Histology of the Reproductive Systems (Pre-Practical Lecture Slides)

Summary

These slides cover the histology of the male and female reproductive systems, detailing the structures, functions, and development of various components like seminiferous tubules, follicles, and Leydig cells. Presented by Dr. Meleshni Naicker at the University of KwaZulu-Natal.

Full Transcript

Histology:
Human Reproductive System
HPHS 222

Dr Meleshni Naicker
Department of Human Physiology
University of KwaZulu-Natal
[email protected]
 Learning Outcomes

Histology of the Male Reproductive System

Histology of the Female Reproductive System
3
 Testis
Each testis is an oval structure
about 5cm long and 3cm in
diameter.
Located in the scrotum.
Covered by: tunica albuginea - a
fibrous capsule that covers each
testis.
The tunica albuginea gives rise to
septa (partitions) that divide the
testis into lobules (about 250
lobules).
Each lobule contains 3 or 4 highly
coiled seminiferous tubules.
These converge to become rete
testis which transport sperm to the
epididymis.

4
 TESTIS H&E
SEMINIFEROUS TUBULES

Seminiferous tubules cut in
various planes of section. The
seminiferous tubules are
highly convoluted and are
lined by:
Germ cells in various
stages of
spermatogenesis and
spermiogenesis, which are
collectively referred to as the
spermatogenic series.

Non–germ cells, called
Sertoli cells, which support
and nourish the developing
spermatozoa are also found
within the seminiferous
tubules.

In the interstitial spaces
between the tubules, 6
 Spermatogenesis

Wheater’s Functional Histology, 6th Edition

Spermatogenesis is a tightly regulated developmental process that involves
sequential mitotic and meiotic cellular divisions, by which developing germ cells
differentiate from spermatogonia to spermatocytes, spermatids and finally to
spermatozoa.
Spermatogenesis occurs within the seminiferous tubules and is orchestrated by
Sertoli cells.
To complete spermatogenesis, differentiating germ cells must migrate through the
lumen

lumen
lumen
lumen
lumen
 Usually 4 to 5 concentric layers of
morphologically distinct spermatogenic
cells at various stages of development
occurs within the seminiferous
epithelium.

As the cells proliferate and differentiate,
they gradually move from the basement
membrane (BM) of the seminiferous
tubule towards the lumen of the tubules.
BM

lumen
Spermatogenesis
lumen
 Interstitial cells of Leydig

Leydig cells are the principal
cell type found in the interstitial
tissue between the
seminiferous tubules.
Produces testosterone in the
presence of lutenizing hormone
(LH).

Structure of Leydig cells:
Polyhedral in shape,
Has a large prominent ovoid
nucleus, containing 1-3
prominent nucleoli & large
amounts of dark-staining
peripheral heterochromatin.
Eosinophilic cytoplasm,
Several lipid-filled vesicles.
Interstitial cells of Leydig
 Rete Testis

The seminiferous
tubules converge upon
the mediastinum testis,
which consists of a
plexiform arrangement
of channels, the rete
testis RT, surrounded
by highly vascular
collagenous supporting
tissue containing myoid
cells.

Rete testis is lined by a
single layer of low
cuboidal epithelial cells
with surface microvilli
and a single cilium. Wheater’s Functional Histology, 6th
Edition
 Ductulus Efferens
Rete testis drains into the head
of the epididymis via some 15
to 20 convoluted ducts, the
ductuli efferentes (DE).
The ductuli are lined by a single
layer of epithelial cells, some of
which are (i) tall columnar and
ciliated (ii) and others which are
short and non-ciliated.
Ciliary action in the ductuli
propels the still non-motile
spermatozoa towards the
epididymis.
The non-ciliated cells reabsorb
some of the fluid produced by
the testis.
A thin band of circularly
arranged smooth muscle Wheater’s Functional Histology, 6th
Edition
 Receives ductuli efferentes.

Divided into head, body and tail.
Epididymis
Pseudostratified epithelium consisting of
principal and basal cells.
Principal cells → primary columnar cell of the
epididymis and their function is protein secretion &
endocytosis.
Basal cells → located on the basement membrane
throughout the epididymis → regulates the
microenvironment where the functionally
incompetent sperm cells produced by the testis are
matured and stored.

From the proximal to the distal end of the
epididymis, the muscular wall increases from a
single circular layer smooth muscle, to three
layers organised in the same manner as in the
ductus deferens.

Smooth muscle in head and tail contract
spontaneously; smooth muscle in tail requires
sympathetic innervation for contraction.
Epididymis

Basal cells

Princip
al cells
 Vas (ductus) deferens
The vas deferens conducts
spermatozoa from the epididymis to
the seminal vesicles.

It is a thick-walled muscular tube
consisting of inner and outer
longitudinal layers and a thick
intermediate circular layer.

Like the distal part of the epididymis,
the vas deferens is innervated by
the sympathetic nervous system,
producing strong peristaltic
contractions to expel its contents
into the urethra during ejaculation.

Similar to that of the epididymis:
The vas deferens is lined by a
 Seminal Vesicles
Seminal vesicles secrete 50–70% of the total
volume of seminal fluid.

The epithelial lining is a pseudostratified tall
columnar type and consists of secretory cells
with lipid droplets in the cytoplasm, giving it a
foamy appearance.

The lumen of each seminal vesicle is highly
irregular.

The seminal vesicles produce a yellowish viscid
alkaline fluid containing a wide range of
substances, including fructose, fibrinogen,
vitamin C and prostaglandins.

The prominent muscular wall is arranged into
inner circular and outer longitudinal layers and
is supplied by the sympathetic nervous system;
during ejaculation,
 Prostate gland

The secretory product of the prostate,
makes up about 30–50% the seminal fluid
volume.

The prostate gland is composed of
glands and stroma.

The supporting stroma SS is a mixture
of collagenous fibrous tissue and smooth
muscle fibres.

The glands G show a convoluted pattern
with the epithelium thrown up into folds.

Wheater’s Functional Histology, 6th
Edition
 Prostate gland

The epithelium of the prostate
gland contains tall columnar
secretory cells with prominent
round basal nuclei and pale-
staining cytoplasm.

There is also a scanty population of
small, flat, basal cells B at the
base of the gland in contact with
the basement membrane.

Wheater’s Functional Histology, 6th
Edition
 Penis
The erectile tissues of the penis is
arranged into three columns.
- Two dorsal columns are called
the corpora cavernosa (CC) and
- a single ventral column is called
the corpus spongiosum (CS).

The penile urethra (U) runs through
the centre of the corpus spongiosum.

The corpus spongiosum expands at its
distal end to form the glans penis.

The erectile corpora (columns) are
enclosed within and separated by a
fibrocollagenous capsule (F).

A sheath of skin (S) encloses the
erectile centre of the penis.
Wheater’s Functional Histology, 6th
 Penis

The erectile
tissues consist of
lacunae, spaces
that fill with
blood,
surrounded by
collagenous
connective tissue
(the tunica
albuginea).
Penis
 Penile Urethra
The penile urethra is lined by stratified
or pseudostratified columnar
epithelium.

There may also occur some small
areas containing stratified squamous
epithelium in human adult males.

The external opening called the
urethral meatus is lined by stratified
squamous epithelium which is
continuous with the glans epithelium.

The urethra is lubricated by mucous
secretions from the para-urethral
glands P and the bulbo -urethral
glands of Cowper.
Wheater’s Functional Histology, 6th
Edition
 Ovary

Review the basic structure of the ovary and the stages of follicular development
 Ovary

Wheater’s Functional Histology, 6th
Edition
 Follicle development - Primordial follicles
Undeveloped follicles known
as primordial follicles
are inactive structures,
awaiting stimulation
from FSH before
reentering their
developmental pathway.
Primordial follicles are
composed of a primary
oocyte surrounded by a
single layer of flattened
follicular cells.
The primary oocyte has
a large nucleus with
dispersed finely
granular chromatin, a
prominent nucleolus and
little cytoplasm.
 Follicle development - Primary follicles

Once stimulated, by
FSH, 30-50 primordial
follicles re-enter
development, and
become primary
follicles.
 Follicle development - Primary follicles

The primary follicle oocyte (O)
has greatly enlarged and the
follicular cells (F) have multiplied
by mitosis and become cuboidal
in shape.
They are now known as
granulosa cells.
A zona pellucida (ZP) layer
develops between the oocyte and
the granular cells – this is a thick
homogeneous layer containing
glycoprotein and acid
proteoglycans.

Wheater’s Functional Histology, 6th
Edition
 Follicle development – Secondary follicle

The zona granulosa (ZG)
continues to proliferate.
In addition, small fluid-filled
spaces begin to develop
between the granulosa cells, Beginning
of
and these fuse to form the
formation
follicular antrum (FA). of the
This is now referred to as the ZP
follicular
secondary follicle. antrum

At this stage, the oocyte (O)
has nearly reached full size
and becomes situated
eccentrically within a
thickened area of the zona
granulosa called the cumulus
oophorus (CO).
The zona pellucida (ZP) Wheater’s Functional Histology, 6th
 Follicle development – Secondary follicle

Stroma around the developing
follicle differentiates into
thecal cells.
At the periphery of the follicle, Beginning
the theca folliculi has of
developed two layers: formation
of antrum
(i) the theca interna TI,
comprising several layers ZP
of rounded cells,
(ii) and the less well-
defined theca externa
TE, consisting of spindle-
shaped cells that merge with
the surrounding stroma.

Wheater’s Functional Histology, 6th
Follicle development – Secondary follicle
 Follicle development – Graafian
follicle
On approaching maturity, further growth of the oocyte
ceases. This stage in follicular development occurs just
before ovulation.

At this stage, the oocyte (O) is known as the secondary
oocyte.

The follicular antrum (FA) is markedly enlarged.

Zona granulosa (ZG) forms a layer of even thickness
around the periphery of the follicle.

At this stage, the maturing follicle has reached between
1.5 and 2.5 cm in diameter and appears as a bulge
beneath the ovarian surface.

Cumulus oophorus diminishes, and the oocyte O is
instead surrounded by the corona radiata CR (i.e a
thickened cell layer), which remains attached to the zona
granulosa (ZG) by thin bridges of cells.
Wheater’s Functional Histology, 6th
 Corpus Luteum
Following ovulation, the ruptured follicle
collapses and fills with a blood clot (B) to
form the corpus luteum of menstruation.

The blood clot B is surrounded by a wide zone
of granulosa lutein cells G, penetrated by
septa S containing large blood vessels.

A thin zone of theca lutein cells T can be
seen peripherally.

Externally, the corpus luteum is bounded by
condensed stromal tissue, that represents the
theca externa of the Graafian follicle.

The corpus luteum serves to provide hormones
that are necessary for implantation and early
development of a fertilized ovum.

Wheater’s Functional Histology, 6th
Edition
 Corpus Albicans
If fertilization does not occur, the
corpus luteum (C) degenerates &
regresses (over approx. 14 days) to
become the corpus albicans → i.e
inactive fibrous tissue mass.

Secretory cells of the degenerated
corpus luteum undergo autolysis and
are therefore phagocytosed by
macrophages M.

Wheater’s Functional Histology, 6th
Edition
 Female Genital Tract

The female genital tract consists of the:
fallopian tubes
uterus
vagina

All above consists of the same basic structure:
a wall of smooth muscle,
an inner mucosal lining and,
an outer layer of loose supporting tissue.
 Fallopian Tube (Uterine Tube/Oviducts)

The Fallopian tubes serve to
carry the released ovum from
the ovary to the uterine
cavity.

It is also the site of
fertilization.

Structurally, the Fallopian
tube appears as an
elongated funnel that is
divided anatomically into
four distinct regions as
follows:

Fimbria (finger-like
projections)
Infundibulum
Fallopian Tube (Ampulla)
The mucosal lining of the
Fallopian tube appears as
branching longitudinal folds, a
feature that is most prominent
in the ampulla (a), i.e. the
usual site of fertilisation.

Micrograph (b) depicts a A
mucosal fold of the ampulla.. B
These contain a branching core.
of vascular supporting tissue
ST which comprises a single
layer of tall columnar epithelial
cells E.

Micrograph (c) depicts the end
of a mucosal fold at high
magnification. The columnar
epithelial cells are of three
types: (i) ciliated, (ii) non- C
 Uterus (Proliferative)

In the proliferative stage
of the uterine cycle, under
control of rising estrogen
from the developing
follicles, the stratum
basalis is regrowing the
stratum functionalis, which
was shed during the
previous menstrual flow.
The diagnostic feature of
this stage are the long and
straight uterine glands
which are not yet
functional.
 Uterus (Secretory)

In the secretory stage of
the uterine cycle, under
the control of estrogen and
progesterone from the
corpus luteum, the uterine
glands of the stratum
functionalis begin to be
functional, producing
glycogen.
The diagnostic feature of
this stage are the curvy,
serrated-looking glands.
 Uterus (Menstrual)

In the menstrual stage
of the uterine cycle,
under the control of lack
of estrogen and
progesterone from the
dead corpus luteum, the
stratum functionalis dies
and loses its anatomical
integrity, breaking lose
and shedding from the
stratum basalis.
 Vagina
The vaginal wall consists of:

a mucosal layer lined by
stratified squamous epithelium
(E),
a layer of smooth muscle (SM) –
SM bundles are arranged as
inner circular & outer
longitudinal layers.
an outer adventitial layer (A)
A fibrous lamina propria (LP)
layer that contains several
elastin fibres, has a rich plexus
of small veins and is devoid of
glands.

The vagina is lubricated by
cervical mucus, a fluid
transudate from the rich
vascular network of the lamina
 THE END
THANK YOU