Experimental studies on a mutant gene, a, causing albinism in the axolotl, Ambystoma mexicanum.

Axolotls which are homozygous for the gene, a, are true albinos, i.e., they lack completely the ability to synthesize melanin. Previous investigations (C. P. Benjamin, 1970; Develop. Biol.23, 62–85) showed that homogenates of albino embryos or larvae, unlike those of normally pigmented axolotls, are unable to carry out melanin synthesis when supplied with l-dopa. This result showed that tyrosine-dopa oxidase (TDO), the only known enzyme in the melanin pathway, is inactive in albinos. The present investigation has shown that, though the albino lacks TDO activity, the enzyme itself is present and can be activated by proteolytic enzymes. Immune precipitation of TDO from fresh crude skin extracts and comparison of the precipitates on SDS-polyacrylamide gels reveals that the inactive subunits from albino samples are some 8000 daltons larger than the active subunits from wild-type samples. Activation apparently consists of the cleavage of a covalently bound fragment(s) from the proenzyme. Albino skin homogenates also contain a TDO inhibitory factor specific for axolotl TDO. Evidence is presented that suggests that the inhibitor interacts reversibly with the proenzyme and irreversibly with the active form. A model is presented that proposes that, in wild-type axolotls, the A gene is responsible for the normal activity of a TDO activator. In the albino the activator does not function properly and this results in the continued presence of the inhibitor and of the latent form of the enzyme.     

Biosynthesis of collagen and other proteins on tightly and loosely bound polyribosomes from chick embryos]

Free polyribosomes and polyribosomes bound to endoplasmic membranes were isolated from 10-day-old chick embryos by differential centrifugation. The tightly and loosely bound polyribosomal fractions were isolated from the membrane-bound polyribosomes using 0,5 M KCl. The synthesis of collagen and non-collagen proteins on the polyribosomes were studied in a homologous cell-free system. It was shown that the polyribosomes tightly bound to the membranes possess a lower protein-synthesizing activity as compared to free and loosely bound polyribosomes. The amount of bacterial collagenase-cleaved polypeptides in the protein product synthesized on the polyribosomes tightly and loosely bound to the memranes and on free polyribosomes is 31, 23 and 9%, respectively. The data obtained suggest that the loosely bound polyribosomes are actively involved in collagen synthesis and that this fraction is not a contamination of free polyribosomes in the preparations of totally bound polyribosomes. The role of tightly and loosely bound polyribosomes in the formation of the membrane polyribosomal complex is discussed.     

Protein Synthesis in BHK-21 Cells Infected with Semliki Forest Virus

[³H]leucine-labeled proteins synthesized in BHK-21 cells infected with Semliki Forest virus were fractionated by polyacrylamide gel electrophoresis (PAGE). Cellular and virus-specific proteins were identified by difference analysis of the PAGE profiles. The specific activity of intracellular [³H]leucine was determined. Two alterations of protein synthesis, which develop with different time courses, were discerned. (i) In infected cultures an inhibition of overall protein synthesis to about 25% of the protein synthesis in mock-infected cultures develops between about 1 and 4 h postinfection (p.i.). (ii) The relative amount of virus-specific polypeptides versus cellular polypeptides increases after infection. About 80% of the proteins synthesized at 4 h p.i. are cellular proteins. Since significant amounts of nontranslocating ribosomes in polyribosomes were not detected up to 7 h p.i., the inhibition of protein synthesis is not caused by inactivation of about 75% of all polyribosomes but by a decreased protein synthetic activity of the majority of polyribosomes. Indirect evidence indicates that an inhibition of elongation and/or release of protein synthesis develops in infected cells, which is sufficient to account for the observed inhibition of protein synthesis. Inhibition of over-all protein synthesis developed when virus-specific RNA began to accumulate at the maximal rate. This relationship was observed during virus multiplication at 37, 30, and 25 C. A possible mechanism by which synthesis of virus-specific RNA in the cytoplasm could inhibit cellular protein synthesis is discussed. Indirect evidence and analysis of polyribosomal RNA show that the increased synthesis of virus-specific protein is brought about by a substitution of cellular by viral mRNA in the polyribosomes.     

Protein synthesis in BHK-21 cells infected with semliki forest virus.

[3H]leucine-labeled proteins synthesized in BHK-21 cells infected with Semliki Forest virus were fractionated by polyacrylamide gel electrophoresis (PAGE). Cellular and virus-specific proteins were identified by difference analysis of the PAGE profiles. The specific activity of intracellular [3H-A1leucine was determined. Two alterations of protein synthesis, which develop with different time courses, were discerned. (i) In infected cultures an inhibition of overall protein synthesis to about 25% of the protein synthesis in mock-infected cultures develops between about 1 and 4 h postinfection (p.i.). (ii) The relative amount of virus-specific polypeptides versus cellular polypeptides increases after infection. About 80% of the proteins synthesized at 4 h p.i. are cellular proteins. Since significant amounts of nontranslocating robosomes in polyribosomes were not detected up to 7 h p.i., the inhibition of protein synthesis is not caused by inactivation of about 75% of all polyribosomes but by a decreased protein synthetic activity of the majority of polyribosomes. Indirect evidence indicates that an inhibition of elongation and/or release of protein synthesis develops in infected cells, which is sufficient to account for the observed inhibition of protein synthesis. Inhibition of over-all protein synthesis developed when virus-specific RNA began to accumulate at the maximal rate. This relationship was observed during virus multiplication at 37, 30, and 25 C. A possible mechanism by which synthesis of virus-specific RNA in the cytoplasm could inhibit cellular protein synthesis is discussed. Indirect evidence and analysis of polyribosomal RNA show that the increased synthesis of virus-specific protein is brought about by a substitution of cellular by viral mRNA in the polyribosomes.     

Protein synthesis,polyribosomes, and peptide elongation in early development of Strongylocentrotus purpuratus

The absolute rate of protein synthesis in developing embryos of Strongylocentrotus purpuratus has been measured by lysine incorporation. Protein synthesis rises to about 240 pg hr^?1 embryo^?1 from the two- to eight-cell stage, and then gradually increases to a maximum of over 500 pg hr^?1 embryo^?1 in the blastula. The changes in protein synthesis are accompanied by similar increase in the polyribosomes in the embryo, so that 60–65% of the ribosomes are in polyribosomes by the blastula stage. The data are used to calculate an average peptide elongation rate of 1.8 amino acids ribosome^?1 sec^?1.     

A direct effect of some rifamycin derivatives on the morphology of mammalian mitochondria

Protein synthesis has been investigated in cell-free preparations from mature ovarian oocytes, unfertilized and fertilized eggs, and early embryos of Drosophila melanogaster. Preparations from unfertilized eggs have a specific activity that is 5- to 6-fold higher than the activity of fractions from ovarian oocytes. There is an additional small increase in activity of preparations from fertilized eggs. The specific activity that is rapidly attained in the fertilized egg remains essentially constant for 2 to 2.5 h after fertilization, decreases sharply during blastoderm formation, and again increases during gastrulation. The activities of unfertilized eggs decline slightly during the first 2 h after oviposition, and then decrease more sharply. About 35 % of the ribosomes in preparations from both unfertilized and fertilized eggs sediment in the polyribosome region of sucrose density gradients, whereas no polyribosomes could be detected in preparations from ovarian oocytes. In both ovarian oocytes and fertilized eggs, less than 1 % of the ribosome populations were present as subunits. Additional ribonucleoprotein material of buoyant densities different from those of ribosomal subunits or ribosomes was found throughout the sucrose gradients. About 3.5 % of the ribosomes were found to be membrane-bound in preparations from both unfertilized and fertilized eggs.     

The synthesis and activity of tyrosinase during development of the frog Rana pipiens

We have established by radioimmunoprecipitation that tyrosine-DOPA oxidase (TDO, tyrosinase) [EC 1.14.18.1] is first synthesized by frog embryos at the early neurula stage soon after embryonic induction of the neural plate by the underlying chordamesoderm. The DOPA moiety of the enzyme, at the time of its first appearance, is almost inactive enzymatically and can be activated by mild proteolysis (with trypsin). A very large increase in the amount of active DOPA oxidizing enzyme (without trypsinization) is observed at hatching (stage 21), and this is accompanied by melanin deposition in pigment cells. The tyrosine moiety of the enzyme is also partially inactive at the time of first synthesis, but the ratio of active to inactive enzyme remains approximately constant throughout early development. DOPA decarboxylase enzymatic activity is first detected at neurula stage, and this activity is accompanied by the first appearance of catechol amines.     

THE EFFECT OF PROTEIN SYNTHESIS INHIBITION ON THE ENTRY OF MESSENGER RNA INTO THE CYTOPLASM OF SEA URCHIN EMBRYOS

Emetine is a potent inhibitor of protein synthesis in sea urchin embryos. At a concentration of the drug that rapidly inhibits protein synthesis in blastulae by 95%, uridine incorporation into RNA continues for more than 1 hr and presumptive histone messenger RNA is synthesized and transported into the cytoplasm where it is apparently associated with polyribosomes. Possible explanations of this result and its implications for the "informasome" theory of messenger transport in embryonic cells are discussed.     

Polyribosome formation and poly(A)-containing RNA in embryos of the sand dollar,Dendraster excentricus

Summary The pattern of appearance of ribosomes, newly synthesized mRNA, and poly(A)-containing mRNA in polyribosomes has been examined in sand dollar embryos. From early blastula until shortly before hatching small polyribosomes engaged in histone synthesis predominate. At the time of hatching, when the rate of cell increase is maximal, the proportion of poly(A)-containing RNA in polyribosomes is low. After hatching a new class of large polyribosomes appears and the amount of poly(A)-containing polyribosomal RNA increases. Cordycepin, an inhibitor of RNA adenylylation, prevents the appearance of the large polyribosomes after hatching as well as the increase in poly(A)-containing polyribosomal RNA.     

Autoregulation of tubulin expression is achieved through specific degradation of polysomal tubulin mRNAs

We have utilized protein synthesis inhibitors to investigate the autoregulatory mechanism that uses the concentration of unpolymerized tubulin subunits to specify tubulin mRNA content in animal cells. Puromycin and pactamycin, both of which remove RNAs from polysomes, completely unlink tubulin RNA content from the level of free subunits, whereas pretreatment of cells with cycloheximide, which traps mRNAs onto stalled polyribosomes, enhances the specific degradation of tubulin RNAs in response to increases in the subunit content. Moreover, in the absence of protein synthesis inhibitors, the tubulin RNAs that are lost from cells with elevated free tubulin subunit levels are those that are associated with polyribosomes. Further, beta-tubulin mRNAs encoding a truncated translation product of only 26 amino acids (and that cannot be polyribosomal) are not substrates for autoregulation. We conclude that autoregulation of tubulin synthesis is achieved by specifically altering the stability of tubulin RNAs that are bound to polyribosomes.     

Melanogenesis in oocytes of wild-type and mutant albino axolotls

Melanogenesis during oogenesis in the wild-type and albino (a/a) axolotl was compared. Tyrosine-dopa oxidase activity, melanin accumulation, and melanosome development were correlated and the effect of the a gene on these biochemical and morphological events was examined. Studies of wild-type oocytes at the electron and light microscope level revealed that premelanosomes first appear in stage 2 oocytes. Mature melanosomes are present in stage 3 oocytes and steadily increase in number, reaching a maximum level in stage 6 oocytes. Melanosomes were detected in the albino. No obvious structural abnormalities were observed in these organelles, although they fail to accumulate melanin. Tyrosine-dopa oxidase (TDO) activity assayed radiometrically is at a very low level in stages 1 and 2 oocytes, reaches a maximum level in stage 3 oocytes, and declines to zero activity in stage 6 oocytes. In contrast to the finding with albino skin homogenates (Harsa-King, 1978), TDO activity was detected in albino oocytes. This activity never declined from its maximal stage 3 level. The addition of an inhibitor of proteolytic enzymes, phenylmethyl sulfonyl fluoride (PMSF), to the oocyte homogenization buffer completely blocks TDO activity in albino samples and reduces it somewhat in wild-type samples. It is suggested that TDO activity eliminated by PMSF represents TDO existing in an inactive form in vivo which is activated by proteolytic enzymes released upon homogenization. These results suggest that TDO is found only in an inactive state in albinos, a conclusion in agreement with the earlier work on albino skin melanocytes (Harsa-King, 1978). There is an inverse relationship between TDO activity and melanization in the wild type. The greater the amount of melanin deposited within the premelanosomes, the less enzyme activity is present. It is suggested, as it has been by others, that as melanin is synthesized within the confines of the oocyte melanosome, the active sites of the enzyme are covered up, resulting in its inactivation. The findings with the albino mutant support this hypothesis. No melanin deposition occurs in the albino, and TDO activity in PMSF-untreated samples does not decline from its maximal stage 3 level.     

The cytoskeletal framework of sea urchin eggs and embryos: developmental changes in the association of messenger RNA

Extraction of sea urchin eggs and embryos with Triton X-100 generated a cytoskeletal framework (CSK) composed of a cortical filamentous network and an internal system of filaments associated with ribosomes. The CSK contained only 10-20% of the cellular protein, RNA, and lipid. A specific subset of proteins was enriched in the CSK. Several lines of evidence suggest that mRNA is a component of the CSK of both eggs and embryos. First, the CSK contained poly(A) sequences which hybridized with [3H]poly(U). Second, the CSK contained polyribosomes. Finally, RNA extracted from the CSK showed translational activity in an in vitro system. The nonhistone messages present in the CSK were qualitatively similar to those solubilized by detergent, as determined by separation on polyacrylamide gels of the products of in vitro translation. In the unfertilized egg, most mRNA was present as nonpolyribosomal messenger ribonucleoprotein complexes which, along with monoribosomes, were efficiently extracted by Triton X-100. The converse was found in blastulae, as most of the mRNA was present as polyribosomes associated with the CSK, although monoribosomes were still efficiently extracted by detergent. These results indicate a correlation between the activation of protein synthesis in eggs and the association of polyribosomes with the CSK.     

Quantitative measurement by microdensitometry of tyrosinase (Dopa oxidase) development in whole small ascidian embryos

Summary Embryos of the ascidian, Ciona intestinalis, were fixed in either cold (5° C) 70% ethanol or cold absolute methanol during their tyrosinase development phase and incubated in buffered (pH 7.2) solutions of the enzyme substrate l-dihydroxyphenylalanine. Optical density of the reaction product (melanin) was measured in the whole small embryos at 450 nm with a Vickers M85 scanning and integrating microdensitometer. The frequency distribution of the reaction density in embryos of a population was Gaussian, and the mean optical density in embryo samples (N=25) increased linearly with incubation time when a saturation level of substrate was used. Absolute optical density units of dopa oxidase activity in embryos increased linearly in proportion to the development time preceding melanin granulogenesis thereby suggesting that the enzyme activity measured by this procedure is proportional to the amount of tyrosinase present. Since this developmental increase in activity was blocked by treatment of the embryos with puromycin, an inhibitor of protein synthesis, the change is apparently caused by new enzyme synthesis. The microdensitometry assay also confirmed results obtained previously with a radiometric assay: embryos cleavage-inhibited at 7 h development time with cytochalasin B to produce giant melanocytes developed only the same amount of enzyme activity as control embryos.     

Endosperms and embryos of mature dry castor bean seeds contain active ribosomes

Mature dry endosperms and embryos of castor bean contain ribosomes which are capable of catalysing protein synthesis in vitro. This observation contradicts previous reports that ribosomes are absent from mature dry endosperms. On hydration of the mature seeds the polyribosome content of both embryos and endosperms increases. These polyribosomes are lost on subsequent dehydration but, again, ribosomes are conserved. REFERENCES     

Induction of glycolate oxidase by SO2 in Nicotiana tabacum

In contrast to the inhibitory action of sulfite on glycolate oxidase, the specific activity of the enzyme in tobacco leaves exposed to SO₂ for 18 hr increases in proportion to the SO₂ concentration. This increase is strongly reduced by pretreatment with cycloheximide. As a consequence of induced de novo synthesis of glycolate oxidase the glycolate content of the leaves is markedly reduced after 18 hr exposure to SO₂.     

The pathway of betalain biosynthesis: Effect of cytokinin on enzymic oxidation and hydroxylation of tyrosine in Amaranthus tricolor seedlings

The effect of exogenously added tyrosine or l -3-(3,4-dihydroxyphenyl) alanine on the accumulation of betacyanin in response to cytokinin in Amaranthus tricolor (L.) var. tricolor half-seedlings depends on the age of the seedlings and the treatment of the seedlings prior to induction of pigment by benzyladenine. Neither extracted polyphenol oxidase, peroxidase or tyrosine hydroxylase activity, nor in vivo tyrosine hydroxylation is increased in response to exposure of seedlings to cytokinin. However a small percentage of the polyphenol oxidase activated or unmasked by Triton X-100 treatment of membrane fractions is increased after cytokinin treatment of half-seedlings for 22 h. It is concluded that cytokinin control may be on a multi-enzyme membrane-located complex involving part of the polyphenol oxidase activity of the tissue (possibly an isoenzyme), and that the majority of the polyphenol oxidase activity in Amaranthus is a constitutive membrane enzyme which is not involved in betacyanin synthesis. Although cytokinins do not affect in vivo tyrosine hydroxylation, this activity follows closely the accumulation of betacyanin which is first detectable about 6.5 h after the application of cytokinin. Only a very low level of in vivo hydroxylation can be demonstrated in half-seedlings treated for 6 h either with or without cytokinin but it begins to increase shortly after this time. A large increase in this activity by 16 h (independent of cytokinin) can be almost completely (79%) prevented by chloramphenicol (300 μM) although the drug increases accumulation of betacyanin. At this concentration about 30% of the protein synthesis in inhibited. In vitro tyrosine hydroxylation is, however, not reduced in half-seedlings treated with chloramphenicol during 16 h induction nor is extractable polyphenol oxidase reduced. It is concluded that chloramphenicol is inhibiting the synthesis of some protein essential for in vivo hydroxylation other than the activity measured during in vitro hydroxylation and that the inhibition of synthesis of 79% in vivo hydroxylation still leaves enough activity for maximum betacyanin synthesis.     

Fluctuations of DNA-dependent RNA polymerase and synthesis of macromolecules during the growth cycle of Novikoff rat hepatoma cells in suspension culture

The transition of suspension cultures of Novikoff rat hepatoma cells from the exponential to the stationary phase is accompanied by decreases of over 90% in the rates of synthesis of RNA, DNA and protein, a 90% loss of the apparent DNA-dependent RNA polymerase activity of the cells, and a disaggregation of the polyribosomes with a concomitant accumulation of 80 S and 110 S ribosomal structures. The cells also attain a minimum content of DNA, RNA and protein and a minimum size. Upon dilution of stationary phase cultures with fresh medium, the rate of protein synthesis begins to increase immediately and this correlates with a rapid reformation of the polyribosomes. The initial re-formation of polyribosomes is little affected by the presence of actinomycin D. RNA polymerase activity also begins to increase immediately after dilution and an increase in rate of RNA synthesis becomes apparent shortly thereafter. The increase in polymerase activity is inhibited by treating the cells with puromycin or actidione. Cell division commences only 9–13 hours after dilution and the rate of DNA synthesis begins to increase about midway through the lag period. During the lag period the average cellular content of protein increases about 80% and that of RNA and DNA about 30%. These increases are accompanied by a marked increase in the average size of the cells. Upon continued incubation of stationary phase cultures, the cells become irreversibly damaged physiologically before gross morphological damage becomes apparent. The irreversible physiological damage is recognized by the fact that the cells fail to recover when suspended in fresh medium.     

Regulation of alcohol oxidase synthesis in Hansenula polymorpha: Oversynthesis during growth on mixed substrates and induction by methanol

The regulation of the synthesis of alcohol oxidase, catalase, formaldehyde dehydrogenase and formate dehydrogenase was investigated in the methanol-utilizing yeast Hansenula polymorpha. The organism was found to synthesize immunologically identical alcohol oxidases during growth on glycerol and methanol. Growth on glycerol, however, was not dependent on the alcohol oxidase, as was shown with a mutant without alcohol oxidase protein. Similarly it was shown with a catalase activity negative mutant that high catalase activity during growth on glycerol was not a prerequisite for the utilization of this substrate, though absolutely required for growth on methanol.Experiments were conducted with mixed substrates to study the influence of methanol on alcohol oxidase synthesis. In batch cultures, growth on ribose plus methanol resulted in an enhanced rate of alcohol oxidase synthesis as compared to ribose alone. In continuous cultures, (D=0.1 h^-1) addition of methanol to glycerol-, glucose-, or sorbose-limited cultures gave rise to increased alcohol oxidase activity of up to 20 U/mg, which is about by 2 times higher than the specific activity used for growth on methanol alone. The increase in specific activity of the dissimilatory enzymes on the mixed substrates is partly due to methanol per se, as was shown by a mutant unable to dissimilate or assimilate methanol.