Structure of the retinal ganglionic layer in mammals

In total preparations impregnated with silver nitrate after Kampos the ganglionic retinal layer has been studied in some Mammalia. Two types of ganglionic cells are demonstrated. Some occupy the retinal spot. These are small (areal, dwarfish), cells, others--large, multipolar, circularly arranging, in layers around the nervus opticus disc along the remaining part of the retina. Both the former and the latter can be arranged in groups of two cells, their bodies situating near each other and their processes having the same direction. Single ganglionic cells possess special dendrites with terminal enlargements (proper sensitive neurons). Small neural cells situating in the layer of neural fibers are of vegetative nature.     

Schwann cell dynamics with respect to newly formed motor—nerve terminal branches on mature (Bufo marinus) muscle fibers

A study has been made of the formation of synaptic terminals from long processes formed at the end of motor nerve branches of endplates in mature amphibian (Bufo marinus) muscle. Injection of fluorescent dyes into individual motor axons showed the full extent of their branches at single endplates. Synaptic vesicle clusters at these branches were identified with styryl dyes. Some terminal branches consisted of well separated varicosities, each possessing a cluster of functioning synaptic vesicles whilst others formed by the same axon consisted of closely spaced clusters of vesicles in a branch of approximately uniform diameter. All the varicosities gave rise to calcium transients on stimulation of their parent axon. Both types of branches sometimes possessed short processes (<5 μm long) or very long thin processes (>10 μm long) which ended in a bulb that possessed a functional synaptic vesicle cluster. These thin processes could move and form a varicosity along their length in less than 30 min. Injection of a fluorescent dye into terminal Schwann cells (TSCs) at an endplate showed that they also possessed very long thin processes (>10 μm long) which could move over relatively short times (<30 min). Injecting fluorescent dyes into both axons and their associated TSCs showed that on some occasions long TSC processes were accompanied by a long nerve terminal process and at other times they were not. It is suggested that the mature motor-nerve terminal is a dynamic structure in which the formation of processes by TSCs guides nerve terminal sprouting.     

Consideration of the neural crest and its skeletal derivatives in the context of novelty/innovation

I examine the neural crest and skeletal tissues derived from neural crest cells in the context of novelty/innovation by asking whether the neural crest is a novel tissue and whether the evolutionary origin of the neural crest required innovative developmental processes. As a vertebrate autapomorphy, the neural crest is a novel structure. I equate novelty with innovation and take a hierarchical approach. Some other workers separate the two, using novelty for new structures not found in an ancestor and not homologous with a feature in an ancestor, and innovation for the new processes required to generate the novel structure. While development clearly evolves, I do not separate those processes that result in the production of novel features from those that lead to change in existing structures, whether that change is a transition or transformation from one homologous feature to another (fins-->tetrapod limbs or locomotory appendages-->crustacean maxilliped feeding appendages). The existence of novelties causes us to consider the concept of latent homology. Neural crest cells form cartilage, dentine and bone. Cartilage is found in invertebrates and so is not a vertebrate innovation. No invertebrate cartilage mineralizes in vivo, although some can be induced to mineralize in vitro. Mineralization of cartilage in vivo is a vertebrate innovation. Dentine is a novel tissue that only forms from neural crest cells. Bone is a vertebrate innovation but not one exclusive to the neural crest. The developmental processes responsible for the neural crest and for these skeletal tissues did not arise de novo with the vertebrates. Novelty/innovation results from tinkering with existing processes, from the flexibility that arises from modifications of existing gene networks, and from the selective advantage provided by gene duplications or modifications.     

The let-7 microRNA target gene,Mlin41/Trim71 is required for mouse embryonic survival and neural tube closure

In the nematode Caenorhabditis elegans, the let-7 microRNA (miRNA) controls the timing of key developmental events and terminal differentiation in part by directly regulating lin-41. C. elegans lin-41 mutants display precocious cell cycle exit and terminal differentiation of epidermal skin cells. lin-41 orthologues are found in more complex organisms including both mice and humans, but their roles are not known. We generated Mlin41 mouse mutants to ascertain a functional role for Mlin41. Strong loss of function Mlin41 gene-trap mutants demonstrated a striking neural tube closure defect during development, and embryonic lethality. Like C. elegans lin-41, Mlin41 also appears to be regulated by the let-7 and mir-125 miRNAs. Since Mlin41 is required for neural tube closure and survival it points to human lin-41 (HLIN41/TRIM71) as a potential human development and disease gene.     

Fine structure of the epidermis of the optic tentacle in a slug, Limax flavus L.

The epidermis at the tip of the optic tentacle in Limax flavus is constructed of columnar epithelial cells, distal processes of nerve cells, and scattered processes of the collar cells. The epithelial cells extend stout microvilli called plasmatic processes by Wright perpendicularly from the free surface. Each plasmic process branches into a few terminal twigs embedded in a fuzzy filamentous substance. Most nerve cells have their nuclei under the basal lamina. The distal processes of these nerve cells reach the free surface and send long microvilli to form the spongy layer under a filamentous covering. At the side surface of the tentacle the epithelial cells are cuboidal or squamous and the neural elements are fewer. Here, no spongy layer is formed; and the collar cell processes are replaced by the lateral cell processes. Peculiar secretion granules are contained in the lateral and collar cell processes as well as in their cell bodies situated beneath the basal lamina.     

Serotonin-immunoreactive neural system and contractile system in the hydroid Cladonema (Cnidaria, Hydrozoa)

Serotonin is a widespread neurotransmitter which is present in almost all animal phyla including lower metazoans such as Cnidaria. Serotonin detected in the polyps of several cnidarian species participates in the functioning of a neural system. It was suggested that serotonin coordinates polyp behavior. For example, serotonin may be involved in muscle contraction and/or cnidocyte discharge. However, the role of serotonin in cnidarians is not revealed completely yet. The aim of this study was to investigate the neural system of Cladonema radiatum polyps. We detected the net of serotonin-positive processes within the whole hydranth body using anti-serotonin antibodies. The hypostome and tentacles had denser neural net in comparison with the gastric region. Electron microscopy revealed muscle processes throughout the hydranth body. Neural processes with specific vesicles and neurotubules in their cytoplasm were also shown at an ultrastructural level. This work demonstrates the structure of serotonin-positive neural system and smooth muscle layer in C. radiatum hydranths.     

Histochemical specificity of beta-galactose binding lectins from Arachis hypogaea (peanut) and Ricinus communis (castor bean)

Previous histochemical studies have demonstrated disparities in the binding of two lectins with a nominal specificity for terminal beta-D-galactose. Biochemical studies have shown that the most complementary structure for binding peanut agglutinin (PNA) is the terminal disaccharide Gal-(beta 1----3)-GalNAc, whereas the most complementary structure for binding Ricinus communis agglutinin I (RCA I) is the terminal disaccharide Gal-(beta 1----4)-GlcNAc. However, it is not known if only these differences in affinity account for the different histochemical staining reactions observed on tissue sections. In the present study we compared the staining patterns of PNA and RCA I by inhibiting in situ the binding of each lectin conjugated to horseradish peroxidase (HRP) with increasing concentrations of unlabeled PNA or RCA I. The PNA-HRP conjugate did not stain most tissue sites suspected of containing an abundance of glycoconjugates with terminal Gal-(beta 1----4)-GlcNAc. Moreover, unlabeled PNA failed to significantly inhibit strong RCA I-HRP staining in these sites. In loci thought to contain variable amounts of glycoconjugates with terminal Gal-(beta 1----3)-GalNAc, unlabeled RCA I decreased PNA-HRP reactivity only slightly or not at all, whereas weak to strong RCA I-HRP staining was diminished or abolished by unlabeled PNA. The results suggest that PNA staining is restricted to glycoconjugates with terminal Gal-(beta 1----3)-GalNAc. RCA I apparently reacts most strongly with glycoconjugates having the terminal disaccharide Gal-(beta 1----4)-GlcNAc, but also stains sites containing a moderate to abundant amount of glycoconjugates with the terminal Gal-(beta 1----3)-GalNAc sequence.     

Monoamine-containing fibres in the pituitary neuro-intermediate lobe of the pig and rat

Summary A rich system of monoamine-containing fibres is described in the neural lobe and pars intermedia of the pig and rat. a) A rich network of delicate varicose fibres is evenly distributed throughout the parenchyma of the neural lobe and surrounds the cells of the pars intermedia. b) Droplets or clusters of droplets are scattered throughout the neural lobe. Most of them probably constitute terminal swellings or end-apparatuses of smooth or varicose fibres. The number of droplets varies from animal to animal; they are found also in the pars intermedia. c) Coarse varicose fibres are mainly localized around larger vessels. At least some of these fibres are nerve fibres of sympathetic origin. A combination of fluorescence microscopy and aldehyde-fuchsin staining on the same sections demonstrated that the majority at least of these monoamine-containing structures were not identical with aldehyde-fuchsin positive neurosecretory fibres.This research was supported by a grant from the Swedish Medical Research Council (B68-12X-712-03B) and by the Faculty of Medicine, University of Lund.     

Citrullination: a posttranslational modification in health and disease

Posttranslational modifications are chemical changes to proteins that take place after synthesis. One such modification, peptidylarginine to peptidylcitrulline conversion, catalysed by peptidylarginine deiminases, has recently received significant interest in biomedicine. Introduction of citrulline dramatically changes the structure and function of proteins. It has been implicated in several physiological and pathological processes. Physiological processes include epithelial terminal differentiation, gene expression regulation, and apoptosis. Rheumatoid arthritis, multiple sclerosis, and Alzheimer's disease are examples of human diseases where protein citrullination involvement has been demonstrated. In this review, we discuss our current understanding on the importance of protein deimination in these processes. We describe the enzymes catalyzing the reaction, as well as their known protein substrates. We review the citrullinated peptide epitopes that are proposed as disease markers, specifically recognized in certain human autoimmune disorders. The potential autopathogenic role of citrullinated epitopes is also discussed.     

On the cause and nature of C9-related heterogeneity of terminal complement complexes generated on target erythrocytes through the action of whole serum

The binding of C8 and C9 from human serum to target erythrocytes was quantified, and the molecular stoichiometries of C9:C8 within terminal C5b-9(m) complexes were determined. Low doses of serum generated terminal complexes with mean C9:C8 ratios of 2 to 3:1, whereas complexes generated by highest serum doses harbored an average of six to eight C9/C8 molecules. From the collective biochemical and ultrastructural data, we concluded that heterogeneous populations of terminal complexes regularly form on target membranes; those containing high numbers of C9 molecules (greater than or equal to six to eight) exhibit the structure of the classical "lesion", whereas those containing low numbers of C9 do not exhibit this typical structure, although they probably still function as small pores. A major cause for this heterogeneity of the lesions derives from shortage of C9, which is naturally present in a 2 to 1 molar ratio relative to C8 in serum. Generation of terminal complexes harboring high numbers of C9 on erythrocyte membranes is possible in spite of this natural shortage because SC5b-9 does not form in the fluid phase to compete for C9 binding. If interrupted, the process of C9-C9 oligomerization cannot be recontinued, and "incomplete" C5b-9 complexes are unable to bind additional C9 upon reincubation with this component. The demonstrated heterogeneity of terminal complexes with respect to their C9 content may explain the functional heterogeneity of complement lesions observed previously by other investigators.     

Crystal structure of the Ig1 domain of the neural cell adhesion molecule NCAM2 displays domain swapping

The crystal structure of the first immunoglobulin (Ig1) domain of neural cell adhesion molecule 2 (NCAM2/OCAM/RNCAM) is presented at a resolution of 2.7 Å. NCAM2 is a member of the immunoglobulin superfamily of cell adhesion molecules (IgCAMs). In the structure, two Ig domains interact by domain swapping, as the two N-terminal β-strands are interchanged. β-Strand swapping at the terminal domain is the accepted mechanism of homophilic interactions amongst the cadherins, another class of CAMs, but it has not been observed within the IgCAM superfamily. Gel-filtration chromatography demonstrated the ability of NCAM2 Ig1 to form dimers in solution. Taken together, these observations suggest that β-strand swapping could have a role in the molecular mechanism of homophilic binding for NCAM2.     

Creative dynamics approach to neural intelligence

The thrust of this paper is to introduce and discuss a substantially new type of dynamical system for modelling biological behavior. The approach was motivated by an attempt to remove one of the most fundamental limitations of artificial neural networks — their rigid behavior compared with even simplest biological systems. This approach exploits a novel paradigm in nonlinear dynamics based upon the concept of terminal attractors and repellers. It was demonstrated that non-Lipschitzian dynamics based upon the failure of Lipschitz condition exhibits a new qualitative effect — a multi-choice response to periodic external excitations. Based upon this property, a substantially new class of dynamical systems — the unpredictable systems — was introduced and analyzed. These systems are represented in the form of coupled activation and learning dynamical equations whose ability to be spontaneously activated is based upon two pathological characteristics. Firstly, such systems have zero Jacobian. As a result of that, they have an infinite number of equilibrium points which occupy curves, surfaces or hypersurfaces. Secondly, at all these equilibrium points, the Lipschitz conditions fails, so the equilibrium points become terminal attractors or repellers depending upon the sign of the periodic excitation. Both of these pathological characteristics result in multi-choice response of unpredictable dynamical systems. It has been shown that the unpredictable systems can be controlled by sign strings which uniquely define the system behaviors by specifying the direction of the motions in the critical points. By changing the combinations of signs in the code strings the system can reproduce any prescribed behavior to a prescribed accuracy. That is why the unpredictable systems driven by sign strings are extremely flexible and are highly adaptable to environmental changes. It was also shown that such systems can serve as a powerful tool for temporal pattern memories and complex pattern recognition. It has been demonstrated that new architecture of neural networks based upon non-Lipschitzian dynamics can be utilized for modelling more complex patterns of behavior which can be associated with phenomenological models of creativity and neural intelligence.     

THE FINE STRUCTURE OF MOTOR ENDPLATE MORPHOGENESIS

The fine structure of the developing neuromuscular junction of rat intercostal muscle has been studied from 16 days in utero to 10 days postpartum. At 16 days, neuromuscular relations consist of close membrane apposition between clusters of axons and groups of myotubes. Focal electron-opaque membrane specializations more intimately connect axon and myotube membranes to each other. What relation these focal contacts bear to future motor endplates is undetermined. The presence of a group of axons lying within a depression in a myotube wall and local thickening of myotube membranes with some overlying basal lamina indicates primitive motor endplate differentiation. At 18 days, large myotubes surrounded by new generations of small muscle cells occur in groups. Clusters of terminal axon sprouts mutually innervate large myotubes and adjacent small muscle cells within the groups. Nerve is separated from muscle plasma membranes by synaptic gaps partially filled by basal lamina. The plasma membranes of large myotubes, where innervated, simulate postsynaptic membranes. At birth, intercostal muscle is composed of separate myofibers. Soleplate nuclei arise coincident with the peripheral migration of myofiber nuclei. A possible source of soleplate nuclei from lateral fusion of small cells' neighboring areas of innervation is suspected but not proven. Adjacent large and small myofibers are mutually innervated by terminal axon networks contained within single Schwann cells. Primary and secondary synaptic clefts are rudimentary. By 10 days, some differentiating motor endplates simulate endplates of mature muscle. Processes of Schwann cells cover primary synaptic clefts. Axon sprouts lie within the primary clefts and are separated from each other. Specific neural control over individual myofibers may occur after neural processes are segregated in this manner.     

Higher nervous activity in rats with symptoms of hereditary galactosemia]

The patterns of behaviour and neural processes in rats with symptoms of hereditary galactosemia were investigated. Certain impairment of neural processes, particularly of the internal inhibition process in galactosemic rats was established. This is evidenced by low conditioning rate and lower level of responding in 2-way shuttle-box avoidance achieved by galactosemic rats in comparison with galactose-resistant rat substrain. Significant changes in motor activity and emotionality level in the course of repeated open-field testings were not found in galactosemic rats. The pecularities of the active avoidance acquisition, an analysis of the capacity to the retention of acquired task demonstrated an impaired mechanism of long-term memory storage in galactosemic animals.     

Effects of Folic Acid and Homocysteine on the Morphogenesis of Mouse Cephalic Neural Crest Cells In Vitro

Folate deficiency and hyperhomocysteinemia have long been associated with developmental anomalies, particularly neural tube defects and neurocristopathies—a group of diverse disorders that result from defective growth, differentiation, and migration of neural crest (NC) cells. However, the exact mechanisms by which homocysteine (Hcys) and/or folate deficiencies disrupt NC development are still poorly understood in mammals. In this work, we employed a well-defined culture system to investigate the effects of Hcys and folic acid (FA) supplementation on the morphogenetic processes of murine NC cells in vitro. We demonstrated that Hcys increases outgrowth and proliferation of cephalic NC cells and impairs their differentiation into smooth muscle cells. In addition, we showed that FA alone does not directly affect the developmental dynamics of the cephalic NC cells but is able to prevent the Hcys-induced effects. Our results, therefore, suggest that elevated Hcys levels per se cause dysmorphogenesis of the cephalic NC and might contribute to neurocristopathies in mammalian embryos.     

Components of the cytoskeleton in the retinal pigmented epithelium of the chick

The retinal pigmented epithelium (RPE) is a simple cuboidal epithelium with apical processes which, unlike many epithelia, do not extend freely into a lumen but rather interdigitate closely with the outer segments of the neural retina. To determine whether this close association was reflected in the cytoskeletal organization of the RPE, we studied the components of the cytoskeleton of the RPE and their localization in the body of the cell and in the apical processes. By relative mobility on SDS gels and by immunoblotting, we identified actin, vimentin, myosin, spectrin (240/235), and alpha-actinin as major components, and vinculin as a minor component. In addition, the RPE cytoskeleton contains polypeptides of Mr 280,000 and 250,000; the latter co-electrophoreses with actin-binding protein. By immunofluorescence, the terminal web region appeared similar to the comparable region of the intestinal epithelium that consists of broad belts of microfilaments containing myosin, actin, spectrin, and alpha-actinin. However, the components of the apical processes were very different from those of intestinal microvilli. We observed staining along the process for myosin, actin, spectrin, alpha-actinin, and vinculin. The presence in the apical processes of contractile proteins and also of proteins typically found at sites of cell attachments suggests that the RPE may actively adhere to, and exert tension on, the neural retina.     

Whole Cell Patch Clamp for Investigating the Mechanisms of Infrared Neural Stimulation

It has been demonstrated in recent years that pulsed, infrared laser light can be used to elicit electrical responses in neural tissue, independent of any further modification of the target tissue. Infrared neural stimulation has been reported in a variety of peripheral and sensory neural tissue in vivo, with particular interest shown in stimulation of neurons in the auditory nerve. However, while INS has been shown to work in these settings, the mechanism (or mechanisms) by which infrared light causes neural excitation is currently not well understood. The protocol presented here describes a whole cell patch clamp method designed to facilitate the investigation of infrared neural stimulation in cultured primary auditory neurons. By thoroughly characterizing the response of these cells to infrared laser illumination in vitro under controlled conditions, it may be possible to gain an improved understanding of the fundamental physical and biochemical processes underlying infrared neural stimulation.     

Ultrastructural differentiation of the intestinal epithelium in the bandicoot Perameles nasuta

Summary The principal cells of the epithelium in the small intestine of the marsupial Perameles nasuta were studied with the electron microscope. The cells in the lower parts of the crypts are undifferentiated and have a high nucleo-cytoplasmic ratio and an abundance of free ribosomes. As the cells move upwards to take their place in the surface epithelium covering the mucosal folds their nucleo-cytoplasmic ratio and the number of free ribosomes decrease, the cells elongate and develop a brush border, a system of microtubules in the apical cytoplasm, a terminal web, terminal bars and desmosomes.The brush border develops from a series of cell processes interdigitating with those from the opposite cell. Spaces arising between the cell processes gradually separate the contiguous cells and the cell processes become microvilli which increase in number and become uniform in size and shape. The Golgi complex gives rise to small vesicles with a different membrane structure than that of the Golgi membranes themselves. It is suggested that the microtubules do not arise as tubular invaginations of the surface membrane but that they develop from the Golgi vesicles.     

Immunochemistry of highly branched N-glycans. Terminal N-acetyl-D-glucosamine (GlcNAc) cluster antigens contain epitopes composed of terminal GlcNAc residues linked to mannose

We have previously demonstrated by the immunoperoxidase method the presence of a chicken heterophile antigenic determinant (CHAD-1) in medullary lymphocytes of the bursa of Fabricius and thymus as well as in some nonlymphoid cells. It has been found that the anti-CHAD-1 antibody could be neutralized by absorption with several glycoproteins or glycopeptides containing highly branched, asparagine-linked oligosaccharides terminating in N-acetylglucosamine residues. In the present study, fetuin, desialo-fetuin, and a series of 27 highly purified oligosaccharides with well-defined structures were used to investigate the chemical composition and fine structure of the CHAD-1 epitope. It was shown that anti-CHAD-1 antibody binds to oligosaccharides with at least three terminal N-acetyl glucosamine residues at the nonreducing end. These residues may be linked beta 1-2, beta 1-4, or beta 1-6 to one, two, or three different mannose residues. The antibody combining site accommodates at least four carbohydrate residues. Oligosaccharides containing five or six terminal N-acetylglucosamine residues at the nonreducing end demonstrated the highest immunoreactivity with the anti-CHAD-1 antibody. Substitution of terminal N-acetylglucosamine residues with galactose, or with galactose and sialic acid, masks CHAD-1. On the basis of this work, epitopes that react with the anti-CHAD-1 antibody will be renamed terminal N-acetylglucosamine cluster antigens (TGCA). Anti-TGCA antibody has potential use in the monitoring of biosynthetic processing of asparagine-linked oligosaccharides and in studies of their cellular distribution and functions.