An Ultrastructural and Immunocytochemical Study of Gastrodermal Cell Types in Microstomum lineare (Turbellaria,Macrostomida)

The gastrodermal cell types of Microstomum lineare (Turbellaria, Macrostomida) were studied by electron microscopy. Their immunoreactivity (IR) to bovine pancreatic peptide (BPP), FMRF-amide and vasotocin, somatostatin, neurotensin, ACTH, CCK, bombesin, secretin, gastrin/CCK and insulin antisera was tested by light microscopic immunocytochemical methods. In addition to granular club cells and phagocytic cells, neurons and neoblasts occur in the gastroderm of this turbellarian species. This is the first observation of neurons in the gastroderm of a flatworm. Dense-core vesicles (70–100 nm diameter), electron lucent cytoplasm and numerous Golgi complexes characterize the neurons. Unpolarized two-way synapses, neuromuscular junctions and polarized chemical synapses can be observed in the gastroderm. Neoblasts with large nuclei and scanty cytoplasm and differentiating cells containing clusters of basal bodies occur next to the basal lamina of the gastroderm. BPP-like, FMRF-amide-like and vasotocin-like immunoreactivity is demonstrated in the gastroderm. Both BPP and FMRF-amide IR is restricted to the basal cytoplasm of the granular club cells, while a different location for IR to vasotocin antiserum is observed. The status of the neuronal cell in the gastroderm of M. lineare is discussed in relation to endocrine (paracrine) cells and neurons in the gastroderm of invertebrates.     

Fine Structure of Subepithelial “Free” and Corpuscular Trigeminal Nerve Endings in Anterior Hard Palate of the Rat

Axonally transported protein labeled many trigeminal nerve endings in subepithelial regions of the anterior hard palate of the rat. Sensory endings were most numerous in the lamina propria near the tips of the palatal rugae where large connective tissue and epithelial papillae interdigitated. Two kinds of sensory ending were found there: “free” endings, and a variety of corpuscular endings. The “free” sensory endings consisted of bundles of unmyelinated axons separated from the connective tissue by relatively unspecialized Schwann cells covering part or all of their surface and a completely continuous basal lamina; they were commonly found running parallel to the epithelium or near corpuscular endings. The corpuscular sensory endings all had a specialized nerve form, specialized Schwann cells, and axonal fingers projecting into the corpuscular basal lamina or connective tissue. There were at least four distinct types of corpuscular ending: Ruffini-like endings were found among dense collagen bundles, and they had a flattened nerve ending with a flattened Schwann lamella on either side. Meissner endings had an ordered stack of flattened nerve terminals with flattened Schwann cells and much basal lamina within and around the corpuscle. Simple corpuscles were single nerve endings surrounded by several layers of concentric lamellar Schwann processes. Glomerular endings were found in lamina propria papillae or encircling epithelial papillae; they were a tangle of varied neural forms each of which had apposed flattened Schwann cells, and a layer of basal lamina of varied thickness. Fibroblasts often formed incomplete partitions around Meissner and simple corpuscles.

The axoplasm of all kinds of subepithelial sensory endings contained numerous mitochondria and vesicles, as well as occasional multivesicular bodies and lysosomes; the axoplasm of all endings was pale with few microtubules and neurofilaments. The specialized lamellar Schwann cells had much pinocytotic activity. Four kinds of junctions were found between the corpuscular sensory endings and the lamellar Schwann cells: (1) symmetric densities that resemble desmosomes; (2) asymmetric densities with either the neuronal or glial membrane more dense; (3) neural membrane densities adjacent to Schwann parallel inner and outer membrane densities; and (4) sites of apparent Schwann endocytosis associated with neural blebs. The “free” sensory endings only made occasional desmosome-like junctions with their Schwann cells.

These observations are discussed in relation to possible mechanosensory transduction mechanisms, with particular attention to axoplasmic structure, axonal fingers, and neural and nonneural cell associations.     

Ultrastructure of Merkel corpuscles in the tongue of the finch,Lonchura striata

Summary Merkel corpuscles in the lingual mucosa of the finch, Lonchura striata, were examined by means of the argyrophilic reaction and electron microscopy. These corpuscles are composed of 12 to 20 flattened Merkel cells and enclosed nerve terminals. The present study demonstrated for the first time argyrophilia in avian subepithelial Merkel cells with the use of Grimelius silver stain. Electron-microscopically, the Merkel cell was characterized by the presence of numerous densecore granules, approximately 80 to 140 nm in diameter, as well as specialized contacts with nerve terminals. The granules showed a tendency to accumulate in the cytoplasm in close association with both nerve terminals and basal lamina. This study also provided unequivocal evidence for exocytotic discharge of Merkel-cell granules at the plasma membrane facing not only the nerve terminals but also the basal lamina. The exocytotic figures toward the nerve terminals can be regarded as synaptic discharge of Merkel-cell granules, but the possibility also exists that the Merkel-cell granules may exert a trophic effect on the nerve terminals. The exocytotic release of Merkel-cell granules toward the basal lamina with no relation to nerve terminals may suggest an endocrine (paracrine) function for the Merkel cell. The avian subepithelial Merkel cells qualify as paraneurons, but their exact nature and function remain enigmatic as is the case of intraepithelial Merkel cells in other vertebrates.     

Cytochemical characterization of basement membranes in the enamel organ of the rat incisor

Ameloblasts are unique epithelial cells, in that once they have deposited the entire thickness of enamel and the process of maturation begins, they reform a basal lamina-like structure at their apical surface. In order to characterize further this basal lamina, its composition was analysed using (1) lectin-gold cytochemistry for glycoconjugates, (2) high-iron diamine (HID) staining for sulfated glycoconjugates and (3) immunogold labeling for collagen type IV and laminin. The labeling patterns were compared to that of other more typical basement membranes found in the enamel organ. Sections of rat incisor enamel organs embedded in Lowicryl K4M were stained with Helix pomatia agglutinin (HPA), Ricinus communis I agglutinin (RCA), wheat germ agglutinin (WGA) and Ulex europaeus I agglutinin (UEA). Samples from the late maturation stage were also reacted en bloc with lectins and embedded in Epon for transmission electron microscopic examination or prepared for scanning electron microscopy. Such samples were also stained with HID and conventionally processed for Epon embedding. Tissue sections were then reacted with thiocarbohydrazide-silver proteinate (TCH-SP). Analysis of the lectin labeling suggested that the region of extracellular matrix immediately adjacent to ameloblasts, where the basal lamina is situated, was intensely reactive with HPA and RCA, moderately reactive with WGA, and weakly reactive with UEA. In general, other basement membranes were mildly reactive with all lectins used. No HID-TCH-SP staining was observed directly over the basal lamina while numerous stain deposits were present over other basement membranes of the enamel organ. Immunolocalization of collagen type IV and laminin yielded a weak and variable labeling over the basal lamina. These results are consistent with the concept of basement membrane heterogeneity and, although the precise nature and composition of the basal lamina associated with maturation stage ameloblasts remain to be determined, they suggest that it may possibly function as a specialized basement membrane with particular compositional characteristics.     

Virus-Vector Cell Interactions Regulating Transmission Specificity of Soybean Dwarf Luteoviruses

Transmission of soybean dwarf viruses (SbDV) indigenous to Japan (SbDV‐D) and to the eastern United States (SbDV‐Va19) were compared in vector and nonvector aphid species. Absolute vector‐specificity was maintained when Aulacorthum solani, Acyrthosiphon pisum, and Myzus persicae were allowed to feed on solutions of either virus (100 μg/ml) through Parafil© membranes. SbDVD was transmitted only by A. solani, and SbDV‐Va19 was transmitted only by A. pisum and M. persicae. Similar results were obtained when individual aphids were micro‐injected with 2 ng virus and subsequently allowed to feed on healthy plants. Ultrastructural studies of A. solani and M. persicae indicated that both SbDV‐D and SbDV‐Va20 were acquired specifically through the aphid hindgut. No difference in hindgut acquisition specificity was observed, and both A. solani and M. persicae were able to transport SbDV‐D and SbDV‐Va20 into the haemocoel by endocytotic/exocytotic pathways. When injected, SbDV was shown to be associated with only the accessory salivary glands (ASG) in aphids, indicating a high level of tissue specificity. Two different interactions with the ASG were observed for SbDV‐D and SbDV‐Va20 in A. solani and M. persicae. SbDV‐D penetrated the ASG basal lamina of A. solani, but was never observed in the basal lamina of M. persicae. The ASG basal lamina was a barrier to SbDV‐D transmission by M. persicae. SbDV‐Va19 penetrated the ASG basal lamina of both A. solani and M. persicae. However, SbDV‐Va20 was not observed in the ASG cytoplasm in A. solani, indicating that the basal plasmalemma functioned as the transmission barrier. Observations indicated that capsid protein structure, aphid basal lamina composition and cell membrane components influenced virus‐aphid interactions regulating SbDV transmission.     

Substance P immunoreactivity in sensory structures and the central and pharyngeal nervous system of Stenostomum leucops (Catenulida) and Microstomum lineare (Macrostomida)

Immunoreactivity (IR) obtained by monoclonal antibodies to substance P (SP) was studied in the asexually reproducing microturbellarians Stenostomum leucops and Microstomum lineare. The IR pattern was studied by confocal and ordinary fluorescence microscopy. In both species, IR occurs in the brain in peripheral cells, neuropilar fibres, in longitudinal cords and in the pharyngeal nervous system. The IR patterns reveal neuroanatomical details not observed with other neuroactive substances. In both species, immunopositive cells send fibers to the ciliary pits. In M. lineare, additional fibres run to more frontally located sensory structures. In S. leucops, two pharyngeal nerve rings are visualized. The pharyngeal nerve ring close to the surface associated with symmetrical immunopositive cell pairs is demonstrated for the first time, while the deeper-lying pharyngeal nerve ring has been previously demonstrated by antibodies to the molluscan cardioactive peptide FMRF-amide. Two cells with strong IR are connected by short fibres to the pharyngeal nerve ring in M. lineare. In the developing new individuals, i.e., the zooids of M. lineare, IR to SP is first revealed in nerve fibres growing out from parental lateral nerve cords towards the centre of the worm where the new brain commissure will appear. Immunopositive cells in the brain periphery and close to the developing ciliary pits appear later. Simultaneous staining by antibodies to SP and 5-HT shows that IR to SP appears later than IR to 5-HT.     

Histochemical staining of the complex carbohydrates of the midgut of the mosquito,Culex tarsalis coquillett

Histochemical staining of the midgut epithelial cell surface complex carbohydrates of the mosquito Culex tarsalis was examined electron microscopically. The microvillar surface is composed primarily of neutral vic-glycoconjugates; positively stained by silver methenamine and silver protein. Lanthanum and alcian blue staining indicate that the microvilli contain a minimal anionic component; possibly phosphoglycoconjugates. Similarly, the intercellular junctions contain a predominance of neutral vic-glycoconjugates. In addition, the intercellular junctions contain fixed positive charges, based on en bloc phosphotungstic acid staining. The midgut basolateral membrane system and the basal lamina are both highly anionic; stained by ruthenium red, tannic acid, alcian blue and periodic acid-chromic acid-phosphotungstic acid. The basolateral plasma membrane also contains some vic-glycoconjugates. Selective staining indicates that the anionic component of the basolateral plasma membrane and the basal lamina is predominantly carboxyl groups; no specific staining for sulfo- or phosphoglycoconjugates was observed.     

Anti-agrin staining is absent at abandoned synaptic sites of frog neuromuscular junctions

The neuromuscular junction is a plastic structure and is constantly undergoing changes as the nerve terminals that innervate the muscle fiber extend and retract their processes. In vivo observations on developing mouse neuromuscular junctions revealed that prior to the retraction of a nerve terminal the acetylcholine receptors (AChRs) under that nerve terminal disperse. Agrin is a protein released by nerve terminals that binds to synaptic basal lamina and directs the aggregation of AChRs and acetylcholinesterase (AChE) in and on the surface of the myotube. Thus, if the AChRs under a nerve terminal disperse, then the cellular signaling mechanism by which agrin maintains the aggregation of those AChRs must have been disrupted. Two possibilities that could lead to the disruption of the agrin induced aggregation are that agrin is present at the synaptic basal lamina but is unable to direct the aggregation of AChRs, or that agrin has been removed from the synaptic basal lamina. Thus, if agrin were blocked, one would expect to see anti-agrin staining at abandoned synaptic sites; whereas if agrin were removed, anti-agrin staining would be absent at abandoned synaptic sites. We find that anti-agrin staining and α-bungarotoxin staining are absent at abandoned synaptic sites. Further, in vivo observations of retracting nerve terminals confirm that agrin is removed from the synaptic basal lamina within 7 days. Thus, while agrin will remain bound to synaptic basal lamina for months following denervation, it is removed within days following synaptic retraction. © 1996 John Wiley & Sons, Inc.     

Implantation-associated changes in bovine uterine expression of integrins and extracellular matrix

Appropriate integrin expression appears to be necessary for successful implantation of human embryos and varies considerably among species. The present study was undertaken to determine the distributions of integrin subunits alpha(1), alpha(3), and alpha(6) as well as the extracellular matrix (ECM) components collagen IV and laminin in implanting bovine trophoblast and endometrium. Immunohistochemical staining of cryostat sections prepared from nonpregnant endometrium, of preattachment through to early villus development pregnant endometrium (Days 18, 21, 24, and 30), and of isolated trophoblast binucleate cells was performed. Trophoblast down-regulated the integrin alpha(1) subunit as attachment proceeded, whereas reactivity scores for alpha(6) antibody tended to increase from Day 18 through 24 and remained high. A subpopulation of trophoblast binucleate cells expressed the alpha(3) integrin subunit. Uterine epithelium constitutively expressed alpha(3) and alpha(6) integrin subunits, but the alpha(1) subunit was down-regulated as the luminal epithelium was modified. Collagen IV and laminin reactivity increased in the basal lamina and underlying subepithelial stroma as pregnancy proceeded. The results suggest that binucleate cell fusion with the maternal epithelium initiates integrin and ECM changes in the subepithelial stroma.     

Lectin binding sites of the mouse ovary,intraovarian and ovulated ova

Summary Fluorescein isothiocyanate (FITC) labeled lectins were used to study the distribution of specific binding sites in histologic sections of mouse ovaries as well as ovulated ova. Four distinct patterns of reactivity of the components of the follicle (exclusive of the ovum) and the surrounding ovarian stroma were recognized: 1. uniform staining of granulosa cells, theca cells and surrounding stroma; 2. weak to moderate staining of the granulosa cells and strong staining of the theca cells and stromal cells; 3. no reactivity of the granulosa cells coupled with strong reactivity of the theca and stromal cells; 4. no reactivity with any component of thecumulus oophorus. Three lectins (from Triticum vulgare, Arachis hypogaea and Maclura pomifera) distinctly accentuated the basal lamina of thecumulus oophorus. The reaction of lectins with oocytes and zona pellucida revealed six distinct patterns: 1. no reactivity with either structure; 2. weak reactivity with the cytoplasm of the oocyte and no reactivity with the zona pellucida; 3. very strong reactivity with the cytoplasm of the oocyte and no reactivity with the zona pellucida; 4. moderate reactivity with both the oocyte and the zona pellucida; 5. moderate reactivity with the oocyte and very strong reactivity with the zona pellucida; 6. no reactivity with the oocyte and moderate reactivity with the zona pellucida. The same pattern of reactivity was seen in the ovulated ova in the oviduct except for the lectin from Arachis hypogaea, the reactivity of which changed upon ovulation and/or fertilization of the ovum. These data provide a list of lectin markers for distinct components of the mouse ovary.     

Histochemical properties of sulfated glycoconjugates in developing enameloid matrix of the fish Polypterus senegalus

Summary I investigated the ultrastructural localization and histochemical properties of sulfated glycoconjugates in developing enameloid matrix of the fish Polypterus senegalus, by use of the high iron diamine thiocarbohydrazide silver proteinate (HID-TCH-SP) staining and enzymatic digestion methods. HID-TCH-SP stain deposits were localized in the dental basal lamina and in the whole thickness of developing enameloid matrix, particularly closely associated with enameloid collagen fibrils. Most HID-TCH-SP stain deposits in the enameloid were susceptible to testicular hyaluronidase but some stain deposits survived. HID-TCH-SP stain deposits in the basal lamina resisted the enzymatic digestion, and were regularly localized to the internal and external sites of lamina densa at an early stage of development, subsequently tending to be randomly arranged with the increase in thickness of enameloid matrix layer. Furthermore, enzymatic digestion with heparitinase preferentially removed HID-TCH-SP stain deposits in the region of the basal lamina. Thus, it was confirmed that most HID-TCH-SP stain deposits in developing enameloid matrix are chondroitin 4-sulfate and/or 6-sulfate and that the stain deposits in the basal lamina represent heparan sulfate. The chondroitin sulfates tended to disappear with the advancement of enameloid mineralization.     

Neuropeptides in free-living and parasitic flatworms (Platyhelminthes). An immunocytochemical study

The nervous systems of the turbellarians Microstomum lineare and Polycelis nigra and of the cestodes Diphyllobothrium dendriticum and Schistocephalus solidus were studied by means of the peroxidase-antiperoxidase (PAP) immunocytochemical method, with the use of antisera to the neuropeptides FMRF-amide, vasotocin, leu-enkephalin, met-enkephalin, neurotensin, somatostatin, and VIP, and to the bioamine serotonin. Anti-FMRF-amide positive perikarya and fibers occurred in all species, while the occurrence of the vertebrate brain-gut peptides and serotonin varied between the species. Anti-somatostatin and anti-VIP gave a negative result. Anti-FMRF-amide and anti-vasotocin positive immunoreactivity was found in the brain and gut of M. lineare, and in the CNS and the peripheral nerve net of the cestodes. We suggest that the brain-gut peptides of free-living flatworms act on the subtegumental region in the cestodes, which lack a gut but absorb their nutrients directly through the tegument.     

Antibodies against Escherichia coli O24 and O56 O-Specific Polysaccharides Recognize Epitopes in Human Glandular Epithelium and Nervous Tissue

Lipopolysaccharide (LPS), the major component of the outer membrane of Gram-negative bacteria, contains the O-polysaccharide, which is important to classify bacteria into different O-serological types within species. The O-polysaccharides of serotypes O24 and O56 of E. coli contain sialic acid in their structures, already established in our previous studies. Here, we report the isolation of specific antibodies with affinity chromatography using immobilized lipopolysaccharides. Next, we evaluated the reactivity of anti-O24 and anti-O56 antibody on human tissues histologically. The study was conducted under the assumption that the sialic acid based molecular identity of bacterial and tissue structures provides not only an understanding of the mimicry-based bacterial pathogenicity. Cross-reacting antibodies could be used to recognize specific human tissues depending on their histogenesis and differentiation, which might be useful for diagnostic purposes. The results indicate that various human tissues are recognized by anti-O24 and anti-O56 antibodies. Interestingly, only a single specific reactivity could be found in the anti-O56 antibody preparation. Several tissues studied were not reactive with either antibody, thus proving that the presence of cross-reactive antigens was tissue specific. In general, O56 antibody performed better than O24 in staining epithelial and nervous tissues. Positive staining was observed for both normal (ganglia) and tumor tissue (ganglioneuroma). Epithelial tissue showed positive staining, but an epitope recognized by O56 antibody should be considered as a marker of glandular epithelium. The reason is that malignant glandular tumor and its metastasis are stained, and also epithelium of renal tubules and glandular structures of the thyroid gland are stained. Stratified epithelium such as that of skin is definitely not stained. Therefore, the most relevant observation is that the epitope recognized by anti-O56 antibodies is a new marker specific for glandular epithelium and nervous tissue. Further studies should be performed to determine the structure of the tissue epitope recognized.     

Action des plasmatocytes sur divers tissus larvaires de Calliphora erythrocephala (Mg.) et Lucilia caesar (L.) (Diptera : Calliphoridae) en metamorphose

During metamorphosis of Diptera some degenerating larval tissues are phagocytosed by plasmatocytes. I studied here the action of plasmatocytes before phagocytosis on 3 tissues (epidermis, salivary gland and midgut) of Calliphora erythrocephala and on epidermis of Lucilia caesar. In all cases, the plasmatocytes accumulate under the basal lamina of larval tissues. They contact the basal lamina, directly or by means of pseudopodia. In the salivary glands, pseudopodia can be observed passing through the basal lamina. In other tissues a flocculent material is seen at the level of contacts; it is probably composed of enzymes since acid phosphatase activity has been revealed between phagocytes and epidermal larval cells. The basal lamina is then detached from the larval cells and thrown into folds. It is generally broken down due to the activity of the plasmatocytes, which often include its fragments. By this time, the plasmatocytes invade the degenerating larval tissue and phagocytose the fragments of larval cells. These results show that plasmatocytes play an active part in the disruption and phagocytosis of the basal lamina.     

Cytochemical and biochemical observations on the alveolar guanylate cyclase of golden hamster lung.

Particulate guanylate cyclase (GTP pyrophosphate-lyase (cyclizing] has been cytochemically evidentiated in the cells which make-up the lung air-blood barrier. The cytochemical procedure utilized demonstrates the presence of membrane-bound guanylate cyclase activity through precipitation of lead pyrophosphate in tissues incubated with GTP or with guanylyl imidodiphosphate. Electron microscopic examination reveals that guanylate cyclase (GC) is localized, as micropinocytic vesicles, within endothelial components of small blood vessels, in basal lamina and in the flat alveolar cells. The secretory alveolar cells also exhibit the positive GC reactivity in their peripheric cytoplasm and in their microvilli. The observations support that GC and cGMP are involved in cellular transport phenomena. The enzyme might play a role in the secretion process of surface active material. Positive staining has been found also in other types of cells, namely alveolar macrophages and fibroblasts. A biochemical evaluation of GC activity shows that about 30-40% of this activity is associated with the particulate fraction, which justifies its abundance in the cytochemical reports shown in the paper.     

Fine structure of the down feather during its early development

The down feather of the chick embryo has been examined by electron microscopy during three distinct stages of its early development; the presumptive stage, represented by dorsal skin of an area from which the feather organ will arise; the thickening stage, during which areas of the basal epidermis form spurs projecting into the mesenchyme, and the latter condenses under a thickened area of the epidermis; the elevation stage, at which time the basal epidermis flattens, the entire epidermis increases in thickness, and the underlying mesenchyme becomes more compact. As development proceeds the rough endoplasmic reticulum of the epidermal cells dilates, but during the elevation stage begins to flatten, and Golgi is observed with increasing frequency. The mitochondria do not appear to differ except for those in the periderm during the presumptive stage, in which case they reveal a vacant matrix and irregular cristae. Evidence is presented for actual contact between basal epidermal spurs and filopodia of cells within the mesenchyme, some of which contain numerous vesicles. The basal epidermal spurs are also seen in intimate association with collagen and anchor filaments and a network of reticulin. Evidence is also presented for the presence of neuronal elements within the mesenchyme during the thickening stage. Cross sections of cell processes within the condensations of the mesenchyme resemble unmyelinated nerve fibers, and cross sections of filopodia similar to arborizing axons abound at and within the basal lamina of both the thickening and elevation stages. Further support for the presence of nerve fibers within the mesenchyme comes from positive staining results with Bodian's and Ungewitter's methods. This comparative study of three stages of early development of the feather organ serves as a basis for more detailed investigations of each stage.     

Fine structure at the basal surface of intestinal epithelium in the midgut region of the balanidae,with special reference to “Neural-like” processes

Observations on fine structure at the basal end of the intestinal epithelium in the midgut region of Balanus balanoides and Balanus improvisus reveal complex interrelationships among several tissues. Numerous elongate cell processes extend towards the intestinal epithelium penetrating between layers of intestinal muscle through blood spaces and into the basal lamina underlying the epithelium. Two types of morphological relationships occur between cell processes and the basal end of the intestinal epithelial cell: 1. The cell process may penetrate the basal lamina and lie closely apposed to the epithelium. 2. The cell process may give rise to narrow, medially-directed, finger-like extensions (projections). The narrow projections penetrate the basal lamina and, in addition, terminate as dilated bulbs within inpocketings of the epithelium. In some respects the cell processes are suggestive of neural tissue.     

Alterations to the subepithelial layers of the larval alimentary tract during metamorphosis in the sea lamprey Petromyzon marinus,with emphasis on tissue interactions

Light-microscopic histochemistry and conventional electron microscopy were used to study the changes to the subepithelial layers in the larval esophagus of the sea lamprey Petromyzon marinus during metamorphosis. During early stages of metamorphosis, smooth muscle cells of the muscularis mucosae and tunica muscularis dedifferentiate into myofibroblast-like cells, which make contact with the basal lamina of the overlying mucosal epithelium. During later stages, these myofibroblast-like cells redifferentiate into smooth muscle cells, reforming the muscularis mucosae and tunica muscularis. Alterations to the extracellular matrix occur concomitantly.     

The organization of the nervous system in Plathelminthes. The neuropeptide F-immunoreactive pattern in Catenulida,Macrostomida, Proseriata

The organization of the nervous system of Archilopsis unipunctata Promonotus schultzei and Paramonotus hamatus (Monocelididae, Proseriata) and Stenostomum leucops (Catenulida) and Microstomum lineare (Macrostomida) was studied by immunocytochemistry, using antibodies to the authentic flatworm neuropeptide F (NPF) (Moniezia expansa). The organization of the nervous system of the Monocelididae was compared to that of the nervous system of Bothriomolus balticus (Otoplanidae), a previously studied species of another family of the Proseriata. The results show that the main nerve cords (MCs), independent of lateral or ventral position in the Monocelididae and the Otoplanidae, correspond to each other. The study also confirms the status of the lateral cords as main cords (MCs) in S. leucops and M. lineare. Common for MCs in the members of the investigated taxa are the following features: MCs consist of many fibres, originate from the brain and are adjoined to 5-HT-positive neurons. In Monocelididae and Otoplanidae, the MCs additionally have the same type of contact to the pharyngeal nervous system. Also common for both proseriate families is the organization of the two lateral nerve cords, with weaker connections to the brain, and the pair of dorsal cords running above the brain. The organization of the minor cords differs. The Monocelididae have a pair of thin ventral cords forming a mirror image of the dorsal pair. Furthermore, an unpaired ventral medial cord connecting medial commissural cells was observed in P. schultzei. Marginal nerve cords, observed in Otoplanidae, are absent in Monocelididae. All minor nerve cords are closely connected to the peripheral nerve plexus. The postulated trends of condensation of plexal fibres to cords and/or the flexibility of the peripheral nerve plexus are discussed. In addition, the immunoreactivity (IR) pattern of NPF was compared to the IR patterns of the neuropeptide RFamide and the indoleamine, 5-HT (serotonin). Significant differences between the distribution of IR to NPF and to 5-HT occur. 5-HT-IR dominates in the submuscular and subepidermal plexuses. In the stomatogastric plexus of M. lineare, only peptidergic IR is observed in the intestinal nerve net. The distribution of NPF-IR in fibres and cells of the intestinal wall in M. lineare indicates a regulatory function for this peptide in the gut, while a relationship with ciliary and muscular locomotion is suggested for the 5-HT-IR occurring in the subepidermal and submuscular nerve, plexuses. In M. lineare, the study revealed an NPF- and RFamide-positive cell pair, marking the finished development of new zooids. This finding indicates that constancy of these cells is maintained in this asexually reproducing and regenerating species.     

New multiple labelling method for improved satellite cell identification in human muscle: application to a cohort of power-lifters and sedentary men

Presently applied methods to identify and quantify human satellite cells (SCs) give discrepant results. We introduce a new immunofluorescence method that simultaneously monitors two SC markers (NCAM and Pax7), the basal lamina and nuclei. Biopsies from power-lifters, power-lifters using anabolic substances and untrained subjects were re-examined. Significantly different results from those with staining for NCAM and nuclei were observed. There were three subtypes of SCs; NCAM⁺/Pax7⁺ (94%), NCAM⁺/Pax7⁻ (4%) and NCAM⁻/Pax7⁺ (1%) but large individual variability existed. The proportion of SCs per nuclei within the basal lamina of myofibres (SC/N) was similar for all groups reflecting a balance between the number of SCs and myonuclei to maintain homeostasis. We emphasise that it is important to quantify both SC/N and the number of SCs per fibre. Our multiple marker method is more reliable for SC identification and quantification and can be used to evaluate other markers of muscle progenitor cells.