Loss of the polyadenylate segment from mammalian messenger RNA. Selective cleavage of this sequence from polyribosomes

Aggressive pituitary tumours and pituitary carcinomas

Although usually benign, anterior pituitary tumours occasionally exhibit aggressive behaviour, with invasion of surrounding tissues, rapid growth, resistance to conventional treatments and multiple recurrences. In very rare cases, they metastasize and are termed pituitary carcinomas. The time between a 'classical' pituitary tumour and a pituitary carcinoma can be years, which means that monitoring should be performed regularly in patients with clinical (invasion and/or tumour growth) or pathological (Ki67 index, mitotic count and/or p53 detection) markers suggesting aggressiveness. However, although both invasion and proliferation have prognostic value, such parameters cannot predict outcome or malignancy without metastasis. Future research should focus on the biology of both tumour cells and their microenvironment, hopefully with improved therapeutic outcomes. Currently, the initial therapeutic approach for aggressive pituitary tumours is generally to repeat surgery or radiotherapy in expert centres. Standard medical treatments usually have no effect on tumour progression but they can be maintained on a long-term basis to, at least partly, control hypersecretion. In cases where standard treatments prove ineffective, temozolomide, the sole formally recommended treatment, is effective in only one-third of patients. Personalized use of emerging therapies, including peptide receptor radionuclide therapy, angiogenesis-targeted therapy and immunotherapy, will hopefully improve the outcomes of patients with this severe condition.

Molecular cloning of the acid-labile subunit of the rat insulin-like growth factor binding protein complex

The insulin-like growth factors, IGF-I and IGF-II, circulate in both humans and rats as part of a 125-150 kDa complex comprising IGFs, the IGF binding protein IGFBP-3, and an acid-labile subunit. Clones encoding rat acid-labile subunit have been isolated from a rat liver cDNA library probed with a human acid-labile subunit cDNA. Two overlapping clones encode a leucine-rich protein of 576 amino acids preceded by a 27-residue signal sequence, with 78% homology to the human acid-labile subunit. Northern analysis of mRNA from adult rat brain, kidney, heart, lung, spleen, muscle and liver shows a major species of about 4.4 kb and minor bands of about 2 kb, 1.4 kb and 1 kb. The tissue distribution of this protein may therefore be wider than previously recognized.

Length heterogeneity in rat salivary gland alpha 2 mu globulin mRNAs: multiple splice-acceptors and polyadenylation sites

Rat alpha 2 mu globulins are coded for by a family of about 25 structurally related genes, some of which are expressed in the male adult liver while the other subset seems to be active in several excretory organs, including salivary and lacrymal glands. To estimate the number and specificity of genes expressed in the salivary glands, we determined nucleotide sequences of 30 cDNA clones. At least two alpha 2 mu globulin genes are active and two thirds of mRNAs were shown to code for the peptide two amino acids shorter than the others. Unexpected observation was the intense length polymorphism in the 3' non-coding 6th intron-7th exon regions presumably caused by alternative splice-acceptor selection. At least six acceptor sites were utilized and the longest type retained the entire 6th intronic sequence resulting in a formation of unusually longer product. A stable mRNA molecule of this type was demonstrated in salivary glands by Northern blotting probed with the 6th intron-specific fragment. Together with three independent polyadenylation sites, the rat salivary glands generate a diverse set of alpha 2 mu globulin mRNAs.

Accelerated poly(A) loss on alpha-tubulin mRNAs during protein synthesis inhibition in Chlamydomonas

Detachment of flagella in Chlamydomonas reinhardii stimulates a rapid accumulation of tubulin mRNAs. The induced tubulin mRNAs are normally rapidly degraded following flagellar regeneration, but inhibition of protein synthesis with cycloheximide prevents their degradation. alpha-Tubulin poly(A) tail lengths were measured during normal accumulation and degradation, and in cycloheximide-treated cells. To measure alpha-tubulin mRNA poly(A) chain lengths with high resolution, specific 3' fragments of alpha 1- and alpha 2-tubulin mRNAs, generated by RNase H digestion of mRNA-oligonucleotide hybrids, were sized by Northern analysis. Both alpha-tubulin mRNAs have a newly synthesized poly(A) chain of about 110 adenylate residues. The poly(A) tails shorten with time, and show an average length of 40 to 60 adenylate residues by 90 minutes after deflagellation, at which time induced alpha-tubulin mRNA is being rapidly degraded. Poly(A) loss is significantly accelerated in cycloheximide-treated cells, and this loss is not attributible simply to the longer time the stabilized molecules spend in the cytoplasm. A large fraction of alpha-tubulin mRNA accumulates as mRNA with very short poly(A) tails (less than 10 residues) in the presence of cycloheximide, indicating that deadenylated alpha-tubulin mRNAs can be stable in vivo, at least in the absence of protein synthesis. The rate and extent of poly(A) loss in cycloheximide are greater for alpha 2-tubulin mRNA than for alpha 1-tubulin mRNA. This difference cannot be attributed to differential ribosome loading. This finding is interesting in that the two mRNAs are very similar in sequence with the exception of their 3' untranslated regions.

Novel electrophoretic approach to study of poly(A)+RNA pool heterogeneity in different areas of human postmortem brain

A simple method for fast fractionation of human postmortem brain total poly(A)+RNA has been developed. Guanidine thiocyanate extractable RNA was directly applied on the membranes of cellulose nitrate with immobilized oligo(dT) chains. After the electrophoresis in 35 mM tris-acetete buffer (pH 7.90) containing 10 mM EDTA and 35% formamide, the membranes were washed with the same buffer for removal of nonbinding poly(A)-lacking RNAs. Then, poly(A)+RNA fractions were selectively stained by 3,5-dimethylphenol in the presence of FeCl3 at pH 2.35. Finally, the resulting electrophorograms were scanned at 500 nm for quantitative evaluation of the data.

Messenger RNA changes during differentiation of murine erythroleukemia cells

During differentiation of murine erythroleukemia cells, the levels of certain mRNA were observed to change. To characterize the various patterns of changes that occur during differentiation, cDNA libraries made from RNA isolated from uninduced and differentiating cells were screened with labeled cDNA or RNA labeled in vivo for different periods of time. cDNA clones that corresponded to individual mRNAs whose level remained constant, increased, or decreased during differentiation were identified. These clones were used to analyze Northern blots containing RNA from uninduced and differentiated cells. A number of characteristic changes in individual mRNAs in differentiating murine erythroleukemia cells could be identified, such as no change, increase in concentration, increase in concentration and slight change in size, decrease in concentration, decrease in concentration and change in size, appearance of new band(s) of entirely different size, and change in relative concentrations of two related mRNAs. Measurements of rates of mRNA synthesis and degradation suggest that both parameters change during differentiation and that these changes are instrumental in establishing cellular concentration of specific mRNAs. It seems that the changes in mRNA stability observed in differentiating murine erythroleukemia cells may be associated with changes in the primary structure of the transcribed portion of mRNA. The observation that specific mRNA synthesized before and after induction may have very different stabilities at the same point in differentiation supports this hypothesis.

Length polymorphism in the 3' noncoding region of rat hepatic alpha 2u-globulin mRNAs

We detected two size classes in rat liver alpha 2u-globulin mRNAs when analyzing cDNA clones, and named the mRNAs corresponding to the cDNA clones having longer and shorter sizes as L-type and S-type, respectively. When sequencing these cDNA clones, a 25 base insertion was present in the L-type at the 6th exon-intron junction. The extra sequence coincided with the 5' part of the reported 6th intronic sequence that is directly contiguous to the 3' part of the 6th exon. The relative abundance of L- and S-type mRNAs in the steady-state liver was determined by a sensitive S1 nuclease analysis using the probe prepared from the L-type cDNA. The same method was also applied for the determination of the L/S ratios during the course of postnatal development and estrogen treatment, all resulting in similar values, of about 0.03. These findings indicated that L-type and S-type mRNAs are generated by an alternative splicing mechanism in the 3' noncoding region of alpha 2u-globulin transcripts. Sequence analysis also elucidated the presence of at least two active genes showing exactly the same pattern of alternative splicing.

Modulation of messenger RNA metabolism in experimental methyl mercury neurotoxicity

We have investigated the effects of methyl mercury of mRNA metabolism in mouse brain cells in vivo. It was demonstrated that methyl mercury substantially reduces the rate of synthesis of ATP and poly(A)-segments of mRNAs. The molecular sizes of poly(A)-segments isolated from hnRNA and polysomal mRNA of the experimental animal brain are smaller than the dimensions of the same segments from the cellular RNA of intact mice. A fall in the mRNA polyadenylation rate seen under methyl mercury directly correlates with reduced metabolic stability (t 1/2) of the respective poly(A)+mRNA. The mean time of nuclear-cytoplasmic transport of these mRNAs (t0 is substantially increased under methyl mercury. At the same time, methyl mercury has no effect on the metabolism of brain polysomal poly(A)-mRNA. Direct addition of methyl mercury to an in vitro system containing excess ATP failed to affect the activity of poly(A) polymerase isolated from the brain of intact mice. The poison-induced alterations in the poly(A)+mRNA metabolism bring about a considerable reduction of the poly(A)+-fraction's share in the total polysomal mRNA and dramatic fall in the intracellular polysomes concentration. All the alterations in the examined metabolic parameters well correlate both with a reduced ATP content in the brain tissue and decreased rate of total protein synthesis in brain cells. Proceeding from these results as well as data from the literature, we developed a hypothetical model of a general molecular mechanism whereby methyl mercury inhibits protein synthesis in the brain.

A conserved AU sequence from the 3' untranslated region of GM-CSF mRNA mediates selective mRNA degradation

The mRNAs of transiently expressed genes frequently contain an AU-rich sequence in the 3' untranslated region. We introduced a 51 nucleotide AT sequence from a human lymphokine gene, GM-CSF, into the 3' untranslated region of the rabbit beta-globin gene. Our experiments demonstrate that this caused the otherwise stable beta-globin mRNA to become highly unstable in vivo. The instability conferred by the AU sequence in the mRNA was partially alleviated by treatment of the cells with cycloheximide. We propose that the AU sequences are the recognition signal for an mRNA processing pathway which specifically degrades the mRNAs for certain lymphokines, cytokines, and proto-oncogenes.

Structural features of the 5' noncoding region of the rabbit globin messenger RNAs engaged in translation

Accessible sites in the 5' noncoding region of the rabbit alpha- and beta-globin mRNAs were identified and compared in deproteinized RNA and in the mRNAs engaged in translation in the reticulocyte lysate. Preparations of RNA and lysate were subjected to limited nuclease digestion by RNase T1 and Neurospora endonuclease, and the cleavage sites were analyzed by a nuclease S1 mapping procedure. The free alpha-globin mRNA contained few nuclease-sensitive sites and its initiation codon AUG was masked. The free beta-globin mRNA contained a larger number of accessible sites and its AUG was highly exposed. The distribution of sensitive sites differed considerably in the lysate. In both mRNA species, a site near the 5' terminus became the one most accessible to Neurospora endonuclease. Also the accessibility of the AUG in beta-globin mRNA decreased considerably. The distribution of accessible sites in the lysate was the same when the mRNAs were undergoing rapid initiation and when initiation became limited after prolonged incubation. Inhibition of initiation by the cap analogue 7-methylguanosine 5'-triphosphate was accompanied by increased sensitivity of some of the sites in both mRNA species. One of the accessible sites in each mRNA species had a sequence complementary to the 3'-terminal portion of the 18S ribosomal RNA.

An analysis of the rate of metallothionein mRNA poly(A)-shortening using RNA blot hybridization

A progressive reduction in the size of rat metallothionein-1 mRNA following induction by copper chloride or dexamethasone was demonstrated on RNA blots, and was shown to be due to shortening of the poly(A)-tail. The rate of poly(A) removal was the same in rat liver and kidney following copper chloride induction, in rat liver following dexamethasone induction, and in mouse liver following copper chloride induction. In mouse liver metallothionein-1 and 2 mRNAs were shortened at the same rate. The reduction of the poly(A) tail was more rapid in the first 5 hours (approximately 20 nucleotides/h) but much slower (approximately 3 nucleotides/h) after the poly(A)-tail had been reduced to about 60 residues. Metallothionein mRNA molecules with poly(A) tail sizes less than 30-40 nucleotides were not observed. Exonuclease digestion of the poly(A)-tail is suggested, at least in the initial rapid phase. It is hypothesized that poly(A)-tails longer than 30 are required for mRNA stability and that much longer poly(A) tails may give newly synthesized mRNA molecules a competitive advantage in protein synthesis.

Regulation of messenger RNA stability in mouse erythroleukemia cells

The decay rates of several messenger RNA species were determined in mouse erythroleukemia cells. The t1/2 values for the actin and tubulin mRNAs were 16 to 26 hours and about seven hours, respectively. The globin mRNA, and two mRNA species subject to translation repression, the P40 and P21 mRNAs, were about as stable as the ribosomal RNA. A stable tubulin mRNA component also appeared to be present in the cells. Exposure of the cells to dimethylsulfoxide for 48 hours led to considerable increases in the rates of decay of all but the globin mRNA. The induction of erythroid differentiation caused by the drug appears to lead to activation of a mRNA-degradation process that affects individual species to different degrees. The newly synthesized actin and tubulin mRNAs lost their poly(A) rather rapidly. This was accompanied by accumulation of poly(A)-deficient mRNA chains, particularly in the case of actin mRNA. The steady-state distribution of mRNA components, determined by Northern blot analysis, also showed that the actin mRNA and one tubulin mRNA species have a high proportion of poly(A)-deficient molecules. The globin, P40 and P21 mRNAs showed little tendency to lose their poly(A) sequence. The steady-state globin and P40 mRNAs also had a low proportion of chains depleted of poly(A). For all five species, the proportions of poly(A)-deficient chains in newly synthesized mRNA were about the same in uninduced and induced cells, in spite of the large decreases in mRNA stability in the induced cells. The lack of correlation between tendency to lose poly(A) and rate of mRNA decay, and the large accumulation of poly(A)-deficient molecules in the cases of the actin and tubulin mRNAs suggest that the stability of mRNA is not determined solely by the presence of poly(A) on the RNA chains. The behavior of the untranslated species in induced and uninduced cells also fails to support the notion of a relationship between translation and mRNA decay.

Preparation of a "functional library" of African green monkey DNA fragments which substitute for the processing/polyadenylation signal in the herpes simplex virus type 1 thymidine kinase gene

Fragments of African green monkey (Cercopithecus aethiops) DNA (3.5 to 18.0 kilobases) were inserted downstream from the thymidine kinase (TK, tk) coding region in pTK206/SV010, a gene construct which lacks both copies of the hexanucleotide 5'-AATAAA-3' and contains a simian virus 40 origin of replication, allowing it to replicate in Cos-1 cells. No polyadenylated tk mRNA was detected in Cos-1 cells transfected by pTK206/SV010. The ability of simian DNA fragments to restore tk gene expression was examined by measuring the incorporation of [125I]iododeoxycytidine into DNA in Cos-1 cells transfected by pTK206/SV010 insertion derivatives. tk gene expression was restored by the insertion in 56 of the 67 plasmids analyzed, and the level of expression equaled or exceeded that obtained with the wild-type tk gene in 30 of these. In all plasmids examined that showed restoration of tk gene expression, polyadenylated tk mRNA of discrete size was detected. The sizes of these tk mRNAs were consistent with the existence of processing and polyadenylation signals within the inserted DNA fragments. The frequency with which inserted fragments restored tk gene expression suggests that the minimal signal for processing and polyadenylation is a hexanucleotide (AAUAAA or a similar sequence). LTK- cells were biochemically transformed to TK+ with representative insertion constructs. pTK206/SV010 transformed LTK- cells at a very low frequency; the frequency of transformation with insertion derivatives was 40 to 12,000 times higher.

Preparation of a "functional library" of African green monkey DNA fragments which substitute for the processing/polyadenylation signal in the herpes simplex virus type 1 thymidine kinase gene

Fragments of African green monkey (Cercopithecus aethiops) DNA (3.5 to 18.0 kilobases) were inserted downstream from the thymidine kinase (TK, tk) coding region in pTK206/SV010, a gene construct which lacks both copies of the hexanucleotide 5'-AATAAA-3' and contains a simian virus 40 origin of replication, allowing it to replicate in Cos-1 cells. No polyadenylated tk mRNA was detected in Cos-1 cells transfected by pTK206/SV010. The ability of simian DNA fragments to restore tk gene expression was examined by measuring the incorporation of [125I]iododeoxycytidine into DNA in Cos-1 cells transfected by pTK206/SV010 insertion derivatives. tk gene expression was restored by the insertion in 56 of the 67 plasmids analyzed, and the level of expression equaled or exceeded that obtained with the wild-type tk gene in 30 of these. In all plasmids examined that showed restoration of tk gene expression, polyadenylated tk mRNA of discrete size was detected. The sizes of these tk mRNAs were consistent with the existence of processing and polyadenylation signals within the inserted DNA fragments. The frequency with which inserted fragments restored tk gene expression suggests that the minimal signal for processing and polyadenylation is a hexanucleotide (AAUAAA or a similar sequence). LTK- cells were biochemically transformed to TK+ with representative insertion constructs. pTK206/SV010 transformed LTK- cells at a very low frequency; the frequency of transformation with insertion derivatives was 40 to 12,000 times higher.

Poly(A) length, cytoplasmic adenylation and synthesis of poly(A)+ RNA in early mouse embryos

The poly(A) content of early mouse embryos fluctuates widely: after a transient increase in the one-cell embryo, there is a 70% drop in the two-cell and an approximately fivefold increase between the two-cell and early blastocyst stages (L. Pikó and K. B. Clegg, 1982, Dev. Biol. 89, 362-378). To shed light on the significance of these changes, we analyzed the size distribution of total poly(A) from embryos at different stages of development by gel electrophoresis and hybridization with [3H]poly(U). The number-average size of poly(A) tracts varies only slightly, from 61 to 77 nucleotides, indicating that the changes in poly(A) content are due primarily to changes in the number of poly(A) sequences, i.e., the number of poly(A)+ mRNA. From these data, the number of poly(A)+ mRNA can be estimated as follows: ovulated egg, 1.7 x 10(7); one-cell embryo, 2.4 x 10(7); late two-cell, 0.7 x 10(7); late eight-cell, 1.3 x 10(7); and early blastocyst, 3.4 x 10(7). These results suggest the elimination of the bulk of maternal poly(A)+ mRNA at the two-cell stage, to be replaced by newly synthesized mRNA derived from the embryonic genome. To study the synthesis of poly(A)+ mRNA, we cultured mouse embryos in vitro with [3H]adenosine and analyzed the labeled poly(A)+ RNA as to molecular size, length of the poly(A) tail, and relative distribution of label in poly(A) vs internal locations. We observed an active incorporation of label into large-molecular-weight (average size about 2 kb) poly(A)+ RNA at all stages from the one-cell to the blastocyst. However, in the one-cell embryo, about 70% of the label was localized in the poly(A) tail, suggesting cytoplasmic polyadenylation, and only about 30% was localized in the remainder of the molecule, suggesting the complete new synthesis of a small amount of poly(A)+ RNA. Differences in the size distribution of the labeled poly(A) as compared with the total poly(A) in the one-cell embryo indicate that the labeling is not due to a general turnover of poly(A) tails, but rather to the polyadenylation of previously nonpolyadenylated, stored RNA. Significant new synthesis of poly(A)+ RNA is evident from the two-cell stage onward and most likely accounts for the sharp rise in the number of poly(A)+ RNA molecules by the early blastocyst stage.

Quantitation of muscle-specific mRNAs by using cDNA probes during chicken embryonic muscle development in ovo

The emergence of abundant-class mRNAs specific for contractile muscle proteins and their distribution between polysomal and free mRNP fractions were studied in skeletal muscle excised from chicken embryos during the transition from myoblasts (day 9) to myotubes (day 18). Muscle-specific cDNA was selectively prepared by hybridizing cDNA to template RNA (polysomal poly(A)+ mRNA) from day-14 embryos followed by isolation of the abundant class, which represents approximately 20% of total mRNA. The specificity of the cDNA probe for this class was confirmed by the differential degree of hybridization to cytoplasmic RNA from cultured myotube and myoblast cells and by its inability to hybridize with mRNA from nonmuscle cells such as liver. Except for muscle from day-9 embryos, the concentrations of the abundant-class muscle-specific mRNAs were higher in polysomes than in free mRNP fractions. Furthermore, the levels of these mRNAs in polysomes increased 12-fold from day 9 (myoblast) to day 14 (intermediate) with a further 3.6-fold increase from day 14 to day 18 (myotube). In contrast to this 45-fold net increase in the polysomal level of these mRNAs from day 9 to day 18, the levels in the free mRNP fraction showed only a 3-fold decrease during this period. Because the amount of mRNA lost from the mRNP fraction is much less than the net increase in the polysome fraction, mRNP does not serve as a reservoir of untranslated muscle-specific mRNA for transfer to polysomes. Consequently, the emergence of muscle-specific polysomal mRNA for contractile proteins during myogenesis in ovo appears to be regulated primarily by transcriptional control.

Nonadenylylated mRNA is present as polyadenylylated RNA in nuclei of Drosophila

The sequence complexity of nuclear total RNA and nuclear poly(A)+RNA from Drosophila third-instar larvae was determined by hybridization of these RNAs to labeled single-copy DNA. At saturation, the nuclear poly(A)+ - and total RNA hybridized to 11% and 22.5% of the single-copy DNA, respectively. The increase in complexity of nuclear total RNA over that observed for nuclear poly(A)+RNA indicates the presence of a discrete class of nonoadenylylated nuclear RNA molecules. The relationship between DNA sequences coding for nuclear RNA and mRNA was then determined by hybridization of nuclear total and poly(A)+RNA to DNA enriched for mRNA coding sequences. The results of these studies show that those single-copy DNA sequences that are represented in either the poly(A)+ - or poly(A)- mRNA population are transcribed into RNA molecules that appear in the nuclear poly(A)+RNA population.

Structure and function of rat liver polysome populations. I. Complexity, frequency distribution, and degree of uniqueness of free and membrane-bound polysomal polyadenylate-containing RNA populations

Free and membrane-bound polysomes were isolated from rat liver in high yields with minimal degradation, cross-contamination, or contamination by nuclear or nonpolysomal cytoplasmic ribonucleoprotein. Poly(A)+ RNA fractions isolated from free and bound polysomal RNA (poly(A)+ RNAfree and poly(A)+ RNAbound) by oligo(dT) cellulose chromatography exhibited number-average lengths of 1,600 and 1,200 nucleotides, respectively, on formamide sucrose gradients. Poly(A)+ RNAfree and poly(A)+ RNAbound contain 9.1 +/- 0.55 and 10.7 +/- 0.50% poly(A) as measured by hybridization to [3H]poly(U) and comprise 2.37 and 1.22% of their respective polysomal RNA populations. Homologous poly(A)+ RNA-cDNA hybridizations revealed that greater than 95% of the mass of poly(A)+ RNAfree and poly(A)+ RNAbound contain nucleotide complexities of about 3.4 x 10(7) and 6.0 x 10(6), respectively. This represents about 20,000 and 5,000 poly(A)+ RNA species of average sizes. Heterologous hybridizations suggested that considerable overlap exists between poly(A)+ RNAfree and poly(A)+ RNAbound sequences that cannot be attributed to cross-contamination. This was confirmed by conducting heterologous reactions using kinetically enriched cDNA populations. Heterologous hybridizations involving poly(A)+ RNA derived from tightly bound polysomes and cDNAfree indicated tha most of the overlapping sequences are not contributed by loosely bound (high-salt releasable) polysomes. The ramifications of these findings are discussed.

Detection of high levels of polyadenylate-containing RNA in bacteria by the use of a single-step RNA isolation procedure

A new one-step procedure for the isolation of bacterial RNA, involving lysis by proteinase K in the presence of sodium dodecyl sulfate, is described. Pulse-labeled RNA isolated by this procedure for Bacillus brevis, Bacillus subtilis, and Escherichia coli B has been found to contain a substantial fraction (15-40%) of polyadenylated RNA as determined by adsorption to oligo(dT)-cellulose. This contrasts with RNA isolated by procedures involving phenol extraction, a process which appears to lead to the selective loss of polyadenylated RNA. The presence of polyadenylated RNA in E. coli was confirmed by an independent method which involved hybridization with [3H]polyuridylic acid. Using the proteinase K method for RNA isolation, it was possible to demonstrate the in vitro synthesis of polyadenylated RNA by toluene-treated cells of B. brevis, B. subtilis, and E. coli.

Cytoplasmic processing events in the polyadenylate region of Physarum messenger RNA

Cytoplasmic processing events in the poly(A) region of mRNA from Physarum polycephalum are reviewed. Two classes of poly-containing RNA [poly(A)+ RNA] exist in the cytoplasm. One contains very short poly(A) sequences, averaging about 15 adenylate residues, while the other contains relatively long poly(A) sequences, averaging about 60 residues. Molecules with short poly(A) sequences are found exclusively in the polysomes while those with long poly(A) sequences are restricted to the free cytoplasmic mRNP. Since proteins are associated with only the long poly(A) sequences the poly(A) . protein complex is also restricted to the free mRNP. The long poly(A) sequences are relatively short-lived. They are degraded by two distinct processes, a shortening process in which 15-20 residues are gradually removed and a turnover process in which long poly(A) tracts are rapidly converted to the short sequences. This process, along with the dissociation of the poly(A) . protein complex, occurs when poly(A)+ RNA molecules located in free mRNP are transferred to the polysomes. Poly(A) . protein complex dissociation appears to precede poly(A) turnover during translational selection. The significance of these processing events in relation to mRNA maturation is discussed.

Cytoplasmic polyadenylate processing events accompany the transfer of mRNA from the free mRNP particles to the polysomes in Physarum

The relationship between the mRNA in the polysomes and the free cytoplasmic messenger ribonucleoprotein of Physarum polycephalum was studied by microinjection techniques. Labeled free cytoplasmic ribonucleoprotein, prepared from donor plasmodia, was microinjected into unlabeled host plasmodia, and its fat was followed in the host ribonucleoprotein particles. Approximately one-half of the poly(A)-containing RNA [poly(A)+RNA] that originated from the microinjected particles was incorporated into the host polysomes by normal translational processes within 1 hr. Very short poly(A) sequences (approximately 15 nucleotide residues) were found in these poly(A)+RNA molecules. These short poly(A) sequences were sensitive to digestion with micrococcal nuclease, suggesting that they were not associated with protein. Because the poly(A)+RNA molecules of the microinjected free cytoplasmic mRNP had originally contained poly(A) sequences 50-65 nucleotides long and were associated with protein extensive poly(A) degradation and poly(A).protein complex dissociation must have occurred during their incorporation into the polysomes or during their translation. These results demonstrate a precursor-product relationship between free cytoplasmic mRNP and polysomal mRNA and suggest that the incorporation process in Physarum is accompanied by structural modifications in the poly(A) region of mRNA. They also imply that the polysome is a site for disruption of the poly(A).protein complex and poly(A) degradation.

The Role of the poly(A) sequence in mammalian messenger RNA

The poly(A) sequence is added to 3' termini of nuclear RNA segments destined to become part of the mRNA, and may play an essential role in the selection of these segments. It appears to be required for at least some of the splicing events involved in mRNA processing. In the cytoplasm, the poly(A) segment is the target of a degradation process which causes its gradual shortening, and leads to a heterogeneous steady-state poly(A)-size distribution. Complete loss of the poly(A) is probably followed by inactivation of the mRNA, since chains depleted of poly(A) do not accumulate in the cells. A role for this sequence in the promotion of mRNA stability is suggested by the behavior of globin mRNA depleted of poly(A) after injection into frog oocytes. The poly(A) shortening process may be part of the mRNA inactivation mechanism, as indicated by the greater sensitivity to degradation of the poly(A) of some short-lived mRNAs. However, the stochastic mRNA decay implies that new and old mRNA chains, with long and short poly(A) segments, respectively are equally susceptible to inactivation. The poly(A)-lacking histone mRNAs are stable only in cells engaged in DNA replication. Present knowledge favors a role for poly(A) in the control of mRNA stability. Loss of this sequence could be controlled through modulation of poly(A)-protein interactions or through masking of a sequence directly adjacent to the poly(A). In the nucleus, the poly(A) sequence could also serve as stabilizing agent, but, in addition, it might interact with the splicing machinery.