Neuromediator provision of the organs of immune system in benzpyrene intoxication]

The density of adrenergic innervation and relative content of catecholamines were investigated in rat lymphoid organs under different type of benzpyrene treatment. It was found that both ante- and postnatal influence of toxicant leads to a decrease of neurotransmitter providing of the thymus, spleen, mesenterial, iliac and popliteal lymph nodes. On the contrary, when mixed ante- and postnatal benzpyrene influence has place, the adrenergic innervation density and relative content of catecholamines are increased. We suppose that benzpyrene treatment of pregnant animals has specific "training" effect for monoaminergic systems of foetus and causes the increase of neurotransmitter providing of immunocompetent organs in conditions of repeat body and toxicant meeting.     

A self-organizing model of walking patterns of insects

It is well known that the motor systems of animals are controlled by a hierarchy consisting of a brain, central pattern generator, and effector organs. An animal's walking patterns change depending on its walking velocities, even when it has been decerebrated, which indicates that the walking patterns may, in fact, be generated in the subregions of the neural systems of the central pattern generator and the effector organs. In order to explain the self-organization of the walking pattern in response to changing circumstances, our model incorporates the following ideas: (1) the brain sends only a few commands to the central pattern generator (CPG) which act as constraints to self-organize the walking patterns in the CPG; (2) the neural network of the CPG is composed of oscillating elements such as the KYS oscillator, which has been shown to simulate effectively the diversity of the neural activities; and (3) we have introduced a rule to coordinate leg movement, in which the excitatory and inhibitory interactions among the neurons act to optimize the efficiency of the energy transduction of the effector organs. We describe this mechanism as the least dissatisfaction for the greatest number of elements, which is a self-organization rule in the generation of walking patterns. By this rule, each leg tends to share the load as efficiently as possible under any circumstances. Using this self-organizing model, we discuss the control mechanism of walking patterns.     

Long Covid: where we stand and challenges ahead

Post-acute sequelae of SARS-CoV-2 (PASC), also known as Post-Covid Syndrome, and colloquially as Long Covid, has been defined as a constellation of signs and symptoms which persist for weeks or months after the initial SARS-CoV-2 infection. PASC affects a wide range of diverse organs and systems, with manifestations involving lungs, brain, the cardiovascular system and other organs such as kidney and the neuromuscular system. The pathogenesis of PASC is complex and multifactorial. Evidence suggests that seeding and persistence of SARS-CoV-2 in different organs, reactivation, and response to unrelated viruses such as EBV, autoimmunity, and uncontrolled inflammation are major drivers of PASC. The relative importance of pathogenetic pathways may differ in different tissue and organ contexts. Evidence suggests that vaccination, in addition to protecting against disease, reduces PASC after breakthrough infection although its actual impact remains to be defined. PASC represents a formidable challenge for health care systems and dissecting pathogenetic mechanisms may pave the way to targeted preventive and therapeutic approaches.Subject terms: Infectious diseases, Immunological disorders     

Therapeutic applications of mesenchymal stromal cells

Mesenchymal stromal cells (MSC) are multipotent cells that can be derived from many different organs and tissues. They have been demonstrated to play a role in tissue repair and regeneration in both preclinical and clinical studies. They also have remarkable immunosuppressive properties. We describe their application in settings that include the cardiovascular, central nervous, gastrointestinal, renal, orthopaedic and haematopoietic systems. Manufacturing of MSC for clinical trials is also discussed. Since tissue matching between MSC donor and recipient does not appear to be required, MSC may be the first cell type able to be used as an "off-the-shelf" therapeutic product.     

Two microvillar organs, new to Crustacea, in the Mystacocarida

The mystacocarid crustacean Derocheilocaris typica has two microvillar organs, one new, the other previously unappreciated in crustacean literature. The first is situated on the head-shield and consists of three pairs of cells: one with microvilli and a ballooned nucleus; one smaller and without special features; the third large and investing the other two and extending down to the foregut. We call this new organ the "cephalic microvillar organ" and discuss the value of the concept "dorsal organ", to which it might have been included. The second organ consists of about 21 cells that cover the proximal part of the dorsal surface of the labrum. The cells are alike, being characterized by an apical field of microvilli and a large residual body. This organ is here called the "labral microvillar organ". Both organs are neither sensory nor secretory and do not qualify for membership in any of the other recognized organ systems. We are unable to deduce their Dero-cheilocaris functions.     

The role of ventral and preventral organs as attachment sites for segmental limb muscles in Onychophora

Background

The so-called ventral organs are amongst the most enigmatic structures in Onychophora (velvet worms). They were described as segmental, ectodermal thickenings in the onychophoran embryo, but the same term has also been applied to mid-ventral, cuticular structures in adults, although the relationship between the embryonic and adult ventral organs is controversial. In the embryo, these structures have been regarded as anlagen of segmental ganglia, but recent studies suggest that they are not associated with neural development. Hence, their function remains obscure. Moreover, their relationship to the anteriorly located preventral organs, described from several onychophoran species, is also unclear. To clarify these issues, we studied the anatomy and development of the ventral and preventral organs in several species of Onychophora.

Results

Our anatomical data, based on histology, and light, confocal and scanning electron microscopy in five species of Peripatidae and three species of Peripatopsidae, revealed that the ventral and preventral organs are present in all species studied. These structures are covered externally with cuticle that forms an internal, longitudinal, apodeme-like ridge. Moreover, phalloidin-rhodamine labelling for f-actin revealed that the anterior and posterior limb depressor muscles in each trunk and the slime papilla segment attach to the preventral and ventral organs, respectively. During embryonic development, the ventral and preventral organs arise as large segmental, paired ectodermal thickenings that decrease in size and are subdivided into the smaller, anterior anlagen of the preventral organs and the larger, posterior anlagen of the ventral organs, both of which persist as paired, medially-fused structures in adults. Our expression data of the genes Delta and Notch from embryos of Euperipatoides rowelli revealed that these genes are expressed in two, paired domains in each body segment, corresponding in number, position and size with the anlagen of the ventral and preventral organs.

Conclusions

Our findings suggest that the ventral and preventral organs are a common feature of onychophorans that serve as attachment sites for segmental limb depressor muscles. The origin of these structures can be traced back in the embryo as latero-ventral segmental, ectodermal thickenings, previously suggested to be associated with the development of the nervous system.

     

Silent endocrine tumors

Some tumors of hormonal organs are clinically active, while others are not. The silent tumors may be discovered by accident or because of effects due to their increase in size. From a simple steady state analysis of hormonal feedback systems follows that hormonal cell multiplication does not significantly influence the systems steady state behaviour (hence the clinical silence). —Exceptions to this rule occur in three situations: when the gain of the system is low; when the growth concerns cells with isolated sensor or reference functions; or because of the growth of autonomous cells. In many biological systems the dangerous situation of clamping to low levels upon sensor cell multiplication has been prevented by lumping, such as the combination of sensor and comparator functions into sensor-comparator cells.     

Cell suspensions,cell cultures,and tissue slices--important metabolic in vitro systems

In vitro subcellular and cellular systems have important and irreplaceable roles in the metabolic investigations that precede the development of new potential drugs. Of these model systems, tissue slices are probably the nearest to in vivo conditions. From the experimental and complexity points of view, perfused organs lie midway between tissue slices and whole organism. Preparation and working with liver slices is quick and easy, and, excess material can be cryopreserved and stored untill the next experiment. Slices can be prepared from a wide variety of organs and it is possible to co-incubate them. Another important feature is the possibility of interspecies comparison of slices. Different experiments can be run both in the short-term as well as long-term incubations. Each in vitro system has an important place for example, in the development of new medicaments. It is therefore important to compare and supplement experimental results from different in vitro systems when extrapolating to in vivo situations is done.     

Toward a universal measure of robustness across model organs and systems

The development of an individual must be capable of resisting the harmful effects of internal and external perturbations. This capacity, called robustness, can make the difference between normal variation and disease. Some systems and organs are more resilient in their capacity to correct the effects of internal disturbances such as mutations. Similarly, organs and organisms differ in their capacity to be resilient against external disturbances, such as changes in temperature. Furthermore, all developmental systems must be somewhat flexible to permit evolutionary change, and understanding robustness requires a comparative framework. Over the last decades, most research on developmental robustness has been focusing on specific model systems and organs. Hence, we lack tools that would allow cross-species and cross-organ comparisons. Here, we emphasize the need for a uniform framework to experimentally test and quantify robustness across study systems and suggest that the analysis of fluctuating asymmetry might be a powerful proxy to do so. Such a comparative framework will ultimately help to resolve why and how organs of the same and different species differ in their sensitivity to internal (e.g., mutations) and external (e.g., temperature) perturbations and at what level of biological organization buffering capacities exist and therefore create robustness of the developmental system.     

Will genomics revolutionise pharmaceutical R&D?

The successful identification of drug targets requires an understanding of the high-level functional interactions between the key components of cells, organs and systems, and how these interactions change in disease states. This information does not reside in the genome, or in the individual proteins that genes code for, it is to be found at a higher level. Genomics will succeed in revolutionising pharmaceutical research and development only if these interactions are also understood by determining the logic of healthy and diseased states. The rapid growth in biological databases, models of cells, tissues and organs, and in computing power has made it possible to explore functionality all the way from the level of genes to whole organs and systems. Combined with genomic and proteomic data, in silico simulation technology is set to transform all stages of drug discovery and development. The major obstacle to achieving this will be obtaining the relevant experimental data at levels higher than genomics and proteomics.     

Moral sensibilities and moral standing: Caplan on xenograft "donors"

[I]nterest in animals as a source of organs and tissues for human beings remains strong. New developments in immunosuppression technology promise to lower the technical barriers to a routine use of nonhumans as organ donors, and the image of colonies of animals kept at the ready for supplying the growing human need for new organs seems a much more plausible scenario now than it did when broached by transplantation specialists in the Sixties. As Arthur Caplan has powerfully argued, the prospects that other sources of organs may resolve the supply problem are grim.... In the face of these "pro-xenograft" pressures, it becomes all the more signficant to assess arguments against the practice that rest on considerations of the moral status of the nonhumans from whom the organs are taken. To be sure, xenograft faces other moral difficulties -- for example, concerns about the quality of informed consent obtained for recipients, worries about the possibility that xenografting will serve as a vector by which new and possibly virulent viruses become established in humans, and problems about whether such spending is equitable in the light of other unresolved human needs. Yet whether we morally wrong animals in taking their organs and their lives remains a decidedly central issue here, one that cannot be finessed away by developing better informed consent procedures, better anti-viral strategies, or by situating transplantation medicine in a just health care system.     

Determination of multielement concentrations in normal human organs from the Japanese

In order to elucidate the distribution of elements in organs from healthy Japanese, instrumental neutron activation analysis (INAA), based on the preliminary examination, was applied to quantitative determination of multielements in nine organs autopsied (brain, heart, kidney, liver, lung, muscle, pancreas, spleen, and thyroid). The following results were obtained: (1) The values obtained for each element could be considered to be representative as "normal values" and "ranges" in organs from healthy Japanese males; (2) the essential elements Br, Cl, Co, Cu, Fe, K, Mn, Na, Rb, Se, and Zn were not affected by external environmental factors or by racial difference; (3) renal and hepatic Cd levels were very high in several cases and the accumulation has still been in progress in the Japanese, whereas the contaminant elements are low in each organ except for lung.     

External Anatomy of the Female Genital (Eighth) Limbs and the Setose Openings in Myodocopid Ostracodes (Cypridinidae)

The external anatomy of various cypridinid female genital (8th) limbs is described. Scanning electron microscopy shows that each female cypridinid genital limb has a medial depression and associated pore (= spermatophore pore); over all of which a male cements a spermatophore. The limb terminates laterally in a superficially smooth rounded knob bearing an additional small opening (= lateral pore). Dorsolateral to this genital limb there are grouped setae, previously called "brush organs", that are really paired, slit–like posterolateral openings, which are probably subdermally united to the female genital limbs. The "brush organs" of all myodocopid females also are likely to be the setose openings. The setose openings are probably homologous to the setose central lobe of male cypridinid copulatory limbs, but not homologous to the limb–like "brush organ" described for some podocopid males. We speculate that the eggs are fertilized via the spermatophore pore associated with the attached spermatophore, and that they are released from the slightly larger and more lateral setose openings into the brood chamber of the posterodorsal area of the bivalved carapace.     

Dealing Death and Retrieving Organs

It has recently been argued by Miller and Truog (2008) that, while procuring vital organs from transplant donors is typically the cause of their deaths, this violation of the requirement that donors be dead prior to the removal of their organs is not a cause for moral concern. In general terms, I endorse this heterodox conclusion, but for different and, as I think, more powerful reasons. I end by arguing that, even if it is agreed that retrieval of vital organs causes the deaths of those who provide them, that does not pose any new substantive difficulties for efforts to justify “opt-out” organ procurement systems.     

An evolutionary treatment of the morphology and physiology of circulatory organs in insects

An overview from an evolutionary perspective is presented on the research of the past 2 decades on insect circulatory organs. Based on various functional morphology it is clear that the flow mode of the dorsal vessel ('heart') has changed during the evolution of hexapods. In all apterygotes and mayflies the flow is bidirectional. In most pterygote insects, however, it is unidirectional. In some endopterygote insects, the direction of the flow alternates. This is achieved by heartbeat reversal, which may have various physiological functions and is a derived condition that probably occurred several times during the course of insect evolution. Special attention is given to the hemolymph flow in body appendages. In ancestral hexapods, they are supplied by arteries, whereas circulation in appendages of higher insects is accomplished by accessory pulsatile organs. These auxiliary hearts are autonomous pumps and exhibit a great diversity in their functional morphology. They represent evolutionary innovations which evolved by recruitment of building blocks from various organ systems and were assembled into new functional units. Almost all pulsatile circulatory organs in insects investigated exhibit a myogenic automatism with a superimposed neuronal control. The neuroanatomy of insect circulatory organs has been investigated only in a small number of species but in considerable detail. Numerous potential peptidergic and a few aminergic mediators could be demonstrated by immunocytochemical and biochemical methods. The cardiotropic effectiveness of these mediators may vary among species and it can be stated that there is no uniform picture of the control of the various circulatory organs in insects. A possible explanation for the differences may lie in the different evolutionary origins of the muscular components. Furthermore, insect circulatory organs may represent important neurohemal releasing sites.     

Plant Embryogenesis

The subject of this review is the development of the plant embryo. Plant embryo-genesis is a unique process in the sense that it can be started not only from the fertilized egg but can also be initiated from other cells of the reproductive apparatus and even from somatic cells. One of the challenges of this field is therefore to unravel the molecular mechanisms that lead to the formation of a cell destined to form an embryo. A second important area of research is to determine the molecular basis of pattern formation in the embryo, a process that results in a stereotyped organization of a seedling. On the one hand, the pattern formation process has to establish precisely arranged tissue organization, but on the other hand sufficient flexibility during plant development has to be maintained to allow continuous formation of new organs from meristems.

In this review we summarize recent work that employs a variety of experimental systems that range from genetic dissection of pattern formation in the zygotic embryo, androgenesis and in vitro fertilization to somatic embryogenesis. While each of these systems highlights a different aspect of embryogenesis, they can be mutually beneficial in helping to understand the making of the plant embryo.     

Mathematical and philosophical reflections on motor control systems

In line with the tradition of the Dutch school of functional morphology, an attempt is made to integrate numerical models of sarcomeres, muscle fibres, muscles, bone-connective-tissue systems, joints, muscle spindles and neural networks into one model simulating motor control. There are two purposes for this attempt. Firstly, to indicate whether numerical properties of the organs forming a system of motor control can be explained in terms of its motor functions. Secondly, to indicate properties that emerge from the integration of the organs into a system of motor control: how much more is an integrated motor system than the sum of its functional components. The motor control system of chewing has been taken as an example, particularly that in rats.