Message-specific sequestration of maternal histone mRNA in the sea urchin egg.

Nucleate and anucleate fragments of sea urchin eggs were prepared by centrifugation on sucrose step gradients. The amount of total RNA, poly(A)+ RNA, histone mRNA, actin mRNA, alpha-tubulin mRNA, and mitochondrial rRNA was determined for each fragment. Total RNA, poly(A)+ RNA, actin mRNA, and alpha-tubulin mRNA all distributed in the same ratio as the volume of the fragments. In contrast, the mitochondrial rRNA was found preferentially distributed in the anucleate fragments, coinciding with the distribution of the mitochondria. Histone mRNAs did not follow the fragment volume ratios, but rather were always found associated with the fragment containing the nucleus. To distinguish between nuclear association and possible artifacts associated with centrifugation, eggs were manually cut into nucleate and anucleate fragments and the amount of histone mRNA was determined for each set. Again only the fragments containing the nucleus had detectable amounts of histone mRNA. Although histone mRNAs were always associated with the nucleate fragment, very little histone mRNA was found associated with isolated egg nuclei prepared under gentle isotonic isolation conditions. Furthermore, embryos that have had first nuclear breakdown blocked with 6-dimethylaminopurine still initiated the recruitment of histone mRNAs into polysomes at the same time as control embryos, thus indicating that nuclear breakdown is not necessary for normal histone message utilization. These results demonstrate a message-specific sequestration of maternal histone mRNA which is physically different from that of other maternal mRNAs and which may govern the timing of maternal histone synthesis in sea urchin embryos.     

Cell cycle regulation of human histone H1 mRNA.

A cloned genomic DNA fragment containing a human histone H1 gene has been used to analyze histone H1 gene expression in two human cell lines (HeLa S3 and WI-38). The cellular abundance of histone H1 mRNA was compared with that of core (H2A, H2B, H3, and H4) histone mRNAs as a function of the cell cycle: core and H1 histone mRNA levels are related both to each other and to the apparent rate of DNA synthesis and are rapidly destabilized after DNA synthesis inhibition. The use of three synchronization protocols, and of transformed and normal diploid cells in culture, suggests that the detected core and H1 histone mRNA levels are regulated by similar mechanisms in continuously dividing human cell lines and nondividing cells stimulated to proliferate.     

A unique subspecies of histone H4 mRNA from rat myoblasts contains poly(A).

Fractionation of rat L6 myoblast histone H4 mRNA into its three component subspecies revealed that one of the major subspecies (H4-1) contained poly(A). The unique poly(A)+ H4 mRNA makes up about 8% of the total polysomal H4 mRNA population detected. Unlike the poly(A)- histone mRNAs, whose levels are reduced by greater than 95% when myoblasts differentiate into myotubes, the poly(A)+ subspecies is reduced by only 70%. The poly(A)+ H4 mRNA from myotubes incubated with actinomycin D decays with a half-life of 37-42 min, which is similar to that obtained for the poly(A)- H4 mRNAs in myoblasts. Both the poly(A)+ and poly(A)- subspecies decay at an increased rate after inhibition of DNA synthesis. In myoblasts the poly(A)+ H4 mRNA exists almost exclusively in the polysomal compartment (greater than 95%) with little (less than 5%) in the free ribonucleoprotein (mRNA-protein or mRNP) complex compartment of the cell. Poly(A)- histone H4 mRNA subspecies, on the other hand, are distributed with approximately 80% in the polysomal compartment and 20% in the free mRNP complex compartment. The unique poly(A)+ H4 mRNA is unusual, not only in that it contains poly(A) but also in its behavior compared to poly(A)- H4 mRNAs during terminal differentiation.     

Expression of cell cycle-dependent genes in young and senescent WI-38 fibroblasts.

We studied the expression of 11 cell cycle-dependent genes in senescent WI-38 fibroblasts and compared the results to those obtained in WI-38 cells from early passages (young cells). Every gene we examined is expressed in the senescent cells at levels similar to those in the young cells, including two genes maximally expressed at the G1/S phase boundary--genes for thymidine kinase and histone H3. The results clearly show that senescent, noncycling WI-38 cells are not similar to quiescent cells. Rather, such senescent WI-38 cells may be blocked just prior to the onset of DNA synthesis.     

Nonrandom distribution of histone mRNAs into polysomes and nonpolysomal ribonucleoprotein particles in sea urchin embryos.

In the early sea urchin embryo, newly synthesized cytoplasmic histone mRNA is found both on polysomes and free of ribosomes as nonpolysomal messenger ribonucleoprotein particles (free RNPs). The distribution of newly synthesized histone mRNAs between translating and nontranslating compartments is nonrandom and dependent on the developmental stage. Gel electrophoresis and autoradiography of polysomal and free RNP RNA from embryos at various stages show that (i) the fraction of total newly synthesized histone mRNA that is in polysomes is greater than the fraction of total newly synthesized poly(A)+mRNA that is in polysomes, at all stages examined, and (ii) among the five histone mRNAs. H1 mRNA and H4 mRNA are relatively more enriched in the free RNPs than are the mRNAs for H2A, H2B, and H3. These data suggest that histone mRNA, as a class, is more efficiently utilized as a template than the average mRNA and, of the cytoplasmic histone mRNAs, the mRNAs for histones H2A, H2B, and possibly H3 are selected more frequently for translation than those for H1 and H4. Cell-free translations of polysomal and free RNP RNAs yield different ratios of in vitro histone products, consistent with the RNA distribution data. To test the possibility that the in vivo distribution of the histone mRNAs is the consequence of different intrinsic initiation capabilities of the individual mRNAs, ribosome-binding assays were carried out and unequal binding abilities of the histone mRNAs in the reticulocyte lysate were shown. A translational level component in the regulation of histone synthesis in the sea urchin embryo is indicated.     

Biphasic pattern of histone gene expression during Drosophila oogenesis.

The expression of histone genes during Drosophila oogenesis was compared to periods of DNA synthesis as well as to the pattern of actin gene expression. Accumulation of histone mRNAs was measured by RNA blot hybridization. Relatively low levels of histone mRNAs are present in egg chambers prior to stage 10, during the period of nurse and follicle cell polyploidization. Surprisingly, histone mRNAs accumulate rapidly and selectively after stage 10, coinciding with the onset of nurse cell degeneration and well after DNA synthesis and actin mRNA accumulation have ceased. A large proportion of the histone mRNAs is associated with polysomes at all times, indicating that expression of histone genes is not strictly coupled to DNA synthesis. The burst of histone mRNA accumulation near the end of oogenesis may provide a store of maternal histone mRNA to support the rapid cleavages that occur during early embryogenesis. These and previous results suggest that genes are independently regulated during differentiation of the Drosophila egg chamber.     

Multiple forms of H4 histone mRNA in human cells.

Two species of H4 histone mRNA were isolated from the polysomes of S phase HeLa S3 cells. Electrophoresis under denaturing and nondenaturing conditions indicates that the two H4 mRNAs differ in size. Both mRNAs translate H4 histones in vitro, lack poly(A) at their 3' termini, and are capped at their 5' termini. Polyacrylamide gel electrophoresis and tryptic peptide analysis suggest that the polypeptides synthesized by the two mRNAs are indistinguishable.     

The steady-state levels of type I collagen mRNA are reduced in senescent fibroblasts

The decreased collagen content in aging skin could be a consequence of decreased synthesis or increased degradation. The possibility that decreased synthesis of collagen results from decreased synthesis of mRNAs for Type I collagen, the major collagen in skin, was investigated by assessing the steady-state levels of alpha 1(I) and alpha 2(I) collagen mRNAs in actively proliferating and senescent WI-38 fibroblasts. The levels of both alpha 1(I) mRNA and alpha 2(I) mRNA were significantly lower in senescent fibroblasts, suggesting that one factor contributing to the decreased collagen content of aging skin may be decreased synthesis of these collagen mRNAs by senescent fibroblasts. Both mRNAs were reduced to the same extent, suggesting that coordinate regulation of the two Type I collagen genes is maintained in senescent fibroblasts.     

Histones: metabolism in simian virus 40-infected cells and incorporation into virions.

The infection of confluent monkey cells with simian virus 40 induced the synthesis of both cellular DNA and histones. However, during the course of infection, cellular histone synthesis was uncoupled from cellular DNA replication and became coupled to viral DNA replication. The synthesis of all five host histone species was induced after virus infection and they appeared to be more highly phosphorylated than their couterparts in uninfected cells. At late times after infection, the cells contained twice as much histones as did uninfected cells. All the histone species except H1 were incorporated into virions. Compared to cellular histones, virion histones were enriched in the arginine-rich species H3 and H4. Although both old and newly synthesized cellular histones were incorporated into virions, there were about 5 times more newly synthesized than old histone polypeptides in virions.     

Synthesis of nuclear proteins during DNA repair synthesis in human diploid fibroblasts damaged with ultraviolet radiation of N-acetoxy-2-acetylaminofluroene.

We have examined the accumulation of newly synthesized nuclear proteins into nuclei during DNA repair synthesis in confluent WI-38 human diploid fibroblasts damaged with ultraviolet radiation or N-acetoxy-2-acetylaminofluroene. In contrast to a marked stimulation of DNA repair synthesis, stimulation of amino acid incorporation into histone polypeptides or into the various molecular weight classes of nonhistone nuclear proteins was not observed. These results suggest that detectable stimulation of newly synthesized nuclear protein incorporation into nuclei does not accompany DNA repair synthesis induced by ultraviolet radiation or a direct acting chemical carcinogen. At least for the special case of repair, DNA synthesis may be uncoupled from histone synthesis.     

Localization of types I, III and IV collagen mRNAs in rat heart cells by in situ hybridization

Previous studies investigating the cellular origins of several collagens in young adult rat hearts (Eghbali et al., 1988) demonstrated that the mRNAs for types I and III collagen occurred in non-myocyte cells, mostly fibroblasts, whereas the mRNA for type IV collagen was observed in both myocytes and non-myocyte cells. In the present study, cellular localization of collagen mRNAs has been achieved by in situ hybridization in rat heart tissue and in isolated heart cells. Frozen tissue sections, isolated cardiomyocytes, cultured neonatal cardiomyocytes and fibroblasts were hybridized with DNA probes for type-specific collagens, actin, and myosin heavy chain. Silver grains were visualized by dark field imaging. In heart sections, types I and III mRNAs were observed predominantly adjacent to myocytes and in the interstitium, where fibroblasts are known to be present. In contrast, type IV collagen mRNA was identified both within the myocytes and the interstitium. In freshly isolated adult cardiomyocytes and in cultured neonatal cardiomyocytes, collagen type IV mRNA was observed but type I collagen mRNA was not. In cultured neonatal fibroblasts, both types IV and I collagen mRNAs were abundant.     

The type II insulin-like growth factor receptor does not mediate deoxyribonucleic acid synthesis in human fibroblasts

Two insulin-like growth factor (IGF) receptors, the type I and type II IGF receptors, have been described. While substantial evidence indicates that the type I receptor is involved in the regulation of cell division, it is uncertain if the type II receptor also mediates this response. Similarly, the role of the insulin receptor in mediating DNA synthesis remains controversial. To address these questions, we used a monoclonal antibody (alpha IR-3) to specifically inhibit type I IGF receptor activity and examined the effects of this inhibition on IGF- and insulin-stimulated DNA synthesis in human fibroblasts. WI-38 human embryonic lung fibroblasts have both type I and type II IGF receptors, as determined by cross-linking [125I] IGF-I and [125I]IGF-II to monolayers of these cells. In serum-free medium both IGF-I and IGF-II stimulate DNA synthesis in WI-38 fibroblasts, with half-maximal effects occurring at 1.5 +/- 0.3 (+/- SD) and 3.4 +/- 1.4 nM, respectively. At maximally effective concentrations, however, both hormones stimulate DNA synthesis to equal levels. alpha IR-3 binds to the type I, but not the type II, IGF receptor on WI-38 cells. It also inhibits IGF binding to the type I receptor on these cells. alpha IR-3 competitively inhibited both IGF-I- and IGF-II-stimulated DNA synthesis in WI-38 cells, but had no effect on either epidermal growth factor- or platelet-derived growth factor-stimulated DNA synthesis. These results indicate that in WI-38 fibroblasts the mitogenic effects of both IGF-I and IGF-II are mediated through the type I receptor and that the type II IGF receptor is not directly involved in this response. To define the role of the insulin receptor in mediating DNA synthesis we compared the effects of alpha IR-3 on insulin-stimulated DNA synthesis in a variety of human cell lines under identical experimental conditions. With WI-38 and HEL, another human embryonic lung fibroblast cell line, alpha IR-3 competitively inhibited the mitogenic effect of insulin. However, in two other fibroblast cell lines (GM498 and HES) and an osteogenic sarcoma cell line (MG63), alpha IR-3 inhibited IGF, but not insulin-stimulated DNA synthesis. These results indicate that human cell lines differ in the receptor type through which insulin stimulates DNA synthesis and that these differences are intrinsic properties of the cell lines and are not artifacts resulting from differences in experimental conditions.     

In vivo distribution and turnover of fluorescently labeled actin microinjected into human fibroblasts.

Graessmann's microinjection technique was chosen to introduce fluorescently labeled muscle actin and other proteins into WI-38 human fibroblasts. The injected cells were examined during culture by fluorescence and reflection contrast microscopy. Within 30 min after injection, rhodamine-labeled actin was incorporated into a distinct network of fluorescent filaments, resembling the stress fibers observed by classical immunofluorescence microscopy. Cytochalasin b prevented the formation of these fibers, but colchicine did not. Neighboring fibers often converged into distinct focal points that appeared to be concentrated near the base of the cell. Examination of these fluorescent fibers and focal points by reflection contrast microscopy confirmed their close location to the substratum. After 6 hr of culture, fluorescent actin and the control proteins were segregated into granules located mainly near the cell nucleus. Thus, the injected actin both enters the intrinsic actin pool and participates in an assembly and disassembly of filamentous structures. Segregation into granules traces the natural turnover of this protein within the cell.