Animal

The female silkworms, Bombyx mori L., we used were F1 hybrids of the bivoltine races ‘Kinshu’ and ‘Showa’. The eggs were incubated at 26°C under illumination. The larvae were reared on a commercially available artificial diet (Yakult Co., Japan) at 26 ± 1°C with a photoperiod of 16L: 8D. Pupae and adults were maintained under the same conditions.

Lucifer Yellow filling

The head of a 5th instar larva was isolated and mounted in an experimental chamber using beeswax. The chamber was filled with physiological saline designed to mimic extracellular conditions within the brain [25]. The SG was exposed by removing surrounding tissues. A pair of insect pins was placed under the SG of a larva to provide a supporting platform for the larval brain. The head of a pupa or a pharate adult was isolated and mounted, ventral or frontal side up, in the chamber. The SG was exposed by removing part of the cuticle over the ganglion. After incubation for 10–20 s in saline containing 1% pronase (Kaken Seiyaku Co. Japan), the sheath of the SG was partially removed, using a fine tungsten needle.

Under visual guidance, a soma of a neurosecretory or non-neurosecretory cell located around the ventral midline of the SG was penetrated with a bevelled glass microelectrode filled with 10% Lucifer Yellow CH (Sigma). An indifferent electrode was placed in the chamber. The microelectrode was connected to a preamplifier (MEZ-8201, Nihon Kohden), which allowed simultaneous recording and current injection via a bridge circuit. An action potential was induced from the soma by passing a depolarizing current pulse (3–4 nA, 3 ms in duration). Intracellular action potentials and signals for injected currents were displayed and stored on a memory oscilloscope (VC-10, Nihon Kohden).

Lucifer Yellow (LY) was iontophoretically injected by passing a hyperpolarizing current (3 nA) for 5–10 min. Subsequently the preparation was maintained at room temperature (19–23°C) for 1 hr. The tissues containing the dye were dissected out together with parts of associated structures (e.g. aorta and oesophagus) and fixed with 4% formaldehyde in 0.15 M sodium phosphate buffer (pH 7.4) for 30 min. The tissues were then washed for 30 min in the buffer, dehydrated, cleared with methyl salicylate and gently compressed under the weight of a coverslip or by a finger. The preparations were viewed and photographed immediately at various focal planes, using a fluorescence photomicroscope (Nikon). The structure of LY-filled cells was reconstructed from photographic films, using a photographic enlarging projector.

Antisera production

Two peptides corresponding to the amino-terminal 12-amino acid sequence of DH and the amino-terminal 15-amino acid sequence of PBAN, both added a cysteine at the carboxyl terminus, were synthesized at The University of Tokyo. These peptides were conjugated with bovine serum albumin (BSA). Six female BALB/c mice were immunized at 2–3 week intervals by giving an intraperitoneal injection of DH(1–12)-Cys-BSA (20 μg/mouse) in Freund's complete adjuvant. Three days after each injection, the mice were bled from the tail vein and the blood was centrifuged. Antibody detection in each mouse serum was carried out by dot-immunobinding assay using the synthetic DH(1–12)-Cys. After injecting the antigen five times, the antibody activity of all mice was detected at 6,000-fold dilution of the antiserum. An antibody for PBAN(1–15)-Cys-BSA was developed by immunizing a rabbit. After injecting 0.4 mg of antigen four times at 2 week intervals, the antibody was detected at 5,000-fold dilution of the antiserum.

Immunocytochemistry

Larval SGs were isolated and the ventral sheath of the ganglions was partially removed. The tissues were fixed in Bouin's solution for 2 hr at room temperature, then were rinsed for 15 hr in phosphate-buffered saline containing 0.2% Triton X-100 (PBT, pH 7.4) and incubated at 4°C for 3 days in rabbit anti-PBAN antiserum diluted 1:250 in PBT containing 0.25% BSA. These tissues were then washed in PBT at room temperature and soaked for 2 hr in rhodamine-labeled goat anti-rabbit IgG antiserum diluted 1:40 in PBT. Next, they were washed in phosphate-buffered saline (PBS), dehydrated and cleared with methyl salicylate. Immunoreactivity of some LY-filled cells was examined in whole mount preparations stained using the same immunocytochemical method described above. The primary and secondary antisera were sometimes replaced with mouse anti-DH and rhodamine-labeled rabbit antimouse IgG antisera, respectively.

DH/PBAN immunoreactive cells of a pupa and an adult moth were usually examined in sectioned preparations because of relatively strong autofluorescence of the SG after pupation. The isolated brain-SG complex was placed in the fixative, dehydrated, soaked in xylene and embedded in paraffin. Serial sections were deparaffinized, rehydrated, washed in PBT and preincubated with PBT containing 10% normal goat serum for 1 hr. These sections were then incubated in anti-PBAN (or anti-DH) antiserum overnight at 4°C. The primary antiserum was diluted 1:500 in PBT. The sections were then rinsed in PBS and exposed to a rhodamine-labeled goat anti-rabbit (or anti-mouse) IgG antiserum diluted 1:30 for 1 hr. After another rinse in PBS, the sections were mounted with glycerol. Sections were sometimes double-labeled using two primary antisera (rabbit anti-PBAN and mouse anti-DH antisera) and two secondary antisera labeled with fluorescein or rhodamine.

For controls concerning the specificity of the immunocytochemical procedure, sections were incubated with the primary antisera inactivated by adding synthetic PBAN-I or DH (1 μg/ml). Immunostaining was almost totally abolished, though in some preparations the somata were faintly stained.

Gross anatomy of brain-SG-retrocerebral neurohaemal organs

Anatomical profile of the brain and SG of the larva appears markedly different from that of the adult as there are gross metamorphic changes in the CNS during adult development. Larval SG is linked to the brain by a pair of long connectives, the circumoesophageal connective, while adult SG is completely fused with the tritocerebral lobe of the brain (Fig. 1). However, all of the major nerve branches associated with the retrocerebral neurohaemal organs, the corpus cardiacum (CC) and the corpus allatum (CA), remain through metamorphosis, despite extensive restructuring of central and peripheral nervous system in the head. The CC-CA complex is connected to the brain by two nerves, nervus corporis cardiaci (NCC) 1 + 2 and NCC 3 and is connected to the SG by NCC-ventralis (NCC-V) and two branches of the maxillary nerve (a and b in Fig. 1). Many thin branches of the maxillary nerve innervating larval muscles in the maxilla appear to be greatly diminished or entirely lost at pupation as the result of changes in target muscles during development. There is a small ellipsoidal node at the point where the two branches of the maxillary nerve join together into the NCC-V. A thin nerve (NCC-RN) extending medially from the CC joins the recurrent nerve.

Fig. 1

Semi-schematic diagrams of the brain-suboesophageal ganglion and connections to retrocerebral neurohaemal organs in the larval (A) and adult silkworm moth (B). Br, brain; CA, corpus allatum; CC, corpus cardiacum; Fr, frontal ganglion; Lb, labial nerve; Md, mandibular nerve; Mx, maxillary nerve; NCC-V, nevus corporis cardiaci ventralis; RN, recurrent nerve; n, node; SG, suboesophageal ganglion. a-c, axonal pathways of DH/PBAN immunoreactive cells.

Localization of DH/PBAN immunoreactive cells

Twelve neurosecretory cells in the SG showed potent immunoreactivity to the rabbit anti-PBAN antiserum. In larva, the somata are localized at three distinct regions, as clusters on the ventral midline of the SG (Fig. 2A). The anterior, medial and posterior clusters are comprised of four, six and two somata, respectively. All neurosecretory cells at larval stage were strongly immunoreactive. At an early pupal stage, SG fuses to the brain and the anterior portion of SG extends laterally to connect to the ventral edge of the brain. The anterior cells move laterally to separate into two clusters as a result of metamorphic changes of the SG (Fig. 2B). The anterior and medial cells at pupal and adult stages were also strongly immunoreactive, whereas immunoreactivity of the posterior cells at the late pupal and adult stages were usually weak (Fig. 2B).

Fig. 2

Ventral views of PBAN immunoreactive cells' somata in the larval (A) and adult SG (B). A, anterior cell (cluster); M, medial cell cluster; P, posterior cell cluster. Bundles of immunoreactive axonal processes (arrowheads) are seen, though they are out of focus in this picture. Inset illustrates a medial cell that has been intracellularly injected with Lucifer Yellow. Scale bars, 100 μm.

Immunocytochemical visualization of the DH/PBAN immunoreactive cells revealed that the anterior and medial cells project an axon into the maxillary nerve while the posterior cells extend an axon to the circumoesophageal connective. Visualization of the entire length of axonal tracts of the cells was not feasible as immunoreactivity of the axons usually disappeared in the maxillary nerve or the connective. Immunoreactive axons often re-appeared in a branch of the maxillary nerve before reaching the node (cf. Fig. 3E).

Fig. 3

Photomicrographs of an anterior and a medial cell in the larval SG visualized by injection of Lucifer Yellow (A-D) or PBAN immunocytochemistry (E, F). A. Ventral view of an anterior cell. S, a soma (out of focus); arrowhead, an axon. B. Axonal profile of the anterior cell. The axon (single arrowhead) is smooth in appearance before reaching the node (arrow), but has varicose appearance in the node and the NCC-V (double arrowheads). C. Varicose axonal processes in the corpus cardiacum (CC). CA, corpus allatum. D. Ventral view of a medial cell. S, a soma; arrowhead, an axon. E. PBAN immunoreactive axonal processes. They (single arrowhead) appear smooth before invading the node (arrow), but give rise to varicose branches in the node and the NCC-V (double arrowheads). F. Varicose branches in the node (n). m, a muscle; t, trachea. Scale bars, 100 μm (A, D), 50 μm (B, C, E, F).

Although we used mostly the anti-PBAN antiserum, similar results were obtained when the anti-DH antiserum was used as a primary antiserum. Double labeling of cells using anti-DH and anti-PBAN antisera revealed that the same three clusters of neurosecretory cells were immunoreactive with the two antisera (data not shown).

Structure of DH/PBAN immunoreactive cells

Somata of neurosecretory cells in the SG could often be distinguished by their opalescence. We impaled many opalescent somata at the three regions where DH/PBAN immunoreactive cells were expected to be present. Before injecting LY, action potentials of an impaled cell were recorded because a neurosecretory cell was discernible from a non-neurosecretory cell by large and prolonged action potentials [12, 25]. All those neurosecretory cells present at medial and posterior regions were DH/PBAN immunoreactive cells (inset of Fig. 2A), but cells at the anterior region were sometimes different neurosecretory cells with no immunoreactivity to the antisera and an axon projecting to the mandibular nerve.

Anterior and medial cells:

Injection of LY into a soma of an anterior or a medial cell of the larva revealed that the primary neurite originating from the soma extended for some distance posteriorly or dorsally and bifurcated into dendritic processes. The dendritic processes of the anterior and medial cells are shaped “π” (Fig. 3A) or T (Fig. 4A) and X (Figs. 3D, 4B), respectively. An axon originating from one of the dendritic processes extends laterally and turns anteriorly to enter the maxillary nerve contralateral to cell's soma. All seven anterior cells examined in this study had an axon that ran in the maxillary nerve toward the mandible and turned posteriorly to reach the ellipsoidal node (route a in Fig. 1A). Six out of eleven medial cells examined had such a long axon and the others had a relatively short axon that entered a shortcut branch on the halfway (route b in Fig. 1A) to reach the node. Axons of both anterior and medial cells had a few varicose branches in the node where two cells of unknown origin were present (Fig. 3B,F). Axons leaving the node passed through the NCC-V and reached the CC (Figs. 3C and 4A, B). They usually invaded into a nerve (NCC-RN) and had a varicose appearance not only in the CC but also in the full length of the NCC-V (Fig. 3B). Such a structural specialization is often present in immunocytochemical preparations (Fig. 3E).

Fig. 4

Drawings of an anterior (A) and a medial cell (B) in the larval SG. CA, corpus allatum; CC, corpus cardiacum; NCC 1 + 2, fused nerve of nervus corporis cardiaci 1 and 2; NCC 3, nervus corporis cardiaci 3; NCC-V, nervus corporis cardiaci ventralis; NCC-RN, nervus corporis cardiaci recurrens that joins the recurrent nerve.

Although the anatomical appearance of neurosecretory cells at a late pupal or an adult stage somewhat differs from that at the larval stage because of the gross anatomical change of SG during adult development, branching patterns of primary dendrites of the cells are basically similar to those of larval cells (Fig. 5). Axons of pupal or adult cells, like the larval cells, extended toward the node and NCC-V via two branches of the maxillary nerve (route a and b in Fig. 1B). Varicose branches of those axons could be observed in the node, but no axon could be traced to its terminal in the CC, using the dye-filling method because of elongation of NCC-V during development.

Fig. 5

Dorsal views of an anterior (A) and a medial cell (B) in adult females. Axons exit the SG into the maxillary nerve at the points indicated by arrowheads.

Posterior cells:

Fig. 6A shows a pair of posterior cells visualized by LY injection. Position of both somata, dendritic branches and axonal pathways are almost symmetric around the midline of the ganglion. LY injection into a single cell reveals that each cell has a symmetric dendritic abor and dendritic branches of the two cells overlap (Fig. 7A). The primary neurite extending from the soma runs toward the dorsal surface for a short distance, then turns anteriorly to bifurcate into dendritic processes. Two dendritic processes run side by side along the midline of the SG for some distance and each process turns laterally and then posteriorly to give off many fine branches. An axon originating from the primary neurite or one of the dendritic processes extends laterally and turns anteriorly to enter the circumoesophageal connective contralateral to the cell's soma. The axon, after running up the connective (route c in Fig. 1A) and passing through the lateral part of the brain, enters the nerves corpus cardiaci 3 (NCC 3) to project to the CC, an area where the terminal branches form a complex network of numerous varicosities. A few terminal branches invaded the associated nerves of the CC, NCC-RN and NCC-V (Figs. 6B, 7B) but did not invade the corpus allatum (CA).

Fig. 6

Photographs of posterior cells in the SG of a 5th instar larva (A,B), a 4-day old pupa (C) and an adult moth (D,E). A. Ventral view of larval SG. S, a soma (out of focus); arrowhead, an axon. B. Dorsal view of larval neurohaemal organs, the corpus cardiacum (CC) and the corpus allatum (CA). arrowhead, a smooth axon in the NCC 3; double arrowheads, varicose axonal branches projecting to the recurrent nerve. C. Ventral view of pupal SG. S, a soma (out of focus); arrowhead, an axon. D. Frontal view of adult SG. S, a soma. E. Ventral view of adult corpus cardiacum (CC). arrowhead, an axonal process invading the recurrent nerve; double arrowheads, an axonal branch in the allatal nerve. Scale bars, 100 μm (A, C, D) or 50 μm (B, E).

Fig. 7

A. Ventral view of a posterior cell in a 5th instar larva. B. Dorsal view of an axon terminal of the cell. Abbreviations are the same as for Fig. 4.

Figure 6C shows a ventral view of a posterior cell of a pupa at 4 days after pupation, a time when the brain-SG complex takes on an adult form. The bilateral dendritic branches expand to cover the anterior edge of the neuropile around the oesophageal foramen. The axon first projects postero-dorsally and finally leaves the brain posteriorly after a few turns in the brain-SG complex. The anatomical profile of the cells in the brain-SG complex at the adult stage is almost identical to that in the complex at the mid-pupal stage (Figs. 6D and 8A,B). Their axons are characterized by dense fasciculation in the CC and many fine, parallel branches in the recurrent nerve under the aorta (Figs. 6E and 8C). A few branches invading the allatal nerve (NCA) reach the proximal portion of the corpora allata (CA) (Fig. 8C).

Fig. 8

Ventral (A) and frontal view (B) of a posterior cell and its axon terminal (C) of an adult female. OF, oesophageal foramen; CC, corpus cardiacum; CA, corpus allatum; NCC 1 + 2, nervi corporis cardiaca 1 and 2; NCC 3, nervus corporis cardiaci 3; NCA, nervus corporis allati.