EVOLUTION DE L''INCORPORATION IN VIVO DE L''ACIDE [14C]OROTIQUE DANS L''ARN ET L''ADN DU CERVELET DE JEUNES RATS HYPO- ET HYPERTHYROIDIENS: EFFETS COMPARATIFS DE L''HYPO- ET L''HYPERTHYROIDIE SUR LES MULTIPLICATIONS CELLULAIRES

The change in the body and cerebellar weights, together with the quantity of RNA, DNA and proteins in the cerebellum were studied for the first 10 days and on the 12th, 14th, and 17th days of postnatal life in normal, hypo- and hyperthyroid rats. In the normal animals: (1) The average cellular protein content decreases from the first to the second day, increases to a maximum at 4 days, then decreases. (2) The specific radioactivity of the RNA, 14 h after an intravenous injection of [6-¹⁴C]orotic acid, varies distinctly from birth to 9 days and reaches two maxima at 4 and 6 days. After 9 days it decreases markedly. (3) Mitotic activity (number of replicating cells) increases, reaches a maximum at 9 days, then decreases. (4) The specific radioactivity of the DNA (used as a measure of the percentage of the cellular population in division) reaches a maximum at 6 days. (5) Mitotic efficiency (number of replicating cells in mitotic activity) decreases from 2 to 7 days, and subsequently increases. In the hypothyroid animals: (1) The average cellular protein content increases from the first to the second day and then decreases. (2) The specific radioactivity of the RNA, always significantly higher than that of normal animals, varies from birth to 9 days, reaches two maxima at 4 and 6 days, then decreases after 9 days. (3) Mitotic activity, always significantly lower than that of normal animals, increases from birth, reaches a maximum at 9 days, then decreases. (4) The specific radioactivity of the DNA reaches a maximum at 6 days and the mitotic efficiency a minimum at 7 days. Neither are significantly different from that of normal animals. In the hyperthyroid animals: (1) The average cellular protein content, is maximal at 2 days, then decreases. (2) The specific radioactivity of the RNA, always significantly lower from that of normal animals, decreases from birth. (3) Mitotic activity is similar to that of normal animals, increases from birth up to 6 days, then decreases. (4) The specific radioactivity of the DNA increases from birth up to 5 days, then decreases. It is significantly lower than that of normal animals. (5) Mitotic efficiency is significantly higher than that of normal animals. In the different groups, the maximum of the average cell size, always precedes the maximum of the cellular division. In the hypothyroid animals, the rate of cell death is higher than that of normal animals, and the average cell size is higher during the first fourteen days. In the hyperthyroid animals, the rate of cell death is lower than that of normal animals, and the average cell size is higher at 14 and 17 days.     

COMPARATIVE EFFECTS OF HYPOTHYROIDISM, HYPERTHYROIDISM AND UNDERNUTRITION ON THE PROTEIN AND NUCLEIC ACID CONTENTS OF THE CEREBELLUM IN THE YOUNG RAT

Abstract— The effects of hypothyroidism, hyperthyroidism and undernutrition on the development of the protein and nucleic acid contents of the cerebellum were studied in young rats ranging in age from 6 to 35 days. Foetal and neonatal propylthiouracil treatment caused a delayed cell multiplication in the organ but this delay had disappeared at 35 days. As early as the age of 10 days, the total cerebellar RNA and protein contents in these hypothyroid animals were lower than in the normal animals but the mean cellular contents of RNA and protein were not lowered before the age of 21 days. Slight neonatal hyperthyroidism, induced by the daily injection of a relatively small dose of thyroxine, produced an accelerated cell multiplication during the first postnatal week and afterwards a delay in cell proliferation. In the hyperthyroid animals, the mean cellular protein content, initially higher than normal, tended to be lower at 35 days. At this age, the cell number had nearly returned to normal. Undernutrition directly led to a reduced cell proliferation and the reduced cell number still persisted at 35 days. At first, the cells were on the average larger than normal, but the effect on the mean RNA and protein contents per cell was not persistent in the underfed animals.
This study correlates the degree of neonatal hyperthyroidism with the further development of the cell population of the cerebellum and emphasizes the importance of the events which take place just after birth in the cerebellum submitted to an excess or a deficiency of thyroid hormone. In addition, the results are discussed in relation to data concerning the morphogenetic action of thyroid and of underfeeding on the cerebellum.     

Neonatal hypothyroidism — A biochemical disorder of α-tubulin metabolism

In mouse brain significant changes in tubulin-tyrosine ligase (TTL) activity were observed during the first week of neonatal life. Brain TTL-activity was found to be higher on postnatal day 5 than on fetal day 15, at birth or on postnatal day 7. In neonatal hypothyroidism both TTL activity and endogenous tyrosinable-tubulin levels were greatly reduced on day 5 relative to euthyroid animals. Gel scanning studies did not show any qualitative differences in the brain supernatant protein patterns of euthyroid and hypothyroid animals. Under conditions of the present study α-tubulin was only substrate for tyrosylation.     

Effects of Undernutrition and Thyroid State on the Ontogenetic Changes of D1, D2, and D3 Brain-Specific Proteins in Rat Cerebellum

Abstract: Disturbances in metabolic balance brought about by alterations in thyroid state and undernutrition during early life had a marked effect on the concentrations of the brain-specific proteins, D1, D2, and D3 in the developing rat cerebellum. In normal rats, the concentrations of D1 and D3 increased and that of D2 decreased during the first 3 weeks after birth. In the hyperthyroid state a small but consistent advancement was observed in the developmental curves of these proteins. The hypothyroid state caused a marked retardation in the maturational pattern of D1 and D2 but not of D3. In undernutrition, at 6 days the concentrations of D1 and D3 proteins were higher than in controls, but thereafter the developmental increase was markedly delayed for D1 only. The concentration of D2 was normal at 6 days, but after the first week a marked retardation was observed in the maturational pattern of this protein in undernourished rats. In addition, the "anodic-immature"form of D2 predominated in 6-day-old controls, but this was gradually replaced by a "cathodic-mature"form which progressively became the dominant form of D2 in 35-day-old rat cerebellum. The developmental switch in terms of the two forms was also advanced in hyperthyroidism and retarded in thyroid deficiency and undernutrition. Furthermore, daily treatment of hypothyroid rats with physiological doses of thyroxine from birth restored the concentrations of D1 and D2 to normal, but that of D3 was increased above control levels, indicating differences between the proteins in their sensitivity to mechanisms of control by thyroid hormone. Also, the overall effects of undernutrition were markedly different from those of hypothyroidism.     

Postnatal Development of a Granule Cell-Enriched, Neurone-Specific Glycoprotein, gp50, in Normal and Thyroid-Deficient Rats

Glycoprotein gp50 is a neurone-specific, granule cell-enriched glycoprotein that is also a major component of isolated synaptic membranes. Here, we describe the use of a monoclonal antibody, mab SM gp50, to study the postnatal development of gp50 in the brain of normal and thyroid-deficient rats. Radioimmunoassay, enzyme-linked immunosorbent assay, and Western blotting show that gp50 is not detectable in brain until postnatal day 4 (P4) in both forebrain and cerebellum. In forebrain, the rate of increase of gp50 levels is maximal between P12 and P20. It is somewhat later in cerebellum, where peak levels are attained between P30 and P35. Immunocytochemical studies show little detectable gp50-like immunoreactivity before P16, and the staining is still weak, relative to adult tissue, at P25. The intense staining of the granule cell layer characteristic of adult cerebellum predominantly appears after P25. Development of gp50 is severely retarded in the cerebellum of thyroid-deficient rats, particularly during the second and third postnatal weeks. However, by the fourth postnatal week, gp50 levels in normal and hypothyroid animals are comparable. The results indicate that significant alterations in the pattern of gp50 expression continue to occur at a late stage of cerebellar development. In particular, the increase in immunocytochemical staining of the granule cells after P25 is striking in that by this time most major events associated with cerebellar development are essentially complete.     

EFFECT OF UNDERNUTRITION ON CELL FORMATION IN THE RAT BRAIN

Abstract— Rats were undernourished by approximately halving the normal food given from the 6th day of gestation throughout lactation. Growth of the foetuses was nearly normal, in marked contrast to the severe retardation caused by undernutrition during the suckling period. In comparison with controls the size and the DNA content of the brain were permanently reduced by undernutrition during the suckling period: this effect was relatively small, approx. 15 per cent decrease at 21 and 35 days. The rate of ¹⁴C incorporation into brain DNA at 30 min after administration of [2-¹⁴C] thymidine was taken as an index of mitotic activity; compared with controls there was severe reduction in mitotic activity (maximal decrease by about 80 per cent at 6 days in the cerebrum and by 70 per cent at 10 days in the cerebellum). The rate of acquisition of cells was calculated from the slopes of the logistic curves fitted to the estimated DNA contents. In normal animals the maximal slope was attained at 2·7 days and at 12·8 days after birth in cerebrum and cerebellum respectively; the daily acquisition of cells at these times was 4·8 × 10⁶ and 18 × 10⁶ cells respectively. The fractional increase in cell number at the maximum was 5·4 percent per day in the cerebrum and 15·2 per cent per day in the cerebellum. The rate of acquisition of cells relative to the rate of mitotic activity was higher in the brains of undernourished animals than in controls. One of the compensatory mechanisms for the severe depression of mitotic activity in the brain of undernourished animals Seems to involve a reduction in the normal rate of cell loss.     

Effect of Hypo- and Hyperthyroidism on Hexokinase in the Developing Cerebellum of the Rat

Abstract: Total hexokinase levels (units/g tissue) have been measured during postnatal development of the cerebellum in control, hypothyroid, and hyperthyroid rats. In addition, distribution of hexokinase in the developing cerebellum has been observed with an immunofluorescence method. Hypothyroidism delays the normally observed postnatal increase in total hexokinase activity, whereas hyperthyroidism accelerates the increase. In normal animals, hexokinase levels in maturing Purkinje cells pass through a transient increase, with maximal levels at approximately 8 days postnatally followed by rapid decline to relatively low levels by 12 days; hypothyroidism delays this transient increase and subsequent decline, but hyperthyroidism does not appear to affect markedly the timing of this phenomenon. Cerebellar glomeruli are relatively enriched in hexokinase content, as judged by their intense fluorescence. Hypothyroidism delays the development of intensely stained glomeruli. Hyperthyroidism did not appear to cause precocious increase in numbers of glomeruli but may have increased the rate at which the hexokinase was assimilated by newly formed glomeruli. The effects of hypo- and hyperthyroidism on total cerebellar hexokinase levels are interpreted in terms of the effect of thyroid hormone on the biochemical maturation of synaptic structures rich in hexokinase.     

Regulation of tubulin and actin mRNA production in rat brain: expression of a new beta-tubulin mRNA with development.

The expression of alpha-tubulin, beta-tubulin, and actin mRNA during rat brain development has been examined by using specific cDNA clones and in vitro translation techniques. During brain maturation (0 to 80 days postnatal), these mRNA species undergo a significant decrease in abundance. The kinetics of this decrease varies between the cerebrum and the cerebellum. These mRNAs are most abundant in both tissues during week 1 postnatal, each representing 10 to 15% of total mRNA activity. Both alpha- and beta-tubulin mRNA content decreases by 90 to 95% in the cerebrum after day 11 postnatal, and 70 to 80% decreases in the cerebellum after day 16. Actin sequences also decrease but to a lesser extent in both tissues (i.e., 50%). These decreases coincide with the major developmental morphological changes (i.e., neurite extension) occurring during this postnatal period. These studies have also identified the appearance of a new 2.5-kilobase beta-tubulin mRNA species, which is more predominant in the cerebellar cytoplasm. The appearance of this form occurs at a time when the major 1.8-kilobase beta-tubulin mRNA levels are declining. The possibility that the tubulin multigene family is phenotypically expressed and then this expression responds to the morphological state of the nerve cells is discussed.     

Net sulfatide synthesis, galactosylceramide sulfotransferase and arylsulfatase A activity in the developing cerebrum and cerebellum of normal mice and myelin-deficient jimpy mice

Net sulfatide synthesis, galactosylceramide sulfotransferase (EC 2.8.2.11) and arylsulfatase A (EC 3.1.6.1) activities were measured in two brain regions, cerebrum and cerebellum, of normal and jimpy mice during postnatal development. In normally myelinating mice, two phases of increasing rates of net sulfatide synthesis were observed, the first coinciding with oligodendrocyte proliferation and the second with myelination. Net sulfatide synthesis was quantitatively higher in the cerebellum than in the cerebrum. In both brain regions, the developmental patterns of net sulfatide synthesis were related to the activity patterns of both galactosylceramide sulfotransferase and arylsulfatase A. In jimpy mice, a neurological mutant showing hypomyelination in brain, the first phase of net sulfatide synthesis was preserved in both brain regions and galactosylceramide sulfotransferase and arylsulfatase A activities were normal up to 12 days. However, during the phase in which myelination occurred in controls, the net sulfatide synthesis in both brain regions of jimpy mice was zero or even negative. The sulfatide deficit was larger in the cerebellum than in the cerebrum. In both mutant brain parts, galactosylceramide sulfotransferase activity increased up to 12 days showing about 50% of the maximal activities observed in normal brain regions. Thereafter up to 15 days, enzyme activity decreased to about 25% of that of controls and remained low in both brain regions. The developmental patterns and the activities of arylsulfatase A were, however, normal in the cerebrum and cerebellum of jimpy mice. These results suggest that the enzyme activities and the developmental patterns of galactosylceramide sulfotransferase and arylsulfatase A as measured in vitro reflect to a high degree their functional activity in vivo. Furthermore, sulfatide degradation by arylsulfatase A seems to be important in regulating net sulfatide synthesis during normal and impaired myelination.     

Effects of methylazoxymethanol given at different stages of postnatal life on development of the rat brain. Comparison with those of thyroid deficiency

Newborn rats were treated at different stages of their development with low doses of methylazoxymethanol acetate. The postnatal increase of the DNA content of the cerebrum did not differ from that of controls. In the cerebellum, the DNA content was transitorily reduced, but later, the external granular layer became thicker and DNA deposition increased in comparison with controls; finally, the cerebellar DNA returned to a normal value. Morphological abnormalities of the cerebellum, abnormal orientation of migrating cells, scattering of Purkinje cell bodies within the internal granule cells and specially striking abnormalities of the morphology and orientation of Purkinje cell dendrites were noted in rats treated with MAM from birth to day 3. The effects on the Purkinje cell morphogenesis persisted but were much less marked when MAM was given from 4 to 7 or from 8 to 11 days. Neonatal thyroid deficiency, as MAM-treatment between days 0 and 3, leads to an abnormal position of Purkinje cell bodies within the cerebellar cortex; it also leads to morphological abnormalities of their dendritic arborization which closely resemble those observed after MAM-treatment during the second postnatal week. It also alters the cell formation in the cerebellum. Thyroid deficiency probably exerts its effect on cell formation earlier than previous biochemical studies have shown. On another hand, the morphological abnormalities of Purkinje cell arborizations in the thyroid-deficient animals may be partly due to the perturbations of cell formation which persist later in the cerebellum.     

Inhibition of thymidine kinase activity by hydroxyurea during highly and less proliferative regions of rat brain

Hydroxyurea, when injected intraperitoneally, exerted marked inhibition on the activity of thymidine kinase in 5 day old postnatal cerebellum and 15 day old embryonic cerebrum. However, it failed to show any sustained inhibition on thymidine kinase activity in 5 day old postnatal cerebrum. In this case, the marginal decrease of thymidine kinase activity noticed during early intervals reversed back to more than normal value at a later time interval. These results along with our earlier findings are taken to indicate the differential action of this drug on thymidine kinase activity in rapidly and slowly proliferating regions of rat brain     

Effects of thyroid status and fasting on hepatic metabolism of apolipoprotein A-I

Metabolism of apolipoprotein (apo)A-I was studied in normal and chow-fed hyperthyroid rats, in 24-h fasted untreated male rats, and in rats after thyroparathyroidectomy (TXPTX). Rats were made hyperthyroid by administration of T3 (9.6 micrograms/day) or T4 (30 micrograms/day) with an Alzet osmotic minipump. Hyperthyroidism produced a similar two- to threefold elevation in plasma levels of apoA-I in male or female animals. During treatment with T3, plasma levels of T3 ranged from 200 to 400 ng/dl and did not correlate with plasma apoA-I levels. The net mass secretion and synthesis ([3H]leucine incorporation) of apoA-I by perfused livers from male hyperthyroid rats was elevated, while secretion of albumin was not different than that of euthyroid rats. Furthermore, the incorporation of [3H]leucine into total perfusate and hepatic protein was not altered by hyperthyroidism. The effect of thyroid hormone on apoA-I synthesis, therefore, does not appear to be a general effect on protein synthesis. After longer periods of treatment (28 days) with T3 (9.6 micrograms/day), hepatic apoA-I production decreased from that observed after 7 or 14 days of treatment, yet plasma apoA-I concentrations remained elevated. Plasma T3 decreased from 100 ng/dl to 40 ng/dl, in the hypothyroid rat resulting from TXPTX, but the plasma concentration of apoA-I did not change during the 2-week experimental period. The net secretion of apoA-I by livers from hypothyroid animals was depressed and albumin was uneffected compared to the euthyroid. Overnight fasting of euthyroid rats did not alter hepatic apoA-I secretion or plasma apoA-I levels, although under fasting conditions we had reported that hepatic output of apoB and E of VLDL is depressed. The addition of oleic acid to the perfusion medium, sufficient to stimulate VLDL production, did not affect net hepatic secretion of apoA-I by livers from euthyroid, hyperthyroid, or hypothyroid rats. In summary, hepatic synthesis of apoA-I appears to be controlled independently of other apo-lipoproteins and secretory proteins (albumin). Hepatic apoA-I synthesis is sensitive to thyroid status, increased in the hyperthyroid and decreased in the hypothyroid state. The specific stimulation of hepatic synthesis and secretion of apoA-I in the hyperthyroid state, however, tends to normalize over an extended period, perhaps from compensatory effects of a hormonal nature.     

ONTOGENETIC DEVELOPMENT OF ADENYL CYCLASE AND PHOSPHODIESTERASE IN RAT BRAIN

Abstract— The activities of adenyl cyclase and phosphodiesterase were determined in homogenates of cerebrum, cerebellum and brain stem of rats of 1 day to 9 weeks of postnatal age. The activity of cerebral and brain stem adenyl cyclase measured either in the absence or presence of sodium fluoride increased rapidly for 2 weeks, reached at 20 days a maximum about three times (brain stem) or six times (cerebrum) that seen on day 1 and then declined slightly during the next several weeks. In contrast, activity of cerebrellar adenyl cyclase increased more slowly and reached a maximum at about 32 days. Activity of phosphodiesterase in cerebrum and brain stem increased several-fold during brain maturation; however, enzymic activity in the cerebellum decreased during the entire 9 week period.
In the pineal gland, adenyl cyclase activity measured in the absence of norepinephrine or sodium fluoride did not change significantly with age. However, enzymic activity measured in the presence of these agents increased with the age of the rat. Bilateral removal of the superior cervical ganglia at 1 day of age is known to arrest the sympathetic innervation of the pineal gland but did not prevent the development of this adenyl cyclase system activated by catecholamines or fluoride.     

The regulator role of thyroid hormones in myogenesis. Analysis of isoforms of myosin in muscular regeneration

Fast-twitch muscle regeneration has been studied in experimental hyper- and hypothyroid adult rats. The degeneration of the muscle fibres was achieved through the injection of a snake venom cardiotoxin and the synthesis of new isomyosins was examined 7, 10, 15, and 21 days after the injury. As early as the 7th day after the toxin treatment, that is 3 days after the start of the regeneration, the muscles of hyperthyroid rats do not contain any neonatal myosins and synthesize only adult myosins. In euthyroid rat muscles, neonatal myosins coexist with adult myosins and are no longer present on the 10th day. In hypothyroid rat muscles, both myosin types are still synthesized on the 21st day. Therefore, as for normal myogenesis, hyperthyroidism is shown to favor the synthesis of adult-type myosins and hypothyroidism the synthesis of neonatal-type myosins during regeneration. These results may account, at least in part, for the previously observed differences between the various types of myosins synthesized respectively in postnatal myogenesis and during adult muscle regeneration.     

Changes in rabbit cerebrum and cerebellum gangliosides during postnatal life. A study especially referring to alkali labile gangliosides

The present study deals with the developmental behaviour of cytosolic and membrane-bound gangliosides, especially the alkali labile species, in rabbit cerebrum and cerebellum from birth to 6 months of life. At all ages the amount of cytosolic gangliosides was less than 0.5% of total gangliosides. The proportion of alkali labile gangliosides on the total membrane-bound ganglioside content and the profile of the individual alkali labile gangliosides during postnatal life were different in cerebellum and cerebrum. In cerebellum the proportion of alkali labile gangliosides progressively increased from 4.6% at birth to 16.7% at 6 months; in cerebrum the proportion decreased from 8.9% at birth to a minimum of 5.5% at 10 days, then slowly increased up to 8.1% at 6 months.All the major alkali labile gangliosides in cerebellum, especially O-Ac-GT1b and O-Ac-GQ1b, tended to accumulate during postnatal life. In cerebrum only two alkali labile gangliosides, namely O-Ac-GT1b and a species not yet identified, increased starting from the 10th day of life, while the other ones progressively diminished after birth.     

Thyroid hormone differentially regulates cellular development in neonatal rat heart and kidney.

The role of thyroid hormone in the control of cardiac and renal cell development was examined in neonatal rats made hyperthyroid by administration of triiodothyronine (T3, 0.1 mg/kg s.c. on postnatal days 1-5) or hypothyroid by administration of propylthiouracil (PTU, 20 mg/kg s.c. given to dams on gestational day 17 through postnatal day 5 and to pups on postnatal days 1-5). Indices of total cell number (total DNA per tissue), cell packing density (DNA per g tissue), and relative cell size (protein/DNA ratio) were evaluated from birth through young adulthood. PTU administration led to primary shortfalls in cell number that were of similar magnitude in both tissues, but persisted somewhat longer in the kidney than in the heart. Deficits in cell packing density and cell size in the hypothyroid animals were secondary to the effect on cell number, displaying smaller magnitudes of effect and a lag in appearance and disappearance of the deficits compared to that for total DNA; indeed, the phase in which tissues were restoring their cell numbers was accompanied by increased cell packing density, reflecting a more rapid restitution of cell numbers than tissue weight or cell size. In contrast to the relatively similar effects of PTU on developing cardiac and renal cells, the effects of T3 were selective for the heart. Although T3 caused general growth impairment, it evoked marked cardiac overgrowth that was accompanied by a striking increase in cell number and a small increase in cell size. The cardiac hyperplasia is unique to the developing animal, as post-replicative heart cells in adult animals show only hypertrophy in response to thyroid hormone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of Altered Thyroid States on Myelinogenesis

Abstract: Myelinogenesis was studied in controls and in rats treated since birth with Methimazole (hypothyroid) or thyroxine (hyperthyroid). The amount of myelin in forebrain and its protein composition were determined between 13 and 40 days of age, the period of most rapid myelin accumulation. Hypothyroid rats had reduced body and brain weights relative to controls and the yield of myelin was reduced on both a per brain and a per milligram brain protein basis. Developmental changes in the protein composition of isolated myelin followed the pattern of control animals (the percentage of total myelin protein present as proteolipid protein, large basic protein, and small basic protein increased, as did the ratio of proteolipid/large basic protein) but were delayed temporally by 1–2 days. Hyperthyroid rats also had reduced body and brain weights. At 13 days myelin accumulation was greater than that of controls, corresponding to an earlier initiation of myelination. At later ages myelin yield was reduced on a per brain basis but not on a per milligram brain protein basis. The developmental pattern of myelin protein composition was accelerated temporally by 1–2 days. Myelination in optic nerve, assayed by proteolipid protein content, also was slightly delayed in hypothyroid animals and somewhat accelerated in hyperthyroid animals. The relative synthesis of myelin proteins (determined as incorporation of intracranially injected [³H]glycine into myelin protein relative to incorporation into whole brain protein), as well as distribution of radioactivity among individual myelin proteins, was determined. The results supported the conclusion of the myelin protein accumulation study; hypothyroidism retards the developmental program for myelinogenesis, whereas in the hyperthyroid state myelin synthesis is initiated earlier but is also terminated earlier.     

BIOCHEMICAL EFFECTS OF THYROID DEFICIENCY ON THE DEVELOPING BRAIN

Abstract— The effects of neonatal thyroidectomy on some constituents of the cerebrum, cerebellum and liver of the rat have been studied during the first 7 weeks of life. In the normal rat between the 6th and 14th post-natal days the RNA content per unit of DNA in the brain increased by 70 per cent. Although the brain continued to grow from the 14th to the 35th day, the amount of RNA relative to DNA decreased by about 20 per cent. The ratio of protein to DNA increased during the whole period studied and in the cerebral cortex it was more than trebled between the age of 6 and 35 days. The growth of the cerebellum extended over a longer period than that of the cerebrum, its weight increasing by 88 per cent between the ages of 14 and 35 days as compared with a cerebral increase of 34 per cent. The DNA content showed a 50 per cent increase during this period. Qualitatively these maturational changes were not affected by neonatal thyroidectomy. Quantitative changes, which applied equally to the cerebral cortex and brain as a whole, were observed. At the age of 35 days, the weights of the cerebral hemispheres and cerebellum were reduced by thyroidectomy by 20 per cent; the overall DNA content per organ did not change, but the amounts of protein and RNA relative to DNA decreased significantly. It is therefore inferred that thyroid deficiency affects the size of the cells in brain and cerebellum rather than their total number. Conversely, the cell population of the liver was only a quarter of that in the control. There was a small but significant decrease in the hepatic protein and RNA content in the hypothyroid animal. The activities of the following enzymes which served as markers for subcellular fractions in homogenates of cerebral cortex were determined: lactate dehydrogenase for the supernatant, glutamate dehydrogenase for the mitochondrial and glutamate decarboxylase for the synaptosomal fractions. When the activities were expressed on a fresh weight basis a significant decrease by comparison with the control values was observed only in the case of glutamate decarboxylase (—15 per cent at the age of 17–32 days); when the activities were based on DNA content all values were reduced, probably as a result of the general decrease in cell size. Pyrimidine metabolism of brain and liver, studied after the administration of [6-¹⁴C]-orotic acid, was not affected in either tissue by neonatal thyroidectomy. A small but significant reduction in the incorporation of labelled pyrimidine nucleotides in liver RNA was observed, but no significant decrease in the incorporation in cerebral RNA was found in the hypothyroid rats.     

Stimulatory Effects of Growth Hormone and Thyroxine on the Concentration of Gangliosides in the Snell Dwarf Cerebrum

The concentration of gangliosides in the Snell dwarf mouse cerebrum was monitored from postnatal day 5 to day 40. In the dwarf cerebrum, the concentration of total gangliosides increased up to postnatal day 20 and then stopped, whereas in the control cerebrum, it continued to increase up to postnatal day 40. At postnatal day 40, the ganglioside level in the dwarf cerebrum was 70% of that in the control cerebrum. Among the ganglioside species, the concentrations of GM4, GM2, GM1, GD1a, GD3, GD1b, GT1b, and GQ1b were significantly lower in the dwarf cerebrum than in the controls at postnatal day 40. The reduced concentrations of ganglioside species GM2, GD1a, GD3, GD1b, and GQ1b were completely restored by administration of bovine growth hormone (GH) during the first 20 days of postnatal life. The reduced concentration of the GM1 and GM4 species were most efficiently restored by administration of bovine GH plus thyroxine (T4) during the second 20 days of postnatal life. These results indicate that the lower ganglioside concentrations in the dwarf cerebrum can be elevated by hormone therapy and that there exist distinct GH and T4 actions on the enzymes participating in ganglioside metabolism.     

Influence of neonatal hypothyroidism on the development of ketone-body-metabolizing enzymes in rat brain.

Neonatal hypothyroidism markedly retarded the postnatal development of three ketone-body-metabolizing enzymes in rat brain during the first 4 weeks after birth. In contrast with normal animals, the brains of hypothyroid rats did not show decreases in the activities of these enzymes during the immediate postweaning period. The activities of ketone-body-oxidizing enzymes were markedly diminished in both non-synaptic and synaptic mitochondria isolated from 4-week-old hypothyroid rats compared with age-matched normal animals.