The synthesis of ninety proteins including actin throughout the HeLa cell cycle.

Abundant cytoplasmic proteins pulse-labeled with [35S]methionine at specific times throughout the HeLa cell cycle were analyzed with two-dimensional gel electrophoresis. More than 300 proteins could be resolved in this way. The frequency of appearance of label in the most abundant 90 proteins, ranging from 4% to less than 0.1% of the total methionine incorporated, was determined at six time points in the cell cycle. 84 of these proteins were made as a similar proportion of the total at all times during the cell cycle. A nonmuscle actin protein (spot 1) identified by molecular weight and isoelectric point represented 2-4% of the total methionine incorporated at all the time points. Only six proteins were found which varied by greater than fourfold during cell division, four appearing to represent a greater proportion of the total synthesis during the period at or immediately surrounding M (spots 31b, 44, 53, and 70d). Two appear to represent a smaller percentage of total synthesis during the early (spot 78) or the total (spot 74) G2 period.

Cell-specific expression of secreted versus membrane forms of immunoglobulin gamma 2b mRNA involves selective use of alternate polyadenylation sites.

Immunoglobulin heavy chain genes encode at least two forms of mRNA, secretory- and membrane-specific. In less mature B cells and tumors arising from them, lymphomas, the membrane form of the protein and mRNA are in high abundance, while in more mature stages, plasma cells, and myeloma tumor cells, the secreted forms of protein and mRNA predominate. In myeloma cells producing approximately 8:1 ratios of secretory- to membrane-encoding forms of gamma-heavy chain mRNA, we observed equimolar transcription of the secretory- and membrane-encoding exons of the gene. In isolated nuclei from 4T001 (gamma 2b) and K23 (gamma 2a) myeloma cells, the secretory-encoding mRNA polyadenylation site was used at least three times as often as the membrane-encoding mRNA polyadenylation site. In the A20 (gamma 2a) lymphoma, which produces equal amounts of mature secretory- and membrane-encoding heavy chain mRNAs, results of experiments with isolated nuclei showed that the membrane mRNA polyadenylation site was used about two times as often as the secretory mRNA polyadenylation site. Selective use of alternate polyadenylation and cleavage sites, therefore, can modulate the production of the two mRNAs from a single gene during B cell differentiation.

Regulation of poly(A) site use during mouse B-cell development involves a change in the binding of a general polyadenylation factor in a B-cell stage-specific manner.

During the development of mouse B cells there is a regulated shift from the production of membrane to the secretion-specific forms of immunoglobulin (Ig) mRNA, which predominate in the late-stage or plasma B cells. By DNA transfection experiments we have previously shown that there is an increase in polyadenylation efficiency accompanying the shift to secretion-specific forms of Ig mRNA (C. R. Lassman, S. Matis, B. L. Hall, D. L. Toppmeyer, and C. Milcarek, J. Immunol. 148:1251-1260, 1992). When we look in vitro at nuclear extracts prepared from early or memory versus late-stage or plasma B cells, we see cell stage-specific differences in the proteins which are UV cross-linked to the input RNAs. We have characterized one of these proteins as the 64-kDa subunit of the general polyadenylation factor cleavage-stimulatory factor (CstF) by immunoprecipitation of UV-cross-linked material. The amount of 64-kDa protein and its mobility on two-dimensional gels do not vary between the B-cell stages. However, the activity of binding of the protein to both Ig and non-Ig substrates increases four- to eightfold in the late-stage or plasma cell lines relative to the binding seen in the early or memory B-cell lines. Therefore, the binding activity of a constitutive factor required for polyadenylation is altered in a B-cell-specific fashion. The increased binding of the 64-kDa protein may lead to a generalized increase in polyadenylation efficiency in plasma cells versus early or memory B cells which may be responsible for the increased use of the secretory poly(A) site seen in vivo.

Sequences near the 3' secretion-specific polyadenylation site influence levels of secretion-specific and membrane-specific IgG2b mRNA in myeloma cells.

The expressed immunoglobulin gamma 2b (IgG2b) heavy-chain gene of 4T001 was cloned into the shuttle vector pSV2-gpt and transfected into myeloma J558L and lymphoma A20.2J. Northern blots indicated that the transfected gamma 2b gene was processed in a manner similar to the endogenous heavy chain in both lymphoma and myeloma cells. To identify sequences important for immunoglobulin mRNA processing, we constructed deletions around the secretion-specific polyadenylation site and introduced the deleted genes into J558L cells. The BAL deletion lacked 670 base pairs of intervening sequence between secreted and membrane regions; the Kpn deletion lacked 830 base pairs in this region. J558L cells transfected with either the entire gamma 2b gene or the delta BAL vector produced predominantly secretion-specific gamma 2b mRNA and protein. J558L cells transfected with the delta Kpn vector produced approximately equimolar amounts of secretion-specific and membrane-specific gamma 2b mRNA. Both 55,000-dalton secreted and 62,000-dalton putative surface IgG2b proteins were detected in the delta Kpn transfectants. We conclude that sequences absent in the Kpn deletion but present in the BAL deletion exert an important role in the production of secretion-specific mRNA. The Kpn deletion removes the normal site of cleavage and poly(A) addition, and it is possible that it is the absence of this site which changes the processing pattern. Alternatively, it is possible that sequences absent in the Kpn deletion but present in the BAL deletion function in regulating the production of predominantly secretion-specific mRNA in myeloma cells. The possible role of a highly conserved sequence found in this region is discussed.

Loss of a consensus splice signal in a mutant immunoglobulin gene eliminates the CH1 domain exon from the mRNA.

A series of mouse myeloma mutants, derived from a cell line of the murine MPC-11 tumor (gamma 2b, kappa), resemble human heavy-chain disease in their loss of an internal domain (exon). In these mutants, most of the gamma 2b CH1 exon was present in the nuclear RNA but was removed during splicing to form the mature cytoplasmic RNA. Amino acid sequence studies of one mutant (10.1) are consistent with the loss of the complete CH1 domain. A second mutant cell line (I17) derived from 10.1 and containing the same CH1 alteration was shown by S1 nuclease protection experiments to have an additional mRNA deletion spanning the CH2-CH3 domain boundary. This second deletion was shown to result from a genomic alteration that provided a marker for the isolation of the expressed H-chain allele. To determine the basis of the CH1 splicing defect, the 117 genome-expressed gamma 2b constant region DNA was cloned. Sequence studies showed a deletion of 99 nucleotides around the 3' end of the CH1 domain, which removed the splice site and flanking DNA, apparently causing the aberrant splicing of the RNA transcript. The sequence deleted in the mutant is flanked by short repeats of the octameric sequence CCAGCCAG in the wild-type gene. In the mutant, one copy of the repeat, in addition to the sequences between the repeats, has been lost.

hnRNP F influences binding of a 64-kilodalton subunit of cleavage stimulation factor to mRNA precursors in mouse B cells.

Previous studies on the regulation of polyadenylation of the immunoglobulin (Ig) heavy-chain pre-mRNA argued for trans-acting modifiers of the cleavage-polyadenylation reaction operating differentially during B-cell developmental stages. Using four complementary approaches, we demonstrate that a change in the level of hnRNP F is an important determinant in the regulated use of alternative polyadenylation sites between memory and plasma stage B cells. First, by Western analyses of cellular proteins, the ratio of hnRNP F to H or H' was found to be higher in memory B cells than in plasma cells. In memory B cells the activity of CstF-64 binding to pre-mRNA, but not its amount, was reduced. Second, examination of the complexes formed on input pre-mRNA in nuclear extracts revealed large assemblages containing hnRNP H, H', and F but deficient in CstF-64 in memory B-cell extracts but not in plasma cells. Formation of these large complexes is dependent on the region downstream of the AAUAAA in pre-mRNA, suggesting that CstF-64 and the hnRNPs compete for a similar region. Third, using a recombinant protein we showed that hnRNP F could bind to the region downstream of a poly(A) site, block CstF-64 association with RNA, and inhibit the cleavage reaction. Fourth, overexpression of recombinant hnRNP F in plasma cells resulted in a decrease in the endogenous Ig heavy-chain mRNA secretory form-to-membrane ratio. These results demonstrate that mammalian hnRNP F can act as a negative regulator in the pre-mRNA cleavage reaction and that increased expression of F in memory B cells contributes to the suppression of the Ig heavy-chain secretory poly(A) site.

Increased half-life of mu immunoglobulin mRNA during mouse B cell development increases its abundancy.

When B cells encounter antigen, the cells mature into terminally differentiated plasma cells and the amount of steady-state immunoglobulin (Ig) mu mRNA is increased 23-60-fold over the amount seen in earlier B cell stages. Most of this dramatic increase in Ig gene mRNA accumulation could be due to post-transcriptional regulation. We have treated a series of mouse cell lines fixed at different stages of B cell differentiation with an adenosine nucleotide analog 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) which specifically blocks synthesis of new RNA polymerase II transcripts. The amount of mu heavy chain cytoplasmic RNA, measured by quantitative Northern blot analysis at various times post DRB treatment, is reflective of the transcript's stability. The mu mRNA half-life values observed from the earliest-stage lymphomas (70Z/3 and WEHI-231) are about 1.9-4 hr, whereas the t1/2 of mu mRNA in the hybridomas (Hyb54.3C2 and IdG11) is about 13-17 hr. There is, therefore, a nine-fold maximal increase in half-life of the mu mRNA in the Hyb54.3C2 over that observed in the earliest stage (70Z/3) cells.

Sequence and polyadenylation site determination of the murine immunoglobulin gamma 2a membrane 3' untranslated region.

We have determined the nucleotide sequence of the murine immunoglobulin gamma 2a membrane 3' untranslated region (1413 nucleotides) and approximately 679 nucleotides of downstream sequence. Two AATAAA hexanucleotide sequences are present in the 2092 nucleotide interval. The first one functions as the major polyA signal, directing cleavage and polyadenylation at a site 20 nucleotides downstream. Within 41 nucleotides downstream of the major membrane polyA signal are two sequences with 75% homology to the consensus sequence, (C/T)GTGTT(C/T)(C/T), identified by McLauchlan et al. [Nucl. Acids Res. 13, 1347-1365 (1985)]. An 80% homology match to the Berget consensus sequence, CA(C/T)TG, begins five nucleotides 3' of the major polyA site (used 20 times more than the second, downstream polyA site) [Berget Nature 309, 179-182 (1984)]. The second AATAAA, located 73 nucleotides 3' of the first, directs cleavage and polyadenylation 18 nucleotides downstream at a minor polyA site. One match with 75% homology to the McLauchlan consensus sequence begins 17 nucleotides 3' of the second (weaker) polyA site. No matches to the Berget consensus sequence are located near this second, weaker polyA site.

Changes in abundance of IgG 2a mRNA in the nucleus and cytoplasm of a murine B-lymphoma before and after fusion to a myeloma cell.

Changes in IgG mRNA half-life, transcription and nuclear and cytoplasmic abundance were studied in two cell lines which contain an identical Ig gamma 2a heavy chain but which differ in its expression. The A20.2J mouse lymphoma expresses about equal amounts of Ig gamma 2a secretory- and membrane-specific mRNAs whereas in the AXJ hybrids, resulting from the fusion of A20.2J with the J558L myeloma, the secretory-specific form dominates. Further evidence of dominance of the myeloma phenotype was seen in the large changes in mRNA abundance and nuclear accumulation as well as in a small increase in Ig gamma 2a mRNA half-lives for both secretory and membrane forms. Contributing to the observed > 100-fold increase in the ratio of secretory vs membrane forms of the Ig gamma 2a heavy chain in the AXJ hybrids are both a 10-fold decrease in the production of the membrane form by post-transcriptional RNA processing events and a approximately 6-7-fold decrease in the nuclear to cytoplasmic ratio for the Ig secretory gamma 2a and kappa light chain RNAs. Differential RNA accumulation in the nucleus in the lymphoma cell therefore contributes to the differential expression of Ig secretory mRNA.

An immunoglobulin heavy chain gene deletion at direct repeats: nucleotide sequence and effect on mRNA accumulation.

The DNA from the mouse myeloma cell, I17, which produces aberrant gamma 2b heavy chain mRNAs, was cloned and sequenced. The I17 mutant, and its parent line 10.1, share a small deletion at the splice junction of the CH1 domain which results in the absence of CH1 sequences from the mRNA. In addition, the genomic DNA of I17 has a deletion of 253 nucleotides which fuses the CH2 and CH3 exons, causes a frameshift of the next 43 amino acids and results in a truncated protein. The deleted nucleotides are flanked by two direct repeats of the CAGCA pentamer in the normal gene. One copy of the repeat and the interposed DNA is removed in the mutant. The DNA deletion is colinear with the mRNA. Both I17 and 10.1 cells have decreased accumulation of the secretory-specific gamma 2b mRNA. The amounts of membrane-specific gamma 2b mRNA are also affected in the mutants.

Somatic DNA rearrangement generates functional rat immunoglobulin kappa chain genes: the J kappa gene cluster is longer in rat than in mouse.

The kappa immunoglobulin (Ig) genes from rat kidney and from rat myeloma cells were cloned and analyzed. In kidney DNA one C kappa species is observed by Southern blotting and cloning in phage vectors; this gene most likely represents the embryonic configuration. In the IR52 myeloma DNA two C kappa species are observed: one in the same configuration seen in kidney and one which has undergone a rearrangement. This somatic rearrangement has brought the expressed V region to within 2.7 kb 5' of the C kappa coding region; the rearrangement site is within the J kappa cluster which we have mapped. The rat somatic Ig rearrangement, therefore, closely resembles that seen in mouse Ig genes. In the rat embryonic fragment two J kappa segments were mapped at 2 and 4.3 kb 5' from the C kappa coding region. Therefore, the rat J kappa cluster extends over about 2.3 kb, a region much longer than the 1.4 kb of the mouse and human J kappa clusters. In the region between C kappa and the expressed J kappa of IR52 myeloma DNA, and XbaI site present in the embryonic kappa gene has been lost. A somatic mutation has therefore occurred in the intervening sequence DNA approx. 0.7 kb 3' from the V/J recombination site. Southern blots of rat kidney DNA hybridized with different rat V kappa probes showed non-overlapping sets of bands which correspond to different subgroups, each composed of 8-10 closely related V kappa genes.

Use of in vitro-transcribed RNAs as immobilized targets during RNA:RNA hybridization.

We describe the use of in vitro-transcribed complementary RNAs as filter-bound targets during nuclear run-on analyses. Use of these single-stranded reagents in high-stringency RNA:RNA hybridizations increases signal-to-background hybridization seen using DNA targets and allows efficient measurement of transcriptional rates across genes in either direction.

HeLa cell cytoplasmic mRNA contains three classes of sequences: predominantly poly(A)-free, predominantly poly(A)-containing and bimorphic.

The mRNA species which exist in the HeLa cell polyribisomes in a form devoid of A sequences longer than 8 nucleotides constitute the poly(A)-free class of mRNA. The rapidly labelled component of this mRNA class shares no measurable sequence homology with poly(A)-containing RNA. If poly(A)-free mRNA larger than 12 S labelled for 2 h in vivo is hybridized with total cellular DNA, it hybridizes primarily with single-copy DNA. When a large excess of steady poly(A)-containing RNA is added before hybridization of labelled poly(A)-free RNA, no inhibition of hybridization occurs. This indicates the existence of a class of poly(A)-free mRNA with no poly(A)-containing counterpart. Some mRNA species can exist solely as poly(A)-containing mRNAs. These mRNAs in HeLa cells are found almost exclusively in the mRNA species present only a few times per cell (scarce sequences). Some mRNA species can exist in two forms, poly(A)containing and lacking, as evidenced by the translation data in vitro of Kaufmann et al. [Proc. Natl Acad. Sci. U.S.A. 74, 4801--4805 (1977)]. In addition, if cDNA to total poly(A)-containing mRNA is fractionated into abundant and scarce classes, 47% of the scarce class cDNA can be readily hybridized with poly(A)-free mRNA. 10% of the abundant cDNA to poly(A)-containing mRNA will hybridize with poly(A)-free sequences very rapidly while the other 90% hybridize 160 times more slowly, indicating two very different frequency distributions. The cytoplasmic metabolism of these three distinct mRNA classes is discussed.

Preliminary mapping of mutations affecting exonuclease 3 in Escherichia coli K-12.

xthA, a structural gene for exonuclease III in Escherichia coli K-12, is cotransducible with aroD, aroH, and pps.

Heat shock induced alterations in polyadenylate metabolism in Drosophila melanogaster.

We have studied the effect of heat shock on poly(adenylic acid) [poly(A)] metabolism in Drosophila melanogaster cells by using hybridization of ribonucleic acid (RNA) samples to [3H]poly(uridylic acid). Shortly after heat shock begins, cytoplasmic poly(A) decays rapidly. Two components were detected. Component I constitutes 46% of the total cytoplasmic poly(A) and decays with a half-life of 10 min. Component II (54% of total) is more stable. A half-life was not estimated for component II because new synthesis was not blocked. Studies on the size of cytoplasmic poly(A) indicate component I is completely degraded while component II remains essentially unchanged. Nuclear poly(A) increases rapidly, peaking at 2 or 3 times the normal level after 90 min of heat shock. Studies on the size of nuclear poly(A) indicate the increase is not due to addition of poly(A) to existing poly(A) segments nor appreciably to newly synthesized RNA unless transit time is markedly increased. We conclude that nuclear poly(A) is added in large part to already existing nonadenylated primers. Studies with RNA and protein synthesis inhibitors show RNA and protein synthesis are not required for the changes in poly(A). As the temperature is raised above 34--35 degrees C, the effect on poly(A) metabolism becomes more severe. Changes in external pH, without increased temperature, also alter poly(A) levels. Poly(A) changes may therefore be a rapid response to a variety of physiological factors.

The binding of a subunit of the general polyadenylation factor cleavage-polyadenylation specificity factor (CPSF) to polyadenylation sites changes during B cell development.

During the development of mouse B cells there is a regulated shift from the production of membrane (mb) to secretory-specific (sec) forms of immunoglobulin (Ig) mRNA. The mRNAs are produced from one gene that is alternatively processed at the 3' end. We have previously shown that there is an increase in polyadenylation efficiency accompanying the developmentally regulated shift to secretory-specific forms of Ig mRNA by DNA transfection experiments (1). When we look in vitro at nuclear extracts prepared from early/memory versus late stage/plasma B cells, we see cell stage-specific differences in the proteins which are crosslinked to poly(A) site-containing RNAs. Here we show that one of these proteins is the mouse homologue of 100 kDa subunit of Hela CPSF by immunoprecipitation and Western analysis of UV crosslinked material. The amount of 100 kDa protein and its mobility on two-dimensional gels do not change between the B cell stages. However, the binding of the 100 kDa polypeptide to poly(A) sites increases in the late stage/plasma cell lines relative to the binding seen in early/memory cell lines. The increased binding may reflect an increase in polyadenylation efficiency at the sec poly(A) site in plasma cells versus early/memory cells seen in vivo.

Differential mRNA stabilities affect mRNA levels in mutant mouse myeloma cells.

A series of mouse myeloma cell lines producing mutant gamma 2b immunoglobin heavy chains, which resemble heavy chain disease proteins, were analyzed for messenger RNA abundance as a function of mRNA alterations. A mutation effectively deleting the gamma 2b-CH1 domain of the mRNA had little or no effect on Ig heavy chain mRNA abundance on half-life (mutant 10.1). A mutation in the gamma 2b-CH2 and CH3 domain, causing premature termination of translation, had more deleterious effects on Ig heavy chain mRNA abundance and half-life (mutant I17). Substitution of the deleted portions of the gamma 2b mRNA with gamma 2a sequences by subclass switching in the cells (mutants K23 and K25) resulted in increased heavy chain abundance and half-life relative to the parent I17. In contrast, kappa light chain mRNA levels and half-lives remain constant among the mutants. The wild-type and mutant cell lines transcribed the Ig heavy chain gamma 2b locus equally when compared with an internal beta-actin standard by transcription run on studies. Therefore, half-life of the Ig heavy chain mRNA seems to be the principal determinant in cytoplasmic mRNA abundance in this system.