Studies of the cellular cure for osteopetrosis by transplanted cells: specificity of the cell type in ia rats.

Spleen cells from normal rats are known to cure osteopetrosis in ia littermates within 3 weeks. In this study cell suspensions from liver, thymus, bone marrow, salivary gland, skeletal muscle and brain from normal rats were tested for their ability to cure osteopetrosis in ia littermates whose ability to reject these cells had been suppressed by whole-body irradiation. Cells from liver, thymus and bone marrow cured the disease as effectively as spleen cells from normal littermates. Mutants that received cells from salivary gland, muscle and brain remained osteopetrotic. These data suggest that some cell found in spleen, liver, thymus and bone marrow of 10-day-old normal rats, such as a lymphoid cell or stem cell, can restore hemopoiesis and bone resorption in osteopetrotic (ia) rats.     

Environmental Influences on Mass Dynamics of the Cotton Rat (Sigmodon hispidus) Thymus Gland

The influence of season on thymus gland mass was examined relative to captivity, gender, and age in 921 cotton rats (Sigmodon hispidus) from free-ranging and laboratory populations. Age-related involution of the thymus gland was evident in free-ranging males and females and captive females. A distinct seasonal cycle in thymus mass dynamics was apparent among adult cotton rats. Mass of the thymus gland was greatest from late fall to early winter before declining 2-4 fold during spring. Thymus gland mass remained low through spring and summer in adult cotton rats when reproductive activity was maximum. No seasonal cycle in thymus mass was apparent among juveniles. Possible involvement of sex hormones in regulating thymus size is discussed.     

The annual involution and regeneration of the thymus in hibernating animals and perspectives of its studies in gerontology and stem cell proliferation

Data on a unique phenomenon of annual involution and neogenesis of thymus gland in hibernating animals are reviewed. In accordance with morphological findings, the annual thymus involution in hibernating animals is close to the age-dependent thymus involution occurring in all mammals once in a lifetime. In opposite, thymus involution in hibernating animals is totally different from the accidental involution. During hibernation, the thymus tissue is substituted by the brown fat tissue. In the spring, thymus gland neogenesis stats with intensive growth of epithelial tissue followed by lymphocyte infiltration and exhaustion of brown tissue. Morphological changes in the thymus gland within the annual cycle were compared with seasonal dynamics of structural and functional changes in peripheral lymphoid organs (spleen, lymphoglandular, peritoneal fluid). A general regularity was observed involving a decreased functional activity of immune cells in autumn, its sharp depression during winter hibernation, and obvious increase in summer with the onset of a season of animal activity. It is supposed that a sharp increase in the tumor necrosis factor (TNF) production observed during short-term awakenings in winter may serve an important link in this unique immune adaptation mechanism. The season changes in cellular TNF secretion suggest a mobilization of protective resources in hibernating animals in autumn and winter, i.e. in seasons when the thymus gland activity is depressed. The annual involution of thymus gland cannot be related to droppings in the environmental or body temperatures, as it comes long before their fall. Additionally, it is not related to ageing, as it occurs already in young hibernating animals. The role of hormones, including melatonine and corticosteroids, in mechanisms regulating thymus gland involution in hibernating animals is discussed.     

Seasonal and age changes in the thymus gland of the Red fox, Vulpes vulpes,

Seasonal and age changes in thymus weight and histological structure were examined in the Red fox ( Vulpes vulpes ). Growth in the fox thymus slowed down after birth compared with the last third of foetal existence, but the gland still grew rapidly to reach a peak first year weight when the cubs were 20 weeks of age. From this point the thymus in both sexes decreased markedly in weight to reach a low point by the beginning of the first breeding season. During this involution lobule structure broke down and adipose tissue and connective tissue was laid down in the gland. Recovery of the thymus towards the second year weight maximum was accompanied by the regaining of lobule structure and the gland resembled that of the juvenile again. The male thymus increased in weight from the middle of the mating season, but recovery in the female thymus was delayed until the end of lactation. Involution occurred prior to the second breeding season. Thereafter, the gland never attained the high weights seen in the first two years of life, but histological changes still occurred even in old animals. The thymus gland of animals infected with sarcoptic mange is described.     

FURTHER PROOF OF THE EXISTENCE OF A SPECIFIC TETANY-PRODUCING SUBSTANCE IN THE THYMUS GLAND

The effect of the thymus gland in producing tetany is due to a specific tetany toxin produced by and contained in the thymus, and the thymus gland must be added to the group of glands for which the function of internal secretion has been demonstrated.     

Noradrenergic responses of peripheral organs to cyclophosphamide in mice

To determine if the chemotherapeutic drug cyclophosphamide influences the activity of the sympathetic nervous system, the effects of cyclophosphamide on norepinephrine concentration in the heart, adrenal gland, spleen, and thymus gland were evaluated. Male BALB/cByJ mice were administered a single injection of cyclophosphamide (15, 50, or 100 mg/kg, i.p) or saline-vehicle. Organs were collected 72 or 120 h after injection and norepinephrine concentrations were determined by high pressure liquid chromatography with electrochemical detection. Cyclophosphamide reduced spleen, thymus gland, and heart mass while also elevating spleen and thymus gland norepinephrine concentrations (both pmoles/mg tissue and pmoles/mg protein) in a dose- and time-dependent manner. Norepinephrine concentrations in heart and adrenal gland were not altered by cyclophosphamide at any drug dose or time point. Dose- and time-dependent cyclophosphamide-mediated changes in peripheral norepinephrine levels in the spleen and thymus gland are interesting because subjects administered cyclophosphamide may be more susceptible to opportunistic infections, not only because the drug is antineoplastic, but also because the drug alters nervous system-immune system communication and the neurochemical milieu in which surviving cells interact.     

The thymus in fish: Development and possible function in the immune response

With the exception of Agnatha, fish possess the functional equivalent of the thymus gland found in higher vertebrates. As in other vertebrates, this gland originates from the pharyngeal pouches and ontogenically is the first lymphoid organ to be infiltrated with lymphoid cells. Histology of the structure may differ from one species to another but the cellular component is basically similar. The (paired) gland is surrounded by an epithelial capsule. Within the gland a framework of reticulo-epithelial cells supports the lymphocytes. The age-related involution process, which characterizes the thymus of higher vertebrates, does not necessarily occur in fish. Nevertheless, thymus growth and function may be modulated by those factors that induce its involution such as aging, season, sexual maturity, and stress. The major role played by the thymus in the immune response of higher vertebrates is presumed to occur in fish. Thymus-derived cell dependent immune reactions have been demonstrated in fish. The cells that mediate these functions are designated as T-like cells. So far, cell surface markers equivalent to those of mammalian T lymphocytes have not been characterized. The T lymphocyte specificities are supposed to be acquired within or via the thymic microenvironment. Unfortunately, there is limited data concerned with the cytological and physiological basis of the maturation of thymus-derived cells. Direct involvement of the fish thymus in defense mechanisms has not been investigated extensively. The gland appears to be weakly protected because of its superficial location and is easily exposed to pathogens. Neoplasia is the main pathologic condition reported in the thymus of fish, with little else having been published regarding thymic pathology.     

Pathogenesis of autoimmunity after xenogeneic thymus transplantation

Thymus transplantation is a promising strategy to induce xenotolerance, but may also induce an autoimmune syndrome (AIS). The pathogenesis of this AIS was explored using nude rats as recipients. Thymus grafts consisted of fetal hamster thymic tissue with or without mixing with fetal rat tissue such as thymus, thyroid, salivary gland, and heart. All hamster thymus recipients died of AIS within 2-3 mo. In most recipients of xenothymus mixed with rat tissues such as thymus, thyroid, and salivary gland, but not heart, AIS was prevented, indicating an insufficient presence of rat epithelial cell Ags within the xenothymus. AIS could be transferred to control nude rats by whole splenocytes or by splenocyte subpopulations such as CD3(+), CD3(-), and B lymphocytes, but not by non-T, non-B cells from AIS animals. This transfer could be suppressed by cotransferring either CD4(+) or CD8(+) lymphocytes from euthymic rats, but not by splenocytes from recipients of syngeneic or xenogeneic thymus mixed with rat tissue, indicating a defective generation of regulatory lymphocytes. As for CD4(+) regulatory cells this defect was probably qualitative, because the percentages of CD4(+)CD25(+) or CD4(+)CD45RC(low) populations were normal after xenothymus transplantation. As for the CD8(+) regulatory cells, the defect was quantitative, as CD8(+) cell levels always remained low. The latter was related to the nonvascularized nature of thymus grafts. In conclusion, AIS after xenothymus transplantation in nude rats is due to a combination of insufficient intrathymic presence of host-type epithelial cell Ags and a defective generation of regulatory T lymphocytes.     

Changes in the structure and cell composition of the thymus as a result of dosed physical loads

By means of histological and morphometrical methods normal age involution of the thymus has been studied, as well as its changes under conditions of dosed physical loadings. The experiment has been performed in 92 non-inbred white male rats. At adaptation of the organism to the loadings, involution of the gland decelerates, and at an insufficient adaptation--accelerates. This is, probably, the cause of decreasing protective forces of the organism.     

Cytokine profiles in mice tissues after irradiation of the thymus projection area with femtosecond laser

The effects of pulsed femtosecond laser irradiation in the near ultraviolet region on the levels of cytokines in the thymus, blood, and skin of irradiated mice have been studied. Irradiation of the thymus projection area with low-intensity laser radiation in the near UV region of the spectrum showed significant changes in cytokine levels in the skin and thymus and, to a lesser extent, in the blood of irradiated mice. Laser irradiation with a power density of 20 mW/cm² affects the cytokine profile in the thymus: IFN-γ, IL-3, IL-4, IL-5, eotaxin, GM-CSF, and chemokine KC–factors that can affect differentiation and proliferation of the cells of the immune system in the gland. Conclusions: It is assumed that changes in the expression of cytokines in the thymus after laser irradiation are explained by the rearrangement of biochemical processes possibly associated with the maturation of cells in the gland.     

The morphology of the trout, Salmo gairdneri Richardson, thymus: some practical and theoretical considerations

An electron microscope study of the thymus in trout, Salmo gairdneri , showed that the membrane separating the thymus gland from the extenal water current was not specialized, but merely a continuation of the pharyngeal epithelium. This is discussed in relation to the evolution of the thymus in vertebrates, and to the possible effects on the thymus during hyperosmotic infiltration, a technique used for immunization.     

Steroid hormone receptors in the thymus: a site of immunomodulatory action of melatonin.

1. Melatonin and glucocorticoids are known to affect the immune response in an opposite mode. The probability for an interaction between these hormones in the thymus gland has been investigated in rats following chronic administration of exogenous melatonin and long-term exposure to variable levels of circulating glucocorticoids. 2. Daily melatonin administration was shown to affect the properties of corticosterone and progestin receptors in the thymus in the presence of normal and increased systemic corticosterone concentrations, but not in adrenalectomized animals. 3. In intact rats melatonin caused a marked increase in the affinity and a decrease in the density of thymic receptors for adrenal steroids. Following corticosterone overdosage, simultaneously with melatonin treatment, a decrease in receptor affinity and a relative increase in the number of binding sites was observed. 4. The results suggest that steroid hormone receptors in the thymus might be considered as a target site for the interaction between melatonin and adrenal steroids in the modulation of the immune response.     

Gas chromatographic analysis of free amino acids in the hyaloplasm of the hypophysis, pineal gland, thyroid gland, spinal cord, thymus and lymph nodes of the cow

Studies of the qualitative and quantitative composition of free amino acids in the hyaloplasm of the hypophysis, pineal gland, thyroid gland, spinal cord, thymus and lymph nodes of the cow are described. The following findings are reported: the highest levels of alanine, valine, glycine, isoleucine, histidine, leucine, threonine, serine, phenylalanine, tyrosine and lysine are found in the thyroid gland, methionine and aspartic acid in the spinal cord, tryptophan and hydroxyproline in the pineal gland, and proline and glutamic acid in the thymus gland. The highest level by weight is that of glutamic acid in all tissues. The presence of α-aminobutyric acid combined with sarcosine and 4-aminoisobutyric acid with 2-AOA and citrulline with cystine was demonstrated. α-Aminoisobutyric acid and isovaline were found in the spinal cord.     

On the Role of the Reticular-epithelial Complex in Transplantation of the Thymus

Transplantation of the neonatal thymus, into young, adult hosts, resulted in massive cell death of graft cortical lymphoid tissue with apparent selective survival of the reticular-epithelial cells. The central area of the graft was progressively cleared of cell debris and the characteristic thymic architecture restored within fourteen days of grafting. Evidence obtained from the regeneration of different-sized transplants suggested that the size and shape attained by the regenerated graft was closely related to the size and shape of the donor tissue.
When donor rat thymuses were transplanted in Millipore chambers, the lymphocyte population did not reappear and after seven days only reticular-epithelial cells remained, retaining their normal appearance. However, when these thymic remnants were removed from the chambers and transplanted into secondary hosts, the thymus regenerated normally, suggesting that the lymphocytes in the regenerated gland were derived from the host. Thymic remnants after cortisol treatment of donors also formed distinct organs after grafting despite the fact that they contained few donor lymphocytes. From the differential effects of cortisol on host and transplanted thymus and the different growth characteristics of transplants it appears that transplants differ in their growth/involution control system from the host thymus.     

Influence of anticarcinogenic agents on the transplacental carcinogenic effect of N-nitroso-N-ethylurea

Experiments on rats were made to study the action of 7 anticarcinogenic substances administered postnatally for a long time (sodium selenite, retinol acetate, phenformin, amber acid, low-molecular polypeptide factors of the thymus, pineal gland, and bone marrow) on the transplacental carcinogenic effect of N-ethyl-N-nitrosourea (ENU) The polypeptide factors of the thymus and pineal gland and phenformin inhibited the development of nervous system and renal tumors induced transplacentally by ENU. The rest of the substances did not influence the transplacental carcinogenesis.     

Muscular dystrophy by merosin deficiency decreases acetylcholinesterase activity in thymus of Lama2dy mice

Half of congenital muscular dystrophy cases arise from laminin alpha2 (merosin) deficiency, and merosin-deficient mice (Lama2dy) exhibit a dystrophic phenotype. The abnormal development of thymus in Lama2dy mice, the occurrence of acetylcholinesterase (AChE) in the gland and the impaired distribution of AChE molecules in skeletal muscle of the mouse mutant prompted us to compare the levels of AChE mRNAs and enzyme species in thymus of control and Lama2dy mice. AChE activity in normal thymus (mean +/- SD 1.42 +/- 0.28 micromol acetylthiocholine/h/mg protein, U/mg) was decreased by approximately 50% in dystrophic thymus (0.77 +/- 0.23 U/mg) (p = 0.007), whereas butyrylcholinesterase activity was little affected. RT-PCR assays revealed variable levels of R, H and T AChE mRNAs in thymus, bone marrow and spinal cord. Control thymus contained amphiphilic AChE dimers (G2A, 64%) and monomers (G1A, 19%), as well as hydrophilic tetramers (G4H, 9%) and monomers (G1H, 8%). The dimers consisted of glycosylphosphatidylinositol-anchored H subunits. Western blot assays with anti-AChE antibodies suggested the occurrence of inactive AChE in mouse thymus. Despite the decrease in AChE activity in Lama2dy thymus, no differences between thymuses from control and dystrophic mice were observed in the distribution of AChE forms, phosphatidylinositol-specific phospholipase C sensitivity, binding to lectins and size of AChE subunits.     

Bilateral thymus found in association with unilateral cleft lip and palate

Ectopic localizations of the thymus have been reported in a variety of unusual sites, but not on the surface of the skin of the neck. As one can see in our case, the left neck mass (1.5 x 2 x 0.5 cm) and the right neck mass (4 x 4 x 0.5 cm), when added together in weight, also equal the total weight of the thymus at birth. Also, not being able to encounter the "sail sign" of the thymus gland on the chest x-ray proved to us that no other thymus gland was present. Because of these unusual findings, prior to excision of any congenital lesion in the neck, a biopsy should be done, and only after that should one proceed with the necessary surgical intervention. We are presenting this case because it is unique in this category.     

Measurement of natural killer activity and target cell binding by mouse metrial gland cells isolated by enzymic or mechanical methods

Cells of the metrial glands of mice were isolated by enzymic or mechanical dissociation procedures. Morphological observations indicated that up to half of the enzymically dissociated cells and nearly all of the mechanically dissociated cells were granulated metrial gland cells, but the presence of some fibroblast-like stromal cells among the latter population was not ruled out. Moreover, the granulated metrial gland cells had lost a substantial part of their granule content during isolation. Both cell preparations had little or no natural killer (NK) activity, indicating either that granulated metrial gland cells are not NK-like or that their NK activity was impaired by loss of granule-associated lytic substances or by other factors. Enzymically dissociated metrial gland cells did not bind significantly to the NK target cell YAC-1, nor did they develop granules, NK activity, or the ability to bind YAC-1 cells during culture in vitro, either in normal medium or with the addition of indomethacin or lymphokines. Mechanically dissociated metrial gland cells bound avidly to YAC-1 cells but not to P815 cells or adult thymus cells, which are not NK target cells. Since many if not most of the mechanically dissociated metrial gland cells appeared morphologically to be granulated metrial gland cells, their selective binding to an NK target cell suggests that granulated metrial gland cells may be related in some way to NK cells.     

Stimulation of energy plastic metabolism by phytohemagglutinin in lymphoid organs and adrenal glands

It has been established that the concentration of nucleic acids, protein, glycogen, ATP, copper, manganese, zinc as well as the activity of cytochromoxidase and succinate dehydrogenase in tissues of the thymus gland and spleen of albino rats a day after stimulation by phytohemagglutinin increase considerably reaching the maximal values three days later. Taking a prolonged term (up to 7 days) after phytohemagglutinin administration it is found that the content and activity of the studied indices in the thymus and spleen tissues lower regularly, but fail reaching normal values even 14 days after stimulation. In this case changes in the test indices in the spleen are less pronounced than in the thymus in all the studied periods. In the tissues of adrenals a tendency of changes in the manganese and copper content is like that in lymphoid organs in all periods after stimulation by phytohemagglutinin; other test indices have an opposite tendency.     

Change in protein synthesis and enzyme activity in avian endocrine glands during ontogenesis

The synthesis of cytoplasmic proteins and the activity of cAMP-dependent protein kinase were studied in the thyroid gland and thymus of intact and irradiated (0.05 Gr) embryos and chicks. The increase in labeled amino acid incorporation into proteins of irradiated chicken endocrine organs during postnatal development was more apparent in thyrocytes. Stimulation of protein kinase activity in the thyroid gland and thymus was observed at the same periods of time. It was supposed that minor doses of ionizing radiation stimulate synthetic processes as well as phosphorylation of proteins responsible for differentiation of avian endocrine organs.