1. A description has been given of the differentiation and metamorphosis of the optic glomeruli.

  2. The giant ganglion cells of the larval brain degenerate at the end of the third instar after differentiation to the imaginal brain primordia is completed.

  3. The outer eye glomerulus was found to differentiate from the brain and not from the optic bud.

  4. The ‘fenestrated zone’ of the outer eye ganglion is an artefact, and develops from the histolytic products of the larval tissues in the head.

  5. The condition in the mutant eyeless is discussed.

Short descriptions of certain parts of the brain of Drosophila have been given by a few workers. Richard & Furrow (1925) briefly considered the optic ganglia in their study of the eyeless mutant. Others have given a more generalized account of the different brain glomeruli (Hertweck, 1931; Strasburger, 1932; Power, 1943). However, no study has been made of the extent of differentiation of the imaginal brain in the larvae nor has there been any investigation of its development during metamorphosis.

In the present work a description of the differentiation and metamorphosis of the optic glomeruli will be given. Material was collected at 5-hourly intervals, from hatching till 50 hours after the formation of the puparium. Hot Bouin was used as a fixative. Larvae were treated by Peterfi’s celloidin method of double embedding. Puparia-free pupae were transferred to amyl acetate after being dehydrated in 90 per cent, alcohol. The application of silver impregnation techniques for staining was found unnecessary, since Delafield’s haematoxylin was fairly satisfactory.

The structure of the imaginal optic glomeruli

The following brief description of the optic glomeruli of the adult has been mainly compiled from the work of Cajal & Sanchez (1915) and Power (1943).

The brain of Drosophila is composed of a cellular cortex and a fibrous core which is organized into aggregates of fibres called ganglia or glomeruli (Plate 1, fig. A). The optic lobes which make up the lateral portions of the brain hemispheres contain, in addition to the cellular cortex, three optic glomeruli: (1) The external glomerulus and its auxiliary layers; these are the ‘intermediate retina’ of Cajal & Sanchez, since they designated the layer of ommatidia as the ‘peripheral layer’. In frontal sections the structure is arc-shaped, with the convex surface more or less parallel to the faceted area. It is connected to the middle glomerulus by a true chiasma, whose two arms can only be seen in frontal sections. (2) The middle glomerulus appears as an oblong saucer whose thickness is about one-third its smaller diameter; it has several diagnostic features based on the arrangement of its component fibres (Power, 1943). (3) The internal glomerulus is a compound structure, made up of two unequal glomerular masses which are separated by the internal chiasma. The larger component is oval and lies anteriorly and is called the anterior inner glomerulus. The smaller is called the posterior inner glomerulus. The internal chiasma is not a true crossing, and originates from the fibres of the external chiasma after penetrating the whole width of the middle glomerulus.

The brain of the early larva

The brain of the newly hatched larva is composed of two cerebral hemispheres which are supra-oesophageal and are connected ventrally to the ventral ganglion. In sections, the brain cortex is largely composed of larval ganglion cells, with a lesser number of much smaller cells which have an intense affinity for basic dyes; a study of their development shows that they represent the primordia of some of the imaginal neurons. A third type of cell, which is distinguished by its much larger size occurs in very small numbers at the periphery of the cortex; these cells are called giant ganglion cells. Their number increases considerably in later stages. They have frequently been used for cytological studies on mitosis. Their function, however, is unknown.

In addition to these three types of cellular components of the brain hemispheres, there are imaginal nerve-cells which are arranged in two regular epithelia and lie in the caudal part of each hemisphere just next to the point of fusion with the ventral ganglion.

The detailed structure of these imaginal epithelia was easiest to study in late second or early third instar larvae where the nerve-supply to the cephalic complex makes its first appearance. Investigations of material of this age (Plate 1, fig. B) have shown that the two imaginal epithelia are parallel to each other and that they extend from the posterior margin of the fibrous brain mass to the extreme posterior end of the cerebral cortex. In transverse sections (Plate 1, fig. C) the ventral or outer epithelium appears saucer-shaped with inwardly bent lateral ends. It is interrupted in its middle part and it is through this interruption that the optic nerve leaves the brain (Plate 1, fig. C). The dorsal or inner epithelium is straight and is again discontinuous, but in this case in its anterior part next to the fibrous core. The nervous tissue included between these two imaginal epithelia appears to consist mainly, as shown in Plate 1, fig. C, of imaginal nerve-cells which, as will be shown later, represent the future outer glomerulus of the adult.

The origin of the optic nerve

The origin of the optic nerve was easiest to study in early stages of the third instar (Plate 1, fig. D). It was found that the fibrous mass of each brain hemisphere extends through the pore of the inner imaginal epithelium and extends as the optic nerve through the aperture of the outer epithelium. Later in the third instar, the proximal part of this extension differentiates into the outer fibrous mass while the distal part, which forms the optic nerve, sub-differentiates into structures which will be dealt with later.

The brain of mid-third instar larvae

While the brain hemispheres of early larval stages were more or less oval, as shown in Plate 1, fig. C, they become more rounded in mid-third instar larvae (Plate 1, figs. D and E). The change from oval to rounded is accompanied by a change in the position of the imaginal epithelia relative to the rest of the brain; the ventral epithelium has become ventro-lateral and the dorsal epithelium lies inside it. We may therefore refer to these two layers as outer and inner imaginal epithelia respectively.

The primordium of the outer glomerulus (ganglion) has increased considerably in size and shows a tendency to protrude through the aperture of the outer imaginal epithelium, which has somewhat increased in diameter (Plate 1, fig. D). In slightly older stages the former undergoes more protrusion as indicated in Plate 1, fig. E, and finally lies outside the rest of the brain. This process of protrusion has gradually brought about the extravasation of the lip of the pore of the outer imaginal epithelium.

In 75-hour-old larvae (Plate 1, fig. E) the future outer ganglion has become differentiated into two distinguishable regions. There is a large outer segment of condensed cells, which is separated by a fibrous layer from a much thinner inner region which is made up of the same type of cells. Investigations of earlier stages showed that this sub-differentiation of the outer ganglion occurred in the late second instar larvae soon after the appearance of the optic nerve. The latter originates from the distal portion of the protrusion of the fibrous core (Plate 1, fig. F); the bundle of fibres, after extending for a short distance through the outer ganglion, forms a longitudinal fibrous band from which side branches extend through the whole length of the remaining major part of the outer ganglion and unite outside the brain to form the optic nerve proper.

In 85-hour-old larvae the lip of the pore of the inner imaginal epithelium proliferates, its cells being pushed across the middle of the enlarged outer fibrous core and coming finally to rest on the ventral cortical cells just caudal to the future outer ganglion (Text-fig. 1). Subsequently, the outer fibrous core becomes divided into two equal portions which are separated by an interglomerular bridge. These two divisions represent the fibrous cores of the middle and inner glomeruli.

Text-fig. 1.

Diagrammatic representation of a transverse section of late third instar brain. For abbreviations see ‘Explanation of Plates’.

Text-fig. 1.

Diagrammatic representation of a transverse section of late third instar brain. For abbreviations see ‘Explanation of Plates’.

Formation of the optic chiasma

While fibrous extensions from the inner fibrous core of the brain hemispheres penetrate the future outer ganglion to form the optic nerve, the nerve-cells of the outer eye ganglion give rise to fibres which extend in the opposite direction and form the external and later the internal chiasma (Text-fig. 2).

Text-fig. 2.

Diagrammatic representation of the formation of the outer chiasma. For abbreviations see ‘Explanation of Plates’.

Text-fig. 2.

Diagrammatic representation of the formation of the outer chiasma. For abbreviations see ‘Explanation of Plates’.

Fibres of the outer ganglion leave its inner end in two separate collections (Text-fig. 2). One of these collections develops extensively so as to cover a large part of the border of the middle eye glomerulus. The other collection crosses the first one and runs along the non-inervated small part of the middle glomerulus. A chiasma composed of two unequal arms is thus formed. This external chiasma gives rise to fibres which penetrate the whole width of the middle glomerulus and further penetrate the inter-glomerular bridge and form a nervebundle which separates the inner glomerulus into two unequal glomeruli.

It will be obvious from the previous description that the three optic glomeruli and their important nerve-bundles become fully differentiated in late third instar larvae. A very significant phenomenon which was observed to occur simultaneously with the completion of differentiation was that the giant ganglion cells exhibit symptoms of degeneration so that late third instar brains do not contain them.

Metamorphosis of the brain

In 3-hour-old prepupa the brain hemispheres have become pear-shaped (Plate 2, fig. G). This may be attributed to the contraction of the cephalic complex during the formation of the puparium; this pulls the optic nerve which, in turn, stretches the lateral part of the brain in the region of the future eye ganglia. It is known that the optic bud metamorphoses to the ommatidial layer and to a part of the imaginal head hypodermis. It may be of interest that, as shown in Plate 2, fig. G, the optic nerve is biramous and that the segment of the optic bud located between the two arms represents the future eye tissue, and that the rest of the optic bud epithelium will become head hypodermis.

Cross sections of early pupal stages (Plate 2, fig. H) reveal that the cerebral hemispheres have become rounded again. The middle and inner optic glomeruli have become more defined and differentiated. Proliferations of the inner imaginal epithelium have largely replaced the ventral larval nerve-cells and formed the imaginal cortex of the inner imaginal glomerulus (Plate 2, fig. I). On the other hand, proliferations of the outer imaginal epithelium have developed into the cortex which surrounds the outer eye ganglion. The imaginal nerve-cells which were scattered between the larval nerve-cells have metamorphosed to the rest of the imaginal cortex.

Fig. J of Plate 2 is a fronto-dorsal section of the same stage as fig. I, and shows that the optic nerve has developed a network of nerve-fibres underneath the eye tissue, which appears contracted.

By 8 hours after pupation the eye tissue has stretched over a large area of the lateral sides of the head, and the optic nerve has expanded equally. The network of fibres of the optic nerve has become connected to the ommatidial layer. It is also at this stage that some of the histolytic products of the larval tissues in the head tend to be enclosed within the fibre network thus giving rise to a false tissue which has been described by several authors as a component layer of the outer eye glomerulus and was given the name fenestrated zone.

In 30-hour-old pupae the inner and outer imaginal epithelia have become exhausted. The optic nerve has contracted sufficiently to bring about protrusion of the outer eye glomerulus which becomes separated from the rest of the brain by the outer chiasma which connects it with the middle glomerulus. It may be interesting to know that the inner and middle glomeruli, which only appeared in cross sections of earlier stages, would only appear in horizontal sections of this stage. This must be the result of the rotation of the brain hemisphere through an angle of 90°.

Kopec (1922) removed the brain of larval Lymantria without injuring the eye rudiment and found that there was neural tissue beneath the ommatidia of the imago. Bodenstein (1939) obtained similar results from transplanted eye-buds of Drosophila. Pilkington (1942) claimed that in his six successful transplants of wild type eye-buds, the external glomeruli developed from the eye-buds and not from the brain. This was indirectly supported by Power (1943), who found that (1) eyeless individuals with a complete absence of one or both eyes have no external glomerulus on the side which is eyeless, and (2) ten eyeless individuals were found with eyes that were not connected to the brain and these showed eyes with external glomeruli. However, as reported by Power, their structure was not normal, since the ‘fenestrated zone’ was hypertrophied and the external glomerulus proper did not show the normal diagnostic histological traits.

The previous description of the differentiation and development of the outer eye glomerulus has shown that it develops, like the other glomeruli, from the brain hemisphere and not from the optic bud. This histological evidence has been supplemented by transplantation experiments carried out along the same line as those of Bodenstein and Pilkington. Results of experiments of this kind should be carefully examined because, just as morphological artefacts exist, experimental ones may possibly occur.

Late third instar optic buds were transplanted into wild-type hosts of the same age, and shortly before the imagos hatched the transplanted eyes were dissected out and sectioned. Microscopic examinations of these buds agreed with the previous workers in that a layer of nondescript tissue with pycnotic nuclei was found beneath the layer of ommatidia. However, the study of hosts with transplants which were fixed at short successive intervals from the late third instar has shown that this tissue, which other authors have believed to be the outer eye glomerulus, is formed from the disintegration products of the larval tissues, which tend to accumulate around developing transplants.

These results suggest that the absence of the outer glomerulus in eyeless flies is not due to the absence of the optic bud which, according to Chen (1929), disintegrates at the end of the second instar. It may be that the eyeless mutation prevents the differentiation of the outer glomerulus as well as causing the disintegration of the optic bud; or it may primarily affect the differentiation of the former which secondarily influences the latter. However, the structure of the brain of third instar eyeless larvae was reported by Chen to be normal, and it seems therefore necessary to check Chen’s results before any conclusion about the action of the eyeless mutation can be made.

We have seen that the size of the giant ganglion-cell tissue increases in step with the pre-imaginal differentiation of the optic glomeruli. At the end of the third instar, when differentiation is completed, the giant ganglion cells exhibit symptoms of degeneration and later disappear. Similar phenomena occur in several other developing tissues of Drosophila. For instance, the lymph glands of the late third instar wild-type larvae degenerate after the imaginal buds have become differentiated. Another example is the degeneration of ‘activating cells’ derived from the lymph glands after the larval primordia have been brought to the state when they can begin imaginal differentiation (Shatoury, 1956 and in preparation). In these cases the degenerative changes were envisaged in terms of immunological phenomena, that is to say, the tissues become antigenic to the individual of which they form part and stimulate the production of immune bodies whose effect was shown in all cases by complement-reactions. The behaviour of the giant ganglion cells after the optic ganglia have differentiated is easy to explain in similar terms. We may assume that the former induces the differentiation of the latter and that at the end of the third instar they become involved in an immune reaction. This hypothesis is now being tested in mutants where the giant cells are antagonized in early larval stages.

I am very grateful to Professor C. H. Waddington, F.R.S., for reading and correcting the manuscript.

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Plate 1

Fig. A. Frontal section in the head of a late pupa, × 210.

Fig. B. Medio-sagittal section in the brain and ventral ganglion of an early third instar larva. x210.

Fig. C. Transverse section in the brain of same stage as fig. B. × 500.

Fig. D. Transverse section in the brain of 10-hour-old third instar larva, × 210.

Fig. E. Transverse section in the brain of mid-third instar larva, × 225.

Fig. F. Section in the brain of late third instar larva showing the origin of the optic nerve, × 500.

Plate 1

Fig. A. Frontal section in the head of a late pupa, × 210.

Fig. B. Medio-sagittal section in the brain and ventral ganglion of an early third instar larva. x210.

Fig. C. Transverse section in the brain of same stage as fig. B. × 500.

Fig. D. Transverse section in the brain of 10-hour-old third instar larva, × 210.

Fig. E. Transverse section in the brain of mid-third instar larva, × 225.

Fig. F. Section in the brain of late third instar larva showing the origin of the optic nerve, × 500.

Plate 2

Fig. G. Horizontal section in a 3-hour-old prepupa, × 210.

Fig. H. Transverse section in early pupa. x210.

Fig. I. Transverse section of a pupa slightly older than that in fig. H. × 210.

Fig. J. Front-dorsal section of same stage as fig. I. × 210.

Plate 2

Fig. G. Horizontal section in a 3-hour-old prepupa, × 210.

Fig. H. Transverse section in early pupa. x210.

Fig. I. Transverse section of a pupa slightly older than that in fig. H. × 210.

Fig. J. Front-dorsal section of same stage as fig. I. × 210.

     
  • DIE

    upper imaginal epithelium

  •  
  • EIF

    extension of the inner fibrous core

  •  
  • ET

    eye tissue

  •  
  • FB

    fibrous band of the optic nerve

  •  
  • GGC

    giant ganglion cells

  •  
  • ICH

    inner chiasma

  •  
  • icx

    imaginal cortex of the inner glomerulus

  •  
  • IEG

    inner eye glomerulus

  •  
  • IFC

    inner fibrous core

  •  
  • IGC

    imaginal ganglion cells

  •  
  • HE

    inner imaginal epithelium

  •  
  • INGB

    inter-glomerular bridge

  •  
  • ISG

    inner segment of the outer glomerulus

  •  
  • MEG

    middle glomerulus

  •  
  • OCH

    outer chiasma

  •  
  • OEG

    outer glomerulus

  •  
  • OFC

    outer fibrous core

  •  
  • OIE

    outer imaginal epithelium

  •  
  • OL

    ommatidia layer

  •  
  • ON

    optic nerve

  •  
  • OON

    origin of optic nerve

  •  
  • LGC

    larval ganglion cells

  •  
  • VIE

    ventral imaginal epithelium.