a. Thin air.
b. Spontaneous generation
c. Beamed in from The Enterprise
d. A small nuclear reactor
e. It doesn't, you can't put in what you haven't got. OK, there is a smidge of DNL in adipocytes.
Q7. If a LIRKO mouse at the gym is losing more calories down the urinals (where glucose is collected for making jam) than it burns on the treadmill, why doesn't it eat more?
a. Blood glucose is 400mg/dl
b. Blood insulin is 80ng/ml
c. Both.
d. Yeugh, is that really how they make jam?
Q8. The LIRKO mouse is hyperinsulinaemic. By how much does this lower plasma free fatty acids?
a. By 40%
b. By 40%
c. By 40%
d. By only 40% because adipocytes, like the rest of the mouse, are intensely insulin resistant.
e. WTF, no one told me they had depressed FFAs.
Q9. How would the LIRKO mouse cope with a saturated fat based, intensely ketogenic diet?
a. Well
b. Really well
c. Really, really well
d. Don't ask, don't even think about it.
Q10. Obesity researchers trot out the LIRKO mouse because:
a. They want to share
b. They want to share
c. They want to share
d. Shut up and eat your carbohydrate. You need insulin to get slim. Mmmm LIRKO jam...
Peter
Friday, November 04, 2011
Metabolic flexibility and the identical twins
This post is highly speculative. It doesn't have any answers. Here is a nice quote to begin with:
"If you want to retain your sanity, don't try to read a textbook on mitochondrial diseases"
This is from Nick Lane on page 281 of Power, Sex, Suicide. I was going to copy out the preceding paragraph but I guess everyone has their own copy of PSS. If not, you know what to do.
Now think about your sanity if you are dealing with a problem like obesity and you don't accept it's mitochondrial... Also think about the likelihood of successful intervention.
So I'm putting this up as a one-liner-which-grew because Liz dropped this paper me a few days ago and I got chance to open it today (OK, over a week ago!).
Enrol monozygotic twins in Finland. Hunt out BMI discordant identical twins (they are very rare) from the study, ie pairs of genetically identical people where one gets fat and one doesn't, despite their identical nuclear genes. Do lots of studies, get a Nature publication or ten out of it and decide obesity occurs because folks eat too much and move too little. Go to the top of the class as obesity researchers. There's a lot of it about.
Let's pick through the discussion and look at some of the conclusions from the metabolic flexibility point of view:
"a slightly higher birth weight (193 g) was observed for the twin that developed obesity during early adulthood, but this difference disappeared by age 6 months and the growth patterns of both twins were virtually identical until the age of 18 years, after which BMI differences between the co-twins became statistically significant (Figure 3)."
Pre-obese half of the pair of twins were heavier at birth, ie heavier in-utero. They must have been sneaking out to Macdonalds while telling their mother they were off to the gym. Amazing what some pregnant women will let their foetuses get up to. Next:
"After age 8, the pairs who later became discordant for obesity were heavier than the population mean, raising the possibility that genetic or environmental factors predisposing to obesity may be present in both co-twins of the discordant pairs. It therefore remains an open question as to whether the lean or the obese co-twin actually is more closely following the genetic predisposition."
Both twins have identical nuclear genes. These may or may not predispose to obesity, who knows? The obese twin has more defective mitochondrial genes than the one who remains slim. Each followed their need to produce adequate ATP. The one with worst mitochondria had to become obese to get there. Even the "slim" twin was heavier than average. His mitochondria might not have been so hot either, but not bad enough for serious malfunction. Next:
"The results suggested that physical inactivity in adolescence strongly predicted the risk for obesity (OR 3.9) and abdominal obesity (OR 4.8) at age 25, even after adjusting for baseline and current BMI."
Physical activity in adolescence is difficult if you have inadequate ATP production, so is minimised. At this age the affected twin is pre-obese. Obesity is necessary for elevation of FFAs to a level which will normalise ATP production to allow normal physical activity with sub normal mitochondria. Insulin will raise fat depots to an adequate size to elevate FFA supply due to adipocyte insulin resistance, once childhood growth has ended. Next:
"At age 25, the obese co-twins were only half as active compared with their lean co-twin as demonstrated in the 7-day accelerometer measurements.31 However, the total energy expenditure and activity-induced energy expenditure from the doubly labelled water did not differ between the co-twins. This discrepancy may be explained by the fact that the obese twins, while moving on average less, do expend more energy when they do because of their higher body weight."
THERE IS NO DIFFERENCE IN ACTIVITY OR CALORIE INTAKE BETWEEN TWINS ONCE OBESITY IS ESTABLISHED. An obese person moving from standing to sitting to standing again is doing a much weightier squat than the equally-idle-but-apparently-active skinny person with no fat to lift. Fatties may look idle because they don't get up from their chair if they don't have to but THERE IS NO DIFFERENCE in energy expenditure AT ALL compared to those equally "lazy" skinny twins who get up a few more times to burn the EXACTLY the same calories. OK, I've stopped shouting now. Doubly labelled water. Next:
"The basal metabolic rates (as measured by calorimetry) were considerably higher in the obese co-twins, presumably for the same reason."
Repeat shouting from previous paragraph. Plus, oops, they could have been talking about the Pima and forgot to mention that post prandial thermogenesis was depressed by almost exactly as much as BMR was increased.... Heard that before? I've not gone in to the logic of what is happening to BMR vs post prandial thermogenesis but it will undoubtedly come down to mitochondrial function. It just amused me that these established stars of obesity research were so familiar in their technique of citation. Next:
"The prospective Norfolk study of 20 000 men and women showed physical activity to attenuate the genetic predisposition to common obesity by 40%, as estimated by the number of risk alleles carried for 12 recently identified obesity predisposing loci.34 In the same study, the genetic risk score was positively associated with weight gain in inactive subjects, but negatively associated in physically active subjects."
No no no no. This appears to be saying that certain nuclear genes are associated with obesity if you are lazy. HOWEVER exactly the same genes are associated with you being THIN if you are active. I've not chased the EPIC paper because it's pure observational stuff but that's what this quote appears to claim EPIC is saying. Correct me if I am wrong. One explanation is that they are looking at the wrong set of genes. Obesity is a mitochondrial disease. It doesn't matter too much what your nuclear DNA says. You need good mitochondria to allow you to be physically active without needing you to be obese to improve ATP production. Duff mitochondria only allow you to be active if you have accumulated enough adipose tissue to trickle out FFAs. Next:
"However, the more objective measures via doubly labelled water revealed a substantial reporting bias by the obese co-twins: the under-reporting of energy intake (3.2±1.1 MJ per day) and over-reporting of physical activity (1.8±0.8 MJ per day) in the obese twins equalled to as much as one Big Mac hamburger, a 16-oz bottle of soft drink and almost 90 min of walking (3 m.p.h.), respectively. Interestingly, however, when asked to compare their own eating habits and physical activity to those of their co-twin, both co-twins openly reported that the obese co-twin had an unhealthier lifestyle with overeating, snacking and an irregular eating pattern as well as less physical exercise (Figure 4)."
This is a lovely paragraph. I think I have to accept from doubly labelled water that fatties lie about their caloric intake. This is very surprising. By doubly labelled water fattie twins do NOT eat any more than slim twins. They do not exercise less. Calories in and calories out are IDENTICAL in the obese and slim halves of the pair. Why should the fatties lie and claim to eat less than their skinny twin? Because they're fat...
I think it is also worth saying that the obesity-destined twin was noted, by all and sundry, to be "overeating, eating badly and eating irregularly" from an early age, with a preference for fatty foods. However I would comment that they did not even begin to become obese until 18 years of age and by 25 years of age doubly labelled water showed... etc etc etc. This moral failing as youngsters might just be translated as the pre-obese half of the pair were HUNGRY at that time. Life is hard when the world views your moral failings at the snack bar as evidence of your lack of will power. Being hungry is no fun. Being hungry because your adipocytes are not fat enough (yet) to ignore your hyperinsulinaemia and let you, grudgingly, have a few FFA molecules from their hoard is somewhat unfair. Your skinny twin is not hungry. He has mitochondrial ATP to spare. He sniggers at your third helping of pizza at your 18th birthday party because he has no gnawing hunger. He knows that you lie about how much you eat by your 25th birthday party. But by then he is eating EXACTLY the same as you are... At the gym, where he is well known, he only burns as many calories as you do walking up stairs. DOUBLY LABELLED water. Life is unfair. Next:
"Environmental influences independent from acquired obesity on liver fat were evaluated based on questionnaires and food diaries. Alcohol consumption from detailed questionnaires of the obese (3.7±0.9 doses per week) and non-obese (3.9±1.1 doses per week) co-twins did not differ and intra-pair differences in alcohol intake did not significantly correlate with differences in liver fat (r¼0.30, P¼0.14). Analysis of data from food diaries showed that the percentage of energy from fat (r¼0.37, P¼0.02) and saturated fat (r¼0.38, P¼0.005) did correlate with liver fat.5"
OMG it's the FAT (see end note), and it's the arterycloggingsaturatedfat (©Mary Eades) too. Phew. Fatty liver is due to (oops, I mean associated with) saturated fat intake. Not with Fanta. The ref for this is free to view. They, surprisingly, never did check the sucrose (or trans fat) intake against fatty liver. I don't suppose anyone thinks sugar has anything to do with fatty liver. Certainly it's not worth a line in the food breakdown table, even though it's probably just a click of the mouse away in the food analysis software... I seem to remember an obesity researcher pointing out that the obesity rise in the USA is associated with a fall in starch intake over 100 years and forgetting to mention the concurrent rise in sugar intake. There's a lot of it about. Excellence in obesity research, that is.
It gets better. The same group looked at fat preference. They really looked at fat preference. Not Fanta preference. They ONLY looked at fat preference. Perhaps there was no Fanta preference, it's not needed if the damage is already done. But the abstract gives no suggestion that they looked at anything other than fat... What answer did they set out to find? As I mentioned, there's a lot of it about.
Here's the scenario. Both twins get home from school. Pre-obese is hungry. Sneaks in to pantry and finds... Dadahhhh, a block of butter! You believe he skipped on the cookies sitting there?
Monozygotic twins have identical nuclear genes. They normally have very similar mitochondrial genes. But if there is mitochondrial heteroplasmy in the oocyst and one twin gets a bigger share of the decent mitochondria while the other gets a duff lot as they separate in-utero, things will be different. There will a discordance in BMI which develops in the attempt to normalise ATP production in the obese twin. The pre-obese twin is pre-obese in utero.
This would all be hunky dory if the mitochondrial heteroplasmy existed, with differing mitochondrial mutations between the twins. It doesn't, apparently. We find this snippet towards the end of the review paper:
"A novel finding of great interest in our obesity-discordant MZ pairs was the dramatic reduction of copies of mitochondrial DNA in the adipose tissue of the obese co-twin.12 Although the sequence of mitochondrial sequence was identical between the MZ twins (no evidence of heteroplasmy), the copy number of mitochondrial DNA in the obese co-twin’s adipose tissue was only 53% of that of the lean co-twin."
Sorry about the odd sentence in exactly the place where we want clarity, that's just how it is. Anyway, no evidence of heteroplasmy. But let's go and look up Ref 12.
This gives us this line:
"The mtDNA sequences of fat showed no evidence for heteroplasmy in co-twins, nor potentially obesity-associated sequence changes between obese and non-obese co-twins in fat or in leukocytes (Figure S1)."
I guess this might mean (as originally cited) that the sequences were identical between obese and normal twins, but it actually says there were no "potentially obesity-associated sequence changes between obese and non-obese co-twins", which may or may not be the same thing.
The next move is to another supplementary document which gives us this text (you don't have to read it if you don't want to):
"Analyses of mitochondrial sequence and copy-number
Known mitochondrial DNA sequence variants were extracted from MITOMAP database (www.mitomap.org) and variant information was annotated to the selected reference sequence AC000021.1 (GI:58615662) from GenBank. PCR primers were selected and re-optimized among those presented by Sigurdsson et al 7. Sequencing primers were designed to avoid known variant positions using The PCR Suite 8. The mitochondrial genome was PCR amplified in two overlapping ~9 kb fragments. PCR amplification was performed using 20-30 ng of DNA, 14 pmol each primer, 200 μM dNTP 1,4 U of DyNAzyme EXT DNA polymerase in 1X DyNAzyme EXT buffer (Finnzymes). Thermocycling consisted of denaturation of DNA template in 94ºC for 2 min followed by 30 cycles of 94ºC for 20s, 60ºC for 30s and of 72ºC for 4 min (extended for 10 s / cycle) and final extension of 72º for 15 min. Correct amplification was verified by agarose gel electrophoresis. PCR products were ExoI / SAP purified and sequencing was performed with BigDye3.1 chemistry on an ABI 3730xl DNA Analyzer. Mitochondrial consensus sequences and sequence variants were determined with SeqScape Software v2.5 (Applied Biosystems). Oligonucleotide sequences used in PCR and sequencing are presented in the Appendix of Supplementary Methods (vide infra)."
This is, to my rather limited experience, a standard PCR and sequencing protocol and is essentially guaranteed to produce mtDNA homoplasmy. Why? The number of abnormal mtDNA sequences is low amongst a huge number of normal copies. If you want to find heteroplasmy you have to individually sequence lots and lots and lots of mtDNA strands. Running a standard sequencing machine will not hack it.
The situation is clearly explained here. As they say:
"Here, we describe digital sequencing of mtDNA genomes using massively parallel sequencing-by-synthesis. Though the mtDNA of human cells is considered to be homogeneous, we found widespread heterogeneity (heteroplasmy) in the mtDNA of normal human cells. Moreover, the frequency of heteroplasmic variants among different tissues of the same individual varied considerably"
I've struggled with the methods to this paper and I'm not sure how many mtDNA strands they sampled from a given tissue. I think they might have done quite a few. This paper adopted a similar approach. Looking this hard you tend to find heteroplasmy if it is there.
It's there.
There are some interesting ideas in both papers about how heteroplasmy gets in to various tissues at various levels but they didn't go so far as to consider identical twins with mismatched phenotypes. A pity, because I think they know a great deal more about this than I do.
An obese twin has only 53% of the mtDNA of the slim one in their adipocytes. How about muscle cells? We know from the EMs of insulin resistant offspring of diabetic parents that their muscle mitochondria are grossly abnormal. We find from the twins study that lots of mtDNA (and presumably the mitochondria which might have originally contained it) simply isn't there.
It must be rather hard to find the mtDNA of mitochondria which are not there. Or mtDNA which is only there in very small copy numbers in the surviving mitochondria.
I personally doubt the mtDNA was homoplasmic in the obese twins. The unanswerable question is whether the heteroplasmy is responsible for the decreased mtDNA count...
There are a whole stack of ideas from the twins papers which need looking at from the mitochondrial selection pressure perspective, what controls mitochondrial number and how mitochondria control nuclear genes for their own synthesis...
Peter
BTW, compare these two abstracts, both from Finland Twins studies group:
Obese people love fat, always have done, 2002
Obese people now eat "avoiding fatty foods" while still indulging in "restrictive eating, frequent snacks, eating in the evening"... Same group 2007. Not snacking on blocks of butter after all then!
Both obese twins are considered, by these researchers, to have identical homoplasmic mtDNA in 2011. When will they change their minds on this? Soon I hope.
"If you want to retain your sanity, don't try to read a textbook on mitochondrial diseases"
This is from Nick Lane on page 281 of Power, Sex, Suicide. I was going to copy out the preceding paragraph but I guess everyone has their own copy of PSS. If not, you know what to do.
Now think about your sanity if you are dealing with a problem like obesity and you don't accept it's mitochondrial... Also think about the likelihood of successful intervention.
So I'm putting this up as a one-liner-which-grew because Liz dropped this paper me a few days ago and I got chance to open it today (OK, over a week ago!).
Enrol monozygotic twins in Finland. Hunt out BMI discordant identical twins (they are very rare) from the study, ie pairs of genetically identical people where one gets fat and one doesn't, despite their identical nuclear genes. Do lots of studies, get a Nature publication or ten out of it and decide obesity occurs because folks eat too much and move too little. Go to the top of the class as obesity researchers. There's a lot of it about.
Let's pick through the discussion and look at some of the conclusions from the metabolic flexibility point of view:
"a slightly higher birth weight (193 g) was observed for the twin that developed obesity during early adulthood, but this difference disappeared by age 6 months and the growth patterns of both twins were virtually identical until the age of 18 years, after which BMI differences between the co-twins became statistically significant (Figure 3)."
Pre-obese half of the pair of twins were heavier at birth, ie heavier in-utero. They must have been sneaking out to Macdonalds while telling their mother they were off to the gym. Amazing what some pregnant women will let their foetuses get up to. Next:
"After age 8, the pairs who later became discordant for obesity were heavier than the population mean, raising the possibility that genetic or environmental factors predisposing to obesity may be present in both co-twins of the discordant pairs. It therefore remains an open question as to whether the lean or the obese co-twin actually is more closely following the genetic predisposition."
Both twins have identical nuclear genes. These may or may not predispose to obesity, who knows? The obese twin has more defective mitochondrial genes than the one who remains slim. Each followed their need to produce adequate ATP. The one with worst mitochondria had to become obese to get there. Even the "slim" twin was heavier than average. His mitochondria might not have been so hot either, but not bad enough for serious malfunction. Next:
"The results suggested that physical inactivity in adolescence strongly predicted the risk for obesity (OR 3.9) and abdominal obesity (OR 4.8) at age 25, even after adjusting for baseline and current BMI."
Physical activity in adolescence is difficult if you have inadequate ATP production, so is minimised. At this age the affected twin is pre-obese. Obesity is necessary for elevation of FFAs to a level which will normalise ATP production to allow normal physical activity with sub normal mitochondria. Insulin will raise fat depots to an adequate size to elevate FFA supply due to adipocyte insulin resistance, once childhood growth has ended. Next:
"At age 25, the obese co-twins were only half as active compared with their lean co-twin as demonstrated in the 7-day accelerometer measurements.31 However, the total energy expenditure and activity-induced energy expenditure from the doubly labelled water did not differ between the co-twins. This discrepancy may be explained by the fact that the obese twins, while moving on average less, do expend more energy when they do because of their higher body weight."
THERE IS NO DIFFERENCE IN ACTIVITY OR CALORIE INTAKE BETWEEN TWINS ONCE OBESITY IS ESTABLISHED. An obese person moving from standing to sitting to standing again is doing a much weightier squat than the equally-idle-but-apparently-active skinny person with no fat to lift. Fatties may look idle because they don't get up from their chair if they don't have to but THERE IS NO DIFFERENCE in energy expenditure AT ALL compared to those equally "lazy" skinny twins who get up a few more times to burn the EXACTLY the same calories. OK, I've stopped shouting now. Doubly labelled water. Next:
"The basal metabolic rates (as measured by calorimetry) were considerably higher in the obese co-twins, presumably for the same reason."
Repeat shouting from previous paragraph. Plus, oops, they could have been talking about the Pima and forgot to mention that post prandial thermogenesis was depressed by almost exactly as much as BMR was increased.... Heard that before? I've not gone in to the logic of what is happening to BMR vs post prandial thermogenesis but it will undoubtedly come down to mitochondrial function. It just amused me that these established stars of obesity research were so familiar in their technique of citation. Next:
"The prospective Norfolk study of 20 000 men and women showed physical activity to attenuate the genetic predisposition to common obesity by 40%, as estimated by the number of risk alleles carried for 12 recently identified obesity predisposing loci.34 In the same study, the genetic risk score was positively associated with weight gain in inactive subjects, but negatively associated in physically active subjects."
No no no no. This appears to be saying that certain nuclear genes are associated with obesity if you are lazy. HOWEVER exactly the same genes are associated with you being THIN if you are active. I've not chased the EPIC paper because it's pure observational stuff but that's what this quote appears to claim EPIC is saying. Correct me if I am wrong. One explanation is that they are looking at the wrong set of genes. Obesity is a mitochondrial disease. It doesn't matter too much what your nuclear DNA says. You need good mitochondria to allow you to be physically active without needing you to be obese to improve ATP production. Duff mitochondria only allow you to be active if you have accumulated enough adipose tissue to trickle out FFAs. Next:
"However, the more objective measures via doubly labelled water revealed a substantial reporting bias by the obese co-twins: the under-reporting of energy intake (3.2±1.1 MJ per day) and over-reporting of physical activity (1.8±0.8 MJ per day) in the obese twins equalled to as much as one Big Mac hamburger, a 16-oz bottle of soft drink and almost 90 min of walking (3 m.p.h.), respectively. Interestingly, however, when asked to compare their own eating habits and physical activity to those of their co-twin, both co-twins openly reported that the obese co-twin had an unhealthier lifestyle with overeating, snacking and an irregular eating pattern as well as less physical exercise (Figure 4)."
This is a lovely paragraph. I think I have to accept from doubly labelled water that fatties lie about their caloric intake. This is very surprising. By doubly labelled water fattie twins do NOT eat any more than slim twins. They do not exercise less. Calories in and calories out are IDENTICAL in the obese and slim halves of the pair. Why should the fatties lie and claim to eat less than their skinny twin? Because they're fat...
I think it is also worth saying that the obesity-destined twin was noted, by all and sundry, to be "overeating, eating badly and eating irregularly" from an early age, with a preference for fatty foods. However I would comment that they did not even begin to become obese until 18 years of age and by 25 years of age doubly labelled water showed... etc etc etc. This moral failing as youngsters might just be translated as the pre-obese half of the pair were HUNGRY at that time. Life is hard when the world views your moral failings at the snack bar as evidence of your lack of will power. Being hungry is no fun. Being hungry because your adipocytes are not fat enough (yet) to ignore your hyperinsulinaemia and let you, grudgingly, have a few FFA molecules from their hoard is somewhat unfair. Your skinny twin is not hungry. He has mitochondrial ATP to spare. He sniggers at your third helping of pizza at your 18th birthday party because he has no gnawing hunger. He knows that you lie about how much you eat by your 25th birthday party. But by then he is eating EXACTLY the same as you are... At the gym, where he is well known, he only burns as many calories as you do walking up stairs. DOUBLY LABELLED water. Life is unfair. Next:
"Environmental influences independent from acquired obesity on liver fat were evaluated based on questionnaires and food diaries. Alcohol consumption from detailed questionnaires of the obese (3.7±0.9 doses per week) and non-obese (3.9±1.1 doses per week) co-twins did not differ and intra-pair differences in alcohol intake did not significantly correlate with differences in liver fat (r¼0.30, P¼0.14). Analysis of data from food diaries showed that the percentage of energy from fat (r¼0.37, P¼0.02) and saturated fat (r¼0.38, P¼0.005) did correlate with liver fat.5"
OMG it's the FAT (see end note), and it's the arterycloggingsaturatedfat (©Mary Eades) too. Phew. Fatty liver is due to (oops, I mean associated with) saturated fat intake. Not with Fanta. The ref for this is free to view. They, surprisingly, never did check the sucrose (or trans fat) intake against fatty liver. I don't suppose anyone thinks sugar has anything to do with fatty liver. Certainly it's not worth a line in the food breakdown table, even though it's probably just a click of the mouse away in the food analysis software... I seem to remember an obesity researcher pointing out that the obesity rise in the USA is associated with a fall in starch intake over 100 years and forgetting to mention the concurrent rise in sugar intake. There's a lot of it about. Excellence in obesity research, that is.
It gets better. The same group looked at fat preference. They really looked at fat preference. Not Fanta preference. They ONLY looked at fat preference. Perhaps there was no Fanta preference, it's not needed if the damage is already done. But the abstract gives no suggestion that they looked at anything other than fat... What answer did they set out to find? As I mentioned, there's a lot of it about.
Here's the scenario. Both twins get home from school. Pre-obese is hungry. Sneaks in to pantry and finds... Dadahhhh, a block of butter! You believe he skipped on the cookies sitting there?
Monozygotic twins have identical nuclear genes. They normally have very similar mitochondrial genes. But if there is mitochondrial heteroplasmy in the oocyst and one twin gets a bigger share of the decent mitochondria while the other gets a duff lot as they separate in-utero, things will be different. There will a discordance in BMI which develops in the attempt to normalise ATP production in the obese twin. The pre-obese twin is pre-obese in utero.
This would all be hunky dory if the mitochondrial heteroplasmy existed, with differing mitochondrial mutations between the twins. It doesn't, apparently. We find this snippet towards the end of the review paper:
"A novel finding of great interest in our obesity-discordant MZ pairs was the dramatic reduction of copies of mitochondrial DNA in the adipose tissue of the obese co-twin.12 Although the sequence of mitochondrial sequence was identical between the MZ twins (no evidence of heteroplasmy), the copy number of mitochondrial DNA in the obese co-twin’s adipose tissue was only 53% of that of the lean co-twin."
Sorry about the odd sentence in exactly the place where we want clarity, that's just how it is. Anyway, no evidence of heteroplasmy. But let's go and look up Ref 12.
This gives us this line:
"The mtDNA sequences of fat showed no evidence for heteroplasmy in co-twins, nor potentially obesity-associated sequence changes between obese and non-obese co-twins in fat or in leukocytes (Figure S1)."
I guess this might mean (as originally cited) that the sequences were identical between obese and normal twins, but it actually says there were no "potentially obesity-associated sequence changes between obese and non-obese co-twins", which may or may not be the same thing.
The next move is to another supplementary document which gives us this text (you don't have to read it if you don't want to):
"Analyses of mitochondrial sequence and copy-number
Known mitochondrial DNA sequence variants were extracted from MITOMAP database (www.mitomap.org) and variant information was annotated to the selected reference sequence AC000021.1 (GI:58615662) from GenBank. PCR primers were selected and re-optimized among those presented by Sigurdsson et al 7. Sequencing primers were designed to avoid known variant positions using The PCR Suite 8. The mitochondrial genome was PCR amplified in two overlapping ~9 kb fragments. PCR amplification was performed using 20-30 ng of DNA, 14 pmol each primer, 200 μM dNTP 1,4 U of DyNAzyme EXT DNA polymerase in 1X DyNAzyme EXT buffer (Finnzymes). Thermocycling consisted of denaturation of DNA template in 94ºC for 2 min followed by 30 cycles of 94ºC for 20s, 60ºC for 30s and of 72ºC for 4 min (extended for 10 s / cycle) and final extension of 72º for 15 min. Correct amplification was verified by agarose gel electrophoresis. PCR products were ExoI / SAP purified and sequencing was performed with BigDye3.1 chemistry on an ABI 3730xl DNA Analyzer. Mitochondrial consensus sequences and sequence variants were determined with SeqScape Software v2.5 (Applied Biosystems). Oligonucleotide sequences used in PCR and sequencing are presented in the Appendix of Supplementary Methods (vide infra)."
This is, to my rather limited experience, a standard PCR and sequencing protocol and is essentially guaranteed to produce mtDNA homoplasmy. Why? The number of abnormal mtDNA sequences is low amongst a huge number of normal copies. If you want to find heteroplasmy you have to individually sequence lots and lots and lots of mtDNA strands. Running a standard sequencing machine will not hack it.
The situation is clearly explained here. As they say:
"Here, we describe digital sequencing of mtDNA genomes using massively parallel sequencing-by-synthesis. Though the mtDNA of human cells is considered to be homogeneous, we found widespread heterogeneity (heteroplasmy) in the mtDNA of normal human cells. Moreover, the frequency of heteroplasmic variants among different tissues of the same individual varied considerably"
I've struggled with the methods to this paper and I'm not sure how many mtDNA strands they sampled from a given tissue. I think they might have done quite a few. This paper adopted a similar approach. Looking this hard you tend to find heteroplasmy if it is there.
It's there.
There are some interesting ideas in both papers about how heteroplasmy gets in to various tissues at various levels but they didn't go so far as to consider identical twins with mismatched phenotypes. A pity, because I think they know a great deal more about this than I do.
An obese twin has only 53% of the mtDNA of the slim one in their adipocytes. How about muscle cells? We know from the EMs of insulin resistant offspring of diabetic parents that their muscle mitochondria are grossly abnormal. We find from the twins study that lots of mtDNA (and presumably the mitochondria which might have originally contained it) simply isn't there.
It must be rather hard to find the mtDNA of mitochondria which are not there. Or mtDNA which is only there in very small copy numbers in the surviving mitochondria.
I personally doubt the mtDNA was homoplasmic in the obese twins. The unanswerable question is whether the heteroplasmy is responsible for the decreased mtDNA count...
There are a whole stack of ideas from the twins papers which need looking at from the mitochondrial selection pressure perspective, what controls mitochondrial number and how mitochondria control nuclear genes for their own synthesis...
Peter
BTW, compare these two abstracts, both from Finland Twins studies group:
Obese people love fat, always have done, 2002
Obese people now eat "avoiding fatty foods" while still indulging in "restrictive eating, frequent snacks, eating in the evening"... Same group 2007. Not snacking on blocks of butter after all then!
Both obese twins are considered, by these researchers, to have identical homoplasmic mtDNA in 2011. When will they change their minds on this? Soon I hope.