THE ANTAGONISM BETWEEN THYROID AND PARATHYROID GLANDS

From the facts stated in this paper it is evident that the thymus gland of mammals contains a substance which is capable of producing tetany when fed to the larvæ of certain species of salamanders (Ambystoma opacum and Ambystoma maculatum). As long as the larvæ have not developed their own thymus glands, they are able, by means of some mechanism, to counterbalance the tetanic action of the thymus substance introduced in their food. When, however, the secretion from their own thymus glands is added to the thymus material introduced with the food, this mechanism of preventing tetany becomes inadequate and tetany ensues. In the larva of a third species of salamander, Ambystoma tigrinum, this mechanism will prevent tetany even when the larvæ are fed on thymus. In mammals the parathyroids are known to prevent tetany and are supposed either to absorb the tetany-producing substance and thus prevent its action or to change it into another non-toxic substance. It is at least probable that in the amphibians the parathyroids play the same rôle. Larvæ of anuran amphibians, which develop their parathyroids soon after hatching, never show tetanic convulsions if they are fed on thymus, but in certain species of salamanders, whose parathyroids develop only during metamorphosis, the larvæ invariably have tetanic convulsions upon thymus feeding, while the metamorphosed animals never show tetany. But in addition to the parathyroids the salamanders must possess still another mechanism which during the larval period inhibits the production of tetany by the animal''s own thymus glands. In the larvæ of Ambystoma opacum and Ambystoma maculatum this mechanism is sufficient only to prevent tetany from the animal''s own thymus, while in the larvæ of Ambystoma tigrinum it is capable of preventing tetany even when the larvæ are fed with thymus. If the thymus is the organ by whose action tetany is produced, we can understand why tetany in human beings occurs far more frequently in children than in adults, since in the latter the thymus gland is replaced, at least to a great extent, by connective tissue. The relation of thymus to tetany may also possibly explain the occurrence of tetany during pregnancy; while the parathyroids of the mother may be sufficient to prevent tetany from her largely atrophied thymus, they may not be sufficient to prevent tetany from the excess of thymus substance furnished by the fetus to the blood of the mother.     

中华鳖胸腺显微和亚显微结构及其在进化上的意义

应用透射电子显微镜观察了中华鳖胸腺的显微和亚显微结构。发现中华鳖胸腺从结构上可分为皮质和髓质,皮质富含淋巴细胞,髓质富含上皮性网状细胞。在各发育期中华鳖胸腺皮质、髓质交界处和髓质区有明显的囊状胸腺小体和交错突细胞。在２００ｇ以上的成年鳖胸腺内发现有同心圆状胸腺小体。电镜下,胸腺内淋巴细胞分为大、中、小３型。上皮性网状细胞从亚显微结构上分为支持型和分泌型。胸腺囊包括细胞内囊和细胞间囊,以细胞内囊居多     

草鱼胸腺组织学的研究

草鱼胸腺位于鳃腔背上角,紧贴在鳃腔膜之下,突起部分伸入到下颞凹,整个胸腺形态形似菱角。其组织结构可分为外区、中区和内区。中区和内区主要由淋巴细胞和网状上皮细胞构成,在组织结构上分别类似于高等脊椎动物胸腺的皮质和髓质区。胸腺淋巴细胞可分大、中、小三型,小淋巴细胞约占78％,中淋巴细胞约占15％,大淋巴细胞约占4％。在Ⅰ龄草鱼,每毫克胸腺约有3.6×106个胸腺淋巴细胞,Ⅱ龄草鱼约为2×106。Ⅰ至Ⅱ龄草鱼胸腺重量明显地随鱼龄增加,Ⅱ龄以上草鱼胸腺重量变化无规律,成鱼胸腺表现出明显的退化。草鱼胸腺除年龄性退化外,还存在环境因素引起的非年龄性退化。       

NATURE OF THE RETARDING INFLUENCE OF THE THYMUS UPON AMPHIBIAN METAMORPHOSIS

1. Though thymus-fed salamander larvæ often metamorphose normally, thymus feeding sometimes retards and in rare cases inhibits metamorphosis completely. 2. The addition of normal food to a thymus diet abolishes the inhibitory effect of the thymus. 3. Addition of a small quantity of iodothyrin leads rapidly to precocious metamorphosis of thymus-fed larvæ. 4. The inhibitory effect of the thymus is not due to a specific inhibiting substance in the thymus, but to the absence from the thymus of a substance required to develop the thyroid to the secretory state.     

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.     

三肽囊素(bursin)的鸡、鸭免疫器官组织学定位特征分析(简报)

三肽囊素(bursin)是法氏囊组织提取物中一种非常重要的活性因子,由Audhya T.等在1986年首次报道。近十几年,有关三肽囊素的研究取得了较大的进展,涉及对三肽囊素的生物学活性、组织学定位、功能机制及其应用前景。本研究分别探索了三肽囊素在鸡、鸭免疫器官中的定位,并对其特征进行分析,以期更深入理解三肽囊素的存在及其生物学意义。鸡用近交系(CB系),由12、14及20日龄胚、新生雏、1—9周龄鸡,采集法氏囊、法氏囊T细胞区、胸腺、哈德氏腺、脾脏及骨髓。鸭用北京鸭,由新生     

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.     

PARATHYROIDS AND CALCIUM METABOLISM

The experiments reported in this article are in full agreement with the facts known about the action of Ca and Mg salts in tetanic animals. In the concentrations used here both Ca lactate and Mg lactate suppressed the muscular convulsions in the tetanic salamander larvæ. The Mg lactate, however, appears to be more effective than the Ca lactate. At any rate the suppression of the tetanic convulsions does not seem to be a specific action of the calcium. The most important result seems to be the fact that the salts used, though they prevented the muscular convulsions, did not prevent the other symptoms of tetany which in the salamander larvæ are very definite and constant. The permanent spasmodic contractions and the paralysis of the muscles developed in spite of the presence of the Ca and Mg, Furthermore, the muscular contractions and the paralysis developed even in such thymus-fed animals in which the convulsions had been suppressed completely; this was the case in one of the animals of the Mg series. From the experiments of Biedl and others it is likely that the tetanic convulsions are due to lesions of the central nervous system, since convulsions of a leg can be prevented by isolating it from the central nervous system by cutting the nerves which connect the muscles with the central nervous system. Evidently these lesions of the central nervous system are the chief factor in tetany, while the convulsions of the muscles are only an effect. In the larvæ of salamanders these lesions find a definite expression in the permanent paralysis of almost the entire muscular system. In the writer''s opinion, MacCallum''s hypothesis that the tetany toxin has a special affinity for Ca, thereby diminishing the Ca content of the organism, cannot be disproved at present. But the present experiments seem to prove, first, that the tetany-producing substance causes permanent lesions of the nervous system, which lead to permanent spasmodic contractions and paralysis of the muscle even in the absence of tetanic convulsions, and second, that these cannot be prevented by either Ca or Mg. For the most part they result in an early death of the animals no matter whether or not Ca or Mg has been applied. In connection with this fact we wish to mention Biedl''s claim that no one has yet succeeded in prolonging the life of parathyroidectomized animals by the application of Ca. From MacCallum''s paper, on account of the lack of controls, it cannot be seen whether his parathyroidectomized dogs lived longer with Ca treatment than without. That in spontaneous tetany Ca treatment may effect a cure, as is evident from the report by Howland and Marriott, does not prove that in this case Ca has inhibited tetany as a disease. In spontaneous tetany the period of the action of the tetany-producing substance may be a very short one and the mere prevention of the tetanic convulsions may keep the patient alive until normal function of the glands involved has been restored. The pathological changes which the central nervous system undergoes in this short period may not be severe enough to endanger the life of the patient after the cessation of the action of the tetany toxin. In the light of the facts presented our experiments lead to the following conclusions: 1. The thymus gland excretes a tetany-producing substance which in the normal animal is antagonized in an unknown way by the parathyroids. 2. In animals devoid of parathyroids (salamander larvæ, parathyroidectomized mammals) this substance may, according to MacCallum, reduce the Ca content of the organism; but by far the most dangerous and important quality of this substance is its highly injurious effect upon the central nervous system, which causes permanent spasmodic contractions of the muscles and paralysis of almost the entire muscular system. 3. It is possible to prevent the muscular contractions by introducing Ca salts into the body, though this can be done more effectively by means of Mg salts. 4. No substance, however, has been found so far to antagonize the tetany toxin and to prevent the development of the lesions of the central nervous system caused by the tetany toxin. 5. This explains why in spite of the application of Ca or Mg and in spite of the suppression by these substances of the tetanic convulsions the other symptoms of tetany develop and frequently lead to the death of the animal. 6. Accordingly the most important function of the parathyroids is to prevent the tetany toxin, by antagonizing it, from coming into contact with the central nervous system.     

METASTATIC CARCINOMA OF THE THYROID GLAND AS THE INITIAL MANIFESTATION OF THE DISEASE

During the past 38 years, 260 patients with thyroid carcinoma have been operated upon at the University of California Hospital. In 26 of these patients the first symptom was a mass distant from the thyroid gland, and the gland was considered normal on clinical examination.In all but three of the 26 cases a small carcinoma of the thyroid gland was observed at operation or in pathological examination.Radical neck dissection with either total lobectomy or total thyroidectomy would seem to be the operation of choice in the treatment of these patients.The ultimate prognosis, even in the presence of metastases, is relatively good.Primary carcinoma of the thyroid gland should be considered in the presence of tumors of the side of the neck even in the absence of palpable nodules in the gland itself.     

Dolichols and enzymatic formation of dolichyl phosphate sugars in the thymus of mice on neoplastic transformation

The content of dolichol in thymus gland of mice increased up to four times upon malignant transformation evoked by X-ray irradiation of animals or/and in the case of spontaneous tumours as compared with normal thymus. Dolichyl phosphate mannose and dolichyl pyrophosphate N-acetylglucosamine were formed in homogenates of transformed thymus at a higher rate than in normal gland.     

Postoperative hypoparathyroidism: Direct para-operative period]

Surgical hypoparathyroidism is a severe complication of the operations on thyroid gland. Hundred thirty patients aged between 17 and 77 years have been analysed clinically. Group I involved 45 patients with surgical hypoparathyroidism of transient or partial character, group II involved 85 patients with severe irreversible surgical hypoparathyroidism. Hypocalcemia in postoperative period was significantly higher in group II than that in group I (p < 0.02), and negatively correlated with the maximal dose of vitamin D3 necessary to compensate calcemia (r = -0.42). Follow-up results indicate that the age and sex of patients, preoperative diagnosis, radiotherapy, and type of surgery have no effect on the degree of damage to parathyroid glands, tetany development rate, degree of hypocalcemia and hyperphosphatemia. High degree hypocalcemia diagnosed in the early postoperative period suggests irreversible injury to parathyroid glands. Management of patients with postoperative tetany requires a close cooperation of surgeon and endocrinologist.     

巨细胞病毒感染对新生豚鼠胸腺的影响

新生豚鼠皮下接种豚鼠巨细胞病毒(GPCMV)后,导致动物胸腺急性感染。感染豚鼠胸腺在接种后第五天开始出现病毒,第十天达高峰。此外,感染动物胸腺的发育受到抑制,细胞总数和T淋巴细胞数随朐腺中病毒滴度的增高而进行性下降,至接种GPCMV后第十天最显著。由于病毒对T细胞的作用,细胞表面红细胞受体的丧失导致胸腺Null细胞百分比高于对照动物。     

STUDIES ON THE REGULATION OF LYMPHOCYTE PRODUCTION IN THE MURINE THYMUS AND SOME EFFECTS OF A CRUDE THYMUS EXTRACT

Cell proliferation in the murine thymus was studied in vivo under normal conditions and from 0 to 24 hr after a single injection of a water-soluble extract from mouse thymus, mouse spleen, and mouse skin. The thymus extract reduced during the first 24 hr the mitotic activity 40%; the spleen extract had a weaker inhibitory effect. The skin extract had no such effect. The thymus extract and spleen extract inhibited the flux of cells into the S phase 0–8 hr after the injection of the extract. Initial labelling index was also reduced in this period. Eight hours after injection of the thymus or spleen extracts the inhibited cells initiated DNA synthesis. The rate of progression of blast cells through the cell cycle was normal 24 hr after the injection of the extracts. It was deduced from the analysis that the thymus extract inhibits processes triggering Go/Gi cells into DNA synthesis, the inhibition of G₂ efflux being of minor importance. Finally a model for the regulation of proliferating thymic blast cells and the emigration of small lymphocytes from the thymus is proposed.     

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.     

中华蜜蜂工蜂蜡腺细胞的超微结构

本文描述了中华蜜蜂(Apis cerana)成体工蜂蜡腺细胞的超微结构.通过电镜观察发现蜡腺细胞具有许多质膜内陷形成的管腔,作为蜂蜡或其前体物的输送通道.细胞质中富含线粒体及粗面内质网,细胞核为不规则的形状,细胞质中还含有少量溶酶体,微管和微丝等结构.     

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.     

扬子鳄皮肤腺结构与发育的初步观察

扬子鳄有三种皮肤腺:背腺、泄殖腔麝腺和下颌腺。背腺位于背中线左右两侧第二行鳞片下方,其确切位置个体间差异很大,如表1。幼鳄背腺形态多种多样,但显示出是一种退化器官,未观察到腺开口,也未观察到半成鳄和成鳄的背腺,因此扬子鳄背腺可能不具功能。泄殖腔麝腺位于泄殖腔腹唇内,梨形,腺管开口于泄殖腔腹壁,成体腺腔很大,腺的底部壁较厚,腺细胞明显地分成若干小叶,其它部位壁较薄,小叶不明显,属全泌腺,分泌油脂物,繁殖期特别发达,但性未成熟个体亦具功能,是一种信息素下颌腺位于下颌后方两侧皮肤内,圆柱状,脉管开口于下颌腹侧皮肤表面,成体腺腔不规则,腺壁厚,从包囊到腺腔,腺细胞可明显地分成三个区,属全泌腺,分泌油脂物,在繁殖期特别发达,此腺到性成熟才具功能。     

小鼠颌下腺内交感神经末梢变性时程的性差异

外源性神经生长因子(NGF)对周边交感系统的营养性影响已有广泛的研究(Black,1978;Purves等,1978)。但是,内源性NGF是否同样行使这种影响,至今还没有被人证实(Nja等,1978)。1979年,Carstairs等人利用丙酸睾酮慢性处理,提高小鼠颌下腺内NGF含量以后,观察到颈上神经节(SCG)中有部分神经元肥大,但其它交感神经节不受影响。作者认为SCG内肥大的神经元就是支配颌下腺的那部分交感神经元。由于雄性小鼠颌下腺内的NGF含量是雌性小鼠的92倍(Hirata等,1979),我们实验室直接检查了小鼠颌下腺和虹膜的交感神经支配,发现成年雄性小鼠颌下腺的荧光基丛索远较雌性小鼠的     

THE FUNCTIONAL ANATOMY OF THE GUT OF THE PROSOBRANCH GASTROPOD POMACEA CANALICULATA AND OF SOME OTHER PILIDS

The structure and functioning of the gut of Pomacea canaliculata (D'Orb.) has been investigated using living and preserved material. Anatomical studies were also carried out on preserved specimens of Pila globosa, Turbinicola saxea and Lanistes ovum bangweolicus .
The gut of pilids is specialised for a macrophagous diet, usually of aquatic angiosperms. The mid-oesophagus is a crop for storage, and the stomach has a large triturating gizzard developed from the gastric shield area. This is the site of extra-cellular digestion; there is no intra-cellular digestion in any part of the gut. The ducts of the digestive gland open into a special region of the stomach, the vestibule, which is histologically similar to them. The style sac begins the compacting of the faeces, which is completed in tho intestine. There is no evidence that absorption ocrurs in the epithelium of tho stomach or intestine; soluble products of digestion are carried into the digestive gland, which is the main site of absorption. Its activity is supplemented by amoebocytes entering the lumen of the style sac and intestine. Two types of cell occur in the gland, one type producing digestive enzymes and absorbing soluble products of digestion, the other type being excretory in function. There is no sign of phagocytosis in either. The excretory activity of the kidney is further supplemented by an anal gland.