Neuromuscular Systems in Molluscs

Molluscs have become increasingly popular in the study of centralneural mechanisms. More recently, there have been attempts torelate activity in central neurons with behavior in animalsof this phylum. The latter studies necessitate an understandingof the effectors of such behaviors. This requires not only informationabout the neuromuscular junction, but also an awareness of thecapabilities of the muscles themselves. Therefore, we have discussedsome structural and related functional characteristics of molluscanmuscle. We suggest that invertebrate mucles might be comparedon three scales: the amount of myofilament organization, theamount of vesicular specialization and organization, and theamount of paramyosin. We have considered some characteristicsof the widely-studied sustained contraction, known as "catch."Finally, we have discussed the neuromuscular junction—thetypes of junctions, the multiplicity of innervation, and someaspects of pharmacology. The results of such a study indicatedmany areas in which further research is essential before wecan understand behavior in terms of activity in the centralnervous system.     

Cellular Interactions in the Development of Stomatal Patterns in Vinca major L

The development of the leaf epidermis of Vinca major L. wasfollowed in situ by epi-illumination microscopy and evidencewas sought for cellular interactions. Stomata were often foundto be initiated in adjoining cells. The epidermal cells whichseparated such stomata when they had matured were formed fromthe same cells as the stomatal complexes themselves. The presenceof developing and mature stomata may influence only the orientationof divisions in neighbouring cells, and not the initiation andmaturation of stomata. There is great variability in the relativeorientation, timing and number of divisions which intervenebetween the first unequal division and the maturation of a stomaas well as the location of stomata relative to the spongy mesophylland minor veins. The results indicate that continuous short-rangeinteractions between the future guard cells and the adjoiningcells, rather than interactions between future stomata or afixed programme of development, are essential for the formationof the pattern of functional stomata in the mature leaf. Vinca major L., cell lineage, cellular interactions, development of stomata, epi-illumination microscopy, meristemoids, patterned differentiation, stomata     

Chelicerate Skeletal Neuromuscular Systems

In the past decade several laboratories began investigatingthe neuromuscular physiology of the arthropod subphylum, Chelicerata.This paper concerning chelicerate skeletal neuromuscular systemsconcentrates on three major areas: fine structural featuresof the skeletal muscles; fine structure of synaptic areas; andinnervation patterns and neuromuscular physiology. For all cheliceratesinvestigated, the fine structural features of the muscle fibersappear to be similar with the exception that the sarcomere lengthsfall into two general size categories (ca. 4 µ. and 7µ.) . Two types of synaptic areas are found in the chelicerates.In horseshoe crabs the synaptic region is formed in a largeevagination of the sarcoplasm, and evaginations from more thanone muscle fiber may combine into one synaptic region. In thearachnids the synaptic area is formed in a slight furrow inthe muscle fiber or along the surface of the fiber. Studiesof innervalion patterns reveal that horseshoe crabs have a muchgreater number of motor axons innervating the skeletal musculaturethan do other chelicerates. The motor axons appear to be similarin function in horseshoe crabs, but in scorpions there are atleast two functional types. In only one investigation has peripheralinhibition been demonstrated in Chelicerata.     

Excitatory Transmission in Insect Neuromuscular Systems

Many, but not all, visceral muscles in insects are innervatedby neurosecretory axons. The neurosecretory junctions with theheart muscle of the American cockroach, Periplaneta americana,show ultrastructural and electrophysiological evidence of chemicallytransmitting synapses, and cytochemical evidence for the presenceof monoamines. Electron microscopy of nerve terminals showsthat synaptic vesicles may be formed directly from electron-dense"neurosecretory" granules Neurotomy of motor axons to skeletal muscles in insects leadsto aggregation and clumping of synaptic vesicles after 48 hours.Treatment of in vitro nerve-muscle preparations with variousrespiratory poisons caused aggregation similar to that developedin neurotomized animals. This suggested that vesicle aggregationin both cases may have resulted from a decrease in availableadenosine triphosphate in the nerve terminal with subsequentalteration in the normal charge density which supports a repulsiveforce between the vesicles.     

Cellular Interactions in Morphogenesis of the Thyroid Gland

The existence of an epithelio-mesodermal interaction in theembryonic chick thyroid has been tested by reaggregation of8- and 16-day epithelial monolayers with capsule, mesentery,heart ventricle, and perichondrial cells. Establishment of thehistological anil cytological pattern of the thyroid occurredonly in the presence of capsule. The loss of endoplasmic reticulumwhich occurs in monolayer culture was shown not to be a resultof spreading, since organ cultures of immediately reaggregatedcells undergo the same degenerative changes. Dissociation itselfalso cannot be the explanation for the loss since membrane destructionand recovery occur at different times in raft cultures and inchorio-allantoic grafts. The similarity of the results afterimmediate reaggregation and in combinations of epithelial cellswith capsule after monolayer culture suggests that the roleof the mesodermal component is to support the specialized cytoplasmicstructure and function of the epithelial cell type.     

Ultrastructural Evidence for Neuromuscular Systems in Coelenterates

Cellular interrelationships and synaptic connections in tentaclesof several species of coelenterates were examined by means ofelectron microscopy to determine if neuromuscular pathways werepresent. The presence of sensory cells, ganglion cells, epitheliomuscularcells, interneuronal synapses, and neuromuscular junctions suggeststhat neuromuscular pathways are present in coelenterates. Nakedaxons without sheath cells form several synapses en passantwith the same and with different epitheliomuscular cells aswell as with nematocytes and other neurons. Interneuronal synapsesand neuromuscular and neuronematocyte junctions have clear ordense-cored vesicles (700–1500 Å in diameter) associatedwith a dense cytoplasmic coat on the presynaptic membrane, acleft (100–300 Å in width) with intracleft filaments,and a subsynaptic membrane with a dense cytoplasmic coat. Atscyphozoan neuromuscular junctions there is a subsurface cisternaof endoplasmic reticulum, which is separated from the epitheliomuscularcell membrane by a narrow cytoplasmic gap (100–300 Åin width) . Neuromuscular junctions in coelenterates resembleen passant axonal junctions with smooth muscle in higher animals. Morphological evidence is presented for a simple reflex involvinga two-cell (sensory or ganglion-epitheliomuscular cell) or three-cell(sensory-ganglion-epitheliomuscular cell) pathway that may resultin the coordinated contraction of the longitudinal muscle intentacles of coelenterates.     

Degeneration and Regeneration in Crustacean Neuromuscular Systems

Crayfish motor neurons seem to repair damage to peripheral axonsby selective fusion of outgrowing proximal stumps with severeddistal processes that can survive morphologically and physiologicallyintact for over 200 days. Survival of isolated motor and CNSgiant axons is associated with much hypertrophy of their glialsheath. The severed stumps of peripheral sensory neurons oftendegenerate within 21 days and their glial sheath does not hypertrophy.Denervation and immobilization produce relatively little changein the morphology and physiology of the opener muscle, whereastenotomy produces much atrophy within 30-60 days. Crayfish motor and CNS giant neurons show no capability forregenerating ablated cell bodies, whereas peripheral sensorysomata regenerate after limb autotomy. An entire opener musclecan be replaced after limb autotomy but the organism shows littleor no ability to redifferentiate an entire muscle in the absenceof body part regeneration. However, a few opener muscle fiberscan be regenerated if the bulk of the muscle mass remains intact.The significance of all these findings are interpreted withrespect to the developmental capabilities and environmentaladaptations of the crayfish together with the evolution of regenerativeabilities in anthropods and vertebrates.     

Remodelling of Neuromuscular Systems During Insect Metamorphosis

During metamorphosis in the hawkmoth, Manduca sexta, the larvalthoracic legs are replaced by a new set of adult legs that includenew sensory neurons and muscles, and participate in new patternsof locomotor activity. Larval leg motoneurons persist to innervatethe new adult leg muscles, but undergo striking changes in dendriticmorphology that are regulated by the insect steroid, 20-hydroxyecdysone.In the periphery, the motor terminals regress as larval musclesdegenerate, and expand as new adult muscles form from myoblasts.Evidence obtained both in vivo and in vitro suggests that theproliferation of myoblasts during metamorphosis is dependentupon innervation.     

Cellular Interactions during the Mating Process in Chlamydomonas eugametos

A method to determine the mating competence of Chlamydomonas eugametos was developed. The contribution of each mating type in the pair formation was investigated using asymmetric gamete mixtures. It was established that pair formation is not mediated by a pheromonal attraction mechanism between partner gametes, but depends on collision chances. On the other hand, it was demonstrated that during transient contacts between partner gametes the flagellar agglutinability of both partners is stimulated, evidently to prepare a successful mating. The plus mating type was generally less agglutinable than the minus mating type and was a rate-limiting factor in the mating process.     

Allelopathic Interactions in Agroforestry Systems

Agroforestry is a modern tool to develop sustainable land use and to increase food production by growing woody species (trees, shrubs, palms, bamboos, etc.) with agricultural crops and/or animals in some form of spatial arrangement or temporal sequence. Because these species co-exist with the agricultural crops, their allelopathic compatibility may be crucial to determine the success of an agroforestry system. A survey of the available information reveals that most of the agroforestry species (AF species) have negative allelopathic effects on food and fodder crops. Therefore, it is desirable to do further research in this direction so that AF species with no or positive allelopathic effects on the companion crops may be promoted for agroforestry programs. As AF species remain a part of the agroecosystem for a longer period, and most of them produce a large amount of leaves and litter, their allelochemicals may play an important role in developing an eco-friendly pest management strategy. Besides these generally studied aspects of allelopathy, some comparatively newer aspects of research have been identified, such as evaluation of qualitative yield of agroforestry systems, selective behavior of the allelochemicals, effect on soil quality, and the role of tree allelochemicals in animal and human nutrition. If given due consideration, allelopathy could play a pivotal role in conservation of the highly threatened environment, biodiversity, natural resource base, and making agriculture more sustainable through broadening the scope of agroforestry.     

Neto-Mediated Intracellular Interactions Shape Postsynaptic Composition at the Drosophila Neuromuscular Junction

The molecular mechanisms controlling the subunit composition of glutamate receptors are crucial for the formation of neural circuits and for the long-term plasticity underlying learning and memory. Here we use the Drosophila neuromuscular junction (NMJ) to examine how specific receptor subtypes are recruited and stabilized at synaptic locations. In flies, clustering of ionotropic glutamate receptors (iGluRs) requires Neto (Neuropillin and Tolloid-like), a highly conserved auxiliary subunit that is essential for NMJ assembly and development. Drosophila neto encodes two isoforms, Neto-α and Neto-β, with common extracellular parts and distinct cytoplasmic domains. Mutations that specifically eliminate Neto-β or its intracellular domain were generated. When Neto-β is missing or is truncated, the larval NMJs show profound changes in the subtype composition of iGluRs due to reduced synaptic accumulation of the GluRIIA subunit. Furthermore, neto-β mutant NMJs fail to accumulate p21-activated kinase (PAK), a critical postsynaptic component implicated in the synaptic stabilization of GluRIIA. Muscle expression of either Neto-α or Neto-β rescued the synaptic transmission at neto null NMJs, indicating that Neto conserved domains mediate iGluRs clustering. However, only Neto-β restored PAK synaptic accumulation at neto null NMJs. Thus, Neto engages in intracellular interactions that regulate the iGluR subtype composition by preferentially recruiting and/or stabilizing selective receptor subtypes.     

Wnt Signaling in Neuromuscular Junction Development

Wnt proteins are best known for their profound roles in cell patterning, because they are required for the embryonic development of all animal species studied to date. Besides regulating cell fate, Wnt proteins are gaining increasing recognition for their roles in nervous system development and function. New studies indicate that multiple positive and negative Wnt signaling pathways take place simultaneously during the formation of vertebrate and invertebrate neuromuscular junctions. Although some Wnts are essential for the formation of NMJs, others appear to play a more modulatory role as part of multiple signaling pathways. Here we review the most recent findings regarding the function of Wnts at the NMJ from both vertebrate and invertebrate model systems.Wnt proteins are evolutionarily conserved, secreted lipo-glycoproteins involved in a wide range of developmental processes in all metazoan organisms examined to date. In addition to governing many embryonic developmental processes, Wnt signaling is also involved in nervous system maintenance and function, and deregulation of Wnt signaling pathways occurs in many neurodegenerative and psychiatric diseases (De Ferrari and Inestrosa 2000; Caricasole et al. 2005; Okerlund and Cheyette 2011). The first link between Wnt signaling and synapse development was established by Salinas and colleagues in the vertebrate nervous system (Lucas and Salinas 1997; Hall et al. 2000) and by Budnik and colleagues at the invertebrate neuromuscular junction (NMJ) (Packard et al. 2002). Since then, Wnt signaling has emerged as an essential regulator of synaptic development and function in both central and peripheral synapses. Although important roles for Wnt signaling have become known from studies in both the central and peripheral nervous system, this article is concerned with the role of Wnts at the NMJ.     

Time Lapse Filming of Cellular Interactions in Organ Culture

A new method of time lapse filming has been developed for the investigation of organ cultures. This method reveals the 3-dimensional structure of the living tissue.
In Paper I the interaction of non-malignant fibroblasts and macrophages with natural membranes is studied. These cells spread on the mesothelial and epithelial surfaces of the membranes. The cell membranes exhibit ruffled movements and glide smoothly over the surface of the normal mesothelial tissues without penetration of the surface layers.     

Time Lapse Filming of Cellular Interactions in Organ Culture

A method of time lapse filming which enables the 3-dimensional structure of living tissues to be studied has been extended to observe the behaviour of malignant cells on natural membranes.
Two types of virus-transformed fibroblasts and a melanoma cell line showed marked differences in behaviour from the non-malignant cells described in Paper I. The malignant cells tended to form points of anchorage on the surface epithelium of the membranes. At a later stage they penetrated into the epithelial layers and sometimes also into the underlying connective tissue.     

Time-Lapse Filming of Cellular Interactions within Living Tissues

By a further development of the technique for time-lapse filming of organ cultures, it has become possible to observe the internal structure of the living tissues and to study the dynamics of intercellular contacts within the tissue. This method has been applied to a study of the interaction between the tissues of the chick chorioallantoic membrane and non-malignant fibroblasts, polyoma virus-transformed fibroblasts, and Harding-Passey melanoma cells. The behaviour of these cells in the absence and in the presence of colcemid has been investigated. From these studies it is concluded that disturbances in cell shape brought about by colcemid do not affect the invasive properties whereas the surface polypodial activity shown by the malignant cells is a major factor in tumour invasion.     

Functional and Structural Parallels in Crustacean and Drosophila Neuromuscular Systems

Comparison of morphological and physiological phenotypes ofrepresentative crustacean motor neurons, and selected motorneurons of Drosophila larval abdominal muscles, shows severalfeatures in common. Crustacean motor nerve terminals, and thoseof Drosophila, possess numerous small synapses with well-definedactive zones. In crustaceans, neurons that are more tonicallyactive have markedly varicose terminals; synapses and mitochondriaare selectively localized in the varicosities. Phasic motoraxons have filiform terminals, sometimes with small varicosities;mitochondrial content is less than for tonic axons, and synapsesare distributed along the terminals. Tonic axons generate smallexcitatory potentials which facilitate strongly at higher frequencies,and which are resistant to depression. Thephasic neurons generatelarge excitatory potentials which exhibit relatively littlefrequency facilitation, and depress rapidly. In Drosophila,counterparts of crustacean phasic and tonic motor neurons havebeen found, but the differentiation is less pronounced. It isinferredthat cellular factors regulating the number of participatingsynapses and the probability of quantal release are similarin crustaceans and Drosophila, and that advantage can be takenof this in future to develop experiments addressing the regulationof synaptic plasticity.     

Possible Specificity of Cellular Interactions Due to Electrostatic Forces

It is known that the cells from a mixed population in a culture medium will finally segregate. This “social behavior” of the cells is a direct consequence of both physical and chemical interactions between cells. The physical forces involved in cell-cell interactions are considered to be the electrostatic, van der Waals, and very-short-range hydration forces.

It has been believed until now that the electrostatic forces acting between identical cells were always repulsive and nonspecific. In the present work, we try to suggest that even the electrostatic forces could manifest a slightly specific character, so that a completely random Brownian motion of the cells could be influenced, corrected, and transformed into a “docking maneuver,” which could favor the specific interactions between cells suspended in a culture medium. The main point of our approach is that the peculiar patterns of electric charge distribution on the cell surfaces act like specific electrostatic fingerprints that could be responsible for the preferential interactions which precede cellular segregation (1).     

Multiscale Systems Analysis of Root Growth and Development: Modeling Beyond the Network and Cellular Scales

Over recent decades, we have gained detailed knowledge of many processes involved in root growth and development. However, with this knowledge come increasing complexity and an increasing need for mechanistic modeling to understand how those individual processes interact. One major challenge is in relating genotypes to phenotypes, requiring us to move beyond the network and cellular scales, to use multiscale modeling to predict emergent dynamics at the tissue and organ levels. In this review, we highlight recent developments in multiscale modeling, illustrating how these are generating new mechanistic insights into the regulation of root growth and development. We consider how these models are motivating new biological data analysis and explore directions for future research. This modeling progress will be crucial as we move from a qualitative to an increasingly quantitative understanding of root biology, generating predictive tools that accelerate the development of improved crop varieties.     

Cortical-subcortical Interactions in the Development of the Emotions

In contrast to the cerebral systems regulating the level of activation, the dynamics of sleep, the organization of sensory functions, and the construction of movements, the structures responsible for emotional responses in humans and higher mammals remain a subject of bitter debate. Although modern physiology of the brain has accumulated much data indicating the functional specialization of cerebral structures classified as emotion-producing, these results have as yet defied attempts to fit them into a relatively coherent system that would clarify the specific contribution made by each particular formation to the development of a particular emotional state.