An analysis of the influence of thyroid hormone on the synthesis of proteins in the tail fin of bullfrog tadpoles

By incubation of explants of tail fin from tadpoles of Rana catesbeiana in a solution of 35S-methionine for 4 h, newly synthesized proteins were labeled isotopically. After separation by two-dimensional polyacrylamide gel electrophoresis, those proteins were visualized by fluorography. Exposure of explants to culture medium containing thyroxine (T4) (150 nM) increased the incorporation of 35S-methionine into several proteins with 48 h. Effects of T4 on the relative abundance of two of these newly synthesized proteins were detected after 8 h of hormonal treatment. Very similar patterns of newly synthesized proteins were observed when proteins from explants of tail fin removed from tadpoles at metamorphic climax and immediately incubated with 35S-methionine were compared with proteins produced in fin derived from premetamorphic animals. These results are interpreted to indicate that both treatment of explants with T4 and elevation of endogenous levels of thyroid hormones during spontaneous metamorphosis increased the relative rates of synthesis of several identical proteins. The potential involvement of those proteins in early phases of metamorphic action which eventually lead to cell death and resorption is discussed.     

The formation, distribution and function of ribosomes and microsomal membranes during induced amphibian metamorphosis

1. A lag period of about 4 days preceded the onset of metamorphosis precociously induced by tri-iodothyronine in tadpoles of the giant American bullfrog (Rana catesbeiana). It was established by the accelerated synthesis or induction of carbamoyl phosphate synthetase and cytochrome oxidase in the liver, serum albumin and adult haemoglobin in the blood, acid phosphatase in the tail, and the increase in the hindleg/tail length ratio. 2. A 4- to 6-fold stimulation, 2 days after the induction of metamorphosis, of the rate of synthesis of rapidly labelled nuclear RNA in liver cells was followed by an increasing amount of RNA appearing in the cytoplasm. Most of the newly formed RNA on induction of metamorphosis was of the ribosomal type. An accelerated turnover at early stages of development preceded a net accumulation of RNA in the cytoplasm, with no change in the amount of DNA per liver. 3. Most hepatic ribosomes of the pre-metamorphic tadpoles were present as 78s monomers and 100s dimers; metamorphosis caused a shift towards larger polysomal aggregates with newly formed ribosomes that were relatively more tightly bound to membranes of the endoplasmic reticulum. 4. The appearance of new polyribosomes in the cytoplasm on induction of metamorphosis was co-ordinated in time with a stimulation of synthesis of phospholipids of the smooth and rough endoplasmic reticulum, followed by a gradual shift in preponderance from the smooth to the rough type of microsomal membranes. 5. Electron- and optical-microscopic examination of intact hepatocytes revealed a striking change in the distribution and nature of ribosomes and microsomal membranes during metamorphosis. 6. Ribosomes prepared from non-metamorphosing and metamorphosing animals were identical in their sedimentation coefficients and in the structural ribosomal proteins. The base composition and sedimentation coefficients of ribosomal RNA were also identical. Induction of metamorphosis also did not alter the incorporation of (32)P into the different phospholipid constituents of microsomal membranes. 7. Nascent (14)C-labelled protein with the highest specific activity was recovered in the ;heavy' rough membrane fraction of microsomes, whereas little (14)C was associated with ;free' polysomes. Protein synthesis in vivo was most markedly stimulated during metamorphosis in the tightly membrane-bound ribosomal fraction after the appearance of new ribosomes. 8. The rate of synthesis of macromolecules in vivo could not be followed beyond 7-8 days after induction because of variable shifts in precursor pools due to regression of larval tissues. 9. The stimulation of RNA and ribosome formation was specifically associated with the process of metamorphosis since no similar response to thyroid hormones occurred in those species (Axolotl and Necturus) in which the hormones failed to induce metamorphosis.     

Changes in amino acid uptake and protein synthesis of bullfrog tadpole liver and tail tissues during triiodothyronine-induced metamorphosis

The effect of triiodothyronine (T₃′) on the uptake of several amino acids into the amino acid pools and into proteins of Rana catesbeiana tadpole liver and tail muscle and tail fin has been studied. Labeling of the alanine and glycine pool was stimulated in the liver more than the leucine pool. After exposure to T₃ for 3 days, uptake of α-aminoisobutyric acid (a transport model substrate) into liver was stimulated about 55%. In tail tissues uptake of leucine was stimulated but uptake of alanine was depressed by T₃. Incorporation of leucine and alanine into tissue protein was stimulated in the liver but inhibited in tail tissues after T₃ injection.Changes in other macromolecules and ATP and ADP levels in liver and tail muscle were also investigated during induced metamorphosis. In the liver, the total DNA content did not change, but the RNA and protein content per liver increased significantly. The increase in RNA/DNA and protein/DNA ratios, suggested that liver cells underwent hypertrophy during induced metamorphosis. The ATP level showed a transient decrease after 3 days of T₃ treatment. In tail muscle, protein and RNA content decreased as the muscle regressed, but the DNA content and ATP level remained unchanged throughout the experimental period.     

Synthesis and processing of RNA in Lemna: Characterization by gel electrophoresis

The synthesis and processing of rapidly labelled RNAs from Lemnaperpusilla 6746 was followed by polyacrylamide electrophoresis,as the first step in a study of the changes which occur withenvironmental changes. Two RNAs with high apparent molecularweights of 2.8 M and 2.3 M were detected. Time-course studyresults were consistent with the idea that the 2.8 M was cleavedto form 2.3 M RNA and "excess" RNA with a molecular weight of0.5 M. The latter had a far lower turnover than the 2.3 M RNA.Another rapidly labelled RNA which has not been described beforein plants, had an apparent weight of 1.2 M. This was followedby labelling the 1.4 M component, then the light rRNA (0.7 M),and finally the heavy rRNA (1.3 M). A relatively large amountof high molecular weight, polydisperse RNA was synthesized understeadystate conditions. Incubation of plants on distilled water reduced synthesis of1.2 M RNA, while other components were less affected. The processingof rRNA precursors was also slowed. (Received December 11, 1972; )     

Ribosomal RNA metabolism in synchronized plasmacytoma cells

Ribosome synthesis and metabolism has been studied in a plasmacytoma cell line synchronized by isoleucine deprivation. Ribosomal RNA (rRNA) was characterized by gel electrophoresis. The rate of ribosome synthesis (as measured by the appearance of labelled rRNA in the cytoplasm) varied greatly during the cell cycle. It was low during the G l phase, increased rapidly during the S phase, remained high during part of the G 2 phase, and dropped to a minimum during mitosis. A slowdown in the increasing rate of RNA synthesis was observed during the middle of the S phase.No significant decrease in the total nucleotide pool per cell could be observed during the S phase. The accumulation of RNA (as determined by absorbance measurements) was highest during the S and G 2 phases.Pulse labelling of rRNA and pulse chase experiments demonstrated that newly synthesized ribosomal subunits entered into free polysomes to the highest extent during the S phase. The percentage of membrane-bound polysomes of total polysomes increased during the G 1 phase, as did the percentage of labelled rRNA in the membrane-bound fraction.     

Regulation of metamorphosis in ascidians involves NO/cGMP signaling and HSP90

Treatment of larvae of the ascidians Boltenia villosa (Family: Pyuridae) and Cnemidocarpa finmarkiensis (Family: Styelidae) with drugs that inhibit the function of the molecular chaperone HSP90 increased the frequency of tail resorption, the primary morphogenetic event of metamorphosis. If treatment was initiated at hatching, metamorphic events subsequent to tail resorption failed to occur, indicating an ongoing role for HSP90 during morphogenesis. Removal of tails from heads of mature, but not newly hatched larvae, induced metamorphosis of the head. Decapitation experiments indicate that the capacity of tails to shorten in response to inhibition of HSP90 function requires communication with heads. To identify candidate proteins with which HSP90 may interact to regulate metamorphosis, we noted that in mammalian cells, nitric oxide synthase (NOS) interacts with HSP90 and its activity is sensitive to drugs that inhibit HSP90 function. In addition, nitric oxide (NO) signaling in the marine snail Ilyanassa obsoleta is an important regulator of metamorphosis. Inhibition of NOS activity in these ascidian larvae with L-NAME increased the frequency of metamorphosis, consistent with a putative interaction of NOS and HSP90. NOS is present in tail muscle cells, implicating them as targets for the drug treatments, consistent with the decapitation experiments. Inhibition of soluble guanylyl cyclase, the most common effector of NO signaling, also increased the frequency of metamorphosis. In contrast to treatment with anti-HSP90 drugs, metamorphosis induced with L-NAME or ODQ was complete. The results presented suggest that an HSP90-dependent, NO-based regulatory mechanism localized in tails represses ascidian metamorphosis. We discuss these results in relation to the induction of ascidian metamorphosis by several unrelated agents.     

Nucleo-cytoplasmic relationships of high-molecular-weight ribonucleic acid, including polyadenylated species, in the developing rat brain.

The metabolism of high-molecular-weight RNA in the nuclear and cytoplasmic fractions of newborn and adult rat brain was investigated after the intracranial administration of [32P]Pi. In young brain, a considerable proportion of the newly synthesized radioactive RNA is transferred to the cytoplasm, in contrast with the adult brain, where there appears to be a high intranuclear turnover. Electrophoretic analysis of the newly synthesized RNA showed that processing of the rRNA precursor to yield the 28S and 18S rRNA may be more rapid in the adult than in the young, although most of the adult rRNA in the nucleus is not transferred to the cytoplasm. In young brain, processing is probably tightly coupled to transport of rRNA into the cytoplasm, so that 28S and 18S rRNA are not subjected to possible degradation within the nucleus. Polyadenylated RNA turns over in concert with high-molecular-weight RNA in the nuclei of the adult rat brain. In the cytoplasm the polyadenylated RNA has a higher turnover rate relative to rRNA. In the young brain the polyadenylated RNA is transferred to the cytoplasm along with rRNA, although polyadenylated RNA is transported into the cytoplasm at a faster rate. The nuclear and cytoplasmic polyadenylated RNA species of young brain are larger than their corresponding adult counterparts. These results suggest that there are considerable changes in the regulation of the nucleo-cytoplasmic relationship of rRNA and polyadenylated RNA during the transition of the brain from a developing replicative phase to an adult differentiated and non-dividing state.     

Thyroxine-binding proteins in liver and tail of Rana catebeiana undergoing metamorphosis.

Presence of a thyroxine-binding protein was demonstrated in vivo in cell sap of tail and liver of metamorphosing Rana catesbeiana tadpoles. Thyroxine-binding protein was not present in tail of prematamorphic tadpoles while it appeared during progressing metamorphosis roughly coinciding with the beginning of tail resorption. Susceptibility to pronase indicates that this thyroxine-binding macromolecule is protein in nature. Thyroxine-binding in liver was already present during premetamorphic stages and increased further during metamorphosis. A further difference between tail and liver thyroxine-binding protein was evidenced by molecular sieve chromatography on Sephadex G-200 indicating a molecular weight of thyroxine-binding protein in the tail of 60 000 as opposed to 42 000 for liver. Scatchard analysis of tail cell sap of tadpoles in metamorphic climax revealed a high affinity thyroxing binding site (Kd of 2 - 10(-10) M) of low capacity (1.7 pmol per mg protein) while tadpoles in premetamorphic stage had a thyroxine-binding site of lower affinity (9 - 10(-10) M) and higher capacity (4.8 pmol per mg protein). Thus affinity of thyroxine binding is 4-fold in metamorphic climax and appears to reflect the appearance of thyroxine binding observed in vivo.     

Histone metabolism during amphibian metamorphosis. Isolation, characterization, and biosynthesis.

The amino acid incorporation rates of several classes of liver protein from Rana catesbeiana tadpoles were examined at different stages of spontaneous and thyroxine-induced metamorphosis, particular attention being given to histones. Incorporation data were corrected for the specific radioactivity of the free amino acid pools in tadpole liver. Little change was observed in the overall incorporation rates for the crude mitochondrial and total liver proteins during thyroxine treatment or at selected stages of spontaneous metamorphosis, except that the incorporation rates for these proteins were approximately twofold greater for the newly metamorphosed froglet than for the other stages. However, an increase in the ratio of the specific radioactivities of the total and crude mitochondrial liver protein within each set of animals was observed during late stages of spontaneous metamorphosis, as well as during the second through sixth days of thyroxine treatment. The amino acid incorporation rates of the histones for the late metamorphic and froglet stages of spontaneous metamorphosis were three- to fourfold higher than those of premetamorphic animals, but no significant changes were observed during thyroxine treatment. Thyroxine treatment also produced no detectable changes in the relative amounts or incorporation rates of the histone fractions or subfractions. Apparently the developmental changes induced by thyroxine do not involve a reorganization of the histone complement of chromatin at this level of analysis. Furthermore, since histone and DNA syntheses are tightly coupled, our results show that the extensive metabolic changes induced in tadpole liver by thyroxine occur in the absence of significant levels of cell division.     

RNA Synthesis in Division Synchronized Tetrahymena: Macronuclear and Cytoplasmic RNA*

SYNOPSIS. Synthesis of RNA in the macronucleus and appearance of RNA in the cytoplasm were studied in heat synchronized Tetrahymena pyriformis GL and compared to those found under conditions of logarithmic growth (28 C) and during heat shocks (34 C). In macronuclei of logarithmically growing cells precursors were processed to 2 rRNA species (25S and 17S). In addition, another RNA (15S), more homogeneous than the RNA (8-15S) in the cytoplasm, was observed in the macronucleus. Both 17S and 25S rRNA species were found in the cytoplasm, 17S rRNA appearing more rapidly than 25S rRNA. Synthesis of rRNA was suppressed at 34 C in cells subjected to heat synchronization; 8-15S RNA synthesis appeared to be inhibited to a lesser extent. During the time preceding the first synchronized division, the synthesis of rRNAs in the macronucleus slowly recovered. Early in the cycle, almost no newly synthesized rRNAs were extracted. By 30 min after the last heat shock (EH), most of the RNA synthesized was not identified as rRNA. By 60 min after EH, the pattern of RNA synthesis had not returned to that observed in logarithmically growing cells.     

Mobilization of newly synthesized RNAs into polysomes inXenopus laevis embryos

Summary The mobilization of newly synthesized 18S and 28S rRNAs, 4S RNA and poly(A)⁺ RNA into polysomes was studied in isolated cells ofXenopus laevis embryos between cleavage and neurula stages. Throughout these stages, 4S RNA and poly(A)⁺ RNA were mobilized immediately following their appearance in the cytoplasm. 18S rRNA however, stayed in the ribosomal subunit fraction for about 30 min until the 28S rRNA appeared, when the two rRNAs were mobilized together at an equimolar ratio. This mobilization, at a 1:1 molar ratio, appeared to be realized at initiation monome formation. Thus, the efficiency of the mobilization of two newly synthesized rRNAs, shortly after their arrival at the cytoplasm, differed considerably but difference disappeared once steady state was reached.The contribution of newly synthesized 18S and 28S rRNAs to polysomes remains small throughout early development. around 3% of newly synthesized 4S RNA is polysomal which is the same distribution observed for unlabeled 4S RNA. Less than 10% of the newly synthesized cytoplasmic poly(A)⁺ RNA was mobilized into polysomes during cleavage, but in later stages the proportion increased to around 20%–25%. These results show that newly synthesized RNAs are utilized for protein synthesis at characteristic rates soon after they are synthesized during early embryonic development. On the basis of the data presented here and elsewhere we discuss quantitative aspects of the utilization of newly synthesized and maternal RNAs during early embryogenesis.     

Electrophoretic analysis of newly synthesized and stored maternal RNA during oogenesis ofCalliphora erythrocephala (Dipt.)

Summary Ovaries ofC. erythrocephala synthesize large amounts of poly(A)⁺ and poly(A)^– RNA during early and middle stages of oogenesis as shown by labelling with³H-uridine in vivo. After incubation for 1 h, a striking difference in the electrophoretic pattern of newly synthesized labelled poly(A)⁺ RNA and the poly(A)⁺ RNA present in sufficient amounts for optical density measurements (steady state poly(A)⁺ RNA) was observed. During early and mid-oogenesis, in the poly(A)^– RNA fraction, 4S predominantly mature rRNA, 5S RNA and tRNA were labelled. These fractions were no longer synthesized during late oogenesis, whereas poly(A)⁺ RNA was labelled continously During oogenesis stage specific differences in the size distribution of newly synthesized and steady state poly(A)⁺ RNA were not obvious. However, different sizes of labelled poly(A)⁺ RNA species were detected in 0–2h old preblastoderm embryos, after injection of³H-uridine into females either 3–4 days (stage 3–4 of oogenesis) or 24 h before oviposition (stage 5–6 of oogenesis). This difference in RNA synthesis was related to the presence of active nurse cell nuclei. The poly(A)⁺ RNA fraction represents about 2–3% of the total RNA in both ovaries and freshly laid eggs as judged by measurements of optical density and radioactivity bound to oligo(dT). The length of poly(A)-segments in ovarian poly(A)⁺ RNA varied from about 30 to 200 nucleotides.     

The control of ribonucleic acid synthesis in bacteria. The synthesis and stability of ribonucleic acids in relaxed and stringent amino acid auxotrophs of Escherichia coli

The biosynthesis and stability of various RNA fractions was studied in RC(str) and RC(rel) multiple amino acid auxotrophs of Escherichia coli. In conditions of amino acid deprivation, RC(str) mutants were labelled with exogenous nucleotide bases at less than 1% of the rate found in cultures growing normally in supplemented media. Studies by DNA-RNA hybridization and by other methods showed that, during a period of amino acid withdrawal, not more than 60-70% of the labelled RNA formed in RC(str) mutants had the characteristics of mRNA. Evidence was obtained for some degradation of newly formed 16S and 23S rRNA species to heterogeneous material of lower molecular weight. This led to overestimations of the mRNA content of rapidly labelled RNA from such methods as simple examination of sucrose-density-gradient profiles. In RC(rel) strains the absolute and relative rates of synthesis of the various RNA fractions were not greatly affected. However, the stability of about half of the mRNA fraction was increased in RC(rel) strains during amino acid starvation, giving kinetics of mRNA labelling and turnover that were identical with those found in either RC(str) or RC(rel) strains inhibited by high concentrations of chloramphenicol. Coincidence hybridization techniques showed that the mRNA content of amino acid-starved RC(str) auxotrophs was unchanged from that found in normally growing cells. In contrast, RC(rel) strains deprived of amino acids increased their mRNA content about threefold. In such cultures the mRNA content of accumulating newly formed RNA was a constant 16% by wt.     

Retardation of thyroxine-induced metamorphosis by Amphenone B in toad tadpoles

The effect of Amphenone B, an inhibitor of corticoid synthesis, on thyroxine (T4)-induced metamorphosis was studied in toad tadpoles kept in thiourea. Amphenone injections retarded T4-induced tail resorption markedly. The effect of Amphenone was nullified by aldosterone and corticosterone added to the water in which tadpoles were kept. Steroidogenic cells of adrenals in Amphenone-injected animals were enlarged markedly as compared with those in the saline-injected tadpoles or the Amphenone-injected tadpoles which were supplemented with corticoids. The results strongly suggest that endogenous corticoids act together with thyroid hormone to accelerate metamorphosis.     

The hybridization capacity of ribonucleic acid produced during hormone action

1. Measurements of hybridization with homologous DNA were used to assess the nature of the RNA synthesized during hormone action in several systems. 2. When increasing amounts of pulse-labelled rat liver nuclear RNA were annealed with constant amounts of DNA, saturation was not achieved even with RNA/DNA ratios of up to 180:1, which is taken to indicate great diversity in the species of labelled RNA molecules. In the converse experiment, when the DNA/RNA ratio was varied up to 20:1, a plateau of hybridization was observed, and the non-hybridizing RNA is believed to represent chiefly ribosomal and ribosomal precursor species. 3. In the livers of hypophysectomized and thyroidectomized rats treated with growth hormone and tri-iodothyronine, and in whole Xenopus larvae during induced metamorphosis, the synthesis of non-hybridizing RNA was consistently stimulated more than that of hybridizing RNA. This is interpreted as reflecting preferential synthesis of ribosomal RNA in response to these hormones.     

Ribosomal RNA Turnover in Contact Inhibited Cells

CONTACT inhibition of animal cell growth is accompanied by a decreased rate of incorporation of nucleosides into RNA^1–3. Contact inhibited cells, however, transport exogenously-supplied nucleosides more slowly than do rapidly growing cells^4,5, suggesting that the rate of incorporation of isotopically labelled precursors into total cellular RNA may be a poor measure of the absolute rate of RNA synthesis by these cells. Recently, Emerson⁶ determined the actual rates of synthesis of ribosomal RNA (rRNA) and of the rapidly labelled heterogeneous species (HnRNA) by labelling with ³H-adenosine and measuring both the specific activity of the ATP pool and the rate of incorporation of isotope into the various RNA species. He concluded that contact inhibited cells synthesize ribosomal precursor RNA two to four times more slowly than do rapidly growing cells, but that there is little if any reduction in the instantaneous rate of synthesis of HnRNA by the non-growing cells. We have independently reached the same conclusion from simultaneous measurements on the specific radioactivity of the UTP pool and the rate of ³H-uridine incorporation into RNAs (unpublished work of Edlin and myself). However, although synthesis of the 45S precursor to ribosomal RNA is reduced two to four times in contact inhibited cells, the rate of cell multiplication and the rate of rRNA accumulation are reduced ten times. This suggests either “wastage”⁷ of newly synthesized 45S rRNA precursor, or turnover of ribosomes in contact inhibited cells Two lines of evidence suggest that “wastage” of 45S RNA does not play a significant role in this system. (1) The rate of synthesis of 45S RNA in both growing and contact inhibited cells agrees well with that expected from the observed rates of synthesis of 28S and 18S RNAs (unpublished work of Edlin and myself). Emerson has made similar calculations⁶. (2) 45S RNA labelled with a 20 min pulse of ³H-uridine is converted in the presence of actinomycin D to 28S and 18S RNAs with the same efficiency (approximately 50%) in both growing and contact inhibited cells. These results indicate that, in order to maintain a balanced complement of ribosomal RNAs, contact inhibited cells must turn over their ribosomes. We present evidence here that rRNA is stable in rapidly growing chick cells, but begins to turn over with a half-life of approximately 35–45 h as cells approach confluence and become contact inhibited.