ALBERT

Notes: Abstract  Using RT-PCR, western blot and enzyme and fluorescence immunocytochemical techniques, the three isoforms of neurofilament proteins (NFPs), namely NF-L (NFP-68 kDa), NF-M (NFP-160 kDa) and NF-H (NFP-200 kDa) were found in Sertoli and Leydig cells of human testes. RT-PCR showed specific for the three NFP fragments in testicular tissue, in isolated seminiferous tubules and in isolated Leydig cells. In protein preparations from the same testicular components, western blot analysis detected bands with molecular weights characteristic for NF-H, NF-M and NF-L. Application of immunofluorescence and immunoenzyme methods on cryostat and paraffin sections resulted in differences in the staining pattern in Sertoli cells and Leydig cells. In these cells, the NFPs showed predominantly a perinuclear location from which bundles emerge that were directed towards the basal, apical and lateral extensions of the Sertoli cells as well as the periphery of Leydig cells. NF-H coexists with vimentin-type filaments as seen by dual staining and staining of conseccutive serial sections of material embedded in paraffin. In Sertoli cells, vimentin and NF-H showed distinct dynamic changes depending on the stage of spermatogenesis and some structural variations of seminiferous tubules. Although in some tubules both vimentin and NF-H immunoreactivity was present at high levels, in the Sertoli cells from most individuals an inverse relationship in the staining intensity of vimentin and NF-H was observed. The strongest NF-H immunoreactivity was detected in Sertoli cells associated with stage 3 spermatids, whereas vimentin immunoreactivity was most abundant in association with stage 5 spermatids. The leydig cells did not show functional changes of the NFP immunoreactivity. The results obtained provide new evidence for the heterogeneous phenotype of human Sertoli cells and raise the question of their exact nature and origin.

Notes: Summary The central catecholamine innervation of the pituitary neural lobe and pars intermedia of the rat have been identified ultrastructurally and their organization has been investigated in a combined fluorescence histochemical and electron microscopical study. The dopamine analogues, 5-hydroxydopamine and 6-hydroxydopamine, were used to “label” the catecholamine terminals, and to enable the direct correlation between the fluorescence microscopical and the electron microscopical pictures. The fibre type that was identified as catecholamine-containing was ultrastructurally chiefly characterized by dense-cored vesicles, 500–1200 Å in diameter, intermingled with varying numbers of small empty vesicles. 5-hydroxydopamine was selectively accumulated in these fibres and caused an increased electron density of the granular vesicles as well as of some small normally agranular vesicles, and systemically administered 6-hydroxydopamine caused a selective degeneration of these fibres, most prominently within the neural lobe. The dopaminergic terminals of the neural lobe showed frequent close contacts (80–120 Å), without real membrane thickenings, to neurosecretory axons and to pituicyte processes. It is suggested that these close contacts might signify a direct dopaminergic influence on the neurosecretory axons and/or on the pituicyte processes. The identified central catecholamine fibres were also found to make common synapse-like contacts on the pars intermedia cells, whereas the innervation by neurosecretory fibres was very rare. This suggests that the direct central nervous control of the rat pars intermedia is exerted by the catecholamine neurons. A very special feature of the catecholamine fibres in the pituitary is the occurrence of peculiar, large dopamine-filled droplet-like swellings. Electron microscopically, such large axonal swellings (more than 2 μ in diameter) were found to contain, in addition to the characteristic vesicles and organelles, strongly osmiophilic lamellated membrane complexes resembling myelin bodies and multivesicular bodies encircling disintegrated vesicles, suggesting that these “droplet fibres” represent dilated stumps of spontaneously degenerating dopaminergic axons. It is suggested that the dopaminergic neural lobe fibres are undergoing continuous reorganization through degeneration—regeneration cycles, a phenomenon previously suggested for the neurosecretory axons of the neural lobe.

Notes: Summary The distribution of lymph vessels in the human testis was investigated using ink injection methods, and light and electron microscopy. Lymph capillaries occur in the septula testis but are absent in the intertubular tissue. They consist of endothelial cells provided with an incomplete basal lamina and anchoring filaments of the adjacent connective tissue. Frequently, the endothelial cells are separated by gaps measuring up to 2μm. The lymph capillaries of the septula testis are connected to lymph vessels in the rete testis and tunica albuginea. These vessels have occasional smooth muscle cells and valves. At the posterior margin of the testis, the network of lymph vessels merges into collecting ducts, which together with vessels derived from the rete testis are drained by the lymphatic system in the spermatic cord.

Notes: Summary The ultrastructure of the lamina propria of human seminiferous tubules was analyzed in normal specimens and compared to biopsies showing great thickenning of this area in light microscopy. The contractile cells are stellate in shape, the intercellular gaps between their branchings being less than 150 Å. The cytoplasmic features of these cells are similar to those described by Ross and Long (1966) and do not differ significantly in the pathological cases examined. The intercellular components, namely collagen fibers, microfibrils and an incomplete basement membrane-like coating of the contractile cells, are strikingly increased in the thickenned lamina propria, although the number of layers making up this structure needs not be increased. Occasionally, the intercellular space is occupied by only one of these materials. The distribution of collagen permits identification of two main patterns in the thickenned lamina propria: a) one where the basement membrane of the seminiferous epithelium is separated from the first layer of contractile cells by a wide collagen zone, and b) another case where the layer displaying greater thickness because of increased collagen deposition is located further away from the germinal epithelium. The functional activity of the contractile cells, the physiological implication of structural alterations of the lamina propria and the necessity to correlate these observations to andrological findings, are discussed.

Notes: Summary The ultrastructure of the normal human rete testis was analyzed. The rete testis cavities are irregularly shaped and contain virtually no spermatozoa. Smooth muscle cells often surround the cavities. In the epithelial lining, two cell types are distinguishable. Flat, dark cells exhibit numerous slender microvilli, and numerous apical and basal microvesicles. Prismatic, lighter cells have more cell organelles, mostly polarized towards a supranuclear position. Both cell types contain variable amounts of glycogen and fat, and an occasional cilium. All cells display intricate lateral cell surfaces that possess different cell-to-cell attachment devices. Intermediate cell types are frequently found. On a morphological basis, the epithelial cells seem to be involved in the release of substances into the lumen and probably also in transport towards the base. Connective tissue elements are found subjacent to the epithelium. Scattered among the fibrocytes are typical smooth muscle cells. Expansions of some smooth muscle cells are connected to the epithelial basement membrane by a network of microfibrillar material. The smooth muscle cells may be involved in changing the shape of the rete testis channels, thus promoting the flux of the rete testis fluid. Different types of nerve fibre bundles are distinguished in the connective tissue of the rete testis which may correspond to autonomic and sensory nerves or sensory receptors.

Notes: Summary Evidence has been obtained by electron microscopy of a direct cytotoxic effect of intraventricularly administered 5,6-dihydroxytryptamine (5,6-DHT) on unmyelinated axons in the rat brain. Ultrastructural signs of axonal damage were observed in areas rich in indolamine nerve terminals as early as 2 hrs after injection. By 6–24 hrs, characteristic and more dramatic signs of degeneration developed, involving coalescence of all axonal constituents—often in combination with a uniform osmiophilic impregnation of the axoplasm—accompanied by engulfment of the dystrophic structures by glial processes. During the next five days, the degenerating axons and axon terminals appeared to be removed by glial cell phagocytosis, whose equivalents were the inclusion of axonal residues into membrane-bound lysosome-like bodies. Concomitantly, there was a progressively increasing number of extremely large and dilated axons in all regions analysed. These axonal swellings, which have an ultramorphology similar to that of dilated stumps of mechanically severed monoamine axons, correspond most probably to proximal, dilated portions of drug-damaged axons. The present results, in combination with biochemical and fluorescence microscopical data, indicate that within a proper dose range the 5,6-DHT-induced degeneration is largely restricted to indolamine axons and axon terminals. However, unselective effects on other unmyelinated axons, on myelin, and on glial cells were observed in narrow subependymal zones close to the lateral ventricles, i.e. close to the injection cannula.

Notes: Summary Ganglia from Auerbach's plexus of the large intestine (caecum, appendix vermiformis, colon transversum and rectum) in man, rhesus monkey and guinea-pig are composed of nerve cells and their processes, typical Schwann cells and a vast neuropil. The neuropil consists of dendrites and axons of intrinsic nerve cell perikarya and axons of extrinsic neurons. Axonal profiles in large nerve fibre bundles are of uniform size and appearance, embedded in infoldings of Schwann cell cytoplasm and contain occasional large granular vesicles, mitochondria and neurotubules. Preterminal axons widen into vesicle filled varicosities, some of which establish synaptic contact with intrinsic nerve cell bodies. At least three different types of neuronal processes can be distinguished in the myenteric neuropil according to the size, appearance and commutual proportion of vesicles present in axonal varicosities, and their ability to accumulate exogenous 5- and 6-hydroxydopamine and 5-hydroxydopa: 1. Axonal enlargements containing a major population of small electron lucent “synaptic” vesicles (350–600 Å in diameter) together with a small number of membrane-bound, opaque granules (800–1,100 Å). These profiles have been identified as “cholinergic” axons. The boutons establish synaptic contacts with dendritic processes of intrinsic nerve cell bodies; membrane specializations are found at the preand postsynaptic sites. 2. Axonal beads of sometimes very large diameter, containing an approximately equal amount of large granular vesicles (850–1,600 Å) and small, electron lucent or faintly opaque vesicles (400–600 Å). The granular core of the large vesicles is of medium electron density and may either fill the entire vesicle or is separated from the limiting membrane by a more or less clear interspace. The fibres probably belong to intrinsic neurons, and because of the similarity of the large, membrane-bound vesicles with neurosecretory elementary granules, they have been designated “p-type fibres” (polypeptide fibres). The granular core of the vesicles in these fibres becomes more electron dense after treatment with 5-OH-dopa. The accumulation of an amine precursor analogue in combination with a possible storage of a polypeptide substance (or an ATP-like substance) resembles the situation in several diffusely distributed endocrine cell systems. 3. Varicosities of axons equipped with small (400–600 Å) empty or sometimes granular vesicles, medium sized (500–900 Å) vesicles with highly electron dense cores and occasional large (900–1,300 Å) granular vesicles. Pretreatment with 5-OH-dopamine increases the electron density in almost all medium-sized granular vesicles and some of the large granular vesicles; an osmiophilic core develops in some small vesicles. 6-hydroxydopamine results in degenerative changes in the varicosities of this type of neurons. Concomitantly, both catecholamine analogues markedly reduce neuronal noradrenaline in the large intestine, as demonstrated by fluorescence histochemistry and in fluorimetric determinations. The ultrastructural features of these varicosities and their reaction to 5- and 6-OH-dopamine indicate that they belong to adrenergic, sympathetic nerves. No membrane specializations could be detected at sites of close contact of the adrenergic boutons with dendrites and cell bodies of intrinsic nerve cells.

Notes: Summary 1. There is a gradual proximo-distal increase in the thickness of the muscle coat of the human ductuli efferentes, duetus epididymidis and ductus deferens. Circularly arranged smooth muscle bundles predominate in the ductuli efferentes and ductus epididymidis of the caput section. Scanty strands of longitudinally and obliquely oriented smooth muscle bundles form an additional, incomplete outer muscle layer around the ductus epididymidis of the corpus. Small smooth muscle-like cells constitute the muscle elements of the upper sections of the excretory ducts (from the ductuli efferentes to the midcauda). At the transition of the corpus and cauda epididymidis ordinary large smooth muscle cells join the small contractile cells to form—in more distal sections of the cauda—a composed, thick subepithelial muscle coat. In most distal portions of the cauda, the two-layered muscle coat of the ductus epididymidis is transformed into a three-layered coat, a pattern of construction which is retained in the vas deferens. 2. Electron microscopically, three types of contractile cells are distinguished in the human ductuli efferentes and ductus epididymidis: a) contractile cells of medium transparency containing exclusively thin myofilaments (60 Å in diameter), b) dark contractile cells containing bundles of thin myofilaments (60 Å in diameter) and single coarse filaments (140 Å in diameter), c) light contractile cells with loosely dispersed, interweaving thin and thick myofilaments. Commutual diameter changes at regular intervals are seen in individual myofilaments, giving the impression of structural periodicity not unlike that of filaments of striated muscle. Ordinary smooth muscle cells of the cauda epididymidis and vas deferens are characterized by uniformly sized, closely packed but evenly distributed thin myofilaments with numerous dense patches. 3. Fluorescence microscopy performed on formaldehyde treated freeze dried tissues reveals that the contractile cells of the ductuli efferentes in man and monkey receive a low number of single adrenergic terminal fibres penetrating the depth of the muscle coat. The adrenergic innervation of the ductus epididymidis is restricted to small peritubular nerve fascicles running contiguous to the most superficially located bundles of smooth muscle-like cells. The adrenergic ground plexus is rather wide-meshed in the proximal cauda, becomes increasingly dense in more distal cauda sections and in initial, funicular portions of the vas deferens, and reaches maximum density in abdominal parts of the ductus. Perivascular and adventitial adrenergic plexuses are well developed at arteries of the caput and corpus epididymidis in man, monkey, rabbit, guinea-pig and rat. 4. Electron microscopically, noradrenergic nerves have been identified by the presence of small granular vesicles in preterminal varicose axon dilatations. Nerve fibre swellings filled with small empty spherical vesicles have been considered to belong to “cholinergic” neurons whereas occasional varicosities equipped with some large membrane bound granules and abundant mitochondria may represent local expansions of sensory axons. 5. Neuromuscular relationships in the upper sections of excretory ducts comprise adrenergic synapses by distance (more than 1000 Å), and a few intimate, ensheated close contacts, whereas the main type of contact of nerves to ordinary smooth muscle cells in the lower duct section is by means of close but not intimate approach (500–2000 Å). 6. Adrenergic synapses in the ductus epididymidis and ductus deferens of the monkey resemble—what concerns their morphology, relationship to effectors and distribution pattern—those of man. 7. In accordance with the total number of vascular and non-vascular adrenergic nerves, visualized by fluorescence microscopy, the amount of noradrenaline varied considerably in different sections of the human male internal genital organs: The lowest amounts were estimated in the testis (0.12±0.03 μg/g). Medium to high concentrations were detected in various sections of the caput and corpus epididymidis (ductuli efferentes 0.60±0.09 μg/g; ductuli efferentes and caput 0.72±0.13 μg/g; corpus epididymidis 1.04±0.25 μg/g; proximal cauda 0.95±0.17 μg/g; distal cauda 0.97±0.19 μg/g). The highest noradrenaline content was found in the human vas deferens (prox. vas deferens 1.11±0.21 μg/g; interm. vas deferens 1.20±0.42 μg/g; distal portion 1.43±0.39 μg/g). 8. For comparison, the noradrenaline content of the testis and epididymis of the rhesus monkey, the epididymis of the rabbit and the vas deferens of the rabbit, mouse, guinea-pig and rat has been determined. 9. Adrenaline of exogenous origin was detected in the vas deferens, cauda epididymidis and plexus pampiniformis of two cases who received this catecholamine as part of the local anaesthetic drug mixture. Due to methodological reasons, the presence of small amounts of adrenaline of endogenous source in adrenergic nerves of the human and monkey internal male genital organs cannot be excluded. 10. The differences in motility behaviour of the ductus epididymidis (spontaneous, rhythmic contractions) and ductus deferens (absence of any spontaneous movements under conditions at rest) in vivo and in vitro have been correlated with the occurrence of specialized contractile cells in the upper segment (ductuli efferentes, ductus epididymidis of the caput, corpus and initial cauda) and ordinary large smooth muscle cells in the lower segment (ductus epididymidis of the distal cauda and the vas deferens) and furthermore correlated with differences in the pattern of the adrenergic innervation; the concept is advanced that progressive cytological differentiation of smooth muscle cells and the development of a dense direct adrenergic innervation suppresses autocontractility and, that the reverse condition may favour spontaneous motility of smooth muscle elements.

Notes: Summary The effect of different doses of 5.6-dihydroxytryptamine—a serotonin analogue which produces a degeneration of serotonin containing nerve terminals in the rat brain—on the noradrenaline (NA) content and—storage sites of peripheral sympathetic nerves in the mouse and rat heart, spleen, rectum and vas deferens has been investigated by fluorescence—, electron microscopical and chemical methods. Moderate doses of 5.6-dihydroxytryptamine (5.6-DHT) (10–45 mg/kg ip.) cause a temporary, reversible displacement of noradrenaline from the adrenergic nerves concomitant with a significant increase in the number and opacity of small and especially large granular vesicles. The recovery of the neuronal NA concentration is, however, retarded after doses higher than 45 mg/kg (60 or 100 mg/kg ip.); a partial degeneration of varicose NA terminals is verified fluorescence- and electron microscopically. A combined treatment of animals with tyrosine hydroxylase inhibitors (α-methyl-paratyrosine or α-propyl-dopacetamide) and 5.6-DHT, in some instances also followed by reserpine, potentiates the destructive properties of 5.6-DHT; a similar potentiation is accomplished by reserpine posttreatment or by an additional pretreatment of animals with reserpine and nialamide. The results suggest that 5.6-DHT when given in moderate doses (up to 45 mg/kg) may be handled by sympathetic adrenergic nerves like a false neurotransmitter which displaces noradrenaline from the stores, but that it causes a “chemical degeneration” of noradrenaline containing nerve terminals when applied either in single high doses (60 or 100 mg/kg ip.), or when administered in moderate non-degenerative doses together with drugs that impair the neuronal inactivation mechanisms for 5.6-DHT (granular uptake and storage mechanism and/or monoamine oxidase activity) and thus provoke a temporary increase in the amount of free 5.6-DHT in the neuron's cytoplasm. The molar efficiency of 5.6-DHT in causing a chemical sympathectomy is clearly inferior to that caused by 6-hydroxydopamine. The differences are probably mainly due to differences in the affinity of both drugs to the amine uptake system located at the cell membrane and the membrane of the intraneuronal storage vesicles of the adrenergic nerve terminals.

Notes: Summary The human tunica dartos has been investigated by light, fluorescence and electron microscopy. It consists of solid bundles of smooth musculature in the subcutis, and small bundles or single muscle cells in the corium. Smooth muscle bundles in both the subcutis and corium are composed of ordinary smooth muscle cells. Single muscle cells of the corium resemble myofibroblasts showing features of fibrocytes and smooth muscle cells. As revealed in single smooth muscle cells, each cell appears to be surrounded by a coat of interweaving microfilaments which penetrate neighbouring bundles of collagen fibres and show inclusions of elastin. Part of the microfilaments extend into the specialized subepithelial connective tissue layer and may insert at the basement membrane. Only ordinary smooth muscle cells have an adrenergic innervation, which indicates their involvement in sympathetic thermoregulatory reflexes.