Quel est le rôle des catécholamines pendant l'exercice ?

Les catécholamines augmentent la mobilisation du glycogène et des triglycérides, facilitant l'accès aux combustibles par les muscles.

Comment l'insuline affecte-t-elle le métabolisme pendant l'exercice ?

L'insuline diminue pendant l'exercice, ce qui favorise la mobilisation des combustibles plutôt que leur stockage.

Quelles hormones sont considérées comme contre-régulatrices ?

Les hormones contre-régulatrices incluent le glucagon, le cortisol et l'hormone de croissance.

Comment le corps maintient-il les niveaux de glucose sanguin pendant l'exercice ?

Le foie stimule la gluconéogenèse pour maintenir des niveaux de glucose sanguin adéquats.

Quel est l'effet de l'exercice chronique sur la réponse hormonale ?

L'exercice chronique réduit la réponse du système nerveux sympathique, rendant l'exercice moins stressant.

KINES 3091- Endo. Control of Metab.- Lecture #3

00:49:08

https://www.youtube.com/watch?v=wJeMYzkA0c4

Resumo

TLDRCette conférence traite de l'impact des hormones sur le métabolisme pendant l'exercice, en mettant l'accent sur les catécholamines, qui favorisent la mobilisation des combustibles comme le glycogène et les graisses. Les catécholamines augmentent la circulation sanguine vers les muscles et stimulent des enzymes comme la lipoprotéine lipase pour faciliter l'absorption des graisses. En parallèle, d'autres hormones comme le glucagon et le cortisol sont également libérées pour soutenir la production de glucose et la mobilisation des graisses. L'insuline, quant à elle, diminue pendant l'exercice pour éviter le stockage des nutriments. La conférence conclut sur l'idée que l'exercice régulier atténue la réponse hormonale au stress, rendant l'exercice moins exigeant pour le corps.

Conclusões

💪 Les catécholamines augmentent la mobilisation des combustibles.
🏃‍♂️ L'exercice stimule la libération de glucose par le foie.
📉 L'insuline diminue pendant l'exercice pour favoriser la mobilisation.
🔄 Le glucagon et le cortisol soutiennent la production de glucose.
⚖️ L'exercice chronique réduit la réponse hormonale au stress.

Linha do tempo

00:00:00 - 00:05:00
Cette troisième conférence aborde le contrôle endocrinien et le métabolisme pendant l'exercice, en se concentrant sur le rôle des catécholamines dans la mobilisation des combustibles. L'augmentation de la noradrénaline et de l'épinéphrine favorise la mobilisation du glycogène musculaire et hépatique, ainsi que des acides gras à partir des triglycérides intramusculaires et des tissus adipeux.
00:05:00 - 00:10:00
Après la mobilisation des graisses, l'enzyme lipoprotéine lipase (LPL) est activée dans les cellules musculaires pour permettre l'absorption des acides gras circulants. L'augmentation de la noradrénaline et de l'épinéphrine stimule l'activité de la LPL musculaire, facilitant ainsi l'accès aux graisses pour la production d'ATP.
00:10:00 - 00:15:00
La contraction musculaire peut également affecter les niveaux de glucose sanguin. Le foie joue un rôle crucial dans le maintien de la glycémie, en produisant du glucose par gluconéogenèse, surtout lorsque l'intensité de l'exercice augmente. Les catécholamines stimulent cette gluconéogenèse en favorisant l'absorption de sous-produits métaboliques par le foie.
00:15:00 - 00:20:00
Les catécholamines influencent également d'autres hormones régulatrices comme le glucagon, le cortisol et l'hormone de croissance, qui augmentent pendant l'exercice pour soutenir la mobilisation des combustibles. Le glucagon stimule la glycogénolyse et la lipolyse, tandis que le cortisol favorise la gluconéogenèse et la lipolyse.
00:20:00 - 00:25:00
L'insuline, en revanche, diminue pendant l'exercice, car elle est une hormone de stockage. La suppression de l'insuline favorise la mobilisation des combustibles, permettant aux muscles squelettiques d'accéder au glucose nécessaire à la production d'ATP.
00:25:00 - 00:30:00
L'activation de la phosphorylase dans les muscles squelettiques est également stimulée par l'augmentation du calcium intracellulaire pendant la contraction, ce qui favorise la dégradation du glycogène pour l'ATP. De plus, le calcium stimule la translocation des transporteurs GLUT4, facilitant l'absorption du glucose par les muscles en contraction.
00:30:00 - 00:35:00
Les réponses hormonales à l'exercice varient en fonction de l'intensité et de la durée. À mesure que l'intensité de l'exercice augmente, les hormones contre-régulatrices comme l'épinéphrine, la noradrénaline, le glucagon et le cortisol augmentent, tandis que l'insuline diminue.
00:35:00 - 00:49:08
L'entraînement chronique modifie la réponse hormonale à l'exercice, réduisant l'augmentation de l'activité du système nerveux sympathique et des niveaux de catécholamines. Cela signifie que l'exercice devient moins stressant pour le corps, entraînant une réponse hormonale plus atténuée et une meilleure gestion des niveaux de glucose sanguin.

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Vídeo de perguntas e respostas

Quel est le rôle des catécholamines pendant l'exercice ?
Les catécholamines augmentent la mobilisation du glycogène et des triglycérides, facilitant l'accès aux combustibles par les muscles.
Comment l'insuline affecte-t-elle le métabolisme pendant l'exercice ?
L'insuline diminue pendant l'exercice, ce qui favorise la mobilisation des combustibles plutôt que leur stockage.
Quelles hormones sont considérées comme contre-régulatrices ?
Les hormones contre-régulatrices incluent le glucagon, le cortisol et l'hormone de croissance.
Comment le corps maintient-il les niveaux de glucose sanguin pendant l'exercice ?
Le foie stimule la gluconéogenèse pour maintenir des niveaux de glucose sanguin adéquats.
Quel est l'effet de l'exercice chronique sur la réponse hormonale ?
L'exercice chronique réduit la réponse du système nerveux sympathique, rendant l'exercice moins stressant.

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Legendas

Rolagem automática:

00:00:00
alright guys let's finish this lecture
00:00:04
up this is the third lecture from this
00:00:10
endocrine control and metabolism during
00:00:12
exercise material and we're gonna pick
00:00:16
up where we left off so last time we
00:00:20
left off with discussing the ways in
00:00:22
which the catecholamines contribute to
00:00:25
fuel mobilization and real broadly we
00:00:28
said that they promote it so increase in
00:00:33
norepinephrine and epinephrine
00:00:37
is going to increase the mobilization of
00:00:42
both glycogen from muscle glycogen as
00:00:49
well as from liver glycogen and increase
00:00:57
triglyceride mobilization or fatty acid
00:01:00
mobilization from intramuscular
00:01:04
triglyceride and adipose tissue
00:01:08
triglyceride so increased mobilization
00:01:12
of both of these fuels and so go back
00:01:17
and take a look at those slides we
00:01:20
talked about how the catecholamines
00:01:22
facilitate the activation of the enzymes
00:01:26
that start glycogenolysis as well as
00:01:29
lipolysis via camp second messenger
00:01:33
pathways in both cases okay so we've got
00:01:40
a pretty big lecture today or now we're
00:01:45
gonna continue on with looking at the
00:01:51
influence of the catecholamines on these
00:01:54
two factors delivery and fuel uptake and
00:01:57
mainly fuel uptake because most of the
00:02:00
the delivery influence of the
00:02:02
catecholamines is via cardiovascular
00:02:04
adaptations to either increase or
00:02:07
decrease blood flow so in the case of
00:02:10
fuel mobilization the fields been
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released into the blood stream
00:02:13
and the influence on fuel delivery is
00:02:16
going to happen by either increasing
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blood flow with that fuel to the
00:02:20
skeletal muscle or cut down on blood
00:02:23
flow and therefore reduce the
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availability of that mobilize fuel to
00:02:29
the skeletal muscle which we clearly
00:02:31
don't want to do during exercise and so
00:02:34
the main emphasis will first be this
00:02:37
fuel uptake process and then I'm going
00:02:42
to talk about the other counter
00:02:45
regulatory hormones and how they
00:02:48
influence fuel use during exercise and
00:02:50
how that's coordinated by these
00:02:52
catecholamines and then we'll talk about
00:02:55
insulin and then we'll leave off with
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some just recapping of the acute as well
00:03:02
as a brief review of the training
00:03:04
related changes that acute or occur with
00:03:07
exercies okay so we've said that and
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again how do we how do the
00:03:15
catecholamines adjust delivery by either
00:03:19
stimulating vaso dilation via beta 2
00:03:29
receptors in the vascular endothelium or
00:03:35
vasodilation oops not visit dilation
00:03:41
that's what I just said physio
00:03:44
constriction via alpha 1 receptors right
00:03:55
ok so let's jump in and start talking
00:04:00
about this issue of uptake so we've
00:04:05
mobilized it we've delivered it through
00:04:07
phase of dilation and now let's talk
00:04:10
about uptake so if we start with looking
00:04:14
at how the skeletal muscle accesses fats
00:04:19
then we start with a increase in blood
00:04:24
flow to
00:04:26
from the fat tissue right so if we're
00:04:30
mobilizing fat out of storage in the
00:04:33
adipose tissue then it doesn't make
00:04:36
sense for us to simultaneously constrict
00:04:39
the vessels in that tissue because then
00:04:41
we mobilize it but it doesn't go
00:04:43
anywhere ray it's been released into the
00:04:45
bloodstream but if the arterioles RV's
00:04:47
are constricted then we're not sending
00:04:50
blood there so we can mobilize or get
00:04:53
that that fuel that's mobilized out of
00:04:56
that tissue and into the skeletal muscle
00:05:00
okay so we have mobilized fat or the
00:05:05
triglyceride Auto storage out of the fat
00:05:08
has been released into circulation now
00:05:11
it cannot be taken up by the skeletal
00:05:15
muscle cell automatically and instead
00:05:19
what has to happen is another enzyme
00:05:21
needs to be stimulated and that enzyme
00:05:24
is called lipoprotein lipase or LPL so
00:05:29
remember that it was HSL inside the fat
00:05:33
cell or inside the intramuscular or
00:05:36
inside the muscle cell that helped to
00:05:39
mobilize the fat out of storage but if
00:05:43
it's released into the bloodstream from
00:05:45
the adipose tissue and circulates to the
00:05:47
skeletal muscle then the skeletal muscle
00:05:51
has to access it via the stimulation of
00:05:53
this other enzyme this other enzyme that
00:05:56
that breaks down lipids so it's another
00:05:59
lipase it's called lipoprotein lipase
00:06:02
and we put the M in front of it to
00:06:05
represent that this is LPL on the muscle
00:06:08
cell so if we have an increase in
00:06:13
norepinephrine and epinephrine one of
00:06:22
the things that's going to happen is
00:06:23
we're going to increase the activity of
00:06:26
muscle LPL and so that enables the
00:06:30
skeletal muscle to access any fats that
00:06:33
are floatin by in circulation this is
00:06:37
also stimulated via
00:06:40
a camp second messenger pathway and it's
00:06:44
gonna make the fat that was released by
00:06:46
the adipose tissue available to the
00:06:49
skeletal muscle cell for use for making
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ATP right so here's our LPL enzyme and
00:07:02
here it is here and and so it kind of
00:07:08
sticks out into circulation and it grabs
00:07:12
on to these triglycerides and it breaks
00:07:15
the fatty acids and glycerol apart just
00:07:17
like hormone sensitive lipase does but
00:07:20
in this case it has or it does that
00:07:24
lipolysis for the purpose of uptake not
00:07:29
mobilization so LPL uptake that's HSL
00:07:43
mobilization fats now we have adipose
00:07:56
tissue
00:07:57
LPL as well but if adipose tissue LPL is
00:08:03
active then the fat that is in
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circulation is going to be taken up and
00:08:11
stored so during exercise we don't want
00:08:21
to store the fats we want to keep them
00:08:24
available for the skeletal muscle tissue
00:08:27
so when norepinephrine and epinephrine
00:08:31
levels rise because exercise has begun
00:08:35
or exercise intensity is going up we're
00:08:39
going to stimulate muscle LPL but we
00:08:43
simultaneously want to inhibit or shut
00:08:46
down adipose tissue LPL and the reason
00:08:50
for that is again muscle LPL is
00:08:53
going to facilitate uptake skeletal
00:08:57
muscle uptake rate and that's going to
00:09:01
be a good thing because that's going to
00:09:03
lead to ATP synthesis for the
00:09:05
contracting skeletal muscle but in the
00:09:08
case of adipose tissue LPL that's going
00:09:12
to increase fat or adipose tissue uptake
00:09:15
and that is not going to help skeletal
00:09:21
muscle tissue make ATP instead that's
00:09:23
going to increase storage and when to
00:09:29
emphasize now exercise is not a time for
00:09:41
storage okay so because we know that
00:09:54
norepinephrine and epinephrine increase
00:09:56
during exercise their primary effect is
00:09:58
going to be on mobilizing and making
00:10:00
fuel available to skeletal muscle it is
00:10:03
simultaneously going to inhibit or
00:10:05
reduce the ability of fuel to be stored
00:10:08
in places like the liver or the adipose
00:10:13
tissue wants to get as much fuel
00:10:15
available to the contracting muscle as
00:10:17
it needs okay so I had mentioned that
00:10:27
during exercise the skeletal muscle
00:10:33
needs to access or facilitate the ATP
00:10:39
demand by mobilizing and circulating and
00:10:45
and taking up fuel but it needs to do
00:10:49
that while maintaining blood glucose
00:10:52
right and so the endocrine system is
00:10:57
trying to do meet those two demands
00:11:00
simultaneously or do those two jobs
00:11:02
simultaneously
00:11:04
so contracting skeletal muscle can work
00:11:08
to deplete blood glucose because
00:11:10
contracting skeletal muscle can access
00:11:14
glucose in the blood
00:11:16
so when skeletal muscle contracts it
00:11:20
pulls glucose out of the blood into the
00:11:32
skeletal muscle so and it uses it for
00:11:37
ATP right vehicle a colossus and so
00:11:46
contracting skeletal muscle can
00:11:48
essentially represent a threat to the
00:11:51
fairly tightly managed or regulated
00:11:54
blood glucose levels and so that is the
00:11:57
primary purpose of hepatic glucose
00:12:01
production so the livers job is or one
00:12:05
of the livers jobs is to maintain
00:12:07
acceptable blood glucose levels now it
00:12:11
needs to get glucose out of the blood if
00:12:15
it gets too high and it needs to put
00:12:19
glucose back into the blood if it gets
00:12:21
too low and I'm saying that skeletal
00:12:23
muscle can pull glucose out of the blood
00:12:25
and so during exercise the the one of
00:12:29
the tasks on the liver is to make sure
00:12:32
that blood glucose levels don't get too
00:12:34
low and so we have a pretty fairly
00:12:37
strong or significant stimulation of
00:12:41
gluconeogenesis during exercise and that
00:12:44
stimulation gets stronger as exercise
00:12:48
intensity and especially as exercise
00:12:50
duration goes up so gluconeogenesis is a
00:12:54
pretty strong or significant effect from
00:13:00
increasing exercise and one of the main
00:13:05
influences to stimulate gluconeogenesis
00:13:09
is through the influence of
00:13:11
catecholamines on the liver via this
00:13:14
cyclic A&P second messenger path
00:13:16
and the main effect of the
00:13:20
catecholamines is going to be this
00:13:24
uptake of these byproducts of metabolism
00:13:29
for example lactate or the glycerol from
00:13:32
the triglycerides pyruvate from slow
00:13:34
glycolysis lactate from fast glycolysis
00:13:37
even amino acids if you're breaking down
00:13:39
proteins can be taken up by the liver
00:13:43
and used to synthesize new glucose that
00:13:46
new glucose then is released into
00:13:48
circulation bringing blood glucose
00:13:51
levels back up to acceptable limits or
00:13:54
ranges okay now I had mentioned that one
00:14:04
of the ways in which the catecholamines
00:14:06
influence fuel metabolism during
00:14:09
exercise is indirectly through their
00:14:12
influence on these other counter
00:14:14
regulatory hormones and so those other
00:14:17
counter regulatory hormones include the
00:14:20
hormone glucagon cortisol and growth
00:14:24
hormone and so you can see that when
00:14:27
catecholamine levels rise again increase
00:14:30
in norepinephrine and epinephrine
00:14:33
they're going to cause all those changes
00:14:35
that we've talked about already directly
00:14:39
but they will simultaneously influence
00:14:42
the endocrine organs that increase the
00:14:44
production of glucagon increase the
00:14:46
production of cortisol and increase in
00:14:48
production of growth hormone so
00:14:50
norepinephrine and epinephrine will
00:14:52
stimulate the pancreatic alpha cells to
00:14:57
produce and release glucagon so as
00:15:01
exercise intensity goes up we're gonna
00:15:04
see a stronger and stronger increase in
00:15:07
sympathetic nervous system activity
00:15:08
which is going to result in more and
00:15:11
more norepinephrine epinephrine being
00:15:13
released from the adrenal medulla into
00:15:15
circulation among other places that
00:15:19
norepinephrine and epinephrine is going
00:15:21
to bind to receptors on the pancreas and
00:15:23
stimulate those pancreatic alpha cells
00:15:26
to release glucagon
00:15:27
now as glucagon
00:15:30
levels go up in the bloodstream they are
00:15:33
going to promote glycogenolysis and
00:15:36
lipolysis in the exact same way that we
00:15:41
saw the catecholamines promote
00:15:43
glycogenolysis and lipolysis and i'll
00:15:47
remind you of what those are here in an
00:15:50
upcoming slide so glucagon promotes
00:15:54
mobilization of glucose and lipid out of
00:15:58
storage
00:15:59
just like norepinephrine and epinephrine
00:16:01
do the norepinephrine and epinephrine is
00:16:05
also going to bind to receptors on the
00:16:10
adrenal cortex so this is the outer
00:16:13
portion of the adrenal gland and it's
00:16:17
going to stimulate the adrenal cortex to
00:16:20
produce and release cortisol into
00:16:23
circulation
00:16:24
now as cortisol levels go up the primary
00:16:28
effect is to promote gluconeogenesis and
00:16:34
lipolysis okay so gluconeogenesis is
00:16:38
going to restore blood glucose levels
00:16:44
and the promotion of lipolysis is going
00:16:52
to increase availability of fats in lieu
00:16:56
of glucose so if there's a greater
00:17:01
availability of fats then the skeletal
00:17:08
muscle might be able to use the fat
00:17:10
instead of using the glucose and if it's
00:17:13
not using the glucose then it's not
00:17:16
threatening blood glucose levels as much
00:17:19
and so the overall focus or primary
00:17:22
purpose of cortisol is really to
00:17:26
maintain or manage blood glucose levels
00:17:29
and it does that in these two ways to
00:17:31
promote gluconeogenesis production of
00:17:33
glucose by the liver as well as the use
00:17:37
of fats rather than glucose by the
00:17:39
skeletal muscle by making more fat
00:17:41
available through lipolysis
00:17:43
now we have a similar goal or influenced
00:17:48
by the hormone growth hormone and growth
00:17:53
hormone is going to increase in response
00:17:55
to the catecholamines binding to
00:17:57
receptors on the pituitary gland and as
00:18:01
growth hormone levels increase they're
00:18:05
also going to help promote the use of
00:18:09
fats over glow glucose and in doing so
00:18:13
help preserve or restore blood glucose
00:18:17
levels so that that variable is is where
00:18:22
it should be and is not you're not
00:18:25
struggling with hypoglycemia so cortisol
00:18:30
helps preserve blood glucose through
00:18:32
both gluconeogenesis and lipolysis
00:18:35
growth hormone helps preserve leg
00:18:38
glucose by promoting lipolysis and then
00:18:41
glucagon is gonna mobilize fuel in
00:18:44
general just increase the mobilization
00:18:48
of glucose out glycogen in the
00:18:50
mobilization of fatty acids out of
00:18:53
adipose tissue now there is another
00:18:58
major effect of the catecholamines on
00:19:01
the regulatory hormone insulin and so
00:19:06
we've seen that the counter regulatory
00:19:09
hormones they're all going to go up so
00:19:11
norepinephrine epi go up and in turn
00:19:14
glucagon cortisol and growth hormone
00:19:16
levels are going to increase also but
00:19:20
insulin is going to decrease we want to
00:19:24
suppress insulin levels and so the
00:19:30
amount of insulin in the blood is
00:19:32
actually going to decrease as exercise
00:19:35
intensity goes up now if you remember
00:19:38
insulin is a horrid hormone
00:19:55
and when did I say on the last slide
00:19:57
exercise is not a time for storage and
00:20:02
so it should make some intuitive sense
00:20:04
that if we don't want to store we want
00:20:06
to mobilize fuel then we should suppress
00:20:09
or inhibit a hormone that stops
00:20:13
mobilization and promote storage and
00:20:15
that's exactly what happens when
00:20:18
norepinephrine and epinephrine stimulate
00:20:20
the pancreatic beta-cells
00:20:23
to stop secreting insulin and so over
00:20:28
time insulin levels are going to
00:20:31
decrease and so that helps promote
00:20:35
mobilization over storage and it also
00:20:41
preserves glucose for uptake by the
00:20:46
skeletal muscle rather than other
00:20:49
tissues that aren't really essential
00:20:52
during exercise so remember that at rest
00:20:56
or if we're talking about other tissues
00:20:59
other than skeletal muscle that those
00:21:03
many of those tissues need insulin in
00:21:07
order to get to the glucose that's in
00:21:10
circulation so resting skeletal muscle
00:21:13
is the same at rest if we want to get
00:21:17
glucose out of the blood because it's
00:21:19
too high we like to send it into
00:21:22
skeletal muscle tissue and for us to be
00:21:24
able to do that at rest we need insulin
00:21:27
levels to climb insulin will bind to its
00:21:30
membrane receptor on the skeletal muscle
00:21:32
cell and stimulate the glute for glucose
00:21:36
transport mechanism which will move to
00:21:39
the surface of the skeletal muscle cell
00:21:41
and essentially facilitate the diffusion
00:21:45
of glucose from the bloodstream into the
00:21:48
interior of the skeletal muscle cell
00:21:50
however we don't want that happening in
00:21:56
non-essential or essentially non
00:21:58
skeletal muscle cell tissues the reason
00:22:01
for that is again because skeletal
00:22:03
muscle is contracting it has a very high
00:22:05
ATP demand so as much as possible we
00:22:08
want to
00:22:08
serve glucose for the skeletal muscle
00:22:12
tissue because it has such a high demand
00:22:16
for ATP synthesis so if it's not staying
00:22:19
in the blood to maintain blood glucose
00:22:22
levels we would like to see it going
00:22:25
into the skeletal muscle cells for ATP
00:22:30
synthesis and so suppressing insulin is
00:22:34
going to help prevent those
00:22:36
non-essential tissues from taking up any
00:22:39
of the glucose that's in the blood and
00:22:43
therefore preserving it either to
00:22:45
maintain blood glucose levels or to help
00:22:48
meet that demands for ATP synthesis and
00:22:51
the working skill muscle and I'll talk a
00:22:55
little bit more about how that happens
00:22:57
in another slide coming up but I just
00:23:00
want to remind you I said early on in
00:23:02
that last slide that glucagon
00:23:05
essentially promotes mobilization just
00:23:08
like epinephrine and norepinephrine do
00:23:10
so if you remember these figures we
00:23:13
talked about these when we looked at how
00:23:15
epinephrine stimulates glycogenolysis
00:23:21
all right so this one is glycogenolysis
00:23:24
and this was adipose tissue lipolysis
00:23:31
and the enzyme for glycogenolysis is
00:23:38
that phosphorylase a and the enzyme for
00:23:42
lipolysis is that hormone sensitive
00:23:44
lipase and if you back up and you see at
00:23:47
the top of both of these figures
00:23:49
glucagon does the exact same thing that
00:23:53
happened nephron did except it it does
00:23:57
it in the skeletal muscle or excuse me
00:23:59
it does it in the liver tissue
00:24:02
specifically glucagon can bind with
00:24:06
receptors on adipose tissue just like
00:24:09
epinephrine can and promote lipolysis
00:24:11
just like epinephrine so same camp
00:24:15
mediated second messenger pathways
00:24:19
and that's why we say that glucagon and
00:24:23
the catecholamines are essentially
00:24:24
redundant because they're both strong
00:24:28
promoters of fuel mobilization out of
00:24:32
storage there we go
00:24:38
and I've also said already repeatedly
00:24:42
that insulin is a storage hormone and we
00:24:44
don't want to store during exercise so
00:24:47
what I'd like you to do is zoom in on
00:24:49
this figure and look and see how insulin
00:24:53
is functioning so if you remember this
00:24:56
was fat tissue lipolysis so fat
00:25:01
so like pollicis and we were exploring
00:25:11
with this figure how both glucagon and
00:25:14
epinephrine can cause this increase in
00:25:19
cyclic ANP which will stimulate hormone
00:25:23
sensitive lipase which will mobilize
00:25:26
glycerol and fatty acid out of storage
00:25:29
and release them into those into
00:25:31
circulation if you look at how insulin
00:25:35
affects lipolysis we can see that when
00:25:41
insulin binds to its receptor same cell
00:25:45
still the fat cell except in this case
00:25:48
we're looking at what happens with
00:25:50
insulin binding to the insulin receptor
00:25:53
insulin is going to work through oh look
00:25:56
you should recognize this second
00:25:59
messenger pathway
00:26:01
we've got insulin binding to its
00:26:02
receptor it's gonna stimulate this
00:26:06
phospho tool inositol to be broken down
00:26:10
into ip3 and dag the ip3
00:26:14
in turn will activate or eventually
00:26:18
stimulate the activation of this enzyme
00:26:22
phosphodiesterase what does
00:26:24
phosphodiesterase do it shuts down camp
00:26:28
if camp levels aren't coming up HSL
00:26:31
isn't coming
00:26:32
if HSL isn't active we're not mobilizing
00:26:36
and we're keeping fuel in storage so
00:26:41
again insulin is a storage hormone it
00:26:44
works against the hormones that mobilize
00:26:48
fuel out of storage
00:26:50
so if exercise is not a time for storage
00:26:55
not only do we want to promote
00:26:59
mobilization through the effects of
00:27:04
glucagon and epinephrine
00:27:07
we also simultaneously want to shut down
00:27:12
any insulin inhibition of those
00:27:16
mobilization efforts and so we're gonna
00:27:22
reduce the insulin influence we're going
00:27:26
to prevent the secretion of insulin by
00:27:31
the pancreas and that will stop it from
00:27:35
inhibiting the mobilization efforts of
00:27:38
the counter regulatory hormones whoops
00:27:48
we see a similar effect of insulin on
00:27:52
glycogenolysis so I'd say this is
00:28:11
right and we we said hey look
00:28:14
epinephrine and glucagon will stimulate
00:28:18
either skeletal muscle or in the case of
00:28:21
glucagon hepatic glycogen Allah says it
00:28:25
again is a camp second messenger pathway
00:28:29
that will ultimately activate this
00:28:33
glycogen phosphorylase enzyme and that
00:28:37
will pull glucose out of glycogen and
00:28:40
that glucose can be either released into
00:28:43
circulation from the liver or used by a
00:28:46
glycolysis within the skeletal muscle
00:28:49
cell right but in the case of if we look
00:28:55
at how insulin influences this pathway
00:28:58
insulin again promotes storage in doing
00:29:02
that it's going to inhibit mobilization
00:29:05
and so just like we saw it inhibiting
00:29:08
the activation of hormone sensitive
00:29:11
lipase insulin will also inhibit the
00:29:15
activation of phosphorylase and it does
00:29:19
this in a couple different ways one way
00:29:22
is again through that PDE producing that
00:29:27
phosphodiesterase it's going to shut
00:29:29
down camp and if we need a camp to
00:29:34
stimulate the activation of
00:29:35
phosphorylase then insulin will in turn
00:29:38
shut down the that process that
00:29:42
activation of a phosphorylase but we
00:29:46
also can see that insulin will stimulate
00:29:48
a different enzyme called phosphatase
00:29:52
and phosphatase will also shut down the
00:29:57
activation of phosphorylase it just does
00:30:00
it at a different point in the second
00:30:04
messenger pathway by which epinephrine
00:30:06
or glucagon stimulates phosphorylase so
00:30:10
phosphatase will directly turn activated
00:30:15
phosphorylase off whereas this PDE route
00:30:20
in impairs the activation of
00:30:23
phosphorylase
00:30:24
by shutting camp down way upstream and
00:30:29
then thirdly insulin will actually
00:30:31
promote the activation of this enzyme
00:30:35
glycogen synthase and glycogen synthase
00:30:39
as its name suggests is the enzyme
00:30:42
that's going to synthesize glycogen so
00:30:52
if we turn off phosphorylase and we turn
00:30:54
on synthase that those three mechanisms
00:30:58
are certainly promoting storage putting
00:31:02
glucose molecules together into making
00:31:05
glycogen rather than breaking down
00:31:08
glycogen and using it to provide glucose
00:31:12
for either blood glucose regulation or
00:31:16
for used by the skeletal muscle cell for
00:31:18
ATP synthesis okay I had said in a
00:31:28
previous slide that skeletal muscle is
00:31:32
pretty amazing because it can feed
00:31:33
itself and if you remember what I had
00:31:36
talked about was the fact that
00:31:38
contraction mediated increases in
00:31:41
intracellular calcium can not only
00:31:45
facilitate contraction but will also
00:31:48
increase the activation of phosphorylase
00:31:52
and therefore start breaking down
00:31:55
intramuscular glycogen stores and start
00:31:59
feeding and the skeletal muscle with
00:32:02
glucose for glycolysis so increase in
00:32:05
skeletal muscle contraction is brought
00:32:09
about by an increase in intracellular
00:32:11
calcium levels inside that skeletal
00:32:14
muscle cell and that can lead to
00:32:16
contraction but it can also stimulate
00:32:20
glycogen phosphorylase
00:32:33
which is going to stimulate
00:32:36
glycogenolysis for ATP production now we
00:32:43
see a similar effect of not breaking
00:32:48
down glycogen but also the increase in
00:32:53
intracellular calcium leading to the
00:32:58
activation of those gluts for transport
00:33:02
proteins and glute for transport
00:33:10
proteins are going to increase glucose
00:33:12
uptake by the skeletal muscle cell so
00:33:20
contraction itself will lead to the
00:33:24
breakdown of skeletal muscle glycogen
00:33:25
for ATP synthesis it will also lead to
00:33:29
the uptake of available glucose from the
00:33:31
blood for ATP synthesis during
00:33:35
contraction and just like we saw with
00:33:38
the activation of the phosphorylase
00:33:41
enzyme this is mediated through that
00:33:44
increase in calcium leading to an
00:33:48
activation of calmodulin and so this
00:33:51
next slide I'll just zoom in on this
00:33:53
figure so we can look at it in a little
00:33:55
bit more detail so we have said that at
00:34:00
rest so resting skeletal muscle cells or
00:34:05
other non skeletal muscle tissue
00:34:17
insulin is required for the cell to
00:34:21
access the glucose in the blood and this
00:34:24
has a lot of detail that you don't need
00:34:26
to know but again the insulin binds to
00:34:29
its receptor mechanism it's going to
00:34:32
function via this ip3 pathway and lead
00:34:39
to the stimulation of or the activation
00:34:44
of glute 4 which is gonna migrate over
00:34:54
here and imbed itself in the membrane of
00:34:59
the cell and allow for glucose to be
00:35:04
brought from the outside to the inside
00:35:05
and so at rest we need insulin for the
00:35:10
skeletal muscle cell to be able to
00:35:12
access that glucose why does it want
00:35:14
glucose well a couple reasons it can use
00:35:18
that glucose that it just brought in to
00:35:20
make glycogen for future use or it can
00:35:24
use it for resting ATP demand and
00:35:27
perhaps more importantly it represents a
00:35:32
way in which the body can get the
00:35:34
glucose out of the bloodstream which is
00:35:36
super important for maintaining the
00:35:39
health of the blood vessels we can't
00:35:41
have real high blood glucose levels
00:35:43
during contraction though we don't need
00:35:47
insulin to be able to access glucose and
00:35:50
get it into the skeletal muscle cell and
00:35:53
thank goodness because what happens to
00:35:55
insulin levels during exercise insulin
00:35:58
goes down right we've talked already
00:36:00
about the fact that as exercise
00:36:03
increases we're gonna have a suppression
00:36:06
of insulin now if we needed insulin to
00:36:13
be able to access glucose then that
00:36:16
would be counterproductive right we're
00:36:19
suppressing the insulin so how the heck
00:36:22
do we get to the glucose and circulation
00:36:24
well fortunately again during
00:36:27
contraction when part of contraction is
00:36:30
an
00:36:30
increase in intracellular calcium levels
00:36:33
some of that calcium is going to bind to
00:36:35
troponin and enable actin and myosin
00:36:38
cross bridge formation and force
00:36:40
production but some of that calcium is
00:36:43
actually going to stimulate calmodulin
00:36:49
and that calmodulin will come down and
00:36:55
stimulate that glute 4 and cause it just
00:37:02
like we saw with insulin to translocate
00:37:04
and get over here and embed itself in
00:37:06
the membrane of the cell and again allow
00:37:10
for the diffusion of the glucose that's
00:37:13
in circulation across that cell membrane
00:37:15
into the skeletal muscle cell now
00:37:17
because this is a contracting cell what
00:37:20
is that glucose going to be used for ATP
00:37:24
synthesis it will not be used synthesis
00:37:31
for it will not be used for glycogen
00:37:35
synthesis right because this is
00:37:37
contracting we're not going to store
00:37:39
fuel while we're contracting we're going
00:37:42
to use it up well we're contracted
00:37:50
alright let's finish up these last
00:37:52
slides and just look at some trends in
00:37:56
how our regulatory and counter
00:37:58
regulatory hormones respond to exercise
00:38:01
let's first look at how they respond to
00:38:05
increases in exercise intensity and so
00:38:07
across the x-axis we've got percent of
00:38:11
vo2 max as our means of measuring
00:38:15
intensity so obviously maximal intensity
00:38:18
is down here on the right and rest is
00:38:21
down here on the left and then we have
00:38:24
the change in plasma hormone
00:38:27
concentration remember that collectively
00:38:30
epinephrine norepinephrine growth
00:38:32
hormone cortisol and glucagon are
00:38:34
together referred to as our counter
00:38:37
regulatory hormones
00:38:46
and insulin is our standalone regulatory
00:38:53
hormone and just like you would expect
00:38:58
based on what we've been talking about
00:39:01
as exercise intensity goes up we're
00:39:05
going to see a progressive increase in
00:39:07
all of those counter regulatory hormones
00:39:10
now differently as exercise intensity
00:39:14
goes down we're gonna see a progressive
00:39:16
decrease in that regulatory hormone
00:39:20
insulin now some interesting data has
00:39:24
shown that at very high exercise
00:39:27
intensities well we can actually
00:39:29
sometimes see this blip back upward in
00:39:33
insulin and this does this isn't shown
00:39:37
always or demonstrated in all data but
00:39:42
the reason why we might see a actual
00:39:47
reduction in the the decrease right and
00:39:50
and maybe even a slight increase in
00:39:52
insulin at very high exercise
00:39:54
intensities is because at those same
00:39:58
exercise intensities the counter
00:40:01
regulatory hormones have so strongly
00:40:05
stimulated hepatic glucose production
00:40:08
and that the body sometimes experiences
00:40:15
hyperglycemia
00:40:24
and again blood-glucose is a very
00:40:28
tightly regulated variable and so if
00:40:31
that is the case at those very high
00:40:33
exercise intensities if the hepatic
00:40:35
glucose production the release of
00:40:37
glucose into circulation by the liver is
00:40:40
so high then we actually may need to
00:40:44
start stimulating non contractile
00:40:47
tissues to help get some of that glucose
00:40:50
back out of the blood and try and keep
00:40:52
blood glucose levels within acceptable
00:40:55
regions but you know for the most part
00:40:59
we're gonna see insulin goes down and
00:41:02
everything else goes up as exercise
00:41:04
intensity goes up we see a similar
00:41:09
pattern in response to increases in
00:41:14
exercise duration so exercise duration
00:41:17
is down here across the x-axis and again
00:41:20
plasma hormone concentration of the
00:41:24
counter regulatory hormones and then our
00:41:26
regulatory hormone insulin here on the y
00:41:30
axis and again know that is the arrival
00:41:35
of the mailman Sofie can't stand the
00:41:39
mailman okay so again as exercise
00:41:43
duration this time increases we see a
00:41:47
progressive ink Lea increase in our
00:41:50
counter regulatory hormones and a
00:41:52
progressive decrease in our regulatory
00:41:54
hormone insulin now the last concept I
00:42:02
want to leave you with is this idea that
00:42:06
one of the main effects of chronic
00:42:10
exercise training is that exercise
00:42:17
becomes less of a stressor now remember
00:42:29
the sympathetic nervous system responds
00:42:33
to stress
00:42:34
right increase stress increase SNS
00:42:40
activity
00:42:41
it's fight-or-flight and stress is
00:42:43
stress it's not going to be able to
00:42:45
differentiate between holy crap I've got
00:42:47
four midterms today and oh I'm going out
00:42:51
for an exercise or a jog or or run up a
00:42:57
hill or something right stress is stress
00:42:58
so when exercise intensity or duration
00:43:02
goes up we see an increase in
00:43:06
sympathetic nervous system activity
00:43:08
however as you do more exercise this
00:43:14
increase becomes attenuated or lessened
00:43:19
so that instead of looking like that
00:43:23
we've got an increase in exercise
00:43:25
instead of SNS coming up dramatically we
00:43:29
might see a small increase in
00:43:31
sympathetic nervous system activity and
00:43:33
so this is pre-training
00:43:39
and this is post training and I you know
00:43:47
I joke sometimes but it's true if you
00:43:50
take somebody who's been habitually
00:43:52
sedentary or sedentary for a fairly
00:43:54
prolonged period of time and they
00:43:56
undertake an exercise session the body
00:43:59
will literally respond in the same way
00:44:03
that it would respond to any other
00:44:05
life-threatening stressor and exercise
00:44:10
can be interpreted as a life-threatening
00:44:13
experience especially if it if it's not
00:44:16
something that the person ever does but
00:44:19
if they keep exercising adaptations to
00:44:23
training will dampen or attenuate that
00:44:28
flight or flight response and that's
00:44:30
reflected in a an overall reduction I
00:44:35
got a cough hold on
00:44:38
sorry a small with me not lower a
00:44:42
smaller increase in epi and nor epi okay
00:44:56
so remember that a lot of the influence
00:45:01
of exercise on our counter regulatory
00:45:03
hormones was facilitated by the increase
00:45:08
in epi and norepi so if you don't
00:45:12
produce as much epi and nor epi because
00:45:15
you are trained then in turn you're not
00:45:20
gonna produce as much of the counter
00:45:23
regulatory hormones and you're not gonna
00:45:26
suppress the regulatory hormone as much
00:45:29
and so that's what we're seeing on these
00:45:32
figures so before training in an
00:45:36
untrained person exercise starts
00:45:42
increase in sympathetic nervous system
00:45:46
activity is going to increase norepi
00:45:50
and epi and what's that going to do
00:45:54
that's going to cause counter regulatory
00:45:57
glucagon to also increase dramatically
00:46:00
right but following training
00:46:10
exercise starts and you've got a smaller
00:46:14
increase in SNS activity you've got a
00:46:18
smaller increase in norepinephrine and
00:46:22
epinephrine and look the the effect
00:46:25
downstream on the pancreatic alpha cells
00:46:30
is a very flatlined response to plasma
00:46:35
glucagon remember that glucagon is
00:46:37
redundant in its effects on mobilizing
00:46:42
fuel and so maybe this is just
00:46:44
reflective that you know the influence
00:46:47
the increase in norepinephrine and
00:46:48
epinephrine are doing just fine on their
00:46:51
own mobilizing fuel and we really don't
00:46:53
need to see a big change in in glucagon
00:46:57
levels okay and so just like we see a
00:47:01
smaller increase in glucagon we're gonna
00:47:07
see a smaller decrease in insulin so
00:47:11
again in the untrained state we're gonna
00:47:13
see a stronger decrease in insulin as
00:47:15
exercise progresses and in a trained
00:47:19
state you don't have to reduce insulin
00:47:22
so much to meet the demands of exercise
00:47:29
and sure enough just like I suggested in
00:47:34
that previous slide these are this is
00:47:36
looking at the effects of training on
00:47:42
exercise induced changes in
00:47:44
norepinephrine and epinephrine and so
00:47:46
certainly in the first few weeks of
00:47:51
exercise training we see that when
00:47:54
exercise starts both epi and norepi
00:47:57
levels rise significantly and that keeps
00:48:01
happening for several weeks and then
00:48:04
over time as the body goes ooh hoo
00:48:06
she's just exercising again it's not
00:48:09
literally life or death situation I'm
00:48:12
not actually needing to fight or flee I
00:48:15
am just exercising and so as a result
00:48:18
there is a much smaller chain
00:48:22
in norepinephrine and epinephrine
00:48:24
following training and that collectively
00:48:27
reflects a reduced overall sympathetic
00:48:31
nervous system response to exercise why
00:48:38
is that exercise is less of a stressor
00:48:49
when you were trained alright folks
00:49:01
that's it
00:49:03
you made it congratulations

Etiquetas

catécholamines
métabolisme
exercice
hormones
insuline
glucagon
cortisol
mobilisation
glycogène
lipides