The sensory innervation of the pineal organ in the lizard,Lacerta viridis,with remarks on its position in the trend of pineal phylogenetic structural and functional evolution

Summary The sensory innervation of the pineal organ of adult Lacerta viridis has been investigated. Some specimens of Lacerta muralis lillfordi were also used. In the pineal epithelium, a small number of nerve cell pericarya of a sensory type are present. They lie either solitary or in small clusters close to the basement membrane. The axons originating from the nerve cell bodies, i. e. the pineal sensory nerve fibers, first course in the intraepithelial nerve fiber layer which is only locally present and contains a restricted number of unmyelinated fibers. In Lacerta viridis, the pineal fibers generally leave the epithelium at the proximal part of the organ proper. They then form small bundles which run along the outer surface of the basement membrane in the leptomeningeal connective tissue covering. At the proximal end of the pineal stalk the single bundles assemble constituting the pineal nerve. In Lacerta muralis the fibers leave the pineal epithelium at the proximal end of the stalk running farther down within the epithelium. Many fibers become myelinated after leaving the pineal epithelium. The pineal nerve runs ventralward in the midplane just caudal to the habenular commissure to which no fibers are given off. Continuing their ventralward course between the habenular commissure and the rostral end of the posterior commissure which is traversed by some of them, the pineal fibers reach the dorsal border of the subcommissural organ. Small separate aberrant pineal bundles traverse the posterior commissure at various more caudal levels. Having reached the dorsal border of the subcommissural organ, part of the pineal fibers continue their ventralward course directly running along the lateral sides of this organ to reach the periventricular nerve fiber layer lateral and ventral to it. A restricted number of fibers first turns in a caudal direction running between the base of the posterior commissure and the base of the subcommissural organ before turning ventralward to reach the periventricular layer. Most probably, pineal fibers do neither join the posterior commissural system nor innervate the subcommissural organ. Once having reached the periventricular layer, some pineal fibers curve in a rostral direction while others, before doing so, send a collateral in a caudal direction. Both, the main fibers and the collaterals, contribute to the formation of the periventricular layer. The sites of termination of the pineal fibers could not be ascertained.From the presence of intraepithelial sensory nerve cell bodies and from literature data on the ultrastructure of pineal neurosensory cells it is concluded that the adult pineal organ of Lacerta has a, although rudimentary, (photo)sensory function. The demonstration by our guest-worker Dr. W. B. Quay, of the intraepithelial presence of a tryptamine compound, probably serotonin, points, moreover, to a secretory function of this organ.In adult Lacerta a well-developed parietal nerve connects the parietal eye with the left lateral habenular nucleus. It traverses the habenular commissure.In gratitude and with admiration this paper is dedicated to Prof. Berta Scharrer and to the memory of Prof. Ernst Scharrer.     

Anaerobic metabolism and activity of European lacertid lizards

1. Lactate production and physical performance during intense activity were measured in Lacerta vivipara, Podarcis muralis and Podarcis hispanica, temperate lizards from progressively lower latitudes. 2. Rates of lactate production during the initial 30 sec of bursts of activity (means = 1.75 mg g-1) and their Q10S (means = 1.36) are similar to previously obtained values for lizards. 3. Maximal anaerobic scope at activity body temperatures is lowest in Lacerta vivipara, which correlates with a tendency to less strenuous behaviour than that of the Podarcis species and may reflect the need for energy economy. 4. Q10S of maximal performance are lower in Lacerta vivipara and Podarcis muralis than Podarcis hispanica, a difference having no demonstrated metabolic basis but which is thermally adaptive for these cooler climate species.     

Spread of hemoparasites in reptiles and amphibians in Italy

Hemoparasites were harvested from 993 individuals belonging to 15 reptilian and 1 amphibian species, from various Italian localities. Hemogregarins were found in 10 reptilian species while a flagellate and microfilariae were found only in Tarentola mauritanica from Lampedusa. For each host species and place of origin the frequencies of hemogregarins are reported and discussed. Longitudinal studies with periodical thin smears were carried out on 5 Tarentola mauritanica, 4 Lacerta viridis, 26 Podarcis filfolensis, 10 Podarcis muralis, 38 Podarcis sicula, 8 Chalcides ocellatus. This material, whose study has not yet been completed, is made available by the author who strongly encourages further investigations on this subject.     

Molecular phylogeography of the moss Tortula muralis Hedw (Pottiaceae) based on chloroplast rps4 gene sequence data

Abstract: Tortula muralis is a moss species of cosmopolitan distribution, for which we present chloroplast rps 4 sequence data. The sequences provided a sufficiently high degree of divergence ( h = 0.878, θ= 0.00989 ± 0.0000106, a total of 18 haplotypes for 49 accessions) for the degree of differentiation between regions from different continents to be investigated. In fact, 18.53 % of the variation found corresponded to differences between these regions, while 81.43 % was attributed to intra-region differences. Only the Japanese area differed significantly from other regions. Some haplotypes are found on several continents, while others are restricted to certain areas. Six of the seven sequenced plants from Japan belong to a haplotype only found there. The phylogenetic analysis suggests that Tortula muralis might be paraphyletic, with Tortula vahliana nested within the Tortula muralis clade. At present, it is not clear whether gene flow between the different clades of Tortula muralis is a continuing process or whether Tortula muralis is an example of cryptic speciation.     

Development of the paratympanic pneumatic system of Japanese quail

Avian heads are characterized as having two extensive air-filled systems lined with epithelia; the paranasal and paratympanic sinuses. Many diverticula derived from the paratympanic sinus system are known to reticulate with each other to form a single merged pneumatic space within the adult braincase. However, the development of these complex branching and reticulating epithelia has not been examined in detail. In this study, we describe the comprehensive developmental pattern of the paratympanic sinus and its associated soft tissues in a model bird, Japanese quail (Coturnix japonica). The data are derived from three-dimensional reconstructions based on histological sections and soft tissue enhanced micro-CT data. Those data provide the foundation of the complex hierarchical developmental pattern of the paratympanic sinus system. Moreover, associations with other tissues help establish key morphologies that identify each pneumatic entity. This study clarifies the developmental relationships of the ventral portions of the paratympanic sinus system, the siphoneal diverticulum and marginal sinus, based on the ligaments associated with the Eustachian tube. In addition, detailed histological pneumatic morphologies reveal hitherto unknown epithelial diversity, which may be indicative of equally complex developmental processes. We use the pneumatization of the quadrate as an example to support a close relationship with vascular growth and pneumatic epithelia invasion into ossified bone. We confirm pneumatic diverticula never enter into cartilages, possibly due to the absence of vasculature in these tissues. Lastly, we use the concept of a morphogenetic tree as a tool to help present the complex developmental pattern of the paratympanic sinus system and apply it toward inferring pneumatic morphologies in a nonavian theropod braincase.     

Unterschiedlicher elektronenmikroskopischer Feinbau der Sinneszellen im Parietalauge und im Pinealorgan (Epiphysis cerebri) der Lacertilia

Zusammenfassung Das Parietalauge und das Pinealorgan (Epiphysis cerebri) der Echsen Lacerta sicula campestris, Lacerta vivipara, Lacerta agilis, Anguis fragilis und Iguana iguana wurden elektronenmikroskopisch untersucht und die Ultrastrukturen ihrer Rezeptoren verglichen. Die langen Außenglieder des Parietalauges sind aus regulären scheibenförmigen Lamellenverbänden aufgebaut. Im Pinealorgan der Echsen findet man zwar eine gewisse Anzahl von kurzen regulär gebauten Außengliedern, im Vordergrund stehen aber die zahlreichen alterierten und degenerierten Außengliedstrukturen. Diese sind durch Auflösung des charakteristischen Lamellenverbandes, die offenbar zur Bildung von Tubuli oder Bläschen führt, konzentrische Lamellenkörper und membranbegrenzte Vakuolen verschiedenen Inhalts gekennzeichnet. Außerdem wurden noch rudimentäre oder unreife (Neubildung ?) Außengliedformen beobachtet. Aufmerksamkeit verdienen einige artspezifische und ontogenetische Unterschiede. Parenchymzellen der Lacertilierepiphyse (1. epitheliale, lumennahe Elemente, die sich offenbar von Sinneszellen herleiten, 2. verzweigte Formen der tieferen Wandschichten) und marklose Nervenfasern enthalten verschiedene Typen elektronendichter Granula. Das Epiphysenproblem wird auf der Basis dieser Befunde und der elektrophysiologischen Ergebnisse von Dodt u. Mitarb. diskutiert.

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Differences in the ultrastructure of the sensory cells in the parietal eye and the pineal organ (epiphysis cerebri) of lacertiliaA contribution to the pineal problem

Summary The parietal eye and the pineal organ (epiphysis cerebri) of the lizards, Lacerta sicula campestris, Lacerta vivipara, Lacerta agilis, Anguis fragilis and Iguana iguana, have been studied by means of electron microscopy. The ultrastructure of the parietal eye and pineal receptor cells is compared. The long outer segments of the parietal eye appear normal and show regular stacks of discs. In the pineal organ some of the short outer segments are essentially normal, but there are many disorganized and degenerated outer segment structures. Separation of discs and transformation into tubules and vesicles, whorllike structures or membrane-bounded and vesicle-filled compartments are very abundant. In addition, some rudimentary or anlage-like (renewal ?) forms of the outer segment were observed. Attention should be given to some interspecific and ontogenetic differences. Different types of dense-core vesicles were found in (1) the epithelial and pinealocyte-like parenchymal cells and (2) the unmyelinated nerve fibers of the lacertilian pineal organs. The pineal problem is discussed in view of these findings and the electrophysiological results of Dodt et al.

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Herrn Prof. Dr. Dr. h. c. W. E. Ankel gewidmet.

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Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Is the avian circadian system a neuroendocrine loop?

Avian circadian organization is a result of a complex interaction of photoreceptive and oscillatory components. The known components include the pineal gland, the lateral eyes, the suprachiasmatic nuclei (SCN), and extraocular brain photoreceptors. The pathways by which these components integrate circadian rhythmicity suggest a neuroendocrine loop in which the SCN inhibits pineal and ocular oscillators during the course of subjective day via a multisynaptic neuronal pathway which includes the superior cervical ganglia (SCG). During the night, the pineal in turn inhibits SCN activity via its secretion of the hormone melatonin into the blood circulation. This neuroendocrine loop, it is proposed, synchronizes multiple oscillators within each component and maintains the stability and precision of the system.     

A quantitative study of microtubules in motor and sensory axons

The number, density and distribution of microtubules were compared in the myelinated motor and sensory axons of the spinal roots of lizard (Lacerta muralis). In both motor and sensory axons the average number and density of microtubules were found to be related to the axonal size: the average number of microtubules rose, while the microtubular density decreased with an increase in the cross-sectional area of the axon. More precisely, a linear relationship was observed between the logarithm of the microtubular density and the cross-sectional area of the axon. No significant differences in the microtubular number and density were found between motor and sensory axons of corresponding size. Microtubules were unevenly distributed throughout the cross section of both motor and sensory axons. In particular, a nonaccidental association between microtubules and mitochondria was found in both axon types.     

Comparative postautotomy tail activity in six Mediterranean lacertid lizard species

Tail autotomy, the self-induced tail separation from the body, is a common and effective antipredator mechanism in lizards. In this study, we examine the muscle energetics of tail shedding in six lacertid lizard species (Podarcis erhardii, Podarcis peloponnesiaca, Podarcis muralis, Podarcis gaigeae, Podarcis milensis, and Lacerta graeca) from the northeast Mediterranean region. Very long periods of postautotomy tail movement were demonstrated for all species (range=6-8 min), and differences among species were not statistically significant. Postautotomy tail movement, powered by anaerobic muscle activity, resulted in a strong increase in lactate concentrations and a concomitant depletion of muscle glycogen of exhausted tails relative to resting tails. No significant differences were found in either lactate or glycogen concentrations among the species examined. Duration of movement was negatively correlated with final lactate concentrations. The lack of differentiation in postautotomy energetic physiology in this group of species that have evolved under very different predation environments indicates that postautotomy muscle metabolism involves an overall conservative suite of characters.     

Über die elektronenmikroskopische Identifizierung von noradrenergen Nervenfasern durch 5-Hydroxydopamin und 5-Hydroxydopa im Pinealorgan der Eidechse (Lacerta muralis)

Zusammenfassung Durch Verwendung von 5-Hydroxydopamin und 5-Hydroxydopa, die endogenes Noradrenalin in den Speichergranula sympathischer Nerven ersetzen, gelang es, noradrenerge Nervenfasern innerhalb des Pinealorgans von Lacerta muralis zu identifizieren. Die Nerven stammen von sympathischen, autonomen Neuronen. Ihre marklosen Fortsätze können an der großen Anzahl von granulierten Vesikeln erkannt werden, deren elektronendichter Inhalt durch die Vorbehandlung eindeutig zugenommen hat. In drei Teilen des Pinealorgans wurden noradrenerge Fasern elektronenmikroskopisch gefunden: 1. Neben den Blutgefäßen im perivaskulären Bindegewebsraum, 2. zwischen den Zellen und deren Fortsätzen innerhalb des Pinealorgans, 3. frei im Lumen des Pinealorgans. In einigen Fällen wurde beobachtet, daß verdickte Endformationen Kontakt mit Teilen von Sinneszellen, besonders deren Außengliedern, aufnehmen. Bisher konnte kein synaptischer Kontakt mit sekretorischen Zellen des Pinealorgans festgestellt werden.

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On the electron microscopic identification of noradrenergic nerves in the pineal organ of the lizard lacerta muralis by 5-hydroxydopamine and 5-hydroxydopa

Summary Using 5-hydroxydopamine and5-hydroxydopa as false sympathetic transmitters the authors identified noradrenergic nerves inside the pineal organ of the lizard. These nerves are part of sympathetic autonomic neurones; their unmyelinated processes are identified by a large number of dense core vesicles the electron dense content of which has increased significantly following pretreatment with the catechol-analogues. There are three parts of the pineal organ where noradrenergic nerves have been found electron microscopically: 1) Close to the blood vessels in the perivascular connective tissue compartment, 2) between cells and their processes inside the epithelium of the pineal organ, 3) free in the lumen of the pineal gland. In some cases club shaped terminations contact parts of sensory cells especially their outer segments. No synaptic contacts to secretory cells have been detected so far.

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Supported by USPHS Research Grant TW 00295-02.

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Mit dankenswerter Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Cytochemical demonstration of acid phosphatase activity in the pineal organ of the rainbow trout,Salmo gairdneri

Summary Activity of acid phosphatase (ACP) was investigated cytochemically in the pineal organ of the rainbow trout, Salmo gairdneri. Intense reaction product for ACP activity was observed (1) in lysosomes varying in size and shape and (2) in endoplasmic reticulum associated with the Golgi complex of (i) the pineal photoreceptor and supporting cells, (ii) vascular endothelial cells, and (iii) macrophages inhabiting pineal lumen, parenchymal epithelium and perivascular spaces. This localization of ACP is discussed with particular reference to the capacity for lysosomal digestion in a pineal organ combining photoreceptive and secretory functions, and lacking a blood-brain barrier, as holds true for the pineal of the rainbow trout. Taking advantage of its capacity for endocytotic uptake and lysosomal digestion, the pineal organ of the rainbow trout may serve as a barrier between the blood circulation and the cerebrospinal-fluid compartment. Furthermore, the macrophages may be considered as an essential component in pineal function of fish.Fellow of the Alexander von Humboldt Foundation.Fellow of the Alexander von Humboldt Foundation.     

Reproductive apparatus and mating system in two tropical goby species

Field observations demonstrated that two gobiid species Amblygobius nocturnus and Valenciennea muralis have a monogamous mating system. Histological analyses showed an extreme reduction of male accessory organs relative to other gobiids in A. nocturnus , and their complete absence in V. muralis.     

Perpetuation of the Lyme disease spirochete Borrelia lusitaniae by lizards

To determine whether the Lyme disease spirochete Borrelia lusitaniae is associated with lizards, we compared the prevalence and genospecies of spirochetes present in rodent- and lizard-associated ticks at a site where this spirochete frequently infects questing ticks. Whereas questing nymphal Ixodes ricinus ticks were infected mainly by Borrelia afzelii, one-half of the infected adult ticks harbored B. lusitaniae at our study site. Lyme disease spirochetes were more prevalent in sand lizards (Lacerta agilis) and common wall lizards (Podarcis muralis) than in small rodents. Although subadult ticks feeding on rodents acquired mainly B. afzelii, subadult ticks feeding on lizards became infected by B. lusitaniae. Genetic analysis confirmed that the spirochetes isolated from ticks feeding on lizards are members of the B. lusitaniae genospecies and resemble type strain PotiB2. At our central European study site, lizards, which were previously considered zooprophylactic for the agent of Lyme disease, appear to perpetuate B. lusitaniae.     

An electron microscopic study of hemoglobin synthesis in the marine annelid,Amphitrite ornata (Polychaeta: Terebellidae)

The heart-body of the marine worm Amphitrite, located within the supraesophageal dorsal vessel, is in the form of a cylinder the thin wall of which is deeply corrugated by luminal projections and folds along its entire length. It is anchored in places to the luminal surface of the dorsal vessel by an extracellular matrix containing collagen fibers. The luminal surfaces of both the heart-body and the dorsal vessel are covered by a basement membrane-like vascular lamina which in turn supports a discontinuous pseudoendothelium of littoral hemocytes. The cells of the heart-body constitute a pseudostratified, high columnar epithelium. They possess extensive rough endoplasmic reticulum (RER), a well developed Golgi zone, ferritin particles and granules, and several types of membrane-bound inclusions. Hemoglobin molecules identical to those in the circulation lie within cytoplasmic, membrane-bound vesicles. Analysis of our electron micrographs suggests the following sequence of hemoglobin production and secretion: Large quantities of a moderately dense flocculent material, probably globin, are synthesized in RER and move to the Golgi zone within partly rough- and partly smooth-surfaced transitional cisternae; small transport vesicles, formed from Golgi cisternae that have fused with transitional cisternae, convey the flocculent material from the convex to the concave face of the Golgi complex; a similar flocculent material and an amorphous, highly dense material are processed in the Golgi complex and are transferred to condensing vacuoles in which clearly identifiable hemoglobin molecules are first observed. Mature secretory vesicles containing only hemoglobin migrate to the cell periphery and discharge their contents by exocytosis. Hemoglobin molecules then cross the vascular lamina to reach the circulation.     

Observations on the pineal system in the hamster. I. Relations of the superficial and deep pineal to the epithalamus

A mass of pineal tissue has been observed associated with the habenular commissure and the apex of the pineal recess in the golden hamster. Previously, it had been thought that all of the pineal system in the hamster was located at the confluence of sinuses just beneath the skull. To distinguish the two components of the pineal system, that in the dural position is called the superficial pineal and the mass associated with the habenular commissure is called the deep pineal.     

Descriptive and functional anatomy of the digital vascular system of the tokay,Gekko gecko

The vascular system of the digits of the tokay is more complex than has hitherto been suspected and has a configuration which suggests it is intimately involved in the process of adhesion. Distinction can be made between lamellae (expanded scales beneath the proximal portion of the digit) and scansors (elaborations of lamellae that contain a large amount of subdermal material and therefore do not technically qualify as scales). Such a distinction is made on anatomical grounds and can be appreciated only if anatomical investigation is carried out. There are no externally obvious features by which lamellae and scansors can be distinguished, except position. Scansors are found beneath hyperextensible phalanges, whereas lamellae are located more proximally and are not subjected to digital hyperextension during locomotion. Whether this distinction can be applied to other pad-bearing geckos and to anoline lizards remains to be seen. The large sinus beneath the penultimate phalanx appears to govern the pressure within the system; the reticular blood systems of the scansors appear to manifest the pressure changes with respect to the locomotor substratum. Changes in pressure within the system probably permit the overlapping scansors to comply precisely with each other and with the substratum. The presence of a system based on fluid pressure differentials means that scansors are deformable along multiple axes at any one time, thus permitting a high degree of compliance with their entire surroundings. It is probable that changes in pressure within the system promote release from the substratum as well as compliance with and attachment to it. The mechanism of control of the system awaits further investigation. The pattern of the digital vascular complex has been considered in relation to the mode of operation of the digits during locomotion. Distal drainage of the sinus is ideally suited to the activity of hyperextension of the digits. This combination permits sequential pressurizing and depressurizing of the scansors and allows the bond to be created or broken in a gradual fashion rather than in an all-or-none manner. By avoiding sudden shifts in the pattern of dynamic loading (the bond is not broken instantaneously but sequentially), the risk of transverse instability during locomotion is lessened. The increase of loading on the other feet is thus gradual. The importance of this is discussed more fully elsewhere in a consideration of the structure and function of scansors. That the digits of the tokay are hyperextended during horizontal as well as vertical locomotion (Russell, '75, p. 463) can now be rationalized not only from the point of view of protection of the setae but also because of the manner in which the vascular system of the digits functions and is drained.     

Nervous connections of the parietal eye in adult Lacerta s. sicula Rafinesque as demonstrated by anterograde and retrograde transport of horseradish peroxidase

Summary Subsequent to the injection of horseradish peroxidase into the parietal eye of adult Lacerta sicula, the course of the parietal nerve and its projections were determined.The parietal nerve enters the left habenular ganglion where it branches into a medial and a lateral route. Some nerve fibers decussate within the habenular commissure. Whereas this pathway exhibits a striking asymmetry at the level of the habenular ganglia, its projections to the dorsolateral nucleus of the thalamus, the periventricular hypothalamic area, the preoptic hypothalamic and telencephalic regions, and the pretectal area are arranged in a strictly symmetric manner. A possible innervation of tegmental areas could not be proven due to the presence of endogenous peroxidase within these regions. No parietal nerve fibers were observed in the optic tectum.In a few animals investigated, scattered labeled perikarya were located in the periventricular hypothalamic gray indicating a parietopetal innervation in Lacerta sicula. The injection of horseradish peroxidase into one of the lateral eyes revealed terminal areas of the optic nerve within the preoptic region, and the thalamic and pretectal nuclei, displaying partial overlapping with the projections of the parietal nerve to these areas.From the present investigation further evidence is obtained that the pineal complex of lower vertebrates is a component of the photoneuroendocrine system. Particular emphasis is placed upon the nervous connections between the parietal eye and the hypothalamus, described for the first time in the present study.Supported by the Deutsche Forschungsgemeinschaft (Grant Ko 758/1)In partial fulfillment of the requirements of the degree of Dr. med., Faculty of Medicine, Justus Liebig University of Giessen     

Acetylcholinesterase-containing nerve cells and their distribution in the pineal organ of the goldfish,Carassius auratus

Summary Histochemically, an intense acetylcholinesterase (AChE) reaction has been observed in the perikarya of the nerve cells and in the neuropil formations of the pineal organ in the goldfish, Carassius auratus. A group of AChE-rich nerve cells has also been observed between the caudal end of the pineal stalk and the habenular ganglion. No component of the complex revealed butyrylcholinesterase (BuChE) activity.Two different types of nerve cells were recognized on the basis of their size, AChE activity and distribution. Type I cells are characterized by large perikarya possessing a moderate AChE activity and by the presence of an extensive AChE-rich neuropil formation in their vicinity; they are restricted to the rostro-lateral regions of the pineal vesicle. Type II cells are situated in the medio-rostral area of the pineal vesicle and along the entire length of the stalk, and are smaller than Type I cells; they show an intense AChE activity in their perikarya.The neuropil formations in the medio-rostral area of the pineal vesicle are almost as large as those in the vicinity of the Type I cells; they exhibit a strong AChE activity. In the rostral half of the vesicle several sensory cells are associated with each nerve cell, while in the caudal portion only a few cells are apposed to each nerve cell. Thus, the ratio of the number of sensory cells to that of AChE-containing nerve cells in the anterior half of the pineal vesicle is high when compared with the remaining area. In the anterior half of the vesicle the outer segments of the sensory cells are more distinct and their inner segments possess a higher AChE activity than those in the posterior region and the stalk. A gradation in the degree of development of neuropil formations along the pineal axis is remarkable; their size and AChE activity gradually diminish in a caudal direction. In view of the structural specialization of the rostral region of the pineal organ, it has been argued that its terminal portion is more photosensitive.This work was supported by a fellowship from the Alexander von Humboldt Foundation, Federal Republic of Germany.     

An ambient water loop system for USP purified water

An ambient loop USP purified water system has been designed and implemented using carbon and ion exchange resin beds, ultraviolet light systems and polishing filters to produce water consistently meeting or exceeding all USP XXIII quality specifications for purified water. The circulation system is constructed of PVDF plastic piping material installed in a continuous fully-drainable loop. The system was sized for a pilot scale fermentation/harvest process at the 1000?l cultivation scale. This system passed all installation and operational qualification testing as well as sixty days of continuous performance qualification testing before entering into an ongoing monitoring regimen. Excursions outside acceptable water quality parameters during this extensive monitoring regimen were minimal. Sanitization of the system, along with bed and filter changes at the time of sanitization, was conducted every 3 to 6 months to insure consistent water quality.     

Bidirectional communication between the pineal gland and the immune system

The pineal gland is a vertebrate neuroendocrine organ converting environmental photoperiodic information into a biochemical message (melatonin) that subsequently regulates the activity of numerous target tissues after its release into the bloodstream. A phylogenetically conserved feature is increased melatonin synthesis during darkness, even though there are differences between mammals and birds in the regulation of rhythmic pinealocyte function. Membrane-bound melatonin receptors are found in many peripheral organs, including lymphoid glands and immune cells, from which melatonin receptor genes have been characterized and cloned. The expression of melatonin receptor genes within the immune system shows species and organ specificity. The pineal gland, via the rhythmical synthesis and release of melatonin, influences the development and function of the immune system, although the postreceptor signal transduction system is poorly understood. Circulating messages produced by activated immune cells are reciprocally perceived by the pineal gland and provide feedback for the regulation of pineal function. The pineal gland and the immune system are, therefore, reciprocally linked by bidirectional communication.