The chicken thymidine kinase gene is transcriptionally repressed during terminal differentiation: the associated decline in TK mRNA cannot account fully for the disappearance of TK enzyme activity

Regulation of the expression of enzymes involved in the replication of DNA in chemically-induced granulocytic differentiation of HL-60 leukemia cells

The expression of seven enzymes involved in the biosynthesis of DNA was measured in HL-60 promyelocytic leukemia cells treated with dimethylsulfoxide (DMSO) or all-trans retinoic acid (RA) to gain information on their role in the termination of proliferation in cells undergoing granulocytic differentiation. The steady-state levels of the mRNAs for topoisomerase I, topoisomerase II. DNA polymerase-alpha, thymidylate synthase, thymidine kinase and hypoxanthine-guanine phosphoribosyltransferase progressively declined from day 3 to day 7 of exposure to the polar solvent or the retinoid suggesting that the expression of these enzymes is coordinately regulated. In contrast, a pronounced difference between the two inducers of differentiation occurred in the expression of the mRNA of the M2 subunit of ribonucleotide reductase, with DMSO causing virtually complete inhibition of the expression of the M2 subunit of the enzyme from day 5 through day 7, with no change in the steady-state levels of the mRNA being produced by retinoic acid. Measurement of the enzymatic activities of two of these catalysts, thymidylate synthase and thymidine kinase, in cells exposed to the two inducers of maturation corroborated the findings at the level of the mRNAs, with corresponding decreases in the activity of these enzymes. The findings collectively demonstrate that the down-regulation of the expression of a relatively wide variety of enzymes involved in DNA replication occurs as late events in the granulocytic differentiation of HL-60 cells, ensuring that cellular replication cannot occur in terminally differentiated cells.

Regulation of the expression of enzymes involved in the replication of DNA in chemically induced monocytic/macrophagic differentiation of HL-60 leukemia cells

The expression of a number of housekeeping enzymes of DNA biosynthesis was measured in HL-60 promyelocytic leukemia cells undergoing monocytic/macrophagic differentiation following treatment with 12-O-tetradecanoylphorbol 13-acetate (TPA) or 1alpha,25-dihydroxyvitamin D3 (vitamin D3). Progressive decreases in the steady-state levels of the mRNAs for thymidylate synthase, topoisomerase II, and hypoxanthine guanine phosphoribosyltransferase occurred following exposure to TPA or vitamin D3. In contrast, the steady-state levels of the mRNAs for thymidine kinase, topoisomerase I, and DNA polymerase-alpha did not decrease until days 3-5 of treatment with vitamin D3 and then progressively declined thereafter. The mRNAs for thymidine kinase and topoisomerase I decreased slightly and the mRNA for DNA polymerase-alpha by 30-40%, and then remained constant between days 1 to 3 of treatment with the phorbol ester. The M2 subunit of ribonucleotide reductase exhibited an even greater difference, with no change in the steady-state concentration of mRNA over 3 days of exposure to TPA or vitamin D3. On days 5-7 of treatment with vitamin D3, essentially complete loss of the expression of the mRNA for the M2 subunit of ribonucleotide reductase occurred. Measurement of the enzymatic activities of thymidylate synthase and thymidine kinase in cells exposed to either of the inducers of maturation corroborated the findings at the level of the mRNAs, with corresponding decreases in the activity of these enzymes. The results indicate that the down-regulation of the expression of housekeeping enzymes of DNA replication occurs as late events in HL-60 cells undergoing monocytic/macrophagic differentiation, implying that the decreases in their gene expression are the result of the termination of proliferation rather than an initiating event in the cessation of DNA biosynthesis.

Mammalian BUB1 protein kinases: map positions and in vivo expression

The spindle assembly checkpoint modulates the timing of anaphase initiation in mitotic cells containing improperly aligned chromosomes and increases the probability of successful delivery of a euploid chromosome set to each daughter cell. We have characterized cDNA sequences from several organisms with highly significant predicted protein sequence homologies to Saccharomyces cerevisiae Bub1p, a protein required for function of the spindle assembly checkpoint in budding yeast. The localization of mouse and human orthologs is in agreement with known conservation of synteny. Mouse backcross mapping data indicate that the murine gene resides on chromosome 2 near IL1A, 73 cM from the mouse centromere. Radiation hybrid mapping data indicate that the human locus exhibits linkage to microsatellite marker D2S176, which is located within 10 cM of human IL1A. Multiple-tissue Northern analysis indicates conservation of expression pattern in mouse and human with markedly high mRNA levels in testis. Northern analysis of two different spindle assembly checkpoint protein gene products from human, BUB1 and MAD2, reveals an expression pattern with common tissue distribution consistent with roles in a common pathway. In addition, we demonstrate that an mRNA found to accumulate in a rat fibroblast cell transformation system encodes rat BUB1, and we find that rat BUB1 mRNA accumulation correlates with the proliferation status of cells in culture.

Spermatid-specific overexpression of the TATA-binding protein gene involves recruitment of two potent testis-specific promoters

The gene encoding the TATA-binding protein, TBP, is highly overexpressed during the haploid stages of spermatogenesis in rodents. RNase protection analyses for mRNAs containing the previously identified first, second, and eighth exons suggested that most TBP mRNAs in testis did not initiate at the first exon used in somatic cells (here designated exon 1C). Using a sensitive ligation-mediated cDNA amplification method, 5' end variants of TBP mRNA were identified, and the corresponding cDNAs were cloned from liver and testis. In liver, a single promoter/first exon is used to generate a steady-state level of roughly five molecules of TBP mRNA per diploid cell equivalent. In testis, we detect modest up-regulation of the somatic promoter and recruitment of at least five other promoters. Three of the alternative promoter/first exons, including 1C and two of the testis-specific promoter/first exons, 1D and 1E, contribute roughly equivalent amounts of mRNA which, in sum, account for greater than 90% of all TBP mRNA in testis. As a result, round spermatids contain an estimated 1000 TBP mRNA molecules per haploid cell. Testis TBP mRNA also exhibits several low abundance 5' end splicing variants; however, all detected TBP mRNA leader sequences splice onto the common exon 2 and are expected to initiate translation at the same site within exon 2. The precise locations of the three major initiation exons are mapped on the gene. The identification of the strong testis-specific promoter/first exons will be important for understanding spermatid-specific tbp gene regulation.

Inhibition of herpes simplex virus reactivation by dipyridamole in a mouse model

Herpes simplex virus (HSV) thymidine kinase (TK) has been demonstrated to be important for reactivation from latency. Specifically, HSV latency-associated transcripts (LAT) are expressed during latent infection established by TK-negative (TK-) HSV mutants, but reactivation is minimal. TK- HSV, however, readily reactivated in the presence of exogenous thymidine (TdR) in explant medium [Tenser et al. (1996): Journal of Virology 70:1271-1276]. In the present report this was further studied by evaluating the effect of dipyridamole (DPM) on HSV reactivation. DPM is known to interfere with nucleoside transport. Inhibition of TdR-enhanced reactivation of TK- HSV and inhibition of reactivation of wild-type TK+ HSV were evaluated in an experimental mouse model of latency. Without DPM, TK- HSV reactivation was increased from 0% to 88% with TdR in explant medium, demonstrating TdR-enhanced reactivation of TK- HSV (as seen previously), TdR-enhanced reactivation of TK- HSV was decreased when DPM (25 or 50 microM) was also present, to 30%-60% and to 0%, respectively. Secondly, DPM also decreased reactivation of wild-type TK+ HSV. The reactivation frequency of latently infected dorsal root ganglia was 90% in standard medium (no added TdR), and this was decreased by DPM to 9% and 0%, respectively. Reactivation of trigeminal ganglia in standard medium was 100%, and this decreased to 59% and 23%, respectively. The possibility of a direct toxic effect of DPM on ganglion neurons to explain the results was unlikely. DPM had a modest antiviral effect on HSV replication in cell culture, and its efficacy in blocking reactivation may be related to this activity, probably by inhibition of nucleoside transport.

Reactivation of thymidine kinase-defective herpes simplex virus is enhanced by nucleoside

Herpes simplex virus (HSV) mutants defective for thymidine kinase expression (TK-) have been reported to establish latent infection of sensory ganglia of mice, in that HSV latency-associated transcript is expressed, but to be defective for reactivation. In the present study, the mechanism of defective reactivation by TK- HSV was investigated. Latent infection established by each of three reactivation-defective HSV type 1 mutants was studied. Reactivation in explant culture was markedly enhanced by the addition of thymidine (dTdR) to the explant culture medium. Without added dTdR, reactivation occurred in 0 of 32 ganglia, while when dTdR (200 microM) was present, reactivation occurred in 32 of 37 ganglia (86%). Reactivation was minimal or did not occur after treatment with other nucleosides; specificity for dTdR would suggest the importance of dTdR nucleotide levels rather than more general nucleotide pool imbalance. Enhanced reactivation by dTdR was dose dependent and was blocked by acyclovir. While some degree of inhibition of TK- HSV by acyclovir may be expected, the complete block of dTdR-enhanced reactivation was unexpected. This result may suggest that HSV is particularly vulnerable during initial reactivation events. The mechanism of dTdR-enhanced reactivation of TK- HSV was further evaluated during in vivo infection by TK- HSV. For mice infected with TK- HSV, virus was undetectable in ganglia 3 days later. However, for mice infected with TK- HSV and treated with dTdR, virus was readily detected (2.8 x 10(3) PFU per ganglion). This result suggested that in vivo treatment with dTdR enhanced replication of TK- HSV in ganglion neurons. In turn, this suggests that in latently infected ganglia, dTdR-enhanced reactivation of TK- HSV occurred as a result of viral replication in neurons following initial reactivation events.

High accumulation of components of the RNA polymerase II transcription machinery in rodent spermatids

Levels of mRNA and protein encoded by the TATA-binding protein (tbp) gene are shown to increase dramatically during late spermatogenesis in rodents, culminating in a highly testis-enriched expression pattern. Whereas adult spleen and liver contained roughly 0.7 and 2.3 molecules of TBP mRNA per haploid genome-equivalent, respectively, adult testis contained 80–200 molecules of TBP mRNA per haploid genome-equivalent. Comparison of nuclear and cytoplasmic levels of TBP mRNA in liver and testis suggested that nuclear events (transcription or processing) contribute roughly 12-fold, and cytoplasmic events (mRNA stability) roughly 6-fold, to testis-specific overaccumulation. Levels of nuclear TBP protein in testis cells were, on average, 8- and 11-fold higher than those in liver and spleen cells, respectively. Overexpression of TBP mRNA in testis began about 20 days after birth and reached a plateau around day 40, corresponding to the developmental emergence of haploid cells. Besides TBP, two other components of the general RNA polymerase II machinery, TFIIB and RNA polymerase II, were also overexpressed in testis. By immunostaining, it was found that TBP and RNA polymerase II were particularly rich in round spermatid nuclei. Our results suggest a molecular explanation for how early spermatids are able to accumulate all of the mRNA necessary for the final week of spermiogenesis.

Characterization of the Spodoptera frugiperda TATA-binding protein: nucleotide sequence and response to baculovirus infection

A cDNA clone containing a 921 bp open-reading frame (307 amino acids; 34 kDa) homologous to the TATA-binding protein (TBP) was isolated and sequenced from a Spodoptera frugiperda cell line that is commonly used in the baculovirus expression system. Analysis of the S. frugiperda TBP (SfTBP) sequence showed that the amino-terminal portion of SfTBP diverged significantly from that of other TBP sequences including Drosophila melanogaster whereas the carboxy-terminal sequence was highly conserved. Southern blot analysis indicated that SfTBP was encoded by a single gene in the S. frugiperda genome. Northern blot analysis indicated that steady-state levels of the 1.3 kb SfTBP transcript declined by 24 h post-infection corresponding to the time of virus-induced inhibition of host-cell transcription. Corresponding western blot analysis showed that TBP protein levels remain constant up to 72 h post-infection.

Cytofluorometric assay for the determination of thymidine uptake and phosphorylation in living cells

Thymidine kinase is a key enzyme for the application of drugs in chemotherapy and for diagnosis. Although of great interest, its regulation during cell cycle and differentiation is difficult to study, as current techniques for isolation of cells in different phases of growth are unsatisfactory. An assay that allows the determination of enzymatic activity in situ in single cells would be much faster than present methods and would elegantly avoid synchronization procedures. We synthesized different analogues of thymidine with the 5-methyl group substituted by a fluorochrome. At least three of these compounds were phosphorylated by thymidine kinase in cell free extracts and were taken up and phosphorylated by cells in culture. The cytofluorometric signal of the accumulated fluorochrome in any given cell reflected the thymidine kinase activity of this cell. Simultaneous measurement of cell-cycle dependent parameters allowed the correlation of thymidine kinase activity with the phase of growth in mixed cell populations.

Pax-5 is expressed at the midbrain-hindbrain boundary during mouse development

The murine paired-box-containing gene 5, Pax-5, is highly homologous to two other Pax genes, Pax-2 and Pax-8. The expression pattern of Pax-5 during mouse embryogenesis was examined by in situ RNA hybridization and compared to those of Pax-2 and Pax-8. Beginning at day 9.5 postcoitum (p.c.), Pax-5 was expressed in the developing brain, predominantly at the midbrain-hindbrain boundary, and in the neural tube. While the neural tube expression pattern overlapped completely with Pax-2 and Pax-8, the expression pattern in the brain was only partially overlapping. Unlike Pax-2 and Pax-8, Pax-5 was not expressed in the developing excretory system, thyroid, eye or ear. Our data suggest that Pax-5 has a role in the development of the central nervous system.

Changes in dihydrofolate reductase (DHFR) mRNA levels can account fully for changes in DHFR synthesis rates during terminal differentiation in a highly amplified myogenic cell line

Dihydrofolate reductase (DHFR) enzyme is preferentially synthesized in proliferative cells. A mouse muscle cell line resistant to 300 microM methotrexate was developed to investigate the molecular levels at which DHFR is down-regulated during myogenic withdrawal from the cell cycle. H- alpha R300T cells contained 540 copies of the endogenous DHFR gene and overexpressed DHFR mRNA and DHFR protein. Despite DHFR gene amplification, the cells remained diploid. As H- alpha R300T myoblasts withdrew from the cell cycle and committed to terminal differentiation, DHFR mRNA levels and DHFR synthesis rates decreased with closely matched kinetics. After 15 to 24 h, committed cells contained 5% the proliferative level of DHFR mRNA (80 molecules per committed cell) and synthesized DHFR protein at 6% the proliferative rate. At no point during the commitment process did the decrease in DHFR synthesis rate exceed the decrease in DHFR message. The decrease in DHFR mRNA levels during commitment was sufficient to account fully for the decrease in rates of DHFR synthesis. Furthermore, DHFR mRNA remained polysomal, and the average number of ribosomes per message remained constant (five to six ribosomes per DHFR mRNA). The constancy of polysome size, along with the uniform rate of DHFR synthesis per message, indicated that DHFR mRNA was efficiently translated in postreplicative cells. The results support a model wherein replication-dependent changes in DHFR synthesis rates are determined exclusively by changes in DHFR mRNA levels.

Changes in dihydrofolate reductase (DHFR) mRNA levels can account fully for changes in DHFR synthesis rates during terminal differentiation in a highly amplified myogenic cell line

Dihydrofolate reductase (DHFR) enzyme is preferentially synthesized in proliferative cells. A mouse muscle cell line resistant to 300 microM methotrexate was developed to investigate the molecular levels at which DHFR is down-regulated during myogenic withdrawal from the cell cycle. H- alpha R300T cells contained 540 copies of the endogenous DHFR gene and overexpressed DHFR mRNA and DHFR protein. Despite DHFR gene amplification, the cells remained diploid. As H- alpha R300T myoblasts withdrew from the cell cycle and committed to terminal differentiation, DHFR mRNA levels and DHFR synthesis rates decreased with closely matched kinetics. After 15 to 24 h, committed cells contained 5% the proliferative level of DHFR mRNA (80 molecules per committed cell) and synthesized DHFR protein at 6% the proliferative rate. At no point during the commitment process did the decrease in DHFR synthesis rate exceed the decrease in DHFR message. The decrease in DHFR mRNA levels during commitment was sufficient to account fully for the decrease in rates of DHFR synthesis. Furthermore, DHFR mRNA remained polysomal, and the average number of ribosomes per message remained constant (five to six ribosomes per DHFR mRNA). The constancy of polysome size, along with the uniform rate of DHFR synthesis per message, indicated that DHFR mRNA was efficiently translated in postreplicative cells. The results support a model wherein replication-dependent changes in DHFR synthesis rates are determined exclusively by changes in DHFR mRNA levels.

Identification of a 70-base-pair cell cycle regulatory unit within the promoter of the human thymidine kinase gene and its interaction with cellular factors

The promoter of the human thymidine kinase gene contains cis-regulatory elements responsible for its cell-cycle-regulated expression. We report here that a 70-bp region between -133 and -64 is sufficient to confer cell cycle regulation on a heterologous promoter. The 20-bp region between -64 and -83, which contains an inverted CCAAT motif, is important for transcriptional stimulation of this functional unit. The sequence of this CCAAT motif is nearly identical to the consensus sequence for the transcriptional factor CP1. We also examined the specificity and binding activities of cellular factors interacting with the 70-bp fragment. We showed that the cellular factors binding to the 70-bp region are similar during the G1, S, and G2 phases, suggesting that the cell cycle regulatory activity observed must involve processes other than factor binding to the DNA.

Identification of a 70-base-pair cell cycle regulatory unit within the promoter of the human thymidine kinase gene and its interaction with cellular factors

The promoter of the human thymidine kinase gene contains cis-regulatory elements responsible for its cell-cycle-regulated expression. We report here that a 70-bp region between -133 and -64 is sufficient to confer cell cycle regulation on a heterologous promoter. The 20-bp region between -64 and -83, which contains an inverted CCAAT motif, is important for transcriptional stimulation of this functional unit. The sequence of this CCAAT motif is nearly identical to the consensus sequence for the transcriptional factor CP1. We also examined the specificity and binding activities of cellular factors interacting with the 70-bp fragment. We showed that the cellular factors binding to the 70-bp region are similar during the G1, S, and G2 phases, suggesting that the cell cycle regulatory activity observed must involve processes other than factor binding to the DNA.

Bidirectional promoter activity of the 5' flanking region of the mouse thymidine kinase gene

The 5' flanking region of the gene coding for cytoplasmic thymidine kinase (TK) in the mouse (a total of 490 bp upstream of the initiation codon) was tested for promoter activity using the chloramphenicol acetyltransferase gene as reporter. It was found that the region can be divided into two parts, one of which carries promoter activity in the direction of TK, whereas the 5'-half has promoter activity in the opposite direction. A fragment of 140 bp was sufficient for growth-dependent promoter activity in the direction of TK, although about 100 bp further upstream, enhanced the activity. Expression from the divergent promoter was independent of cell growth.

Post-transcriptional regulation of thymidine kinase gene expression during monocytic differentiation of HL60 promyelocytes

The regulatory mechanism of human thymidine kinase (TK) gene expression was investigated in HL-60 promyelocytes during induction of monocytic differentiation with 12-O-tetradecanoyl phorbol-13-acetate (TPA). The steady-state levels of TK mRNA diminished gradually as cells were treated with TPA. The nuclear run-on experiments were performed and revealed that TPA treatment did not change TK gene activity in HL-60 cells. These findings suggested that the expression of TK mRNA was controlled by a post-transcriptional mechanism. The half-life of mature TK mRNA transcript was found to be more than 8 hours in both proliferating and differentiated HL-60 cells, which indicated that the stability of mature TK mRNA does not play a role in regulating TK gene expression. Analysis of poly(A-) TK mRNAs showed the high molecular weight precursors of TK mRNA which appeared in proliferating cells were not detectable in TPA-treated cells. This finding suggested that the TK mRNA processing event is implicated in the regulation of human TK gene expression in HL-60 cells during monocytic terminal differentiation.

Maintenance of dihydrofolate reductase enzyme after disappearance of DHFR mRNA during muscle cell differentiation

Terminally differentiating mouse muscle cells were used to examine the relationship between myogenic withdrawal from the cell cycle and the levels of dihydrofolate reductase (DHFR) mRNA and DHFR activity. Differentiation was induced by removal of fibroblast growth factor activity from the medium. DHFR mRNA was measured by a RNase protection assay. DHFR activity was measured by a spectrophotometric assay and by a [3H]methotrexate binding assay. Proliferative myoblasts contained four DHFR mRNA molecules and 1.8 X 10(5) DHFR enzyme molecules. By 12.5 h after induction, when [3H]thymidine labeling indices showed all cells had withdrawn from the cell cycle, DHFR mRNA levels had declined to 0.7 copies per cell. In contrast, myogenic withdrawal did not result in reduced DHFR activity. Qualitatively similar results, i.e. down-regulation of mRNA and constitutive expression of activity, were observed in a methotrexate-selected muscle cell line with greater than 50-fold amplification of the DHFR gene. Enzyme synthesis rate and stability measurements indicated that persistence of DHFR activity in postreplicative cells was due to a long enzyme lifetime rather than to continued synthesis from residual normal DHFR mRNA or an alternative mRNA species not detected by the RNase protection assay. Unlike DHFR, thymidine kinase (TK) activity disappeared rapidly as muscle cells differentiated. Both DHFR mRNA and TK mRNA are expressed in a replication-dependent manner; however, the enzymes encoded by these messages are subject to different fates in postreplicative cells.

Thymidine kinase synthesis is repressed in nonreplicating muscle cells by a translational mechanism that does not affect the polysomal distribution of thymidine kinase mRNA

The molecular basis for replication-dependent expression of thymidine kinase (TK) activity (EC 2.7.1.21) was investigated in mouse skeletal muscle cells transformed with multiple copies of the chicken TK gene. When shifted to mitogen-depleted medium, proliferating myoblasts irreversibly withdraw from the cell cycle and commit to terminal differentiation. Early after commitment, postreplicative myocytes maintain nearly proliferative levels of TK mRNA but have greatly reduced levels of TK activity. Metabolic labeling studies with [35S]methionine indicated that the decrease in TK activity was associated with a 10-fold reduction in the rate of TK protein synthesis. Commitment had little effect on the stability or catalytic efficiency of TK protein. The decrease in TK synthetic rate in the continued presence of TK mRNA indicated that translation of TK mRNA was repressed in committed cells. The distribution of TK mRNA between ribonucleoprotein particles and polysomes was determined. In both proliferative cells and committed cells, TK mRNA levels were maximal in polysomes containing five to seven ribosomes. Thus, the synthesis of TK protein in nonreplicating muscle cells was inhibited by a translational mechanism that did not alter the average number of ribosomes engaged by TK mRNA.

Clonal derivation of a rat muscle cell strain that forms contraction-competent myotubes

A muscle cell strain capable of forming contracting myotubes was isolated from an established rat embryo cell line. The myogenic cells, termed rat myoblast omega or RMo cells, have a diploid complement of chromosomes (n = 42). In the presence of mitogen-containing growth medium, RMo cells proliferated with a cell generation time of about 12 hours. In mitogen-depleted medium, RMo cells withdrew from the cell cycle and formed myotubes that spontaneously contracted. Differentiated RMo cells produced creatine kinase isozymes in a ratio characteristic of skeletal muscle cells. RMo cells were easy to cultivate. Cells proliferated and differentiated equally well on gelatin-coated or noncoated culture dishes, at clonal or mass culture densities, and in all basal media tested. In most experiments, growth medium consisted of horse serum-containing medium supplemented with either chicken embryo extract or FGF activity; cells proliferated equally well in medium containing unsupplemented calf serum. RMo cells differentiated if growth medium was not replenished regularly. Alternatively, differentiation was induceable by incubation in mitogen-depleted medium consisting of basal medium supplemented either with 10(-6) M insulin, 0.5% serum, or 50% conditioned growth medium. RMo cells were competently transformed with cloned exogenous genes. Because it forms functional myofibrils, the RMo cell line constitutes a useful model system for studying the cell biology and biochemistry of proteins involved in contractile apparatus assembly and muscle disease.

Tissue-specific transcriptional control of alpha- and beta-tropomyosins in chicken muscle development

During muscle maturation, isoform switching of contractile proteins to attain the adult phenotype involves both stage-specific and muscle-specific regulatory mechanisms. Chicken pectoralis major (PM) provides an interesting model to study the latter since a specific pattern of tropomyosin (TM) with repression of the beta TM isoform is displayed by the adult PM. The developmental pattern of alpha and beta fast skeletal muscle tropomyosins' (alpha f and beta TM) RNAs was investigated with 3' untranslated region specific probes. In PM, the beta TM messenger ceased to accumulate after hatching through a transcriptional control, as shown by run-on assays, so that, at Day 8 ex ovo, no beta TM mRNA was detected. In this same muscle, in parallel with the disappearance of the beta TM mRNA, there was a boost in the accumulation of the alpha f TM mRNA. In the leg muscles, following hatching, there was only a moderate increase in the level of the alpha f TM mRNA, together with a slight decrease in the accumulation of the beta TM mRNA. Taken together, these results show that chicken muscle maturation involves tissue-specific transcriptional control of tropomyosin genes and could suggest a possible coordinate regulation of the two genes.

Regulation of thymidine kinase protein levels during myogenic withdrawal from the cell cycle is independent of mRNA regulation

Replication-dependent changes in levels of enzymes involved in DNA precursor biosynthesis are accompanied frequently by changes in levels of cognate mRNA. We tested the common assumption that changes in mRNA levels are responsible for growth-dependent expression of these enzymes using a line of mouse muscle cells that irreversibly withdraws from the cell cycle as part of its terminal differentiation program. Thymidine kinase (TK) mRNA, activity, and protein levels were quantitated in cells transformed with multiple copies of the chicken TK gene. The decline in TK mRNA (both whole cell and cytoplasmic) during myogenesis was poor (2-fold average) and variable (1.2 to 8-fold). In contrast, TK activity always was regulated efficiently (20-fold), even in cells which regulated TK mRNA very poorly. Thus, regulation of TK activity was independent of TK mRNA regulation as myoblasts withdrew from the cell cycle. A TK/beta-galactosidase fusion protein was used to derive an antibody against chicken TK. Immunoblot and immunoprecipitation analyses demonstrated TK protein levels, like TK activity levels, declined to a greater extent than TK mRNA levels. Thus, TK activity likely was regulated by a mechanism involving either decreased translation of TK mRNA or increased degradation of TK protein in committed muscle cells.

Posttranscriptional regulation of the expression of CAD gene during differentiation of F9 teratocarcinoma cells by induction with retinoic acid and dibutyryl cyclic AMP

We have studied the regulation of expression of the carbamoyl-phosphate synthetase II-aspartate transcarbamylase-dihydroorotase gene in F9 teratocarcinoma cells during their differentiation into parietal endoderm cells by induction with a combination of retinoic acid and dibutyryl cyclic AMP. Steady-state levels of CAD mRNA decreased by 7-fold in F9 cells following 120 h of retinoic acid and dibutyryl cyclic AMP induction as compared to levels in uninduced cells. Conversely, no apparent changes were found in the steady-state levels of beta-actin mRNA between induced and uninduced cells. Despite a 7-fold decrease in the steady-state levels of CAD mRNA, its rate of transcription remained the same between induced and uninduced cells, indicating a role for posttranscriptional mechanisms for its down regulation during retinoic acid- and dibutyryl cyclic AMP-induced differentiation of F9 cells. The cellular growth rate of F9 cells as determined by [3H]thymidine uptake and parallel cell counting decreased markedly during their induction with retinoic acid and dibutyryl cyclic AMP. Taken together, it is apparent that the expression of the CAD gene is cell-growth-dependent and its regulation in this system is at the posttranscriptional level.

Transcriptional repression of an embryo-specific muscle gene

Skeletal muscle involves both the induction and repression of gene expression. Although activation and up-regulation of several contractile protein genes has been shown to occur via transcriptional mechanisms, the mechanisms by which contractile protein genes are repressed during muscle development remain unknown. However, a post-transcriptional mechanism has been implicated in the repression of thymidine kinase expression during muscle development. The chicken cardiac troponin T (cTNT) gene is expressed in early embryonic skeletal muscle but is abruptly repressed in late embryonic/fetal development. Using run-on transcription assays we demonstrate here that cTNT gene repression occurs at the level of transcription. Thus, transcriptional as well as post-transcriptional mechanisms operate both to activate and repress gene expression during skeletal muscle development.

Introns are inconsequential to efficient formation of cellular thymidine kinase mRNA in mouse L cells

TK mRNA levels were determined in mouse L cells transformed with intron deletion mutations of the chicken TK gene. Whether normalized per cell, per integrated gene, or per internal control signal, intron deletion did not diminish the efficiency of TK mRNA formation in transformed L cells. The results demonstrated that introns are not required for efficient biogenesis of cellular mRNA in transformed mouse L cells.

Regulation of enzyme levels by proteolysis: the role of pest regions

Enzymes can be regulated in a variety of ways. Readily reversible mechanisms, such as phosphorylation, are frequently used by cells to control metabolic pathways. Less often, enzyme levels are regulated by changing the rate at which the protein is destroyed. Although these changes, too, are reversible through protein synthesis, large variations in enzyme concentration can be produced in very short periods of time by combinations of transcriptional control, translational control and rapid degradation. We recently examined the primary sequences of proteins whose intracellular half-lives are less than two hours. With a single exception, each short-lived protein contains one or more regions rich in proline (P), glutamic acid (E), serine (S) and threonine (T). These PEST regions range in length from 12 to 60 residues, and they are often flanked by possibly charged amino acids. Similar inspection of 35 more stable, structurally characterized proteins revealed only three weak PEST regions. All PEST proteins appear to be important regulatory molecules, and their fast turnover surely reflects a metabolic requirement for rapid changes in their concentrations. Known PEST proteins include oncogene products, key enzymes and components of signal pathways. In addition, there are a number of PEST-containing proteins that are suspected of being rapidly degraded. These proteins include Drosophila homeotic proteins (e.g., notch, snake, caudal, ftz and even-skipped) and a host of yeast cdc mutants. PEST regions, which target the molecules containing them for destruction, thus appear to be widely distributed among metabolically unstable proteins.

Introns are inconsequential to efficient formation of cellular thymidine kinase mRNA in mouse L cells

TK mRNA levels were determined in mouse L cells transformed with intron deletion mutations of the chicken TK gene. Whether normalized per cell, per integrated gene, or per internal control signal, intron deletion did not diminish the efficiency of TK mRNA formation in transformed L cells. The results demonstrated that introns are not required for efficient biogenesis of cellular mRNA in transformed mouse L cells.