Adenine-rich polymer associated with rabbit reticulocyte messenger RNA

Enhancing RNA-lipid nanoparticle delivery: Organ- and cell-specificity and barcoding strategies

Recent advancements in RNA therapeutics highlight the critical need for precision gene delivery systems that target specific organs and cells. Lipid nanoparticles (LNPs) have emerged as key vectors in delivering mRNA and siRNA, offering protection against enzymatic degradation, enabling targeted delivery and cellular uptake, and facilitating RNA cargo release into the cytosol. This review discusses the development and optimization of organ- and cell-specific LNPs, focusing on their design, mechanisms of action, and therapeutic applications. We explore innovations such as DNA/RNA barcoding, which facilitates high-throughput screening and precise adjustments in formulations. We address major challenges, including improving endosomal escape, minimizing off-target effects, and enhancing delivery efficiencies. Notable clinical trials and recent FDA approvals illustrate the practical applications and future potential of LNP-based RNA therapies. Our findings suggest that while considerable progress has been made, continued research is essential to resolve existing limitations and bridge the gap between preclinical and clinical evaluation of the safety and efficacy of RNA therapeutics. This review highlights the dynamic progress in LNP research. It outlines a roadmap for future advancements in RNA-based precision medicine.

Decoupled degradation and translation enables noise modulation by poly(A) tails

Poly(A) tails are crucial for mRNA translation and degradation, but the exact relationship between tail length and mRNA kinetics remains unclear. Here, we employ a small library of identical mRNAs that differ only in their poly(A)-tail length to examine their behavior in human embryonic kidney cells. We find that tail length strongly correlates with mRNA degradation rates but is decoupled from translation. Interestingly, an optimal tail length of ∼100 nt displays the highest translation rate, which is identical to the average endogenous tail length measured by nanopore sequencing. Furthermore, poly(A)-tail length variability-a feature of endogenous mRNAs-impacts translation efficiency but not mRNA degradation rates. Stochastic modeling combined with single-cell tracking reveals that poly(A) tails provide cells with an independent handle to tune gene expression fluctuations by decoupling mRNA degradation and translation. Together, this work contributes to the basic understanding of gene expression regulation and has potential applications in nucleic acid therapeutics.

Roles of mRNA poly(A) tails in regulation of eukaryotic gene expression

In eukaryotes, poly(A) tails are present on almost every mRNA. Early experiments led to the hypothesis that poly(A) tails and the cytoplasmic polyadenylate-binding protein (PABPC) promote translation and prevent mRNA degradation, but the details remained unclear. More recent data suggest that the role of poly(A) tails is much more complex: poly(A)-binding protein can stimulate poly(A) tail removal (deadenylation) and the poly(A) tails of stable, highly translated mRNAs at steady state are much shorter than expected. Furthermore, the rate of translation elongation affects deadenylation. Consequently, the interplay between poly(A) tails, PABPC, translation and mRNA decay has a major role in gene regulation. In this Review, we discuss recent work that is revolutionizing our understanding of the roles of poly(A) tails in the cytoplasm. Specifically, we discuss the roles of poly(A) tails in translation and control of mRNA stability and how poly(A) tails are removed by exonucleases (deadenylases), including CCR4-NOT and PAN2-PAN3. We also discuss how deadenylation rate is determined, the integration of deadenylation with other cellular processes and the function of PABPC. We conclude with an outlook for the future of research in this field.

A proposal for comprehensive newborn hearing screening to improve identification of deaf and hard-of-hearing children

Early intervention for newborns who are deaf or hard-of-hearing leads to improved language, communication, and social-emotional outcomes. Universal physiologic newborn hearing screening has been widely implemented across the United States with the goal of identifying newborns who are deaf or hard-of-hearing, thereby reducing time to diagnosis and intervention. The current physiologic newborn hearing screen is generally successful in accomplishing its goals but improvements could be made. In the past ten years, genetic testing has emerged as the most important etiological diagnostic test for evaluation of children with deafness and congenital cytomegalovirus has been recognized as a major cause of childhood deafness that may be treatable. A comprehensive newborn hearing screen that includes physiologic, genetic, and cytomegalovirus testing would have multiple benefits, including (1) identifying newborns with deafness missed by the current physiologic screen, (2) providing etiologic information, and (3) possibly decreasing the number of children lost to follow up. We present a framework for integrating limited genetic testing and cytomegalovirus screening into the current physiologic newborn hearing screening. We identify needed areas of research and include an overview of genome sequencing, which we believe will become available over the next decade as a complement to universal physiologic newborn hearing screening.

Tales around the clock: Poly(A) tails in circadian gene expression

Circadian rhythms are ubiquitous time-keeping processes in eukaryotes with a period of ~24 hr. Light is perhaps the main environmental cue (zeitgeber) that affects several aspects of physiology and behaviour, such as sleep/wake cycles, orientation of birds and bees, and leaf movements in plants. Temperature can serve as the main zeitgeber in the absence of light cycles, even though it does not lead to rhythmicity through the same mechanism as light. Additional cues include feeding patterns, humidity, and social rhythms. At the molecular level, a master oscillator orchestrates circadian rhythms and organizes molecular clocks located in most cells. The generation of the 24 hr molecular clock is based on transcriptional regulation, as it drives intrinsic rhythmic changes based on interlocked transcription/translation feedback loops that synchronize expression of genes. Thus, processes and factors that determine rhythmic gene expression are important to understand circadian rhythms. Among these, the poly(A) tails of RNAs play key roles in their stability, translational efficiency and degradation. In this article, we summarize current knowledge and discuss perspectives on the role and significance of poly(A) tails and associating factors in the context of the circadian clock. This article is categorized under: RNA Turnover and Surveillance > Regulation of RNA Stability RNA Processing > 3' End Processing.

Poly a blocks in the nuclear ribonucleoprotein complexes, containing pre-mRNA

Poly A was found in nuclear particles containing pre-mRNA. It was shown that during the isolation of 30S particles from rat liver or Ehrlich ascites carcinoma nuclei, all poly A is detached from the particles containing pre-mRNA and is found in the form of RNP with a sedimentation coefficient of about 14S. When RNP polyparticles are isolated in the presence of RNase inhibitor poly A is distributed among the particles of higher molecular weights.Since the sedimentation properties and buoyant density of the poly A-containing particles are different from the 30S particles it was suggested that the poly A fragments are bound not with informofers, but with another kind of protein.

Ending the message: poly(A) signals then and now

Polyadenylation [poly(A)] signals (PAS) are a defining feature of eukaryotic protein-coding genes. The central sequence motif AAUAAA was identified in the mid-1970s and subsequently shown to require flanking, auxiliary elements for both 3'-end cleavage and polyadenylation of premessenger RNA (pre-mRNA) as well as to promote downstream transcriptional termination. More recent genomic analysis has established the generality of the PAS for eukaryotic mRNA. Evidence for the mechanism of mRNA 3'-end formation is outlined, as is the way this RNA processing reaction communicates with RNA polymerase II to terminate transcription. The widespread phenomenon of alternative poly(A) site usage and how this interrelates with pre-mRNA splicing is then reviewed. This shows that gene expression can be drastically affected by how the message is ended. A central theme of this review is that while genomic analysis provides generality for the importance of PAS selection, detailed mechanistic understanding still requires the direct analysis of specific genes by genetic and biochemical approaches.

Mechanisms of deadenylation-dependent decay

Degradation of messenger RNAs (mRNAs) plays an essential role in modulation of gene expression and in quality control of mRNA biogenesis. Nearly all major mRNA decay pathways characterized thus far in eukaryotes are initiated by deadenylation, i.e., shortening of the mRNA 3(') poly(A) tail. Deadenylation is often a rate-limiting step for mRNA degradation and translational silencing, making it an important control point for both processes. In this review, we discuss the fundamental principles that govern mRNA deadenylation in eukaryotes. We use several major mRNA decay pathways in mammalian cells to illustrate mechanisms and regulation of deadenylation-dependent mRNA decay, including decay directed by adenine/uridine-rich elements (AREs) in the 3(') -untranslated region (UTR), the rapid decay mediated by destabilizing elements in protein-coding regions, the surveillance mechanism that detects and degrades nonsense-containing mRNA [i.e., nonsense-mediated decay (NMD)], the decay directed by miRNAs, and the default decay pathway for stable messages. Mammalian mRNA deadenylation involves two consecutive phases mediated by the PAN2-PAN3 and the CCR4-CAF1 complexes, respectively. Decapping takes place after deadenylation and may serve as a backup mechanism to trigger mRNA decay if initial deadenylation is compromised. In addition, we discuss how deadenylation impacts the dynamics of RNA processing bodies (P-bodies), where nontranslatable mRNAs can be degraded or stored. Possible models for mechanisms of various deadenylation-dependent mRNA decay pathways are also discussed.

Poly(A) polymerase and poly(g) polymerase in wheat chloroplasts

Extracts of wheat chloroplasts contain a poly(A) polymerase which can polymerize AMP residues from ATP onto an RNA primer. Whole extracts of wheat leaves also contain another poly(A) polymerase which is present in much larger amount and is probably derived from the nuclei. Both polymerases can utilize as primer poly(A), poly(C), transfer RNA, and ribosomal RNA, but only the chloroplast polymerase can utilize poly(U) and poly(G). Both enzymes have a specific requirement for ATP. Extracts of wheat chloroplasts contain, in addition to the poly(A) polymerase, a poly(G) polymerase which can polymerize GMP residues from GTP onto primers such as poly(G), poly(A), or ribosomal RNA. The poly(G) polymerase cannot utilize ATP but can slowly polymerize CMP from CTP. When the two chloroplast polymerases are present together in an in vitro incubation with ATP plus GTP and poly(A), the polymerization product is a mixed poly(A,G) tract.

[Genetics and molecular medicine in cardiology]

The discoveries on molecular aspects of cellular function are changing the concepts of health and disease. All medical fields, including cardiology, have been enriched with several diagnostic test to determine predisposition and to detect molecular dysfunctions. This review on the genetic and molecular aspects of cardiovascular diseases is written at the Centenary of the rediscovery of Mendel's principles on heredity and at the time of the announcement of the end of the human genome sequencing task. The review starts with considerations on the pluricellular constitution of the human body, and the principles of genetics with their molecular bases; including a short description of the methods for gene mapping. The following sections give a historic synopsis on the concepts of medical genetics, molecular medicine, and the Human Genome Project. The review ends with a brief description of the spectrum of genetic diseases, using examples of cardiovascular diseases.

Generation of catalytically active 6-phosphofructokinase from Saccharomyces cerevisiae in a cell-free system

PFK1 and PFK2 coding for the subunits of 6-phosphofructokinase from Saccharomyces cerevisiae were cloned into plasmids suitable for runoff transcription. In vitro translation products of both kinds of subunit were obtained using rabbit reticulocyte lysate as the synthesis and folding system. They were monitored by chemiluminescent Western-blot analysis. Folding and assembly of the alpha-subunit and beta-subunit of 6-phosphofructokinase were found to occur in the cell-free system resulting in an enzymatically active protein. The in vitro generated enzyme exhibits a folding state that is similar to that of the heterooctameric form of 6-phosphofructokinase in the presence of fructose 6-phosphate, ATP and ammonium sulfate, as demonstrated by size-exclusion HPLC followed by ELISA.

Poly(A) dependent translation in rabbit reticulocyte lysate

Poly(A) tail has been known to enhance mRNA translation in eukaryotic cells. However, the effect of poly(A) tail in in vitro is rather small. Rabbit reticulocyte lysate (RRL) is widely used for studying translation in vitro. Translation in RRL is typically performed in nuclease-treated lysate in which most of the endogenous mRNA have been removed. In this condition, the difference in the translational efficiency between poly(A)+ and poly(A)- mRNAs is about two-fold. We studied the effect of poly(A) tail on luciferase mRNA translation in nuclease untreated rabbit reticulocyte lysate, in which endogenous globin mRNAs were actively translated. In the case of capped mRNAs, stimulation of translation by poly(A) addition was about 1.5- to 1.6-fold and the effect of the poly(A) length was small. However, in the case of uncapped mRNAs, the addition of poly(A) tail increased luciferase expression over 10-fold. The effect of the poly(A) tail was dependent on its length. The difference in the translational efficiency was not due to the change of mRNA stability. These data indicate that RRL has the potential to translate mRNA in a poly(A) dependent manner.

Mutations in STS1 suppress the defect in 3' mRNA processing caused by the rna15-2 mutation in Saccharomyces cerevisiae

In a search for proteins associated with Rna15p in processing the 3' ends of messenger RNAs, we have looked for suppressors that correct, even partially, the thermosensitive growth defect of the rna15-2 mutant. Mutations in a single locus that we named SSM5, were able to suppress both the thermosensitivity of cell growth and the mRNA 3' processing defect associated with the rna15-2 mutation, but only slightly alleviated the thermosensitive growth defect of an rna14-1 mutant. The ssm5-1 mutant is sensitive to hydroxyurea at 37 degrees C, a drug that inhibits DNA synthesis. By screening for complementation of the hydroxyurea-sensitive phenotype we cloned the corresponding wild-type gene and found that it corresponds to the essential gene STS1 (also named DBF8). Sts1p has an apparent molecular weight of 30 kDa and was confirmed to be a cytosolic protein by immunofluorescence analysis. Western blot analysis indicates that the thermosensitive mutant strains rna15-2, rna14-1 and pap1-1 present a very low level of the Rna15p at 37 degrees C. The ssm5-1 mutation restores the level of Rna15p in the rna15-2 ssm5-1 double mutant. Use of the two-hybrid system suggests that Sts1p does not interact directly with Rna15p, but may be active as a homodimer. The present data suggest that Sts1p may play a role in the transport of Rna15p from the cytoplasm to the nucleus.

ANTISENSE oligonucleotides: a new tool in neuroscience

1. Recent studies have shown that gene expression can be selectively attenuated by administration of short sequences of nucleotides (oligonucleotides) that are complementary to a portion of messenger RNA coding for a particular gene product. 2. This technique is known as ANTISENSE, because the oligonucleotides are complementary to the mRNA which has the same sequence as the SENSE strand of DNA. 3. In the present review we focus, after a brief discussion of gene expression and mechanisms of action of ANTISENSE, on the methodological aspects of ANTISENSE experiments in neuroscience. In particular, we address the advantages, disadvantages and controls for the ANTISENSE technique, as well as the choice, design, mode of delivery, dose and storage of ANTISENSE oligonucleotides.

Why, when and how does the poly(A) tail shorten during mRNA translation?

1. The length of the poly(A) tail at the 3'-end of mRNA may control protein synthesis by bringing the 3'-end in close proximity to the 5'-end of the noncoding region as well as increasing the duration of mRNA translation by its binding to the poly(A) binding protein. 2. The rate-limiting step in the decay of the body of the message is the shortening of a long poly(A) tail during mRNA translation. The shortening of the poly(A) tail occurs during pre-elongation in the protein synthesis cycle. 3. The shortening of the poly(A) tail during mRNA translation may not involve RNase activity, however poly(A) binding protein seems to play a role, at least in part, in shortening of the poly(A) tail.

Two distinct destabilizing elements in the c-fos message trigger deadenylation as a first step in rapid mRNA decay

The mechanisms by which c-fos mRNA is targeted for decay have been examined. Rapid removal of the poly(A) tail occurs before the transcribed portion of the c-fos message is degraded. Identification of the determinants that mediate c-fos message deadenylation reveals that they coincide directly with previously characterized determinants of c-fos mRNA instability, one in the protein-coding region and the other an AU-rich element (ARE) in the 3'-untranslated region. Insertion of either of these c-fos instability elements into the stable beta-globin message confers the property of rapid deadenylation. Mutation of the ARE indicates that this sequence controls two steps in the process of c-fos mRNA degradation: removal of the poly(A) tail, which does not require intact AUUUA pentanucleotides within the ARE, and subsequent degradation of the transcribed portion of the message, which appears to be dependent on the AUUUA pentanucleotides. These results indicate that structurally distinct instability determinants within the transcribed portion of labile messages can function by promoting rapid removal of the poly(A) tail as a first step in the decay process.

mRNA poly(A) tail, a 3' enhancer of translational initiation

To evaluate the hypothesis that the 3' poly(A) tract of mRNA plays a role in translational initiation, we constructed derivatives of pSP65 which direct the in vitro synthesis of mRNAs with different poly(A) tail lengths and compared, in reticulocyte extracts, the relative efficiencies with which such mRNAs were translated, degraded, recruited into polysomes, and assembled into messenger ribonucleoproteins or intermediates in the translational initiation pathway. Relative to mRNAs which were polyadenylated, we found that nonpolyadenylated [poly(A)-]mRNAs had a reduced translational capacity which was not due to an increase in their decay rates, but was attributable to a reduction in their efficiency of recruitment into polysomes. The defect in poly(A)- mRNAs affected a late step in translational initiation, was distinct from the phenotype associated with cap-deficient mRNAs, and resulted in a reduced ability to form 80S initiation complexes. Moreover, poly(A) added in trans inhibited translation from capped polyadenylated mRNAs but stimulated translation from capped poly(A)- mRNAs. We suggest that the presence of a 3' poly(A) tail may facilitate the binding of an initiation factor or ribosomal subunit at the mRNA 5' end.

Tales of poly(A): a review

Until recently, evidence to support a translational role for the 3'-poly(A) tract of eukaryotic mRNAs has been mostly indirect, including: a correlation between the adenylation status of individual mRNAs and their translatability in vivo or in vitro, the demonstration that exogenously added poly(A) is a potent competitive inhibitor of the translation of poly(A)+mRNA, but not poly(A)-mRNAs in vitro, and a correlation between the abundance and stability of poly(A)-binding proteins (PABPs) and the rate of translational initiation in vivo. However, more recent studies demonstrate directly that poly(A)+mRNAs can initiate translation more efficiently than poly(A)-mRNAs, and indicate that this effect is: (i) targeted to the formation of 80S initiation complexes, and (ii) likely to be mediated by the cytoplasmic PABP. We suggest that the 3'-poly(A) tail should be considered a translational enhancer which may stimulate translational initiation in much the same way that transcriptional enhancers are thought to stimulate transcriptional initiation.

mRNA poly(A) tail, a 3' enhancer of translational initiation

To evaluate the hypothesis that the 3' poly(A) tract of mRNA plays a role in translational initiation, we constructed derivatives of pSP65 which direct the in vitro synthesis of mRNAs with different poly(A) tail lengths and compared, in reticulocyte extracts, the relative efficiencies with which such mRNAs were translated, degraded, recruited into polysomes, and assembled into messenger ribonucleoproteins or intermediates in the translational initiation pathway. Relative to mRNAs which were polyadenylated, we found that nonpolyadenylated [poly(A)-]mRNAs had a reduced translational capacity which was not due to an increase in their decay rates, but was attributable to a reduction in their efficiency of recruitment into polysomes. The defect in poly(A)- mRNAs affected a late step in translational initiation, was distinct from the phenotype associated with cap-deficient mRNAs, and resulted in a reduced ability to form 80S initiation complexes. Moreover, poly(A) added in trans inhibited translation from capped polyadenylated mRNAs but stimulated translation from capped poly(A)- mRNAs. We suggest that the presence of a 3' poly(A) tail may facilitate the binding of an initiation factor or ribosomal subunit at the mRNA 5' end.

The poly(A) binding protein is required for poly(A) shortening and 60S ribosomal subunit-dependent translation initiation

Depletion of the essential poly(A) binding protein (PAB) in S. cerevisiae by promoter inactivation or by the utilization of a temperature-sensitive mutation (pab1-F364L) results in the inhibition of translation initiation and poly(A) tail shortening. Reversion analysis of pab1-F364L yielded seven independent, extragenic cold-sensitive mutations (spb1-spb7) that also suppress a PAB1 deletion. These mutations allow translation initiation without significantly changing poly(A) tail lengths in the absence of PAB, and they affect the amount of 60S ribosomal subunit. Consistent with this, SPB2 encodes the ribosomal protein L46. These data suggest that the 60S subunit mediates the PAB requirement of translation initiation, thereby ensuring that only intact poly(A)+ mRNA will be translated efficiently in vivo.

Recombinant DNA--potential for gene therapy

Certainly, if progress in recombinant DNA technology continues at its present rate, we have every reason to expect many more major breakthroughs in the diagnosis and treatment of human disease. Much of the progress from which we already benefit is not the increased understanding of just the molecular basis of genetic disease, but also of the molecular mechanisms of viral, bacterial, and parasite pathogenicity. Exploiting cloned antigens from pathogens to make vaccines is an ever expanding approach to preventive medicine. The other realm from which we already benefit is that in which we have bacteria produce large quantities of product from normal cloned genes, such as insulin, for treatment of patients deficient in that gene product. Although we cannot expect to eliminate some, or even treat all, genetic disease within the foreseeable future, it is quite clear that research in the area of genetic engineering has vast potential for improving the conditions of mankind.

The relationship of the rat brain 68 kDa microtubule-associated protein with synaptosomal plasma membranes and with the Drosophila 70 kDa heat-shock protein

A protein of molecular mass 68 kDa and pI5.6 is a major translation product of rat brain mRNA [Hall, Mahadevan, Whatley, Biswas & Lim (1984) Biochem. J. 219, 751-761]. In the rat brain this protein was associated with microtubule preparations and was present together with tubulin as a component of the synaptosomal plasma membranes, synaptic vesicles and post-synaptic structures. The brain mRNA for this protein was found to hybridize specifically to the Drosophila gene for the 70 kDa heat-shock protein, thus enabling its rapid isolation.

Structural analysis of a 1.7-kilobase mouse mammary tumor virus-specific RNA

We have detected a mouse mammary tumor virus (MMTV)-specific 1.7-kilobase (kb) polyadenylated RNA in mammary glands of several mouse strains. In BALB/c mice, it is the only MMTV-specific RNA species present. C3H and GR mammary glands and tumors contain, in addition, 3.8- and 7.8-kb MMTV RNAs. Nuclease S1 analysis was performed to map 1.7-kb polyadenylated RNA. It contains predominantly long terminal repeat (LTR) sequences. The 5' end maps approximately 134 nucleotides upstream from the 3' end of the LTR. Colinearity with complete proviral DNA continues to a site about 153 nucleotides downstream from the left (5') LTR. No sequences from the middle part of proviral DNA were found. Colinearity with proviral DNA is resumed 72 nucleotides upstream from the right (3') LTR. The nucleotide sequence in this area is TTCCAGT, which is a splice acceptor consensus sequence. The anatomy of 1.7-kb RNA indicates that it may serve as a messenger for the 36,700-dalton protein encoded by the LTRs of MMTV.

The polyadenylated RNA directing the synthesis of the rat myelin basic proteins is present in both free and membrane-bound forebrain polyribosomes

Free and membrane-bound polyribosomes were isolated from the forebrain of actively myelinating 24-day-old rats. The poly(A)+ RNA (polyadenylated RNA) extracted from both fractions was translated in vitro in reticulocyte lysates [Hall & Lim (1981) Biochem. J. 196. 327-336] in the presence or absence of a heterologous microsomal membrane fraction from dog pancreas. The rat myelin basic proteins synthesized in vitro were isolated by CM-cellulose chromatography and by immunoprecipitation with purified anti-(myelin basic protein) antibody. The large (mol.wt. 18 500) and small (mol.wt. 16 000) myelin basic proteins were translational products of poly(A)+ RNA from both free and membrane-bound polyribosomes. The identity of the myelin basic proteins was verified by analysis of peptides generated by the cathepsin D digestion of the immunoprecipitated proteins synthesized in vitro, in comparison with authentic rat myelin basic proteins. Although several other translational products of membrane-bound polyribosomal poly(A)+ RNA were modified when microsomal membranes were present during translation, molecular weights of the myelin basic proteins themselves were unchanged. The myelin basic proteins synthesized in vitro also did not differ significantly in size from the authentic myelin basic proteins, indicating that these membrane proteins are unlikely to be synthesized as substantially larger precursor molecules. The presence of the specific mRNA species on both free and membrane-bound polyribosomes is compatible with the extrinsic location of the myelin basic proteins on the cytoplasmic surface of the myelin membrane.

Cloning of Xenopus laevis nuclear poly(A)-rich RNA sequences. Evidence for post-transcriptional control

cDNA/RNA hybridization experiments of polysomal and nuclear poly(A)-rich RNA from early tadpole stages of Xenopus laevis revealed that part of the nuclear poly(A)-rich RNA sequences are not present within the polysomal polyadenylated RNA. For a more detailed analysis of these sequences we have cloned double-stranded cDNA derived from tadpole nuclear poly(A)-rich RNA in the PstI cleavage site of pBR 322. By colony screening with 32P-labelled cDNA from polysomal and nuclear poly(A)-rich RNA of the tadpole stage we could identify and isolate some of the cloned sequences, which are present only within the nuclear RNA. However, hybridization with cDNA from polysomal poly(A)-rich RNA of the gastrula stage indicated that at least one of those sequences which are confined to the nucleus at tadpole stage may serve as mRNA at gastrula stage. We present evidence that nuclear and polysomal poly(A)-rich RNA molecules containing the same nucleotide sequence differ in size and that size reduction at the level of processing precedes and may enable cytoplasmic export. We conclude that, besides stage-specific regulation of transcription, post-transcriptional control mechanisms are also involved in gene expression during embryonic development.

Stability of non-polyadenylated viral mRNAs injected into frog oocytes

The naturally non-polyadenylated mRNAs of reovirus were shown to have a half-life in excess of 3 days when injected into Xenopus laevis oocytes. Hybridization analysis and gel electrophoresis showed that all 10 mRNA species had a similar high stability, despite being translated at widely differing rates. We have confirmed previous findings indicating a role for the 5'-terminal cap structure in determining reovirus mRNA stability [Furuichi et al. (1977) Nature (Lond.) 266, 235-239]. The significance of these results in relation to a general role for poly(A) in messenger RNA function is discussed.

Developmental changes in the composition of polyadenylated RNA isolated from free and membrane-bound polyribosomes of the rat forebrain, analysed by translation in vitro

Free and membrane-bound polyribosomes were isolated from the rat forebrain during its development. Polyadenylated RNA [poly(A)+ RNA] was isolated from both fractions, by using oligo(dT)-cellulose chromatography, and its composition studied by translating the poly(A)+ RNA in vitro in reticulocyte lysates. Electrophoretic analysis of the translation products showed that both free and membrane-bound polyribosomal poly(A)+ RNA gave many common components, but that there were also distinct differences in the protein composition of the products of the two fractions. Several proteins, of mol.wts. 39 000, 37 000, 31 000, 27 000 and 17 000, appeared to be products predominantly of free polyribosomal poly(A)+ RNA, whereas others, of mol.wt. 47 000, 33 000, 24 000 and 21 000 were specific to the membrane-bound polyribosomal poly(A)+ RNA fraction. More developmental changes were observed in the translational products of the membrane-bound poly(A)+ RNA fraction. Proteins of mol.wts. 33 000 and 21 000, which were predominant components of the translational products of this fraction when isolated from 10-day and older rats, were not present in translational products derived from preparations isolated from 3-day-old rats. The developmental appearance of these proteins as translational products of the membrane-bound poly(A)+ RNA suggests the appearance of new mRNA species. These transcriptional changes are discussed in relation to processes involved in brain differentiation, including myelination.

Long-lasting effects of electroconvulsive shock on the pattern of poly(A)-RNA synthesis in rabbit cerebral cortex

The pattern of poly(A)-associated [poly(A)+] RNA synthesis was studied in rabbit cerebral cortex in the period following a single electroconvulsive shock (ECS). Labeled uridine was injected into the brain 2 and 4 hr after ECS and the animals sacrificed 1 hr later. Total and poly(A)+ RNA were then prepared from cortical nuclei and microsomes and analyzed. The amounts of newly synthesized total and poly(A)+ RNA in nuclei and microsomes appeared to be close to the control. However, the pattern of newly synthesized poly(A)+ nuclear RNA appeared to be still displaced toward the high molecular weights as it was in the early post-ECS period. The result indicates a long-lasting disturbance of brain poly(A)+-RNA metabolism by ECS.

Developmental changes in the protein and ribonucleic acid components of rat brain messenger ribonucleic acid-protein particles isolated from free polyribosomes by oligo(dT)-cellulose chromatography

A study has been made of the developmental changes that occur in the RNA and protein moieties of mRNA-protein particles isolated from newborn and adult rat forebrain free polyribosomes. mRNA-protein particles were isolated by oligo(dT)-cellulose chromatography from salt-washed polyribosomes dissociated by puromycin/0.5 M-KCl treatment as two fractions (E1 and E2) by using Tris/HCl/NaCl eluting buffers containing respectively 25 and 50% (v/v) formamide. Isopycnic centrifugation on CsCl gradients showed that the newborn-derived fractions E1 and E2 has buoyant densities of 1.48--1.50 and 1.41--1.43 g/cm3. Adult-derived E1 and E2 fractions had corresponding values of 1.47 and 1.42 g/cm3. The pooled mRNA-protein particles from the E1 and E2 fractions after deproteinization with proteinase K sedimented with a mean size of approx. 18 S on a sucrose gradient containing 85% formamide with little differences between mRNA molecules from newborn and adult. The mean lengths of the poly(A) segments were similar, being about 130 nucleotides long. Distinct changes were found in the protein composition of the mRNA-protein particles. Fractions E1 and E2 from the newborn contained two major proteins of mol.wts. 74 000 and 52 000 with differences in the relative proportions in each fraction. In contrast, adult fractions E1 and E2 contained predominantly the larger protein. However, the adult fraction E2 contained a more heterogeneous population of minor bands of proteins, including that of mol.wt. 52 000. The findings are discussed briefly in relation to other changes in the developing brain.

Sequence organization of animal nuclear DNA

Animal nuclear genomes contain DNA sequences of various degrees of repetition. These sequences are organized in highly ordered fashions; repetitive and nonrepetitive sequences either alternate in short periods, i.e., short [0.2-0.4 kilobases (kb) long] repeats are flanked by nonrepetitive sequences less than 2 kb long, or in longer periods, with repetitive and/or nonrepetitive sequences extending for several kilobases. There are two main categories of genome organization, namely those exhibiting short-period interspersion and those that do not. There are arguments for and against a regulatory role of short interspersed repetitive sequences. Besides the merely 'statistical' kinetic approach by conventional reassociation kinetics, sequence organization has been studied by restriction endonuclease mapping and nucleotide sequencing. Such studies have revealed some general features of the organization of the eukaryotic gene and its transcripts, namely possible 'promoters', 'leaders', 'introns', 'exons', 'flanking sequences', 'caps', ribosome-binding sites, and poly(A) sequences. This paper discusses how these elements of a gene might serve regulatory roles in its expression.

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.