Inona no atao hoe transaminasa amin'ny asidra alanine amin'ny resaka fanodinkodinam-bozika amin'ny asidra?

Ny transaminasa amin'ny asidra alanine dia manala ny vondrona amine avy amin'ny alanine ary manome azy azy amin'ny alpha-ketoglutarate, izay mivadika ho glutamate.

Inona ny alanine sy ny alpha-ketoglutarate no afaka mivadika ho azy?

Alanine dia mivadika ho pyruvate ary alpha-ketoglutarate mivadika ho glutamate.

Inona no atao hoe oxidative deamination ao amin'ny glutamate?

Ny oxidative deamination dia dingana izay manala ny vondrona amine avy amin'ny glutamate ary mamorona ammonia, miaraka amin'ny famokarana alpha-ketoglutarate.

Aiza no mitranga mazàna ny oxidative deamination?

Ny oxidative deamination dia mitranga indrindra ao amin'ny aty satria misy famokarana ammonia, izay mila avotana ho lasa urea.

Inona no mety afaka mivadika ho glucose amin'ny dingana glycolysis tsy avy amin'ny glucosa fotsiny?

Ny amino amin'ny asidra toy ny alanine sy ny aspartate dia afaka mivadika ho glucose amin'ny alalan'ny gluconeogenesis.

Metabolism | Amino Acid Metabolism

00:27:28

https://www.youtube.com/watch?v=0M-B2dOfcUo

Résumé

TLDRIty horonantsary ity dia mamelabelatra ny metabolism amin'ny asidra amino, izay singa fototry ny sela mba hiteraka angovo. Izy io dia miompana indrindra amin'ny dingana transaminasyon ao amin'ny hozatra sy ny fidiran-dra ao amin'ny aty. Rehefa tahirizina ny amino asidra ao amin'ny hozatra, ny alanine sy ny alpha-ketoglutarate no mihetsika amin'ny transaminasy manoloana ny pyruvate sy ny glutamate. Ny pyruvate dia afaka mivadika ho lactic acid na acetyl CoA, izay mampiditra ny tsingerina Krebs sy ny tsingerina elektronika ho matin'ny ATP. Mandritra izany fotoana izany, ny glutamate voaova tao amin'ny asidra amin'ny alfa koa dia maneho "deaminasy oxidatif" mba hamorona ketona alfa ary hamoaka amoniaka, izay afa-mivoaka amin'ny angovo haingana raha toa ka ao anaty aty no misy azy. Ny amino amin'ny asidra dia azo ampiasaina amin'ny dingana gluconeogenesis mba hanodinana glucose avy amin'ny loharano tsy avy amin'ny tontolo karbonina fotsiny, manambara fanamaivanana goavana ho an'ny fandriampahalemana metabolika sy ny famerenan'ny tavy simika entina manampy.

A retenir

🔄 Ny alanine dia afaka mivadika ho pyruvate sy ny alpha-ketoglutarate ho glutamate.
⚙️ Ny transaminasa amin'ny asidra dia mivoaka amin'ny asidra amin'ny alalan'ny enzyme manokana.
🧬 Ny glutamate dia miditra amin'ny deaminasy oxidatif ary miaraka aminy no mamoaka amoniaka.
📈 Ny lactate dia afaka mivadika ho glucose amin'ny aty.
🔍 Ny asidra amin'ny tahiry dia manosika ny glucogenic pathways.
💬 Ny fahitana enzyme amin'ny rà dia mety manondro fahasimban'ny organa.
💪 Ny tsingerina Krebs dia mampiasa ny pyruvate sy ny acetyl CoA ho an'ny ATP.
🌀 Ny fanodinana asidra amin'ny pyruvate dia mitarika amin'ny lactate na acetyl CoA.
🌐 Ny asidra amin'ny asidra dia afaka mamokatra angovo.
🚨 Ny amoniaka dia mila avotana satria mampidi-doza izany.

Chronologie

00:00:00 - 00:05:00
Amin'ny asidra amines, ny alany mena ao amin'ny hozatra dia mihatra amin'ny transamination miaraka amin'ny alpha-ketoglutarate amin'ny alany aminotransaminase, manova ny alany ho pyruvate ary miteraka glutamate.
00:05:00 - 00:10:00
Ny pyruvate vokarin'ny transamination dia mety ho lasa lactic acid na acetyl-CoA, miteraka ATP amin'ny lalan'ny Krebs sy ny electron transport chain. Ny lactic acid dia miditra amin'ny ra ary mamorona glucose, manohana ny gluconeogenesis.
00:10:00 - 00:15:00
Ny glutamate dia entina any amin'ny atiny, mamoaka amoniaka alohan'ny hidirana amin'ny tsingerina ura amin'ny oxidative deamination miaraka amin'ny glutamate dehydrogenase, miantoka ny fanesorana ny amoniaka.
00:15:00 - 00:20:00
Ny aspartate, toy ny alany, dia miatrika transamination amin'ny aspartate aminotransferase, mamorona oxaloacetate ary mihatra ao amin'ny Tsingerin'ny Krebs na gluconeogenesis.
00:20:00 - 00:27:28
Amin'ny tetikasan'ny asidra amines, asidra ensamblin'asa amin'zava-maniry samihafa no mampiavaka azy amin'ny famoronana angovo (ATP) na glucose, miaraka amin'ny voka-dratsy mety amin'ny fanandramana ALT sy AST ra, hilazana ny ratra amin'ny atiny na ny fo.

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Carte mentale

Vidéo Q&R

Inona no atao hoe transaminasa amin'ny asidra alanine amin'ny resaka fanodinkodinam-bozika amin'ny asidra?
Ny transaminasa amin'ny asidra alanine dia manala ny vondrona amine avy amin'ny alanine ary manome azy azy amin'ny alpha-ketoglutarate, izay mivadika ho glutamate.
Inona ny alanine sy ny alpha-ketoglutarate no afaka mivadika ho azy?
Alanine dia mivadika ho pyruvate ary alpha-ketoglutarate mivadika ho glutamate.
Inona no atao hoe oxidative deamination ao amin'ny glutamate?
Ny oxidative deamination dia dingana izay manala ny vondrona amine avy amin'ny glutamate ary mamorona ammonia, miaraka amin'ny famokarana alpha-ketoglutarate.
Aiza no mitranga mazàna ny oxidative deamination?
Ny oxidative deamination dia mitranga indrindra ao amin'ny aty satria misy famokarana ammonia, izay mila avotana ho lasa urea.
Inona no mety afaka mivadika ho glucose amin'ny dingana glycolysis tsy avy amin'ny glucosa fotsiny?
Ny amino amin'ny asidra toy ny alanine sy ny aspartate dia afaka mivadika ho glucose amin'ny alalan'ny gluconeogenesis.

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Sous-titres

Défilement automatique:

00:00:07
all right Niners in this video we're
00:00:08
going to talk about amino acid
00:00:10
metabolism so specifically when we talk
00:00:12
about amino acids we're going to have to
00:00:14
look at each you know a couple different
00:00:16
amino acids how they're actually being
00:00:18
metabolized and utilized for energy okay
00:00:21
so we're going to kind of take what's
00:00:23
happening here we're going to take some
00:00:24
amino acids that are going to be in the
00:00:26
muscle we're going to undergo a
00:00:27
transamination process and then we're
00:00:29
going to see how what's going to happen
00:00:31
afterwards in the liver okay so first
00:00:34
thing you know there's going to be a lot
00:00:35
of different amino acids that can be
00:00:36
found within our actual muscle here
00:00:37
because you know you need amino acids
00:00:39
for protein synthesis right so let's say
00:00:41
that I have certain types of amino acids
00:00:43
in this area let's say I take for a
00:00:44
specific one for example let's say I
00:00:47
take alanine so I'm going to draw the
00:00:49
basic structure of alanine so you can
00:00:50
remember an amino acid always has what's
00:00:52
called a n c c on this end it's going to
00:00:57
have a NH3 group with a plus
00:01:00
charge and then it's going to have a
00:01:02
alpha hydrogen and then for this case
00:01:05
for alanine it has a methyl group okay
00:01:08
so then it has that methyl group now
00:01:10
another thing about the alanine is it
00:01:12
has a
00:01:13
carboxin has a carboxin now this is
00:01:17
going to be the zwitter iion form of
00:01:19
alanine zwitter iion meaning it has a
00:01:21
plus and negative charge but the overall
00:01:23
charge is neutral this right here is
00:01:25
going to be
00:01:27
alanine you know what I can do with this
00:01:30
alanine I can utilize it for energy when
00:01:32
it's the body I'm going to take this
00:01:34
alanine and I'm going to react with
00:01:36
another molecule I'm going to react with
00:01:38
a very specific molecule and that
00:01:41
molecule is going to be called Alpha
00:01:44
ketoglutarate so you know Alpha glut8 is
00:01:47
going to have something like this so
00:01:49
you're actually going to for example you
00:01:50
know it's actually derived from uh
00:01:52
specifically glutamat so let's say I
00:01:53
have an NH3 group here for a second then
00:01:56
I have this carbon here with the
00:01:58
hydrogen then I have the carboxy group
00:02:02
and then usually it actually is coming
00:02:03
from glutamate which is
00:02:05
ch2 ch2 and then it has a carboxy group
00:02:09
over here okay but instead of having
00:02:13
this amine group Alpha ketoglutarate
00:02:15
just has a double bond here so you're
00:02:18
going to have a double bond right there
00:02:20
and this is going to be specifically our
00:02:22
Alpha
00:02:23
ketoglutarate this is our Alpha
00:02:24
ketoglutarate right here so who is this
00:02:26
molecule this is
00:02:27
specifically Alpha Keto glutarate I'm
00:02:30
going to just denote it a k g Alpha
00:02:34
ketoglutarate what happens is I'm going
00:02:36
to have a specific enzyme and what this
00:02:38
enzyme is going to do is it's going to
00:02:40
take this alanine and it's going to take
00:02:41
these Al this Alpha ketoglutarate and
00:02:43
it's going to react with both of them so
00:02:45
let's say that I take for example here I
00:02:47
take alanine and I take Alpha
00:02:48
ketoglutarate and what I'm going to do
00:02:50
is I'm going to react these puppies in a
00:02:53
special enzyme so for example I'm going
00:02:55
to take here let's say here is
00:02:57
my enzyme okay on one pocket I'm going
00:03:02
to have the alpha ketoglutarate so for
00:03:04
right now I'm just going to show Alpha
00:03:06
ketoglutarate
00:03:08
here okay in the other pocket I'm going
00:03:11
to have over here
00:03:15
alanine you know what I'm going to have
00:03:17
right here in the middle let's fix our
00:03:18
alanine there guys that should be a l a
00:03:21
n i e right then if what I'm going to do
00:03:24
is right here in the middle I'm going to
00:03:25
have a special molecule this special
00:03:27
molecule is going to be called parox
00:03:30
phosphate you know paradoxal phosphate
00:03:32
is actually a derivative from vitamin
00:03:35
B6 you know what happens here what's
00:03:38
special about this alanine this alanine
00:03:41
has a amine group that's what makes him
00:03:43
really really
00:03:45
special and this Alpha ketoglutarate has
00:03:47
this specialized
00:03:50
oxygen what happens is this paradoxal
00:03:53
phosphate is going to act as the
00:03:54
transferring structure because you know
00:03:56
this parod oxal phosphate is actually
00:03:57
linked with this enzyme through what's
00:03:59
called a sh shift based linkage shift
00:04:01
Bas linkage now remember it's not what
00:04:02
you think it is it's called
00:04:05
shift
00:04:07
base okay so this enzyme right here is
00:04:10
linked to that perod oxal phosphate
00:04:12
through a shift base linkage you know
00:04:14
what that is uh just by structure you
00:04:17
never heard what's called an an emine
00:04:19
this is from organic chemistry an emine
00:04:22
an emine is just basically when you have
00:04:23
a carbon here double bonded to a
00:04:25
nitrogen like this who could be bound to
00:04:28
maybe like should say a methyl for that
00:04:29
case and who's going to have some type
00:04:31
of General structure like this this is
00:04:32
an
00:04:33
emine that is how this enzyme is linked
00:04:36
to the paradoxal phosphate through a
00:04:38
shift based linkage now what this enzyme
00:04:41
does is it takes the amine group from
00:04:43
the allany and gives it to the paradoxal
00:04:45
phosphate then this paradoxal phosphate
00:04:48
takes that amine and gives it to the
00:04:50
alpha
00:04:51
ketoglutarate then another thing that
00:04:53
happens this Alpha ketoglutarate gives
00:04:55
his oxygen onto the parod oxal phosphate
00:04:58
and the paradoxal phos phate gives this
00:05:00
oxygen onto the
00:05:01
alanine so in other words these two
00:05:04
molecules are just swapping what let me
00:05:07
Circle What specifically is being
00:05:08
swapped this is being
00:05:10
swapped and this is being swapped and as
00:05:14
a result look what happens as a result
00:05:15
of these two molecules reacting here so
00:05:18
I'm going to take this guy here and I'm
00:05:20
going to take this guy
00:05:22
here and you're going to get two new
00:05:24
molecules now question is what is the
00:05:28
name of this enzyme that's actually
00:05:30
causing this process to
00:05:31
occur we're going to abbreviate it
00:05:34
called
00:05:35
alanine so Al
00:05:39
Amino trans trans aminase so alanine
00:05:43
Amino trans aminase so this is a
00:05:45
transaminase enzyme so again what is
00:05:47
this enzyme here called specifically
00:05:49
he's called
00:05:53
alanine
00:05:56
Amino transferase or transaminase so
00:05:59
we're going to stick with
00:06:02
trans
00:06:03
aminase okay what is this enzyme going
00:06:07
to do he's going to take the amine group
00:06:08
from the alanine give it to the
00:06:09
paradoxal phosphate who gives it to the
00:06:11
alpha ketoglutarate the alpha
00:06:13
ketoglutarate is going to give the
00:06:14
paradoxal phosphate its oxygen which is
00:06:15
going to give it to the alany as a
00:06:17
result these two guys are going to swap
00:06:20
now look what happens to the alany now
00:06:23
this alany is now going to have a double
00:06:24
bond oxygen right there so now you're
00:06:26
going to have a carbon double bond
00:06:28
oxygen with the methyl group and then
00:06:31
what carbon double bond oxygen if you
00:06:35
guys know a little bit about your
00:06:36
structures here from biochemistry this
00:06:39
right here is pyruvate how many carbons
00:06:41
is it one two three I know we've show it
00:06:44
showed it simply which just circles but
00:06:46
this is specifically pyruvate that is
00:06:53
pyruvate
00:06:54
now I have this pyruvate here that I
00:06:57
under had underwent this process called
00:06:59
called transamination all this
00:07:01
transamination process is is that this
00:07:03
alanine is doing what he's giving his
00:07:06
amine group to Alpha ketoglutarate then
00:07:08
what this Alpha ketoglutarate is doing
00:07:11
what he's giving his oxygen to the
00:07:12
alamine and this Alpha ketoglutarate is
00:07:14
becoming a new molecule so now wherever
00:07:16
this oxygen is put an amine group and
00:07:19
what are you going to get out of this
00:07:22
process so now we're going to get rid of
00:07:24
that actual oxygen group and we're just
00:07:26
going to replace it with a amine group
00:07:29
then we're going to have over here we're
00:07:30
going to have the carboxy end so just
00:07:33
the co negative here I'll put the double
00:07:34
bond for those of you who want to see it
00:07:37
I'm put the double bond oxygen with the
00:07:38
O negative charge and then coming down
00:07:41
what am I going to have I'm going to
00:07:42
specifically have a hydrogen right here
00:07:44
and then a
00:07:45
ch2
00:07:48
ch2 and then a carboxy Groove you know
00:07:50
what this molecule is called this
00:07:52
molecule is called
00:07:54
glutamate this molecule is called
00:07:58
glutamate
00:08:00
okay so what happened within this
00:08:01
process and what is this process here
00:08:02
called let's define what this process is
00:08:04
called This is called
00:08:07
trans
00:08:10
amination all trans amination is is I am
00:08:15
taking the amine group from an amino
00:08:17
acid in this case it just so happened to
00:08:19
be alanine it could be many many
00:08:21
different types of amino acids so I can
00:08:23
take this am group from the alanine and
00:08:26
I'm going to transfer it to who to this
00:08:28
keto acid what is this keto acid called
00:08:30
Alpha ketoglutarate so this is called a
00:08:33
keto
00:08:34
acid keto acid you might recognize him
00:08:39
as a kreb cycle intermediate so he's a
00:08:41
kreb cycle intermediate then this Alpha
00:08:44
ketoglutarate is giving his oxygen to
00:08:45
the alanine and then this alanine will
00:08:47
turn into
00:08:48
pyruvate and then when the alpha
00:08:50
ketoglutarate gains that Aman group he
00:08:52
will turn into glutamate now this
00:08:55
process is catalyzed by a alanine aminot
00:08:58
transferase enzyme which is having a
00:09:00
shift based linkage with the paradoxal
00:09:02
phosphate all a shift based linkage is
00:09:04
is it's just going to be an emine and an
00:09:06
amine is just the carbon double bounded
00:09:07
to a nitrogen right in this
00:09:09
form then this paradoxal phosphate is
00:09:12
playing a very important role in being
00:09:14
able to transfer the amine to one guy
00:09:16
and then the oxygen to the other guy now
00:09:20
we what can we do with this pyruvate and
00:09:21
what can we do with this glutamate
00:09:22
that's the question now in the muscle
00:09:24
cell you know what you can do with
00:09:25
pyruvate what can I do with the pyruvate
00:09:26
in the muscle cell you know I can take
00:09:28
this pyruvate
00:09:30
and I can do two things with him one
00:09:32
thing is I can convert him into lactic
00:09:36
acid okay and then the other component
00:09:39
is I can take and convert him into
00:09:42
acetal COA where can acetyl coo it can
00:09:45
go into the you already know this guys
00:09:48
the kreb cycle and then from the kreb
00:09:50
cycle you can go to the electron
00:09:52
transport chain and then the electron
00:09:54
transport chain will allow for the
00:09:55
production of
00:09:58
ATP so look what I just did there with
00:10:00
this whole transamination process I did
00:10:02
I did two things one is I turned alanine
00:10:05
into pyruvate that pyruvate can then do
00:10:07
what it can get converted into lactic
00:10:09
acid or it can get converted into acety
00:10:11
COA the acetylcoa pathway will
00:10:13
ultimately lead to the production of ATP
00:10:15
energy production what will happen with
00:10:17
this lactic acid watch this you guys
00:10:20
remember this this is called the Corey
00:10:23
cycle what happens with the lactic acid
00:10:25
you know the lactic acid is going to do
00:10:26
what it's going to come into the blood
00:10:28
and we're going to we're going to zip
00:10:29
through this guys so what happens with
00:10:30
the lactic acid the lactic acid is going
00:10:32
to be what it's going to be converted
00:10:34
into pyruvate in the liver you know by
00:10:37
specifically by the lactate
00:10:39
dehydrogenase enzyme it's stimulating
00:10:41
this step and it's taking NAD D what NAD
00:10:45
positive and converting it into NAD H
00:10:50
then we're taking that pyruvate and
00:10:51
we're doing what we're converting it
00:10:52
eventually into glucose six phosphate
00:10:55
and then only in the liver do they have
00:10:57
that specialized enzyme let's put that
00:10:59
enzyme here in red this enzyme is called
00:11:02
glucose
00:11:03
6
00:11:06
phosphatase and this enzyme is
00:11:07
stimulating this step and then what are
00:11:09
you going to get as a result here you
00:11:11
can get free
00:11:13
glucose and that can get taken back into
00:11:15
the muscle right through the Corey cycle
00:11:17
what is the whole purpose of this I
00:11:18
helped with this process of
00:11:21
gluconeogenesis so what are the two
00:11:23
Fates then so far of this actual
00:11:25
transamination process one is that can
00:11:28
lead to the formation pyruvate and that
00:11:29
pyruvate can either go and make ATP
00:11:32
energy formation the second thing is I
00:11:34
can make lactic acid and that lactic
00:11:36
acid can do what it can get taken up by
00:11:38
the liver and get converted into glucose
00:11:41
with this glucose 6 phosphatase enzyme
00:11:42
being present and this is called glucon
00:11:46
neogenesis okay what about this
00:11:48
glutamate what's so special about him
00:11:50
what can happen with this glutamate
00:11:52
let's come over here and let's bring
00:11:53
this glutamate over to the liver because
00:11:55
that's what he's going to do he's going
00:11:56
to come from the muscles or even other
00:11:58
different tissues cells and come to the
00:12:00
liver okay so now we're going to have
00:12:02
this glutamate that we brought over from
00:12:03
the muscle so this glutamate it has that
00:12:06
Amin group right there right that amine
00:12:08
group is going to be very very special
00:12:10
because we're going to want to get rid
00:12:10
of it okay so now how does this happen
00:12:14
okay there's a special special pathway
00:12:16
here and we have to be very very uh
00:12:18
particular about this pathway let's make
00:12:20
this a blue line here okay what happens
00:12:23
here is there's going to be a special
00:12:26
enzyme involved in this pathway and
00:12:29
what's going to happen here is I'm going
00:12:31
to take
00:12:33
NAD P positive okay you guys have
00:12:37
probably not seen this one yet this is a
00:12:39
very very whenever it forms this next
00:12:41
molecule because what will'll happen is
00:12:42
it'll come into this reaction and
00:12:44
generate
00:12:47
nadph this molecule nadph is a very
00:12:51
strong
00:12:52
reducing agent we use this in a lot of
00:12:56
fatty acid synthesis Pathways and for
00:12:58
free radical reactions that we'll talk
00:13:01
about okay what I'm going to do is I'm
00:13:03
going to take this molecule here who is
00:13:05
this molecule again this is our
00:13:06
glutamate which is coming from the
00:13:07
muscles and it can be coming from other
00:13:09
tissues I just picked the muscles as a
00:13:12
specific example but many many many
00:13:14
tissues do this transamination process
00:13:16
that we talked about but now glutamate
00:13:19
which is coming from the muscles it's
00:13:20
going to get acted on by a specific
00:13:22
enzyme in this area that's going to have
00:13:23
nadp positive get converted into nadph
00:13:26
which is a reducing agent for fatty acid
00:13:28
synthesis and and specific free radical
00:13:30
reactions the enzyme catalyzing this
00:13:33
pathway is called
00:13:38
glutamate
00:13:41
dehydrogenase this enzyme is super
00:13:43
important because glutamate dehydrogen
00:13:46
is going to do two things one is it's
00:13:47
going to get rid of this amine group so
00:13:49
you see this amine group right here
00:13:51
we're going to chop that sucker off and
00:13:54
we're gonna release that amine group off
00:13:56
of this so you know what else we're
00:13:57
going to lose as a result of this let's
00:13:59
bring this Arrow up a little bit more
00:14:01
and look what's going to happen as a
00:14:02
result two things are going to
00:14:05
happen Okay I'm going to release out of
00:14:08
this this
00:14:10
what ammonia
00:14:13
molecule oh man ammonia is extremely
00:14:17
extremely toxic extremely toxic we'll
00:14:20
talk about
00:14:21
why but then what happens is this
00:14:23
glutamate dehydrogenase enzyme is going
00:14:25
to help to bring nadp positive to nadph
00:14:28
and then convert
00:14:29
this it goes through another mechanism
00:14:31
it actually goes through another
00:14:33
mechanism but we're going to go straight
00:14:34
to it because it actually has to get
00:14:35
hydrated for a second step this is a
00:14:36
two-step mechanism but we're just going
00:14:38
to go straight to the end step where we
00:14:40
remove the am group off and we add water
00:14:42
so we're going to add water into this
00:14:43
reaction when we add water into this
00:14:46
reaction you're going to get a special
00:14:48
molecule look what you're going to get
00:14:50
you guys are going to love this look you
00:14:52
get your carbon double bond oxygen ch2
00:14:57
ch2 and then the carboxy group right
00:15:00
there then I'm going to get another
00:15:02
carboxy group right over
00:15:04
here this molecule is called you already
00:15:07
know what this one is that's Alpha
00:15:08
ketoglutarate so this molecule right
00:15:10
here is specifically
00:15:12
called
00:15:14
Alpha
00:15:17
keto
00:15:20
glutarate okay now we will talk about
00:15:23
this ammonia in another individual video
00:15:27
because what's going to happen is this
00:15:28
Ammon
00:15:29
is extremely extremely extremely toxic
00:15:32
so this ammonia you know he's actually
00:15:34
going to react with a proton and when he
00:15:36
reacts with the proton he forms ammonium
00:15:39
and then ammonium is actually going to
00:15:40
go into our mitochondria we'll undergo
00:15:43
the Ura cycle and we'll talk about that
00:15:44
in individual video but we can do
00:15:47
something else you see this Alpha
00:15:48
ketoglutarate that we actually made from
00:15:51
this converting glutamate into Alpha
00:15:53
ketoglutarate with the presence of
00:15:54
glutamate dehydrogenase and N positive
00:15:56
to
00:15:57
NPH this reaction here this whole
00:16:01
process that we just discussed this
00:16:03
whole
00:16:04
process is called
00:16:09
oxidative
00:16:12
deamination okay this is called
00:16:13
oxidative deamination oxidative
00:16:16
deamination is where you're taking
00:16:17
glutamate and specifically this is
00:16:19
occurring mainly in the
00:16:21
liver and the reason why is because
00:16:23
you're generating ammonia and you want
00:16:24
ammonia to be taken into specifically
00:16:26
into the mitochondria but this can
00:16:27
oxidative damage can occur in other
00:16:29
tissues like the muscles just not as
00:16:32
significantly but oxidated deamination
00:16:34
is where you're taking glutamate
00:16:35
removing the amine group and releasing
00:16:37
it out as ammonia and ammonia is
00:16:39
extremely toxic it'll combine
00:16:41
with this is ammonia and which is
00:16:44
extremely toxic it'll combine with the
00:16:46
proton to make
00:16:47
ammonium and then ammonium can actually
00:16:50
be taken into the mitochondria and
00:16:53
eventually convert into Ura this
00:16:55
glutamate dehydrogenase and this nadp
00:16:57
positive to n pH which is a reducing
00:16:59
agent whenever it's ripping that am
00:17:01
Groove off it's regenerating Alpha
00:17:04
ketoglutarate now you know there's other
00:17:06
different types of amino acids that can
00:17:08
undergo this transamination process so
00:17:11
now you know what I'm going to do with
00:17:12
this Alpha ketoglutarate I'm going to
00:17:13
react him with a special amino acid so
00:17:17
let's say I take and I draw a sparate so
00:17:18
you know sparate is going to have it's
00:17:20
very similar to glutamate you have the
00:17:22
amine group here again and then remember
00:17:26
carboxy group but then it's just in
00:17:28
instead of two ch2s it goes straight ch2
00:17:30
to
00:17:32
carboxin this right here is a sparate
00:17:36
all right or aspartic acid right but in
00:17:38
this case since he's in the B the base
00:17:39
form this is aspartate if he had the
00:17:41
hydrogen there he'd be as spartic acid
00:17:43
but specifically we're going to call
00:17:46
this aspartate or sometimes they call it
00:17:49
you know if I'm pronouncing it wrong
00:17:51
they be call aspartate but now what I'm
00:17:53
going to do is I'm going to take the
00:17:54
aspartate I'm going to react it with the
00:17:56
alphaet glutarate so now let me draw
00:17:57
this alphaet glutarate from this
00:17:58
reaction that we generated up here so
00:18:01
now I'm going to have this carbon double
00:18:04
bond oxygen specifically with a carox
00:18:06
group then I'm going to have ch2 ch2 and
00:18:10
another carboxy group and this molecule
00:18:13
was specifically called
00:18:15
Alpha
00:18:18
ketoglutarate now what I'm going to do
00:18:20
is I'm going to do the same reaction
00:18:21
that you guys saw before so what I'm
00:18:23
going to do is is I'm going to take
00:18:25
these two guys
00:18:27
aspartate and Alpha toluate and I'm
00:18:29
going to react them with each
00:18:32
other and if you guys remember there's
00:18:35
an enzyme that's catalyzing this process
00:18:38
we're not going to go back into the
00:18:40
mechanism because you guys should
00:18:40
already know it but this
00:18:43
enzyme is actually going to be
00:18:45
specifically dealing with aspartate and
00:18:47
specifically transferring the amine
00:18:48
group from the aspartate to the alpha
00:18:51
ketoglutarate and transferring the
00:18:52
oxygen from alpha lutate onto aspartate
00:18:55
so this enzyme is called
00:18:57
aspartate Amino transferase a and again
00:19:01
what is the name of this enzyme called
00:19:03
it's called
00:19:07
aspartate Amino and then specifically
00:19:10
you can call it trans aminase but I
00:19:12
believe it is interchangeable with
00:19:14
transas because what it's doing is it's
00:19:16
doing what what's in here in the center
00:19:18
which connected through that shift based
00:19:20
linkage the perod oxal phosphate and
00:19:23
then what would you have over here you
00:19:24
could have a sparate I'm going to put
00:19:26
ASP and then over here I can have Alpha
00:19:29
ketoglutarate I'm going to put AKG and
00:19:32
if I have this Alpha ketoglutarate over
00:19:34
here what's special about the aspartate
00:19:38
the aspartate if you guys remember has
00:19:40
the amine group coming off of it so it
00:19:42
has this amine group and then this
00:19:45
alphaet glate has that oxygen what
00:19:47
happens they're swapping so this
00:19:50
transaminase enzyme is taking the aming
00:19:52
from the aspartate giving it to
00:19:53
paradoxal phosphate who gives it to
00:19:55
Alpha ketoglutarate then the alpha
00:19:57
kogate is giving the oxygen to perod
00:19:58
oxal phosphate who's giving it to
00:20:00
aspartate aspartate will gain the oxygen
00:20:02
and look what happens as a result so get
00:20:04
rid of this amine group and that
00:20:05
hydrogen and then look what happens
00:20:08
double bond oxygen carboxy group
00:20:11
ch2 Co
00:20:14
negative and then look what I get out of
00:20:16
this I put an amine group there you guys
00:20:19
already know this molecule look at this
00:20:21
guy I put a
00:20:23
NH3 positive group a hydrogen my carboxy
00:20:27
group
00:20:29
ch2
00:20:30
ch2 carboxy group what is this molecule
00:20:34
that I formed here this molecule is
00:20:36
called glutamate we already talked about
00:20:40
him this is glutamate what is this one
00:20:43
called this one is called
00:20:47
oxaloacetate okay where can oxaloacetate
00:20:50
go if you guys remember let me move this
00:20:54
mitochondria out of the way so that we
00:20:56
can look at this because you guys will
00:20:57
know we'll talk about urea CLE
00:20:58
specifically afterwards if you guys
00:21:00
remember really really quickly you have
00:21:03
aetl COA then you have oxaloacetate
00:21:07
which combines with acetyl COA to make
00:21:10
citrate citrate gets converted into
00:21:13
isocitrate isocitrate gets converted
00:21:15
into Alpha deuterate then into suxin COA
00:21:18
then into soate then into fumate and
00:21:23
then into malate and then into
00:21:27
oxaloacetate
00:21:28
if you guys remember we took what we
00:21:31
took the pyruvate right we have pyruvate
00:21:34
coming into this
00:21:36
guy who funneled into pyruvate who do we
00:21:39
actually undergo this transamination
00:21:41
process to make pyruvate we had alanine
00:21:44
all n he can get converted into pyruvate
00:21:47
through this transamination process then
00:21:50
oh a sparate I could take a
00:21:55
sparate and I could undergo
00:21:57
transamination process to to make him oh
00:22:00
what about glutamate you know glutamate
00:22:01
can do the same process also what can
00:22:03
glutamate form if he undergoes
00:22:05
transamination processes because you
00:22:07
know this reaction here where you take
00:22:08
glutamate and
00:22:09
oxaloacetate being formed from aspartate
00:22:11
and Alpha deuterate
00:22:15
really this is reversible and the same
00:22:18
way this is reversible what do you think
00:22:20
over here is going to be over here is
00:22:22
also reversible so not only can I take
00:22:25
alanine and Alpha ketoglutarate to make
00:22:28
pyruvate and glutamate but I can take
00:22:30
glutamate and pyruvate to make alanine
00:22:32
and Alpha ketoglutarate that is so
00:22:34
beautiful that this enzyme is reversible
00:22:36
and it can allow for this process as
00:22:39
well as this enzyme so that means what
00:22:42
that means that glutamate can react with
00:22:44
oxaloacetate to make aspartate and Alpha
00:22:47
glutarate so that means glutamate can
00:22:49
feed into this one
00:22:51
here what this is showing you is is
00:22:54
something very very interesting that I
00:22:56
can take a sparate and convert into OA I
00:22:58
can take alanine converted into pyruvate
00:23:00
I can take glutamate and converted into
00:23:01
Alpha hutter you know there's many many
00:23:03
many amino acids that you can use in
00:23:05
different steps so many different amino
00:23:07
acids but you know these aren't the only
00:23:09
amino acids that can be involved in this
00:23:11
process there's so many other amino
00:23:12
acids we're not going to go over every
00:23:14
single one of them but to give you an
00:23:16
example you know fate I can actually
00:23:19
utilize a specific amino acid called
00:23:21
tyrosine and I could take tyrosine I can
00:23:23
convert him into fate through different
00:23:24
types of mechanisms I could make suino
00:23:27
COA I could do this through specific
00:23:28
types of mechanism utilizing veine so I
00:23:32
could take veine and convert that into
00:23:33
suino and I could even have certain
00:23:35
amino acids made into aceto COA you know
00:23:37
specifically maybe I could take for
00:23:39
example even uh Lucine you know so maybe
00:23:42
Lucine I could turn turn into aceto
00:23:45
there's many many amino acids that can
00:23:46
be converted into many points within
00:23:48
this actual either this transition step
00:23:51
or CB cycle why is that
00:23:53
significant because two things can
00:23:55
result out of this what are the two sign
00:23:57
ific things that can result if it goes
00:24:00
and gets utilized in the KB cycle can't
00:24:01
that make
00:24:03
ATP yes that can that's one significant
00:24:07
component what's the other significant
00:24:09
component remember how from
00:24:11
gluconeogenesis some of these actual
00:24:13
molecules can get converted into OA and
00:24:15
then what can happen to the OAA you guys
00:24:17
remember that the OA gets converted into
00:24:19
malate and then what happens to that
00:24:21
malate it gets pumped out through the
00:24:23
malet to sparate shuttle right that
00:24:26
malate then gets converted back into
00:24:28
oxyacetate and oxyacetate if it's acted
00:24:31
on by Pepsi K what can happen it can get
00:24:35
converted into phospho enol pyu because
00:24:38
this step is irreversible this step
00:24:40
right here but this step is reversible
00:24:43
and then I can take pep up eventually to
00:24:46
glucose so Pepsi K is stimulating this
00:24:49
step so in other words what is the
00:24:51
significance of this amino acid
00:24:53
metabolism I can use amino acids to make
00:24:56
ATP or or I can use amino acids to make
00:24:59
glucose what is that call whenever you
00:25:01
make glucose from non-carbohydrate
00:25:03
sources like amino acids they call it
00:25:05
glucon
00:25:07
neogenesis wow that's beautiful okay and
00:25:10
then again what is significant about
00:25:12
these transamination processes that if
00:25:15
you have the transamination process and
00:25:17
you form a lots of glutamate because
00:25:18
that's usually some of the Bas the main
00:25:20
products of transamination if you
00:25:22
noticed what do we get from this
00:25:23
transamination reaction glutamate what
00:25:25
do we get from this transamination
00:25:26
reaction glutamate you're going to get a
00:25:29
lot of glutamate produced in these
00:25:31
processes and then what can happen is
00:25:33
that glutamate can actually be acted on
00:25:35
by glutamate dehydrogenase that
00:25:37
glutamate dehydrogenase will then be
00:25:40
taking NP positive to make NPH which is
00:25:42
a reducing agent for fatty acid
00:25:44
synthesis and free radical reactions and
00:25:46
it's going to add water in the second
00:25:47
step to make alpha heog glutarate but
00:25:49
it's going to remove out of it ammonia
00:25:53
and then what can happen to ammonia he
00:25:54
can go into the mitochondrial he'll go
00:25:56
through the Ura cycle to convert the
00:25:58
ammonia into a less toxic form called
00:26:00
Ura which we'll talk about in another
00:26:01
video last thing guys since you can find
00:26:05
these enzymes in many different tissues
00:26:06
you can find this uh specifically this
00:26:09
sparate Amino transferase and you can
00:26:10
find this Amino alanine Amino
00:26:12
transferase you can find this in the
00:26:13
heart you can find this within the
00:26:15
skeletal muscles you can find it within
00:26:16
the liver why is that important because
00:26:19
you know let's say for example this
00:26:20
liver is damaged tissues are damaged you
00:26:22
know what it can release out into the
00:26:24
blood if it's actually damaged it can
00:26:27
release out this a
00:26:29
enzyme you know if this actual muscle
00:26:31
skeletal muscle or cardiac muscle is
00:26:33
damaged you know what can release out
00:26:34
into the
00:26:35
blood alt
00:26:37
enzymes why is that significant because
00:26:39
let's say that you run a blood test you
00:26:41
think that there maybe there's some type
00:26:42
of suspection of uh maybe a myocardial
00:26:45
farction or liver damage you find out
00:26:47
that their blood test comes back and
00:26:49
they have elevated a enzymes and
00:26:52
elevated ALT enzymes this is indicative
00:26:55
of someone having possible liver damage
00:26:57
Dage or maybe even primarily cardiac
00:27:00
tissue heart damage okay so if you find
00:27:03
elevated a alt and maybe even some
00:27:05
elevated creatine cyas levels and
00:27:07
troponin you might even assume oh man
00:27:09
this person might have had a heart
00:27:10
attack or if they have elevated as
00:27:12
enzyme levels they might have possibly
00:27:15
some type of liver damage all right guys
00:27:17
I hope all this made sense I really hope
00:27:19
you guys enjoyed it if you guys did hit
00:27:20
that like button comment down the
00:27:21
comment section and please subscribe in
00:27:24
the next video guys we're going to hit
00:27:25
the Ura cycle until next time