00:01
Welcome to our discussion of adrenal gland
pathology.
00:04
Before we begin, we’ll take a look at the
adrenal cortex and do a brief review.
00:10
Illustration here on your right, you divide
your axis into two components like you would
with many of the other axes.
00:21
For example, the hypothalamus and the pituitary
play a role in many, many, many axes including
that of your gonads, hypothalamus, pituitary,
gonadal axis, we’ll talk about later, hypothalamus,
pituitary type of thyroid axis that we have
discussed.
00:40
Here, we have the hypothalamus, pituitary,
adrenal axis.
00:47
From the hypothalamus, the pattern that we’ve
established over and over again is that you
release your releasing hormones.
00:54
This then triggers the pituitary to then release
the appropriate hormone where, in this case,
it will be ACTH and the target organ for ACTH
would in fact be your adrenal cortex.
01:06
Let’s dive into this a little bit deeper.
01:12
From your hypothalamus, we have the corticotrophin
releasing hormone which then acts upon your
anterior pituitary here and when it does so,
it triggers the breakdown of your pro-opio,
the opioid will be beta endorphin, the melano
would be the melanocyte stimulating hormone
and the corticotroph would obviously be our
ACTH, our primary focus of our entire discussion.
01:44
ACTH will then be released into circulation
and then the receptor that you see down at
the bottom would represent the receptor upon
the adrenal cortex.
01:56
You are now down in your abdominal region.
01:59
In the box, what you are seeing here is the
control of ACTH and when ACTH would play a
role especially its responsibility would be
cortisol release.
02:13
Sure, ACTH has a minor influence upon aldosterone
synthesis and I say minor because for you
to form a fully pledged or fully mature aldosterone,
that’s a discussion that we’ll have in
a little bit, but ACTH is definitely responsible
for cortisol synthesis.
02:34
That cortisol is incredibly important during
those times of stress… what kind of stress?
Well, how about fasting when you are hungry,
infection, and any time that you’re fasting,
you know that you then have to follow your
gluconeogenic pathway, so cortisol and glucagon
will always have permissive action.
02:57
If at any point in time you’re missing cortisol,
your patient now is at risk for death.
03:04
So, absolutely necessary for sustenance of
life.
03:10
When is cortisol released?
At the end of the day, when you feel tired
is when your cortisol levels are the lowest.
03:18
Around midnight and thereafter when you’re
sleeping at night is when your cortisol levels
start rising.
03:26
Wake up in the morning, it is at its highest
level; we call this number one, diurnal rhythm.
03:33
It’s imperative that you know the normal
rhythm of your cortisol because you will be
responsible for understanding how the dexamethasone
suppression test actually functions.
03:46
You will be responsible for that, I’ll walk
you through it.
03:51
It is a stress hormone and cortisol inhibition.
03:54
If you take a look at the picture on your
left, you’ll notice that cortisol has inhibitory
effect or feedback upon your hypothalamus
and the anterior pituitary inhibiting the
release of those respective hormones.
04:08
ACTH… do not forget will work through your
GS-protein therefore, we have cyclic AMP as
its signal transducer.
04:19
Here, the adrenal cortex down the abdomen…
what I would like for you to do is establish
a pattern of what this looks like anatomically
granted these are biochemical pathways.
04:33
But, from left to right, you will be moving
from superficial deep side, literally I need
you to think of the adrenal gland and our
focus only in this discussion will be with
the cortex, right?
Whereas the medulla will be responsible for
epinephrine… that discussion to be had at
a later time.
04:55
Now, with the cortex, you were moving from
superficial to deep, I need you to move from
the left… in the left column and at this
point, all we’re doing is an overview.
05:08
We will get into greater detail where you
will be able to see these specific substrates
and enzymes, but I just want you to understand
the pattern here.
05:18
We have the zona glomerulosa, we’ll then
refer to what’s known as the zona fasciculata
responsible for cortisol release and then
finally reticularis which is that green box
that you see way to the right and that is
your reticularis.
05:34
That is the deepest structure of the adrenal
cortex.
05:37
So, those are the three columns that we’ll
be focusing upon, each one of those columns
play pivotal role with synthesis of various
adrenocortical hormones.
05:52
Adrenal cortex in the cell, where are we?
Okay, now, the same pattern, but now we’re
blowing it up.
05:57
First, you’ll notice ACTH binding to a receptor,
we have GS-protein, cyclic AMP.
06:03
It’s important that you know the enzyme
here, understand that cholesterol is brought
into the adrenal cortex.
06:11
Cholesterol from biochemistry, carried by
LDL and I will give you a little bit of an
overview to show you the LDL receptors bringing
in the cholesterol.
06:20
That is important for you to know because
at any point in time, if LDL receptors aren’t
working properly such as type II hyperlipidaemia,
huh, you can’t even bring in cholesterol
into your-into your organ.
06:31
Anyhow, cholesterol is the-is the omnipotent
factor here that is responsible for synthesis
of adrenocortical hormones.
06:41
So, begin there, please.
06:43
Next, the rate limiting enzyme that we’ll
refer to here is called desmolase responsible
for breaking down your cholesterol into pregnenolone.
06:52
Now, where are you in the adrenal cortex?
This first column and all we’re doing is
the first step here is the zona glomerulosa.
07:03
You tell me what is zona glomerulosa responsible
for synthesizing?
Good, aldosterone.
07:11
However, as I said, ACTH will kick-start the
synthesis of aldosterone, but it will not
complete the job, that’s important because
you know that aldosterone and its major feedback
is going to be with whom?
You’ve heard of the acronym RAS, right?
Renin… angiotensin… aah, aldosterone,
so renin clinically will be the most important
feedback for you with aldosterone.
07:39
Let’s move on.
07:41
We’ll then going to move from the glomerulosa
into the fasciculata which is that blue box
that you see there.
07:49
Here, there’s an enzyme that will take you
from the glomerulosa to the fasciculata this
is then noted and abbreviated as 17-alpha-hydroxylase.
07:59
So, 17-alpha-hydroxylase is an enzyme that
allows you to go from your glomerulosa into
the fasciculata… that must be understood.
08:11
At some point in time, obviously, we’ll
start talking about pathologies in which you’re
deficient or your patient is deficient of
certain enzymes.
08:21
17-alpha-hydroxylase deficiency could be a
possibility, but I’ll tell you which ones
to focus upon first.
08:28
Something else that I want you to focus on
now that we’re officially in our fasciculata,
you have something called hydroxy… you see
that?
So, this is hydroxypregnenolone that becomes
important for us and it’s 17…
17 hydroxypregnenolone.
08:43
That becomes important for us because of...
just keep that in mind, they could ask you
something about what you might find in the
urine and I’ll give you a table in which
you will… we’ll take a look at that further.
08:56
And then you go from your fasciculata down
into the green box there, that would be the
deepest of the layers and that would be your
reticularis and that DHEA stands for dehydroepiandrosterone.
09:12
Your focus there would be the “A” because
the reticularis is responsible for synthesizing
androgen type of hormones.
09:20
Androgen, not estrogen, so any time that you
would find, let’s say, excess activity of
the reticularis, what’s your patient going
to look like?
If it’s a female, a young girl… masculinization,
right?
If it’s a male, well, he’s already a boy,
but he might then have or experience precocious
puberty.
09:45
Let’s move on.
09:46
We’re going to add bit by bit by bit so
that you remain focused and organized with
what is happening.
09:53
Our next enzyme here, I’ll tell you exactly
what to take a look at here would be where
we left off in the glomerulosa, identify that
first and that would be your leftmost column.
10:04
We already discussed desmolase and pregnenolone
and in the previous discussion, we went from
pregnenolone into the fasciculate.
10:13
What’s the name of that enzyme called?
17-alpha-hydroxylase, that’s what that bar
stands for, that bar that you see there is
an enzyme.
10:23
But, what if you want to go through each of
the columns?
What if you want to go from… please identify
pregnenolone.
10:30
Next, I want you to then identify your progesterone.
10:35
How did you convert your pregnenolone to progesterone?
Very important that you know this enzyme,
it’s called 3-beta hydroxysteroid dehydrogenase.
10:43
It’s abbreviated here as being 3-beta, at
least be able to identify 3-beta.
10:48
3-beta hydroxysteroid dehydrogenase, where
is this enzyme located?
You see that bar horizontally, it is in the
superficial most layer, the glomerulosa.
10:59
It is also in the fasciculate, it is also
in the reticularis.
11:04
Hence, you see the bar going all the way through
the cortex.
11:08
What does that help you do?
It helps you go through each layer, meaning
to say you’ll go within the glomerulosa,
you convert your pregnenolone into progesterone.
11:18
Next, I want you to go into the blue box,
that’s your fasciculata.
11:23
We were at hydroxypregnenolone, identify that
with the help of the enzyme 3-beta hydroxysteroid
dehydrogenase, you convert it into 17-hydroxyprogesterone
and then finally reticularis.
11:35
I told you to focus upon the letter “A”
because that then to you means an androgen,
the androgen here would be androstenedione.
11:45
Our next enzyme that we’ll take a look at
and ultimately the most important enzyme of
all the enzymes so far, we’ll look at two…
17-alpha, 3-beta.
11:57
However, the most important enzyme and the
reason I say that is because there’s a pathology
that you know of known as congenital adrenal
hyperplasia… congenital adrenal hyperplasia.
12:07
Who’s your patient?
Congenital, child, so in utero, the child,
the foetus never developed the enzyme.
12:18
There are three enzymes that might be deficient.
12:23
Of all the enzymes… actually, four to be
technical, but at least know the most important
one of all the enzymes that could be deficient
in the adrenal cortex it is this one, this
one, this one.
12:34
Which one is it am I referring to?
21-beta hydroxylase here abbreviated as 21-beta.
12:39
What does it do?
Take a look.
12:43
That 21-beta hydroxylase... first and foremost,
where do you see the bar?
The bar is horizontal only located in the
glomerulosa, only located in fasciculata,
obviously not located in reticularis, so you
don’t need it there.
12:58
Hence, the bar stops there.
13:00
What does it do?
Ah, now, this is where it becomes important
and really interesting because I’m going
to add in your clinical application.
13:06
I’m going to show your patient or you’re
going to imagine your patient here.
13:09
So, you take the…
I want you to go with the glomerulosa, we’re
at the progesterone.
13:16
From your progesterone, what does this enzyme
help you convert to?
21-beta hydroxylase permitted you do convert
into your DUC, D-U-C that stands for 11 deoxycorticosterone
or 11-DUC… that you have to... you have
to commit to memory.
13:35
It has a weak… physiologically, it has a
weak mineralocorticoid activity… weak mineralocorticoid,
physiologically.
13:44
Pathologically, completely different picture.
13:48
What does mineralocorticoid activity mean
to you?
It means reabsorbing sodium and water.
13:57
The operative element, the sodium.
14:00
You tell me if you’re reabsorbing, retaining
more sodium, what does it affect?
Blood pressure?
Sure, and blood pressure meaning what?
Systolic, diastolic, right?
Blood pressure will be elevated when you’re
retaining more sodium.
14:16
Let’s talk about this patient and our focus...
and your focus should be on 21-beta hydroxylase.
14:22
Keep in mind that they could technically give
you other enzyme deficiencies, but let me
show you if you’re deficient 21-beta hydroxylase
identify please, are you producing DUC?
No, if you’re not producing any DUC, you
sure as heck are not producing any aldosterone.
14:44
If you have no mineralocorticoid, what’s
your blood pressure in your child?
Decreased.
14:49
Okay, we’ll talk more about this later step
by step by step so that you have a firm understanding
of these enzymes and how they operate.
14:58
There’s another enzyme here.
15:00
We are now moving on to the blue bar which
is 11-beta hydroxylase.
15:07
What does it do?
Notice here, please, now at this point, we
can move a little bit faster, I believe that
you’ve established the pattern quite well.
15:14
So, in the glomerulosa, which is the first
column on your left, which is responsible
for all aldosterone synthesis, you’ll notice
that this bar representing the enzyme is only
in the glomerulosa and it’s only in the
fasciculata.
15:28
Once again, why do you require it in the reticularis?
You already have your androgen, so let it
go, hmm?
Next, where do we leave off in the glomerulosa?
We formed our DUC, deoxycorticosterone.
15:41
Please be very careful because you will get
answer choices in biochemistry in which your
deoxycorticosterone might look like your deoxycortisol.
15:49
You see that in the blue box they look alike
and you’re tired maybe perhaps when you’re
taking the exam very easy that your eyes can
get confused between those two.
15:59
Do not ever do that.
16:00
So, we’ll take our DUC and with the help
of the enzyme 11-beta hydroxylase, we’ll
then form our corticosterone and that corticosterone
with the help of… here’s an enzyme called
aldosterone synthase.
16:14
Aldosterone synthase, hmm, what’s responsible
for stimulating aldosterone synthase?
Well, if you know it’s aldosterone, what
is its major feedback mechanism?
Renin-angiotensin.
16:28
What kind of angiotensin?
Angiotensin 2 stimulates aldosterone synthase
so that you form your aldosterone… welcome
to RAS.
16:38
We’ve completed our discussion of the glomerulosa,
let’s move over into the blue box which
is the fasciculata.
16:44
You’ll notice here that your deoxycortisol
is being converted into cortisol and there’s
a little stanza there that says that cortisol,
remember, these are all adrenocortical hormones,
these are all lipid soluble that will pass
through the membrane and where is the receptor
for your adrenocortical hormones located?
Nucleus or cytoplasm?
Good, cytoplasm.
17:07
And that’s what that paragraph says there.
17:10
In the meantime, take a look at the reticularis.
17:12
What are you producing?
What kind of hormones?
General theme… androgen, androgen, androgen.
17:19
This is an overview of your adrenal cortex
and its major enzymes, your focus should be
on 21-beta hydroxylase and I gave you one
little clue here about your patient where,
if your patient is deficient of the enzyme
21-beta, you are not producing any mineralocorticoid,
your patient’s blood pressure is decreased.
17:35
I will tell you later as to why your patient
will be… if-if-if your patient’s a female,
the young girl will be virilised; where if
it’s a male, then your child, the boy, will
be experiencing precocious puberty.
17:51
I’ll tell you why.
17:52
For those of you who are ahead of me, you
already understand this.