Translational control of the circadian rhythm of liver sterol carrier protein

Rat liver sterol carrier protein (SCP), a major regulator of lipid metabolism and transport, undergoes a rapid turnover and dramatic circadian variation in amount. The level of SCP was quantitated by a specific immunochemical assay using an antibody to homogeneous liver SCP. During a 12-h dark, 12-h light cycle, liver exhibits a biphasic pattern in SCP level. A 7-fold increase in SCP (i.e. from 1 to 7 mg/g of liver) occurs in the dark period, peaking at the midpoint and returning to basal levels by the beginning of the light period. A similar but smaller pattern of variation in SCP amount occurs in the light cycle. To elucidate the basic mechanism responsible for these changes in SCP level, the relative synthetic rate of SCP and mRNA functional activity for SCP were measured during the dark-light cycle. Alterations in the rate of SCP synthesis can account for the variations in SCP concentration. Although large changes occur in relative synthetic rate, no significant changes were found in the level of mRNA for SCP. Therefore, the circadian rhythm in SCP synthesis and amount does not reflect variations in the concentration of mRNA for SCP, but instead is caused by some mechanism controlling the efficiency of translation of SCP mRNA.     

Hormonal triggering of the diurnal variation of sterol carrier protein

Rat liver sterol carrier protein (SCP) is a major intracellular protein regulating lipid metabolism and transport. During a dark-light cycle, SCP undergoes a dramatic diurnal variation in synthesis and level, reflecting translational events. Several hormones participate in the control of SCP synthesis. Insulin was implicated when the circadian rhythm of SCP was lost in both diabetes and fasting, states where insulin is low. After a 12-h fast the amplitude of the diurnal rhythm is diminished; after a 48-h fast it disappears, although SCP synthesis and level remain high. When endogenous insulin secretion is increased in fasted rats by glucose administration, SCP increases 2-fold in less than 30 min. When food intake is manipulated, but the dark-light cycle is unchanged, the circadian rhythm of SCP corresponds to feeding patterns and not light cycling. During feeding, increases in SCP are triggered following the expected increase in serum insulin. However, SCP is rapidly and significantly elevated in response to insulin only when glucocorticoids are normally high or increased by injection of the synthetic glucocorticoid, dexamethasone. Hepatocyte SCP levels are also induced by a combination of insulin and dexamethasone (2.3-fold) or insulin alone (1.3-fold). Dexamethasone alone causes a striking depression of SCP (2.4-fold). Thus, insulin is a major regulator of the diurnal variation of SCP synthesis. Glucocorticoids and other hormones (e.g. triiodothyronine) are also essential for maximum induction of SCP but play permissive roles.     

Translation of an mRNA in rat L6 muscle cells is regulated within the cell cycle

In muscle cells two populations of mRNA are present in the cytoplasm. The majority of mRNA is associated with ribosomes and active in protein synthesis. A small population of cytoplasmic mRNA occur as free mRNA-protein complex and is not associated with ribosomes. This apparently repressed population of mRNA from rat L6 myoblast cells was used to construct a cDNA library. Radioactively labeled cDNA preparations of polysomal and free (or repressed) mRNA populations showed that at least ten recombinant clones preferentially annealed to the cDNA from repressed mRNA. One of these clones was extensively studied. The DNA from a recombinant plasmid D12 hybridized to a 1.3-kb poly(A)-rich mRNA. In proliferating myoblast cells, the 1.3-kb mRNA was more abundant in the polysomal fraction and mostly free in the non-dividing myotubes. In contrast to this mRNA, 90% of alpha and beta actin mRNAs were translated in both myoblasts and myotubes. Further analysis of distribution of the 1.3-kb RNA in the polysomal (active) and free (repressed) fractions in fusion-arrested postmitotic myotubes suggested that fusion of myoblasts was not necessary for the control of translation of this mRNA. Withdrawal of muscle cells from the cell cycle appeared to be involved in regulating translation of this mRNA. The presence of this mRNA was not, however, limited to muscle cells. This mRNA was also present in the repressed state in rat liver and kidney cells. These results, therefore, suggest that the 1.3-kb mRNA is probably translated during a particular phase of the cell cycle and is not translated in terminally differentiated non-dividing cells. Messenger RNA homologous to the 600-base-pair insert of the recombinant plasmid D12 was isolated by hybrid selection procedure from both polysomal mRNA of myoblasts and free mRNA of myotubes. Translation of the hybrid selected mRNAs from both myoblasts and myotubes in rabbit reticulocyte lysate cell-free system synthesized a 40-kDa polypeptide. These results suggest that the repressed population of 1.3-kb mRNA can be translated in vitro. The hybridization pattern of DNA from the recombinant plasmid D12 with rat genomic DNA suggested that the 1.3-kb mRNA is derived from moderately repetitive rat DNA with a repetition frequency of approximately 100 copies per haploid genome.     

alpha-Fetoprotein biosynthesis and hepatocellular differentiation

In anemia of the Belgrade rat ($\text{b}\text{b}$) reticulocytes contain less than half of the normal amount of mRNA for seven adult rat globin chains. cDNA hybridization measurements of the relative sizes of polysomal and nonpolysomal pools of globin mRNAs in these cells show that 45% of all globin mRNA molecules are not used at any given time in protein synthesis. This implies a translational control which ensures a production of globin chains in a correct ratio despite a severe mRNA unbalance.     

Characterization of a cDNA encoding rat sterol carrier protein2

Sterol carrier protein2 (SCP2) is a 13.2-kD protein that is thought to be involved in the intracellular transport of cholesterol. Using synthetic oligonucleotides based on the protein sequence of SCP2, a clone (SP43) was isolated from a rat liver cDNA library. The DNA sequence revealed that the cDNA could encode a polypeptide of 273 amino acids (28.9 kD) or 143 amino acids (15.3 kD) in which the carboxy-terminal 123 amino acids are identical to the SCP2 protein. RNA blot hybridization revealed that a variety of rat tissues contain a homologous RNA of a size similar to SP43 (approximately 1.5 kb). Levels of SCP2 mRNA increased in parallel with cytochrome P450scc mRNA in the immature gonadotropin-primed rat ovary. The isolation of a cDNA clone encoding SCP2 will facilitate studies on its role in cholesterol metabolism.     

Cell-free synthesis of rat liver zinc-thioneins.

The induction of rat liver zinc-thioneins mRNA was studied in a wheat germ cell-free translation system. Liver poly A rich polysomal RNA was isolated from rats which had been injected with zinc sulfate 5 h previously. These RNA preparations stimulated the incorporation of [35S]cystine into trichloroacetic acid insoluble proteins when assayed in the cell-free synthetic system. The translation products were characterized by Sephadex G-75 chromatography in 8 M urea--50 mM beta-mercaptoethanol, by disc gel electrophoresis in 4 M area--Tris-glycine buffer (pH 9.2), and by peptide fingerprinting with pepsin. These results were identical with authentic rat liver zinc-thioneins. The zinc-thioneins mRNA activity in the control rats, however, was minimal. The stimulation in zinc-thioneins synthesis observed in the cell-free synthesis was similar to the increased synthesis of these polypeptides in vivo.     

Changes in expression of albumin and alpha-fetoprotein genes during rat liver development and neoplasia.

Albumin mRNA was isolated and purified from rat liver polysomes by a combination of immunoprecipitation of specific polysomes, poly(U)-Sepharose 4B chromatography, and fractionation of the resulting poly(A)-containing RNA on a sucrose gradient. alpha-Fetoprotein (AFP) mRNA was isolated from Morris hepatoma 7777 by a similar procedure. The purity of the mRNA preparations was determined by analytical gel electrophoresis under denaturing conditions, analysis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the polypeptides synthesized in a wheat germ cell-free system, and the kinetics of hybridization to cDNA transcribed from albumin mRNA and AFP mRNA. The albumin mRNA possessed a chain length of approximately 2265 nucleotides and the AFP mRNA possesed a length of approximately 2235 nucleotides when examined under stringent denaturing conditions on agarose gels containing 10 mM methylmercury hydroxide. Analysis of poly(A) content by a hybridization assay with [3H]poly(U) revealed the presence in albumin mRNA of a poly(A) region containing approximately 100 adenosine residues. The AFP mRNA preparation was found to contain an average poly(A) tract of approximately 190 bases. Thus, albumin mRNA appears to contain approximately 330 untranslated nucleotides, and AFP mRNA appears to contain a similar number (approximately 285) of noncoding, nonpoly(A) bases. The purified albumin and AFP mRNA's were used as templates for synthesis of full-length cDNA hybridization probes. Both of the probes selectively hybridized to their templates with kinetics expected for single RNA species the sizes of albumin and AFP mRNA. ROt analysis was used to quantitate albumin and AFP mRNA sequences during normal liver postnatal development and liver oncogenesis. The number of polysomal AFP mRNA molecules per liver was found to drastically decrease during the first weeks of postnatal life, concomitant with a decline in the AFP synthetic capacity of the livers and in the serum concentrations of AFP. During this period, the concentration of albumin mRNA molecules per cell in the liver remained at high, approximately constant levels. In Morris hepatoma 7777, the concentration of AFP-specifying sequences was at least 10(3)-fold higher than that found in normal adult liver, whereas the content of albumin nRNA was four- to five-fold lower. These changes in concentration of albumin and AFP mRNA sequences closely correlated with a parallel variation in the specific protein synthetic capacity of the tissues.     

Mouse kidney nonpolysomal messenger ribonucleic acid: metabolism, coding function, and translational activity

To elucidate the distribution and function of mRNA in mouse kidney cytoplasm, we compared mRNA isolated from polysomal (greater than 80S) and native postpolysomal (20--80S) ribonucleoproteins with respect to synthesis and lifetime, sequence content, and translational activity. The 20--25% of cytoplasmic mRNA recovered from postpolysomal ribonucleoprotein is similar to polysomal mRNA in size (20--22S), in apparent half-life (11--13 h), in major products of cell-free translation, and in nucleotide complexity (approximately 4 x 10(7) nucleotides). The labeling kinetics of polysomal and postpolysomal mRNA suggest these mRNA populations are in equilibrium. [3H]cDNAs transcribed from polysomal and from postpolysomal poly(A)-containing mRNAs react with template mRNA and with the heterologous mRNA at the same rate (Cot1/2 approximately 6.3 mol.s/L) and to the same extent (95%). Therefore, these mRNAs are equally diverse and homologous and occur at similar relative frequencies. Postpolysomal mRNA directs cell-free protein synthesis at only approximately 30% of the rate of polysomal mRNA and to only 30% of the extent of mRNA from polysomes. Postpolysomal mRNA is approximately 3-fold less sensitive than polysomal mRNA to inhibition of translation by m7GMP, suggesting postpolysomal mRNA contains a greater fraction of molecules deficient in 5'-terminal caps. Postpolysomal mRNA may derive from renal mRNAs that initiate translation inefficiently and thus accumulate as postpolysomal ribonucleoproteins.     

Comparison of complexity and diversity of polyadenylated polysomal and informosomal messenger ribonucleic acid from Chinese hamster cells.

The sequence complexity and relative abundance of cytoplasmic polyadenylated polysomal (ribosome-bound) mRNA and cytoplasmic polyadenylated informosomal (ribosome-free) mRNA were analyzed in exponentially growing Chinese hamster cells (line CHO) using the technique of cDNA hybridization to excess poly(A)+ mRNA. Polysomal and informosomal mRNAs had similar complexities ( approximately 8300 mRNA species), but both the fraction of mRNA and the number of sequences comprising the mRNA abundance classes were different. Heterologous annealing reactions showed that all of the mRNA sequences detected were shared by the polysomal and informosomal mRNAs. However, the most abundant informosomal mRNA component was considerably different from the most abundant polysomal mRNA component. For a more detailed analysis, cDNA complementary to the most abundant informosomal and polysomal mRNAs was isolated. By use of the fractionated cDNA, it could be demonstrated that the most abundant informosomal mRNA sequences were distributed in the polysomal mRNA with an approximately fivefold reduction in relative frequency. These results are not compatible with models postulating translational control of gene expression by the complete sequestering of some mRNA sequences in an untranslatable form in the cytoplasm. The data are, however, consistent with models encompassing differential rates of initiation on the polysome and/or preferential affinity of some mRNAs for initiation factors.     

Reduction of prostatic binding protein-messenger ribonucleic acid sequences in rat prostate by castration

Messenger RNA coding for the three subunits of prostatic binding protein was isolated from polysomal RNA of rat ventral prostate by oligo (dT)-cellulose affinity chromatography and purified by repeated sedimentations through sucrose gradients under denaturing conditions. The purified mRNA migrated as a 9S peak in sucrose gradient centrifugation and hybridized with its cDNA within 2 log Rot units. In a cell-free reticulocyte lysate system, the mRNA directed the synthesis of three polypeptides of 12000, 9000, and 8000 daltons. These translation products were identified as the subunits of prostatic binding protein by immunoreaction with antibodies to this protein. Quantitation of prostatic binding protein-mRNA sequences in normal and castrated rats by hybridization with the cDNA probe showed that 3-day castration reduced the prostatic binding protein-mRNA sequences to less than 2% of the normal level. Similar hybridization was performed by using the cDNA to determine the level of prostatic binding protein coding sequences in polysomal poly(A) RNA following castration. The results showed a first-order rate constant of 3.92 X 10-2 h-1 for reduction of prostatic binding protein-mRNA sequences in polysomes. The period of castration required to reduce the level of these sequences to 50% of the normal level was calculated to be 17.6 h.     

Cell-free synthesis of ornithine decarboxylase. Changes in mRNA activity in the liver of thioacetamide-treated rats

Ornithine decarboxylase (ODC)mRNA associated with free polysomes of rat liver was translated in a reticulocyte lysate cell-free system. Newly synthesized ODC protein was identified by specific immunoprecipitation, molecular size as determined by polyacrylamide gel electrophoresis with sodium dodecyl sulfate, and competition by excess unlabeled ODC in the immunoprecipitation. A single injection of thioacetamide was found to cause several fold increases in both immunotitratable ODC protein and polysomal ODC-mRNA activity, while it provoked a much larger increase in ODC activity in rat liver. The results indicate that the induction of hepatic ODC activity by thioacetamide treatment is due not only to an increase in the activity of polysomal ODC-mRNA but also to a translational and/or posttranslational control.     

Role of sterol carrier protein in cholesterol metabolism

This report summarizes our recent studies on the protein known as sterol carrier protein (SCP) or fatty acid binding protein (FABP). SCP is a highly abundant, ubiquitous protein with multifunctional roles in the regulation of lipid metabolism and transport. SCP in vitro activates membrane-bound enzymes catalyzing cholesterol synthesis and metabolism, as well as those catalyzing long chain fatty acid metabolism. SCP also binds cholesterol and fatty acids with high affinity and rapidly penetrates cholesterol containing model membranes. Studies in vivo showed SCP undergoes a remarkable diurnal cycle in level and synthesis, induced by hormones and regulated in liver by translational events. SCP rapidly responds in vivo to physiological events and manipulations affecting lipid metabolism by changes in level. Thus SCP appears to be an important regulator of lipid metabolism. Preliminary evidence is presented that SCP is secreted by liver and intestine into blood and then taken up by tissues requiring SCP but incapable of adequate SCP synthesis.     

Synthesis and transport of the precursor for the beta-subunit of rat liver F1-ATPase

The synthesis and intracellular transport of the beta-subunit of rat liver F1-ATPase was studied in a cell-free system, using free polysomal mRNA from rat liver and isolated rat hepatocytes. The beta-subunit of rat liver F1-ATPase is synthesized as a larger precursor form in rabbit reticulocyte lysate and then transported into isolated mitochondria in the absence of protein synthesis. In pulse experiments at 37 degrees C, the precursor of the beta-subunit reached a plateau 30 min after the pulse. The labeled mature beta-subunit appeared in the particulate fraction (containing mitochondria) after a time lag and increased almost linearly with time up to 40 min.