Incorporation of 3H-thymidine into glial cells of the parietal region and cells of the subependymal zone of two-week and adult mice under normal conditions and following brain injury]

Potencies of brain cells to DNA synthesis and proliferation were studied in two weeks old and adult mice in the norm and after the brain mechanical injury. No labeled large and middle neurons were found in the brain of intact and operated animals both under the pulse 3H-thymidine incorporation and saturation of mice with 3H-thymidine during 36 hrs. The same types of brains cells were labeled both in intact and operated two weeks old and adult mice: glial cells, cells of the subependymal zone, cells of the dentate gyrus inner margin, and sometimes, cells having characteristics of microneurons. The number of glial cells in the temporal cortex of intact mice diminished with the age. Under the brain trauma, the proliferative reaction of glia was expressed in a similiar way both in two weeks old and adult mice. The index of labeled cells in the subependymal zone is the same in these two age groups. With the age the cellular mass of subependymal zone decreases, rather than proliferative tendencies of supependymal zone. The brain traumatization resulted in the increase of labeled subependymal cell only under the direct injury of subependymal zone.     

The pattern of lymphocytes in the thymus and spleen after labeling with 3H-thymidine and 3H-deoxycytidine.

Adult male untreated mice (NMRI) were investigated after radioactive labeling with 3H-thymidine and 3H-deoxycytidine to find out whether the lymphocytes in the cortex and medulla of the thymus as well as in the perifollicular and periarteriolar regions of the spleen show a labeling pattern which allows a classification into T- and B-lymphocytes. The percentages of radioactively labeled small lymphocytes and their mean grain counts were determined. The percentages of radioactively labeled small lymphocytes after 3H-TdR and 3H-CdR showed no significant differences in both splenic zones. The grain counts over the lymphocyte nuclei in the periarteriolar zone showed lower values after 3H-TdR than after 3H-CdR. The lymphocytes in the perifollicular zone were strongly labeled with 3H-TdR and weakly labeled with 3H-CdR. In the thymus medulla, lymphocytes were weakly labeled with 3H-thymidine and strongly labeled with 3H-CdR. In the cortex no significant differences were observed. 75 to 80% of the small lymphocytes in the peripheral blood were weakly and 20-25% strongly labeled after 3H-TdR. Therefore there are similarities in the radioactive labeling pattern of thymic medulla lymphocytes and that of small lymphocytes of the periarteriolar zone of the spleen by both DNA precursors. The small lymphocytes in the peripheral T-dependent tissue zones, for example in the spleen, as well as in the mixed lymphocyte population of the peripheral blood can be differentiated from the B-lymphocytes through the difference in the amount of incorporation of 3H-thymidine and 3H-deoxycytidine.     

17 alpha-oxidoreductase activity in kidneys of male and female mice of various ages

Male and female mice at 0-120 days of age were used. Homogenates of kidneys were incubated with [14C]4-androstene-3,17-dione, and 17 alpha-oxidoreductase activity per g tissue was examined. The activities of 17 alpha-oxidoreductase in the kidneys of both sexes increased markedly with age during sexual development by up to 150-fold and reached the maximum values (2700 and 1500 nmol/g/h in male and female kidneys, respectively) at 60 days of age. In the adult male mouse kidney, the activity in isolated cortex fractions was 14 times as high as the activity in isolated medulla fractions; in the medulla fractions renal tubules from the cortex accounted for 3-15% of the total tissue. Furthermore, histochemical examination showed the activity present only in the cortex, at which much higher levels in the tubules than in the glomerulus. Activity at 35-120 days of age was significantly higher in male kidneys than in female kidneys. The difference appears to be induced by testicular androgens during sexual development, since neonatal castration in males resulted in decreases of activity to levels similar to those in female kidneys. However, castration at 60 days of age showed no significant effect on the activity. The present results show that the activity per g tissue of 17 alpha-oxidoreductase in the mouse kidney increases markedly with age, and that the activity is largely confined to the renal tubules of the cortex.     

Morphological changes in the submandibular glands and in the X zone of the adrenal gland following ovariectomy in mice

Summary Morphological changes in submandibular glands of female mice following ovariectomy were studied morphometrically by light microscopy and ultrastructurally by electron microscopy. The X zone of the adrenal gland was examined in order to assess possible changes that might be expected to occur after ovariectomy.In submandibular glands, 1 to 4 weeks after ovariectomy, no changes were observed in percentages of the acinar, intercalated duct, and granular convoluted tubular areas occupying photomicrographs. However, an increase in the granular content of both intercalated duct and granular convoluted tubular cells was recognized. By contrast, the glandular picture 4 months after ovariectomy changed remarkably, resembling that of the male mouse both morphometrically and in terms of fine structure. In the adrenal cortex of control female mice, the X zone became thinner with aging. As compared with this, the X zone of ovariectomized mice at any time after the operation was thicker than that of controls.These observations suggest that the absence of ovarian hormones in the ovariectomized mouse may lead to prolonged functioning of X zone cells, which in turn may cause masculinization of the submandibular gland.     

Induction of lymph follicle formation with several mitogens and adjuvants in the mouse popliteal lymph node

The formation of lymph follicles in draining popliteal nodes was investigated in young adult male mice which had been injected in the rear footpad with several mitogens and adjuvants, and killed after 3-21 days. PPD (100 micrograms-1 mg) and PHA (25-500 micrograms) induced germinal centers in association with existing follicles and mild plasmacytosis, but failed to produce new follicles in draining nodes. Endotoxin LPS (50-200 micrograms), Con A (50 micrograms-1 mg) and PWM (50 micrograms-1 mg) induced germinal centers within existing follicles and plasmacytosis, and also produced new follicles which soon developed germinal centers. Both Freund's complete and incomplete adjuvants (FCA and FICA, 25 microliters) induced virtually no germinal centers and plasmacytosis, but produced a significant number of new primary follicles. Poly (A, U) (600 micrograms) produced neither germinal centers nor plasmacytosis, and did not induce new follicles. Analysis of the distribution of lymphoid cells which had incorporated 3H-thymidine in the draining nodes at 3 days after the injection of test substances indicated that PPD, PHA, LPS, Con A and PWM preferentially stimulated in vivo the same types of lymphocytes as they do in vitro. FCA triggered lymphocyte activation in the deep cortex, whereas Poly (A, U) appeared not to stimulate lymphocytes in vivo. In further experiments, induction of lymph follicles with artificially precipitated PPD and PHA was studied. The draining nodes treated with alum-precipitated PPD or PHA were found to produce a significant number of new follicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of androgen pretreatments at adulthood on androgen-induced proliferative response of seminal vesicles in neonatally castrated mice

Male mice were castrated on days 0 and 60 after birth. The majority of the neonatally castrated mice were pretreated with androgen; the mice were given daily injections of testosterone propionate (TP; 4 or 8 micrograms/g body wt) for 20 or 30 days starting from day 60. Daily injections of TP (4 micrograms/g body wt) to examine androgen-induced proliferation were started from day 30 or 60 after the end of TP pretreatments or from day 60 after castration; on various days after starting TP injections, the weight and the incorporation of 5-[125I]iodo-2'-deoxyuridine into the whole seminal vesicles were determined as indices for proliferation. The seminal vesicles of neonatally castrated adult mice were characterized by long duration of androgen-induced proliferation (greater than 20 days) with a low peak (neonatal castration type), whereas the seminal vesicles of adult castrated mice were characterized by short duration of proliferation (10 days) with a high peak (adult castration type). In neonatally castrated adult mice, the neonatal castration type of androgen-induced proliferation was changed largely to the adult castration type when pretreatment with 8 micrograms/g body wt of TP had been given for 30 days. However, this effect gradually disappeared when the mice had been pretreated with decreasing amounts of TP for a shorter period. The present findings suggest that the defect in the androgen-induced proliferative response of mouse seminal vesicles induced by the absence of neonatal and prepubertal testicular androgens can be compensated by androgens given in adulthood, if enough androgen is given for a sufficiently long time.     

Roles of neonatal and prepubertal testicular androgens on androgen-induced proliferative response of seminal vesicle cells in adult mice

Male mice were castrated at 0, 10, 20, 30, 40 and 60 days of age; daily injections of testosterone propionate (TP, 4 micrograms/g b. wt) were started from day 90. On various days after starting the TP injections, the incorporation of 5-[125I]iodo-2'-deoxyuridine into the whole seminal vesicles was determined as an index for proliferation. The seminal vesicle cells in mice castrated on days 0 and 20 were characterized by low weight (0.5-1 mg) before TP injection, long duration of androgen-induced proliferation (greater than 20 days) with a low peak, and involvement of both epithelial and fibromuscular cells (neonatal castration type). The seminal vesicle cells in mice castrated on days 60 and 40 were characterized by relatively high weight (5-10 mg) before TP injection, short duration of androgen-induced proliferation (10 days) with a high peak, and involvement of only the epithelial cells (adult castration type). In mice castrated on days 0 and 20, the neonatal castration type of androgen-induced proliferation was completely changed to the adult castration type when TP pretreatment (2 micrograms/g b. wt per 12 h) had been given from day 20 to day 40. However, the TP pretreatment given from day 90 to day 110 instead of days 20-40 had no such effect in 140-day old mice castrated on day 0. The present findings suggest that testicular androgens secreted from day 20 to day 40 play an indispensable role in the induction of irreversible proliferative response of the mouse seminal vesicle. The activity of the prepubertal androgens may not be completely compensated by androgen activity at adulthood.     

Differentiation of lymphocytes in mouse bone marrow. II. Kinetics of maturation and renewal of antiglobulin-binding cells studied by double labeling

DNA labeling by ³H-thymidine in vitro and antiglobulin-¹³¹I binding in vitro were used to determine the development and turnover of immunoglobulin-bearing lymphocytes in mouse bone marrow.Bone marrow cells from CBA mice previously injected repeatedly with ³H-thymidine for 1–84 hr were exposed to ¹³¹I-labeled rabbit-antimouse globulin for 30 min at 0 °C, and examined radioautographically. The antiglobulin-binding cells in bone marrow were predominantly (97–98%) nondividing small lymphocytes. Some plasmacytoid and monocytoid cells, but not the proliferating large lymphoid cells, also bound antiglobulin. The ³H-thymidine labeling index of the small lymphocyte population showed a rapid exponential increase (50% in 32 hr). The first small lymphocytes to show ³H-thymidine labeling were those lacking antiglobulin-binding capacity, reaching approximately 90% ³H-thymidine labeling after 2 days. Small lymphocytes which bound antiglobulin-¹³¹I at a concentration of 1.0 μg/ml became labeled with ³H-thymidine only after a lag of approximately 1.5 days. More avid antiglobulinbinding cells were delayed a further 12 hr in ³H-thymidine labeling. During in vitro culture the proportion of antiglobulin-binding small lymphocytes increased progressively in bone marrow but decreased in spleen cell suspensions.The results demonstrate a continuous, rapid renewal of immunoglobulin-bearing small lymphocytes in adult mouse bone marrow. Surface immunoglobulin molecules are not detectable when marrow small lymphocytes are first formed, but they appear and increase progressively in density as the cells mature.     

Migration of glial cells in the brains of intact mice and mice with brain injuries during the first hours after DNA synthesis and cell division]

The behaviour of labelled (3H-thymidine) glial cells was studied in the brain of intact mice and mice with mechanical trauma of brain. Formation of pairs of labelled cells and their subsequent disjunction in the brain regions under study occurs at different rates. The rates of these processes in white matter and subependymal zone exceed those in parietal cortex, thalamus and hypothalamus. The brain traumatization does not influence the rate of disjunction of separated glial cells. Angles between axes of separated cells are different in the brain regions under study. In cortex and white matter, separated cells with axial angles equal to 180 degrees predominate whereas in thalamus, hypothalamus and subependymal zone many separated cells have axial angles below 180 degrees (120-160 degrees). The possible relationship between the form of the brain regions under study and the value of axial angles of separated cells is discussed.     

TESTOSTERONE-INDUCED CELL PROLIFERATION IN THE ACCESSORY SEX GLANDS OF MICE AT VARIOUS TIMES AFTER CASTRATION

The proliferative response to testosterone in the accessory sex glands (seminal vesicle and coagulating gland) of castrated male Balb/c mice has been examined by pulse and continuous thymidine-labelling experiments, and by the fraction of labelled mitoses technique. Progressive reductions in cellularity followed castration, and by varying the time elapsing between castration and the initiation of testosterone treatment, it was clear that the size of the response depended upon the number of cells in the tissue, relative to the normal complement. Interpretation of FLM data was difficult in periods where proliferative rates changed rapidly. We have attempted to explain the cell kinetic events by postulating a G₀ compartment, from which cells are stimulated to enter the proliferative cycle before subsequently returning to an out of cycle state. It was thought unlikely that substantial changes in cell cycle time occurred. In both the accessory sex glands, the overall form of the continuous thymidine labelling curves showed that most proliferative cells entered DNA synthesis in a shorter time after stimulation at 14 days after castration than they did at 3 days after castration. The data were not consistent with cells moving deeper into G₀ with time after castration. In the seminal vesicle almost all epithelial cells were potentially proliferative by 3 days after castration. In the coagulating gland only 30% were potentially proliferative at 3 days, increasing to 85% at 14 days after castration. However, such proportional increases represented much smaller changes in terms of absolute numbers of cells, because of a concomitant decline in cellularity from 3 to 14 days after castration.     

The origin of syncytial muscle fibres in the myotomes of Xenopus laevis--a revision

During the early stages of myogenesis in X. laevis, the primary myoblasts (of mesodermal origin) differentiate simultaneously, in each myotome, into mononucleate myotubes. At later stages mesenchymal cells appear in intermyotomal fissures and then in the myotomes between myotubes and contribute to the formation ofsyncytial muscle fibres. The pathway of mesenchymals cell during myogenesis was described in X laevis by monitoring the incorporation of 3H-thymidine. 3H-thymidine was incorporated in the nuclei of mesenchymal cells in intermyotomal fissures of younger myotomes and then in those of older myotomes between the myotubes revealing the proliferation of mesenchymal cells. As expected, nuclei of differentiating mononucleate myotubes did not incorporate 3H-thymidine. At later stages of myogenesis the myotubes were found to contain two classes of nuclei: large nuclei of the primary myoblasts (of myotomal origin) and smaller nuclei originating from secondary myoblasts ofmesenchymal origin. TEM and autoradiographic analyses confirm that mulinucleate myotubes in X. laevis arise through fusion of secondary myoblasts with mononucleate myotubes.     

Early postnatal proliferation of the retinal pigment epithelium cells in the mouse

A burst of proliferative activity with a maximum of DNA-synthesizing cells on the first day after birth was found in the central zone of the retinal pigment epithelium (RPE) in albino mice from the moment of birth to 9 days of life using radioautography with 3H-thymidine pulse labelling. During this period the central RPE zone, which consists in newborns of mononuclear cells by 95%, gradually transforms in a population with predominance of binuclear cells and fluctuations in the index of labelled nuclei (after the kinetics of cell population in the central RPE zone is similar in mice and rats both in accumulation of binuclear cells and fluctuations in the index of labelled nuclei (after pulse labelling), except that in mice the peak of the index of labelled nuclei is observed earlier than in rats.     

Increase in epithelial cell growth by hyperprolactinemia induces delay of castration-induced involution of mouse seminal vesicle

Male (C57BL/6 x DBA)F1 hybrid mice were castrated on day 60 after birth; two pituitaries from 60-day-old female mice were immediately grafted under the capsule of the left kidney in half of the castrated mice to induce hyperprolactinemia. The seminal vesicles in the absence of androgen treatment were examined 15, 22, 30 and 60 days after castration with or without grafting. Significant increases in the weight (1.3-1.4-fold), DNA content (1.2-1.3-fold) and labeling index of epithelial cells (4-10-fold) of the seminal vesicles were found in mice with pituitary grafts compared to mice without grafts on days 15-30 after castration but not on day 60 after castration. Such stimulatory effects of hyperprolactinemia on mouse seminal vesicle cells were also observed on day 15 after castration plus adrenalectomy. Cell loss from the seminal vesicles was found to be similar in castrated mice with and without the grafts. The present findings demonstrate that hyperprolactinemia induces an increase in DNA synthesis of epithelial cells in the seminal vesicles until 30 days after castration and results in a significant delay of castration-induced involution of the weight and DNA content of the seminal vesicles for 1 month. However, the delay with increased epithelial cell growth by hyperprolactinemia disappeared 60 days after castration.     

Perturbation of early development of the immune system by normal adult lymphoid cells

Seven-day-old C57BL/10 mice injected with 3 X 10(6) normal adult lymph node cells (NAL) from syngeneic donors were compared with uninjected littermates when 5 to 7 wk old. The direct PFC response to sheep erythrocytes was suppressed by 60%. Responses to PHA and Con A but not LPS were suppressed by 60 to 90%. Primary and secondary (after skin graft rejection) MLR responses were suppressed by 30 to 40%. Active suppressor cells were demonstrable in these mice. Skin grafts incompatible for H-2 were rejected in normal time. NAL derived from adult mice conferred the effect, but not cells from 7-day-old donors. Mice inoculated with Rous sarcoma virus within the 1st day of life and 3 X 10(6) NAL at 7 days of age displayed up to 5-fold increased incidence of primary sarcomas.     

Oxidative stress signalling in the apoptosis of Jurkat T-lymphocytes

Within the first 24 h after castration of an adult male rat, the vascular system of the ventral prostate gland undergoes a degenerative process that drastically reduces blood flow to the tissue. Since the vascular degeneration precedes the loss of the prostatic epithelium (by apoptosis), we have proposed that the onset of epithelial cell apoptosis in this tissue is caused by an ischemic/hypoxic environment resulting from the loss of blood flow. In order to further evaluate the extent to which ischemia/hypoxia might be a factor in apoptosis of the prostate epithelium after castration, we analyzed for biomarkers of cellular hypoxia in rat ventral prostates during the first 3 days following castration. Ventral prostate tissues removed from hypoxyprobe-1-treated adult male rats (uncastrated controls; surgically castrated for 24, 48 or 72 h, or sham-castrated for equivalent times) were directly analyzed for evidence of hypoxia by in situ immunohistochemical evaluation of hypoxyprobe-1 adduct formation in the prostate cells. Protein extracts from these tissues were also tested for expression of the 120 kDa hypoxia-inducible factor-1-alpha (HIF-1-alpha) protein as well as for expression of mitogen-activated protein kinase (MAPK) and c-Jun N-terminal kinase (JNK) proteins using a Western blot assay. The tyrosine phosphorylation status of the latter signaling molecules was also evaluated by Western blotting using anti-tyrosine phosphate antibodies. Our results showed that epithelial cells of the rat ventral prostate stained positively for hypoxyprobe-1 adducts at all times after castration, whereas cells in control tissues were unstained by this procedure. In addition, the prostatic expression of HIF-1-alpha protein was increased approximately 20-fold at 48 h after castration compared to control tissues. Finally, although prostatic MAPK and JNK protein expression was unaltered during the early period after castration, phosphorylation of the JUN kinase protein was significantly elevated, indicating that this stress-activated cellular signaling pathway becomes more active subsequent to castration. These results support our proposal that early castration-induced degeneration and constriction of the vascular system of the rat ventral prostate gland leads to reduced oxygenation of prostatic epithelial cells and the activation of hypoxic cellular signaling in these cells through upregulation of HIF-1-alpha expression and stimulation of the JUN kinase signaling pathway.     

LYMPHOCYTE POPULATIONS IN MOUSE BONE MARROW: QUANTITATIVE KINETIC STUDIES IN YOUNG, PUBERTAL AND ADULT C3H MICE

Continuous ³H-thymidine infusion was used to characterize two kinetic subpopula-tions of small lymphocytes in mouse bone marrow during normal growth and development. Young (4 wk), pubertal (8 wk) and mature (16 wk) C3H mice were infused subcutaneously with ³H-thymidine for periods up to 10 days. Femoral marrow was then examined in radioautographic smears. During the first 3 days the proportion of marrow small lymphocytes labelled by ³H-thymidine showed a rapid exponential increase to 93%, 81% and 72% in 4 wk, 8 wk and 16 wk mice respectively. The rate of appearance of labelled small lymphocytes then declined markedly but remained higher in younger than in older animals. The labelling curves were found to represent the summation of two exponential curves from which the proportions and renewal rate of corresponding cell populations were calculated. Most marrow small lymphocytes comprised a rapidly renewing population but in mice of increasing age the relative incidence of these cells fell (93-3% at 4 wk; 88-0% at 8 wk; 78-5% at 16 wk) and their half-renewal time (T_½) lengthened (14 hr at 4 wk; 18 hr at 8 wk; 24 hr at 16 wk). The remaining small lymphocytes were slowly renewing with mean T_½ of 4, 7 and 14 days in 4, 8 and 16 wk mice, respectively. Some heavily labelled small lymphocytes persisted in the marrow up to 10 wk after fourteen daily ³H-thymidine injections in 10–12 wk mice. The numbers of rapidly renewing cells decreased from 604 times 10³ to 228 times 10³ per mm³ of marrow from 4 wk to 16 wk, respectively, while slowly renewing cells increased from 44 times 10³ to 61 times 10³ per mm³. The total number of nucleated marrow cells per femur increased from 4 wk to 16 wk but the rapidly renewing small lymphocytes per femur fell in numbers by 36% and in renewal rate by 63%. The results demonstrate a selective change in bone marrow small lymphocytes with age; rapidly renewing cells decline in number and renewal rate while the number of slowly renewing cells increases. The concept of bone marrow as a primary lymphoid organ is discussed.     

Morphological changes of pituitary gonadotrophs and thyrotrophs following treatment with LH-RH or TRH in vitro

Summary To investigate the relationship between LH-RH and TRH and the formation of castration cells and thyroidectomy cells, pituitary glands of 14-day old female rats were cultured with LH-RH or TRH for 10 days. Observed in these glands were external and internal zones, the former containing active, healthy appearing cells, and the latter consisting of many degenerative and necrotic cells. Gonadotrophs and thyrotrophs were readily demonstrated in the external zone of the organs by immunocytochemistry. Hypertrophie gonadotrophs (castration cells) and thyrotrophs (thyroidectomy cells) were observed only in the external zone by electron microscopy. Neither the typical signet-ring gonadotrophs nor intracisternal granules of thyroidectomy cells were seen in the present study. However, the hypertrophic gonadotrophs or thyrotrophs were similar to castration cells or thyroidectomy cells observed in the pituitary gland following castration or thyroidectomy. The results indicate that LH-RH and TRH directly stimulate the secretion of hormones and alter the morphological features of pituitary target cells.Supported by USPHS Grant HD 11826. The author wishes to express his thanks to NIAMDD for providing pituitary hormones     

Testosterone-induced cell proliferation in the accessory sex glands of mice at various times after castration

The proliferative response to testosterone in the accessory sex glands (seminal vesicle and coagulating gland) of castrated pale Balb/c mice has been examined by pulse and continuous thymidine-labelling experiments, and by the fraction of labelled mitoses technique. Progressive reductions in cellularity followed castration, and by varying the time elapsing between castration and the initiation of testosterone treatment, it was clear that the size of the response depended upon the number of cells in the tissue, relative to the normal complement. Interpretation of FLM data was difficult in periods where proliferative rates changed rapidly. We have attempted to explain the cell kinetic events by postulating a G0 compartment, form which cells are stimulated to enter the proliferative cycle before subsequently returning to an out of cycle state. It was thought unlikely that substantial changes in cell cycle time occurred. In both the accessory sex glands, the overall form of the continuous thymidine labelling curves showed that most proliferative cells entered DNA synthesis in a shorter time after stimulation at 14 days after castration than they did at 3 days after castration. The data were not consistent with cells moving deeper into G0 with time after castration. In the seminal vesicle almost all epithelial cells were potentially proliferative by 3 days after castration. In the coagulating gland only 30% were potentially proliferative at 3 days, increasing to 85% at 14 days after castration. However, such proportional increases represented much smaller changes in terms of absolute numbers of cells, because of a concomitant decline in cellularity from 3 to 14 days after castration.     

TNF receptor-1 is required for the formation of splenic compartments during adult, but not embryonic life

Lymphotoxin β-receptor (LTβR) and TNF receptor-1 (TNFR1) are important for the development of secondary lymphoid organs during embryonic life. The significance of LTβR and TNFR1 for the formation of lymphoid tissue during adult life is not well understood. Immunohistochemistry, morphometry, flow cytometry, and laser microdissection were used to compare wild-type, LTβR(-/-), TNFR1(-/-) spleens with splenic tissue that has been newly formed 8 wk after avascular implantation into adult mice. During ontogeny, LTβR is sufficient to induce formation of the marginal zone, similar-sized T and B cell zones, and a mixed T/B cell zone that completely surrounded the T cell zone. Strikingly, in adult mice, the formation of splenic compartments required both LTβR and TNFR1 expression, demonstrating that the molecular requirements for lymphoid tissue formation are different during embryonic and adult life. Thus, interfering with the TNFR1 pathway offers the possibility to selectively block the formation of ectopic lymphoid tissue and at the same time to spare secondary lymphoid organs such as spleen and lymph nodes. This opens a new perspective for the treatment of autoimmune and inflammatory diseases.     

Binding protein for 5 alpha-dihydrotestosterone in mouse submandibular gland.

The changes in the levels of the binding protein for 5 alpha-dihydrotestosterone in cytoplasmic extract of the submandibular glands during development were compared in male and female mice using a DEAE-cellulose filter assay. The binding protein was first detectable 5 days after birth in both sexes, at a time coincident with androgen-independent cytodifferentiation of the convoluted tubular cells in the submadibular gland. The level of the binding protein in female mice was maintained at 5 pmol/mg protein after birth, whereas in males it began to decrease from 3 weeks after birth with inccrease in serum testosterone, becoming much less than a quarter of the level in females or immature mice by 4 weeks after birth. However, after castration, the level of detectable binding protein in mature male mice increased within 7 days to the same level as that in females or immature mice. This suggests that the low binding capacity for exogenous hormone in mature male mice is due to occupancy of the binding sites by endogenous hormone.