The Spermatozoon

The male germ ceil is extremely minute, approximately 0.03 mm. in length. There is a long cylindrical head containing the nucleus and a slender tail which is twice the length of the head.

The eggs escape from the follicles of the ovary and are collected in the oviducts. When stimulated by the embrace (amplexus) of the male, the eggs are discharged from the cloaca, while the spermatozoa of the male are simultaneously emitted as a stream of milt. Pituitaryinduced eggs may be artificially fertilized with spermatozoa removed from the sperm ducts of the male.

As the eggs enter the water, the egg jelly swells and the outer layer becomes sticl^ so that all the eggs from one ovary tend to form a large mass of spawn containing about 2(K)0 eggs.

Examine the demonstrations of eggs and sperm provided.

First Cleavage (Stage 3). A furrow appears in tile animal hemisphere after fertilization. This furrow grows down throu^ the vegetal hemisphere, thus dividing the egg into the first two blastomeres. In fresh material it can be seen that this furrow usually passes through the gray crescent.

Fra. 1 Gerin cells of the frog (Aona ptpieru) a, Croa9-«ectto& of the ovarian egg (approximately 26 X); b, Bpemiatoeoon (apptozimately 1000 X>

‘ Hus may be dons by demonstration.

In the frog’s egg the layer of cells left on the surface after gastrulation is complete is the ectoderm. The layer of cells turned in at the lips of the blastopore gives rise to the notochord and mesoderm which form a temporary roof of the gastrocoel. Soon, however, endoderm cells move up beneath the chordamesoderm and transform it into a middle germ layer. The median axial strip of this middle layer is the primordium of the notochord; the rest becomes the mesoderm, which soon grows out between the ectoderm and endoderm in other regions of the embryo. In an exactly sagittal section it can be seen that the notochord forms part of the roof of the gastrocoel (Fig. 2d). During the formation of the neural tube the endoderm grows beneath the notochord from either side (Fig. 3).

FORMATION OF THE NEURAL TUBE (Reorulation)

SThJs may be ehtnm by damonstral^

each other along the inid>dor8al line but have not yet fused. Posterior to Ihe sense plate, the gill plate can be seen on either side of the neural folds. Here the visceral grooves will develop. Sections show that the neural crests are being drawn over the developing neural tube, and that the neural folds enclose a longitudinsJ canal, the neurocoel. The mesoderm nearest the notochord is segmented into blocks, or somites, of which three or four pairs may be distinguished in sagittal or frontal sections. The gut is now completely roofed by endoderm (Fig. 3h).

Neural Tube (Stage 16). The embryo is now a little more than 2.5 nun. in length, and the neural folds have fused to produce the neural tube. From the dorsal aspect the embryo is pear shaped and marked on each side by short transverse grooves enclosing the gill plate and representing the first and fifth visceral grooves. On the ventral surface at the anterior end are two swellings, the primordia of the mucous glands. Between them is a depression which is the beginning of the stomodeum. At the posterior end the blastopore is obliterated by the fused neural folds, and at the ventral end of the strip a depression, resulting from this fusion, marks the beginning of the proctodeum. Slight transverse grooves on the sides of the embryo indicate the presence of six somites. In certain sections it can be seen that the neural tube is completely separated from the epidermis and that the neural crest material lies between them.* Between the notochord and the roof of the gut lies the hypochord, a temporary structure formed from endoderm which disappears in later development (Fig. 3c).

3-MM. EMBRYO (Stage 17, Tail Bud)

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Make an outline sketch of the S-mm. embryo from the left side in the space provided below. Label all structures you have identified.

The 3-mm. Frog Embryo.

croscopic obsowation. Figure 4 indicates the rdationship of a transverse section to the embryo as a whole. In order to read a series of sections you should examine each section, identifying the structures you fAnKxvB.

The epidermis is ciliated except on the ventral side, but the cilia themselves are too small to be seen with your microscope. It will be noticed with high power that the ectoderm is divided into two layers, the epidermal layer and the nervous layer. The stomodeum, between the two mucous glands, has not yet joined the fore-gut. From the dorsal region of the stomodeum a solid hypophysis grows toward the forebrain. Notice with high power the structure of the mucous glands. The cells in these glands are more qiecialized at this time than any others of the body. The proctodeum has opened into the hindgut, thus forming the cloaca.

The hind-gut, posterior to the yolk mass, has united with the proctodeum to form the cloaca, opening to the exterior by the small vent already noticed.

The notochord extends forward to the base of the mesencephalon where it turns down very slightly. At the posterior end it joins a mass of relatively undifferentiated tissue which forms the core of the tail bud.

3-MM, EMBRYO

Transverse Sections of 3-mni. Prog Embryo.

' The embryo of Ram pipiens batches spontaneously at a length of 6 mm. The stage now to be described is marked exactly by the beginning of circulation in the capillary loops of the first external gill.

The head is marked off from the trunk by a notch behind the mucous glands which have approached each other at their posterior ends. The stomodeum, now a deeper pit, is anterior and slightly dorsal to the anterior ends of the mucous glands but has not yet opened into the fore-gut. On either side of the stomodeum and somewhat dorsal to it is a nasal pit. On the sides of the head optic bulges are still prominent. All five visceral grooves (hyomandibular and branchials 1-4) have appeared but have not opened into the corresponding visceral pouches. External gills are developing on the first and second branchial arches, and circulation can be demonstrated in the first of these.

The tail is now one-half of the body length. Intersomitic grooves continue into the tail. A prominent tail fin extends completely around the tail from the vent on the ventral side to the dorsal junction with the trunk.

The 6-mm. Frog Embryo.

Rbphesentativb Sections of the 6-mm. Embryo

A. Section through the Epiphysis and Nasal Pit (Section 10, Fig. 5)

Because of a slight lateral curvature of the head, this section shows a slight asymmetry. The plane of the section passed* through the left side at a region that is anterior to that on the right. The nasal pit (1), therefore, is cut on the left through its openini^ to the exterior, and on the right through its posterior side wall. The groove on the ventral side is the beginning of the stomodeum (2). The brain is cut through its most anterior division, the telencephalon (3), at the level of the primordium of the pineal

brj’O. Transverse section through Transverse section through optic cup.

Between these structures lies the mesenchyme (10) containing a few blood vessels. Those located between the eye and brain are parts of the ophthalmic vein (12) which lead to the anterior cardinals (see later). Those between the brain and the pharynx are part of the cerebral arteries (11) which represent anterior extensions from the carotids (see later).

Beneath the brain is the conspicuous notochord (4) with large vesicular cells. Beneath this in turn lies the widdy expanded pharynx (5). The lateral thickenings of its walls represent the fourth visceral pouch (6). Ventral to this in the cavity of a great bulging projection lies the heart, represented by the dorsal atrium (8) and ventral ventricle (7). It is contained in the most anterior part of the coelum, the pericardial cavity (9). Note that this cavity is lined on the outside by the somatic layer of the mesoderm (10) and on the inner side by the splanchnic layer of the mesoderm (11), which gives rise to the myocardium and visceral pericardium. The endocardium (12) separated at an earlier stage.

From either side of the embryo projects the first external gill (13) borne on the third visceral arch. This gill is now

heart, fio X- beneath the pharynx. The capillary loops of the gill discharge

their blood to the first efferent branchial artery, which is dorsal to the side of the pharynx and is uniting (on the right side) with the radix aortae (16). These arteries represent the third aortic arch of vertebrates. Below and lateral to the otic vesicle is the ventral branch (inferior jugular) of the anterior cardinal vein (17). Between the otic veside and the brain may be seen the dorsal branch (superior jugular) of the anterior cardinal vein (18). The mesenchyme and epidermis are readily identified.

This section cuts through the region where the liver (1) joins the intestine (2). The brain b cut in the region of the myelencephalon (8) as shown by the thin roof. Lying beneath it is the nc^odiord (10) and just below this is a smaller rod, the hypochord (11), formed from the roof of the gut fout^unr separated from it by the dorsal aortae (6) which are h^ uniting together.

6-MM. EMBRYO

pronephros. SO X- of cloacal opening.

(3), notochord (4), and hypochord (5). On either side is one of the tail myotomes (6). Beneath the hypochord is the small caudal artery (7), and some little distance beneath this the caudal vein (8). lire tail fiin is composed chiefly of mesenchyme (9) and epidermis (10) with many ciliated cells.

Thk Study of Serial Se(3tion8

I. EPIDERMAL STRUCTURES

b. Stomodeum. A pit on the ventral anterior surface of the head separated by a plate (ectoderm on the outside, endoderm on the inside) from the fore-gut.

c. Proctodeum. A pit on the ventral surface of the trunk where it joins the tail, opening directly into the hind-gut to form the cloaca.

d. Mucous glands. Prominences on the ventral side of the head on either mde of the stomodeum and behind it. Observe deep groove in each.

3. Hypophysis, a derivative from the anterior end of the stomodeum. It will unite with the infundibulum to form the pituitary gland.

c. Mesencephalon. With a thick roof. Lies between optic cups and above the infundibulum.

d. Metencephalon. A thin roof. Lies between otic vesicles.

f. Spinal cord. Thick walls, thinner roof and floor. Continues back into tail almost to the end.

lU. SENSE ORGANS OF THE HEAD

a. Nasal (olfactory) pit. Most anterior sense organ, on ventral side of head, mark^ by thickness of epitiielium and opeiung to the exterior <mly.

joined to diencephalon by optic stalk.

2. Lem vesicle. With central cavity, located in mouth of optic

cup Md separated from epidermis.

a. Anterior to the otic vesicle and proceeding forward.

b. Posterior to the otic vesicle and proceeding backward.

1. Glossopharyngeal ganglion. Just posterior to the otic vesi

IX.

a. Mouth. The region of the fore-gut just behind the plate separating it from the stomodeum will form the oral cavity of the mouth. This continues as pharynx.

b. Pharynx. This region with its visceral (pharyngeal) pouches is best seen in frontal section (Fig. 10). Lay your ruler across this figure and draw a line to show the position of the transverse section shown in Fig. 7.

c. Thyroid gland. Originates from the floor of the pharynx as a solid rod from the level of the second visceral pouch to the fifth.

d. Liver. The liver diverticulum noted in the 3-mm. embryo has grown forward towards the heart. The posterior ventral portion shown in Fig. 8 will become the gall bladder.

e. Intestine. From the liver backward the mid-gut becomes the intestine, with a small cavity and an exceedingly thick floor which contains the yolk.

f. Cloaca. Starting with the proctodeum trace the cloaca forward until it unites with two small longitudinal tubes, the pronephric ducts (see later).

g. Hypochord. This is a small rod of endoderm separating from the roof of die gut and lying beneath the notochord. It extends back into the tail.

III. nERivATivEs OF THE SOMITES. The souiites extend from behind the otic vesicle well into die tail. There are thirteen somitra in the trunk and approximately twenty more in the tail. The inner ventral portion of each so^te (sderotome) is now broken down into a mesenchymal tissue investing the not^ord and neural tube from which the axial skeleton will be framed. The dermatome or outer layer (from which the dermis of the skin will develop) is still associated with the musdeforming remainder of the somite or myotome. In these myotomes musde fibers are developing.

b. Pronepkric duct. Originates from the last pnmeplurie tiibe and craitinues in the ventral portion of the neidtrotranal band, lyaaa the pHTon^hric duct to its junction with the doaea,

a. Somatic meeoderm. CSomSy apqilied to the cbfihdend in; trunk. â–  '

b. Splanchnic mesoderm. Closely applied to the endoderm in the trunk region.

c. Coelom. The cavity located between the somatic and splanchnic layers of mesoderm. The anterior portion of the coelom known as the pericardial cavity surrounds the heart. The coelom is not to be found in the head or tail.

d. Mesenteries. The right and left splanchnic and somatic layers of the mesoderm unite above the intestine and heart. These regions constitute the dorsal mesentery and dorsal mesocardium, respectively.

VI. cntcuiATORY SYSTEM. The blood vessels and lymphatics of the frog embryo originate in a system or network of capillaries (plexus) associated with the organ systems and derived from splanchnic mesoderm in the trunk region or from mesenchyme in the head or tail. They are best demonstrated by injection^ preparations.

a. Heart. Locate the heart, at the level of the external gills, proceeding backward until it divides into two large vessels entering from the liver.

1. Sinus venosus. The point where the two vessels converge,

forming a stubby inverted Y.

2. Atrium. The sinus continues forward and dorsal, bending to

3. Ventricle. The heart in more anterior sections takes on the appearance of a reversed C. The lower limb bending from the atrium to the left side is the ventricle.

4. Bulbus arteriosus. Continuing forward, the lower left por

tion of the reversed C becomes detached from the atrium and is now known as the bulbus.

b. Arteries.

1. Of the head.

Ventral aorta {truncus arteriosus). Following the bulbus

towards the head, it immediately assumes the form of a letter T. The base represents the bulbus, the shaft the short ventral aorta, and the right and left arms at the top are the branches of the truncus which later subdivide , to form the afferent branchial arteries.

Afferent branchial arteries. Three on each side, located in the first, second, and third branchial arches (visceral arches III, IV, and V). Those of the fourth branchial arch have not yet appeared.

side unite to form an aortic root.

»The aSerent aad effemst branchial arteries are the representatives of the aortic arches III, IV, and V, generally devel^SQ^j^vutebraSs embryos.

Dorad aorta. Formed by the union of the right and left radices aortae in the region of the pronephros.

3. Of the tail.

Caudal artery. The direct continuation of the dorsal aorta.

c. Veins.

1. Splanchnic.

Vitelline (omphalomesenteric) veins. These arise on the ventral side of the thick-walled gut and pass forward around the liver to join the heart at the sinus venosus.

2. Somatic (cardinal system).

Anterior cardinal veins. These collect the blood from nu- ^ merous small tributaries in the head and convey it backward as far as the pronephros, where they turn and bend sharply downward to course along the anterior surface of that organ.

Posterior cardinal veins. These vessels course forward from the region of the cloaca ventral and lateral to the dorsal aorta, passing along the ventral surface of the pronephros until they meet and join the anterior cardinal veins.

Common cardinal veins (ducts of Cuvier). These vessels, formed by the union of the anterior and posterior cardinals on each side, course downward and enter the sinus venosus at points just dorsal to and lateral of the vitelline veins.

Caudal vein. This courses through the tail just ventral to the caudal artery. It divides into two branches which unite with the posterior cardinal veins on meeting the cloaca. Further details of the smaller arteries, veins, and lymphatics are omitted. The more advanced student is referred to the textbook and its references.

11 -MM. EMBRYO (Stage 2S, Opercuhm Ccanplete)

The embryo of Rana pipiens at the length of 11 mm. has assumed the familiar tadpole sbape. The head and trunk form an ovoid compressed dorsoventrally and the tail, compressed laterally, is twice the length of the body. The mouth is open and surrounded by homy raspers or oral combs. Tlie mucous glands have degenerated but persist as two small vestiges. The large eyes protrude sli^tly. The openings of the nose, external nares, are located anterior to the eyes. The external gills are covered by op^cular folds developed from the hyoid arches (visceral arch II). This fold is fused with the ectoderm of the body on the right side, but on the left an opening, the spiracle or <^>ercular I4»ertur8, p^eists. At the base of the tail is the vent or doacal aperture.

Make a drawing of the frog embryo from the left side.

The ll-mm. tadpole is a larval stage in the development of the frog. It is a free-swimming animal carrying on all the functions of animal life except that of reproduction. It is to be expected, therefore, that its internal anatomy will be more complex than that of the embryos studied heretofore. Accordingly drawings of certain organ systems are provided, based on wax reconstructions. The student is expected to trace the organ systems through the series of transverse sections, noting in the marginal blanks the number of the slide, row, and section in which each particular structure is well represented. It is suggested that the study be commenced by examining a typical section of the tail and comparing it in detail with the tail of the 6-mm. embryo. It will usually be easier to start at the region of the cloaca and trace all structures forward.

ECTODERMAL DERIVATIVES