Solid cell nests of the human thyroid in early stages of postnatal life. Systematic autopsy study

The anatomical position and prevalence of solid cell nests (SCN) of the thyroid in early stages of postnatal life have not yet been clearly determined. In order to find out about these unsettled questions a systematic search of these ultimobranchial nests from 92 autopsied thyroids from neonates, children and young adults was undertaken. SCN were present in 61% of the patients; they were mainly located in the middle third of the lateral thyroid lobes, and placed along a central to paracentral and slightly dorsal longitudinal axis. These findings, as compared with our previous observations made in older adult thyroids, further demonstrate that there exist a constant anatomical position and prevalence of SCN in postnatal life. The significantly higher frequency of SCN in males (68%) than in females (48%) (p less than 0.01) found in a study that was further extended to 192 thyroids at early and late stages of postnatal life, is a question that requires further investigation.     

A GABAergic mechanism is necessary for coupling dissociable ventral and dorsal regional oscillators within the circadian clock

BACKGROUND: Circadian rhythms in mammalian behavior, physiology, and biochemistry are controlled by the central clock of the suprachiasmatic nucleus (SCN). The clock is synchronized to environmental light-dark cycles via the retino-hypothalamic tract, which terminates predominantly in the ventral SCN of the rat. In order to understand synchronization of the clock to the external light-dark cycle, we performed ex vivo recordings of spontaneous impulse activity in SCN slices of the rat. RESULTS: We observed bimodal patterns of spontaneous impulse activity in the dorsal and ventral SCN after a 6 hr delay of the light schedule. Bisection of the SCN slice revealed a separate fast-resetting oscillator in the ventral SCN and a distinct slow-resetting oscillator in the dorsal SCN. Continuous application of the GABA(A) antagonist bicuculline yielded similar results as cut slices. Short application of bicuculline at different phases of the circadian cycle increased the electrical discharge rate in the ventral SCN but, unexpectedly, decreased activity in the dorsal SCN. CONCLUSIONS: GABA transmits phase information between the ventral and dorsal SCN oscillators. GABA can act excitatory in the dorsal SCN and inhibits neurons in the ventral SCN. We hypothesize that this difference results in asymmetrical interregional coupling within the SCN, with a stronger phase-shifting effect of the ventral on the dorsal SCN than vice versa. A model is proposed that focuses on this asymmetry and on the role of GABA in phase regulation.     

Antibacterial action of lactoperoxidase-thiocyanate-hydrogen peroxide on Streptococcus agalactiae.

Antibacterial activity of lactoperoxidase (LP)-thiocyanate (SCN)-hydrogen peroxide (H2O2) on Streptococcus agalactiae requires that the three reactants must be in contact with the cells simultaneously. Small but assayable amounts of LP adsorb to the cell surface and are not removed by washing. A diffusible antibacterial product of LP-SCN-H2O2 reaction was not found under our experimental conditions. Incubation of S. agalactiae cells with LP-H2O2 and 14C-labeled sodium SCN resulted in the incorporation of SCN into the bacterial protein. Most of the LP-catalyzed, incorporated SCN was released from the bacterial protein. Most of the LP-catalyzed, incorporated SCN was released from the bacterial protein with dithiothreitol. Cells that had their membrane permeability changed by treatment with Cetab or 80% ethanol incorporated more SCN than did untreated cells, i.e., approximately 1 mol of SCN for each mol of sulfhydryl group present in the reaction mixture. Alteration of membrane permeability caused protein sulfhydryls, normally protected by the cytoplasmic membrane, to become exposed to oxidation. The results suggest the LP-H2O2-catalyzed incorporation of SCN into the proteins of S. agalactiae by a mechanism similar to that reported for bovine serum albumin. Removal of reactive protein sulfhydryls from a functional role in membrane transport and in glucolysis in a likely cause of the antibacterial effect for S. agalactiae.     

Antibacterial action of lactoperoxidase-thiocyanate-hydrogen peroxide on Streptococcus agalactiae.

Antibacterial activity of lactoperoxidase (LP)-thiocyanate (SCN)-hydrogen peroxide (H2O2) on Streptococcus agalactiae requires that the three reactants must be in contact with the cells simultaneously. Small but assayable amounts of LP adsorb to the cell surface and are not removed by washing. A diffusible antibacterial product of LP-SCN-H2O2 reaction was not found under our experimental conditions. Incubation of S. agalactiae cells with LP-H2O2 and 14C-labeled sodium SCN resulted in the incorporation of SCN into the bacterial protein. Most of the LP-catalyzed, incorporated SCN was released from the bacterial protein. Most of the LP-catalyzed, incorporated SCN was released from the bacterial protein with dithiothreitol. Cells that had their membrane permeability changed by treatment with Cetab or 80% ethanol incorporated more SCN than did untreated cells, i.e., approximately 1 mol of SCN for each mol of sulfhydryl group present in the reaction mixture. Alteration of membrane permeability caused protein sulfhydryls, normally protected by the cytoplasmic membrane, to become exposed to oxidation. The results suggest the LP-H2O2-catalyzed incorporation of SCN into the proteins of S. agalactiae by a mechanism similar to that reported for bovine serum albumin. Removal of reactive protein sulfhydryls from a functional role in membrane transport and in glucolysis in a likely cause of the antibacterial effect for S. agalactiae.     

Circadian locomotor rhythms, but not photoperiodic responses, survive surgical isolation of the SCN in hamsters.

Surgical isolation of the suprachiasmatic nuclei (SCN) within a hypothalamic island is reported to produce loss of circadian rhythmicity. The results have been interpreted to indicate that SCN efferents are necessary for the expression of circadian rhythms. It is not clear, however, whether the loss of circadian rhythms in behavioral responses following SCN isolation is attributable to transection of efferents, to loss of cells within the island, or to gliosis produced by the knife cut. To explore this issue, we examined locomotor activity and gonadal state of male golden hamsters housed in constant darkness (DD, with a dim red light for maintenance) for at least 10 weeks following isolation of the SCN from the rest of the brain by cuts by means of a Halasz wire microknife. Brain sections were immunocytochemically stained for the peptides vasoactive intestinal polypeptide (VIP), vasopressin (VP) or neurophysin II (NP II), and neuropeptide Y (NPY) to localize the SCN and to assess its viability, and for glial fibrillary acidic protein (GFAP) to delimit the border of the knife cut. Experimental animals with VIP and VP/NP II immunoreactivity in the SCN within the island retained free-running locomotor rhythms following transection of SCN efferents. Animals with cuts that failed to sever SCN efferents, and sham-operated animals (in which the Halasz knife was lowered but not rotated), also maintained circadian rhythmicity. Hamsters sustaining severe damage to the SCN showed disrupted locomotor activity. In those hamsters that retained circadian locomotor rhythmicity following SCN isolation, gonads failed to regress in DD, demonstrating the absence of an appropriate photoperiodic response. The results suggest a multiplicity of SCN coupling mechanisms in the control of circadian rhythms.     

Further evaluation of the tetrodotoxin-resistant circadian pacemaker in the suprachiasmatic nuclei.

We previously reported the results of an experimental paradigm in which tetrodotoxin (TTX) was chronically infused by miniosmotic pump into the rat suprachiasmatic nuclei (SCN) (Schwartz et al., 1987). Although TTX reversibly blocked photic entrainment and overt expression of the circadian drinking rhythm, the circadian pacemaker in the SCN continued to oscillate unperturbed by the toxin, and we concluded that Na(+)-dependent action potentials are not a part of the SCN pacemaker's internal timekeeping mechanism. In the research reported in the present paper, we used our paradigm to chronically infuse other agents, in order to evaluate the validity of this interpretation further. (1) Infusion of 50% procaine into the SCN of blinded rats resulted in a disorganized circadian drinking rhythm during the infusion, after which behavioral rhythmicity returned without apparent phase shift. In intact rats, procaine reduced the phase-resetting action of a reversed light-dark cycle imposed during the infusion. Thus, the effects of voltage-dependent Na+ channel blockade by a local anesthetic resemble those produced by TTX. (2) Infusion of high (20 mM) K+ or 100 microM veratridine into the SCN of blinded rats resulted in an apparent phase advance of the circadian drinking rhythm by over 4 hr. The phase-shifting effect of veratridine was blocked by simultaneous infusion of 1 microM TTX. Thus, membrane depolarization or direct activation of voltage-dependent Na+ channels can affect the pacemaker's oscillation. Our infusion paradigm can detect alterations of rhythm phase, and the lack of phase shift after TTX or procaine infusion is not an artifact of an insensitive method.     

Developmental and functional aspects of grafting of the suprachiasmatic nucleus in the Brattleboro and the arrhythmic rat

The development of suprachiasmatic nuclei (SCN) dissected from fetal rats and grafted in adult rat brains has provided additional insights in the normal ontogeny of the SCN. The SCN survives rather easily and develops to its typical adult cytoarchitectonical arrangement of contiguous clusters of vasopressin (VP)-, vasoactive intestinal polypeptide (VIP)- and somatostatin (SOM)- immunoreactive cells. Neither site of implantation, nor the establishment of efferent or afferent connections of the grafted SCN seems to be essential to allow it to develop normally into this distinguishing cytology. This independent maturation does certainly not contradict with its known endogenous and independent potency of circadian pacemaker function in the brain. If the fetal SCN is grafted in such a way that it could merge with the parenchyma of the brain of a VP-deficient Brattleboro rat, the VP neurons of the SCN often establish efferent connections with the genuine target areas of this nucleus as could be shown immunocytochemically. When the fetal SCN is grafted homotopically in the brain of SCN-lesioned rat (or hamster), the surviving SCN neurons are able to reverse the arrhythmicity of these rats. Free-running circadian rhythm of drinking or motor behaviour in constant darkness are induced within weeks after grafting. A correlation between this restorative effect and the immunocytochemical staining pattern of the SCN in the transplant and/or the afferent and efferent connections between graft and host brain, could, however, not be shown conclusively. Transplants with surviving SCN are also seen when arrhythmicity was still present, which made us conclude that there has to be a neural connection between graft and host rather than a neurohumoral control in order to explain the restorative effect of the SCN graft in SCN-lesioned animals.     

Solid cell nests of the thyroid. An anatomical survey and immunohistochemical study for the presence of thyroglobulin

A systematic anatomical study of 100 adult human thyroids from autopsies was undertaken for the presence of solid cell nests (SCN). SCN were mainly located in the middle third, with a slight tendency to the upper third, of the lateral thyroid lobes, and placed along a central to paracentral and slightly dorsal longitudinal axis. Immunohistochemical studies for thyroglobulin revealed positive staining in follicular cells connected to SCN and, occasionally, in isolated cells lying within solid clusters from SCN. The anatomical position SCN showed in the present survey is comparable to that shown by the ultimobranchial body (UB) vestiges of human fetuses. The presence of thyroglobulin-positive cells within solid clusters, together with the existence of follicular cells connected to SCN, suggest that SCN may also be a probable source of follicular epithelium as occurs with the UB of some mammals.     

Immortalized suprachiasmatic nucleus cells express components of multiple circadian regulatory pathways

We undertook an extensive antigenic characterization of the SCN 2.2 cell line in order to further evaluate whether the line expresses components of circadian regulatory pathways common to the hypothalamic suprachiasmatic nucleus (SCN), the central circadian clock in mammals. We found that differentiated SCN 2.2 cultures expressed a broad range of putative clock genes, as well as components of daytime, nighttime, and crepuscular circadian regulatory pathways found within the SCN in vivo. The line also exhibits several antigens that are highly expressed in a circadian pattern and/or differentially localized in the SCN relative to other hypothalamic regions. Expression of a broad complement of circadian regulatory proteins and putative clock genes further support growing evidence in recent reports that the SCN 2.2 cell line is an appropriate model for investigating the regulation of central mammalian pacemaker.     

Free radical inactivation of lactate dehydrogenase.

The enzyme lactate dehydrogenase (LDH) has been irradiated under various conditions to assess the relative contributions of -H, -OH, H2O2 and -O2- to LDH inactivation, and it is concluded that -OH is the only important inactivating species. Further the effect of the selective free radicals, -(SCN)2-, -Br2- and -I2- on the activity has been studied. In neutral solution, the order of inactivating effectiveness is -I2- greater than -OH greater than -Br2- greater than -(SCN)2-. At pH 8-6, -OH and -Br2- are approximately equal in effectiveness, whereas -(SCN)2- is the least efficient. The radiation inactivation of LDH is accompanied by a loss of sulphydryl groups, and it is suggested that the primary target for radiation damage in LDH is the active site cysteine-165. Subsequent conformational changes are suggested to account for the apparent loss of coenzyme-binding ability and changes in the enzyme's kinetic parameters. The effect of bound coenzyme (NAD) on radiation-induced inactivation of N2O and air-saturated solutions was also investigated, and it is shown that NAD binding protects LDH.     

SCN efferents to peripheral tissues: implications for biological rhythms.

The suprachiasmatic nucleus (SCN) is the principal generator of circadian rhythms and is part of an entrainment system that synchronizes the animal with its environment. Here, we review the possible communication of timing information from the SCN to peripheral tissues involved in regulating fundamental physiological functions as revealed using a viral, transneuronal tract tracer, the pseudorabies virus (PRV). The sympathetic nervous system innervation of the pineal gland and the sympathetic outflow from brain to white adipose tissue were the first demonstrations of SCN-peripheral tissue connections. The inclusion of the SCN as part of these and other circuits was the result of lengthened postviral injection times compared with those used previously. Subsequently, the SCN has been found to be part of the sympathetic outflow from the brain to brown adipose tissue, thyroid gland, kidney, bladder, spleen, adrenal medulla, and perhaps the adrenal cortex. The SCN also is involved in the parasympathetic nervous system innervation of the thyroid, liver, pancreas, and submandibular gland. Individual SCN neurons appear connected to more than one autonomic circuit involving both sympathetic and parasympathetic innervation of a single tissue, or sympathetic innervation of two different peripheral tissues. Collectively, the results of these PRV studies require an expansion of the traditional roles of the SCN to include the autonomic innervation of peripheral tissues and perhaps the modulation of neuroendocrine systems traditionally thought to be controlled solely by hypothalamic stimulating/inhibiting factors.     

Transmembrane electrical and pH gradients across human erythrocytes and human peripheral lymphocytes.

Transmembrane electrical and pH gradients have been measured across human erythrocytes and peripheral blood lymphocytes using equilibrium distributions of radioactively labelled lipophilic ions, and of weak acids and weak bases, respectively. The distributions of methylamine, trimethylamine, acetic acid and trimethylacetic acid give calculated transmembrane pH gradients (pHe-pHi) for erythrocytes of between 0.14-0.21 for extracellular pH values of 7.28-7.16. The distributions of trimethylacetic acid. DMO and trimethylamine were determined for lymphocytes, establishing upper and lower limits of the calculated pH gradient over the external pH range of 6.7 to 7.7. Tritiated triphenylmethyl phosphonium ion (TPMP) and 14C-thiocyanate ion (SCN) equilibrium distributions were measured in order to calculate transmembrane electrical potentials, using tetraphenylboron as a catalyst to facilitate TPMP equilibrium. Transmembrane potentials of -7 to -10 mV were calculated from SCN and TPMP, respectively for red cells, and -35 to -52 mV respectively, in the case of lymphocytes. Distributions of TPMP and potassium ions were determined in the presence of valinomycin over a wide range of extracellular potassium concentrations for red cells and the calculated Nernst potentials for TPMP compared to the calculated potential using the Goldman equation for chloride and potassium ions. Distributions of TPMP, SCN and potassium ions were also determined for lymphocyte suspensions as a function of extracellular potassium and the calculated Nernst potentials for TPMP and SCN compared to the calculated potassium diffusion potential.     

Hypothalamic circadian organization in birds. I. Anatomy,functional morphology,and terminology of the suprachiasmatic region

In mammals, the “master clock” controlling circadian rhythmicity is located in the hypothalamic suprachiasmatic nuclei (SCN). Until now, no comparable structure has been unambiguously described in the brain of any nonmammalian vertebrate. In birds, early anatomical and lesioning studies described a SCN located in the anterior hypothalamus, but whether birds possess a nucleus equivalent to the mammalian SCN remained controversial. By reviewing the existing literature it became evident that confusion in delineation and nomenclature of hypothalamic cell groups may be one of the major reasons that no coherent picture of the avian hypothalamus exists. In this review, we attempt to clarify certain aspects of the organization of the avian hypothalamus by summarizing anatomical and functional studies and comparing them to immunocytochemical results from our laboratory. There is no single cell group in the avian hypothalamus that combines the morphological and neurochemical features of the mammalian SCN. Instead, certain aspects of anatomy and morphology suggest that at least two anatomically distinct cell groups, the SCN and the lateral hypothalamic nucleus (LHN), bear some of the characteristics of the mammalian SCN.     

Constructing Suprachiasmatic Nucleus Chimeras In Vivo

We introduce a new transplantation technique for analyzing suprachiasmatic nucleus (SCN) development and function. Neural precursor ('stem') cells are harvested from the brains of mice engineered to express the green fluorescent protein, propagated in culture with growth factors, and injected into the forebrain ventricles of individual embryos in order to gain access to the ventricular germinal zone and the developing brain. Initial data indicate that such cells can incorporate within the SCN and appear to differentiate into astroglial phenotypes. In addition to applications in chronobiology, SCN chimeras may be a potentially powerful model system for analyzing the structural and functional plasticity of implanted precursor cells.     

The mammalian circadian clock shop.

In mammals, a master circadian pacemaker driving daily rhythms in behavior and physiology resides in the suprachiasmatic nucleus (SCN). The SCN contains multiple circadian oscillators that synchronize to environmental cycles and to each other in vivo. Rhythm production, an intracellular event, depends on more than eight identified genes. The period of the rhythms within the SCN also depends upon intercellular communication. Many other tissues also retain the ability to generate near 24 -h periodicities although their place in the organization of circadian timing is still unclear. This paper focuses on the tissue-, cellular- and molecular-level events that generate and entrain circadian rhythms in behavior in mammals and emphasizes the apparent differences between the SCN and peripheral oscillators.     

Constructing Suprachiasmatic Nucleus Chimeras In Vivo

We introduce a new transplantation technique for analyzing suprachiasmatic nucleus (SCN) development and function. Neural precursor (‘stem’) cells are harvested from the brains of mice engineered to express the green fluorescent protein, propagated in culture with growth factors, and injected into the forebrain ventricles of individual embryos in order to gain access to the ventricular germinal zone and the developing brain. Initial data indicate that such cells can incorporate within the SCN and appear to differentiate into astroglial phenotypes. In addition to applications in chronobiology, SCN chimeras may be a potentially powerful model system for analyzing the structural and functional plasticity of implanted precursor cells.     

The relation between solid cell nests and C cells of the thyroid gland

Summary Thyroid tissue of 300 routine autopsies was processed in a standardized manner. So-called solid cell nests (SCN) were found in 21 patients (7 %). These cases were investigated carefully by serial step sectioning. In order to explore the correlation of SCN to the C-cell system, the sections were stained by silver impregnation and the immunoperoxidase method. Morphometric analyses revealed a significant increase in the density of C cells in the proximity of the SCN. With progressive distance from the SCN, the C-cell density decreased and reached normal values. In 30 % of the cases argyrophilic and calcitonin-positive cells were found lying within the SCN. Occasionally, mixed follicles could be discerned: These were lined on the one side by a multilayered squamous epithelium, on the other side by normal monolayered cubic follicular epithelium, and contained a peculiar granular material. In one case, SCN were associated with intrathyroid portions of the parathyroids and adult adipose tissue, in a second case with adipose tissue only. Most probably SCN are vestiges of the ultimobranchial body and should be interpreted as such, despite the fact that other authors have expressed different views. The lack of disturbances in the calcium metabolism of the patients and the absence of medullary carcinoma in their family histories led us to interpret locally confined C-cell hyperplasia not as reactive nor premalignant, but rather as normal.     

Interaction of radical anion probes with glucoamylase I from Aspergillus niger.

The radical anions (SCN)2.- and Br2.- produced during a pulse radiolysis of the respective potassium salts have been used to study the tryptophan residues of the glucoenzyme, glucoamylase I (EC 3.2.1.3.). At neutral pH, Br2.- reacted with the tryptophan residues of glucoamylase I as expected from previous studies of proteins and free amino acids. However, (SCN)2.- at neutral and high pH was surprisingly unreactive towards the native enzyme. Reaction did occur, however, between (SCN)2.- and glucoamylase from which one-third of the covalently bound carbohydrate had been removed, producing a tryptophyl radical. Reaction also occured between (SCN)2.- and glucoamylase I inactivated by treatment with sodium dodecyl sulphate, but the tryptophan residues were not involved. It is concluded from the results that two 'types' of tryptophan residues are found in glucoamylase I; both are attacked by Br2.- but only one type is attacked by (SCN)2.-.