U1A inhibits cleavage at the immunoglobulin M heavy-chain secretory poly(A) site by binding between the two downstream GU-rich regions

The immunoglobulin M heavy-chain locus contains two poly(A) sites which are alternatively expressed during B-cell differentiation. Despite its promoter proximal location, the secretory poly(A) site is not expressed in undifferentiated cells. Crucial to the activation of the secretory poly(A) site during B-cell differentiation are changes in the binding of cleavage stimulatory factor 64K to GU-rich elements downstream of the poly(A) site. What regulates this change is not understood. The secretory poly(A) site contains two downstream GU-rich regions separated by a 29-nucleotide sequence. Both GU-rich regions are necessary for binding of the specific cleavage-polyadenylation complex. We demonstrate here that U1A binds two (AUGCN(1-3)C) motifs within the 29-nucleotide sequence and inhibits the binding of cleavage stimulatory factor 64K and cleavage at the secretory poly(A) site.     

Rrp6p controls mRNA poly(A) tail length and its decoration with poly(A) binding proteins

Poly(A) (pA) tail binding proteins (PABPs) control mRNA polyadenylation, stability, and translation. In a purified system, S. cerevisiae PABPs, Pab1p and Nab2p, are individually sufficient to provide normal pA tail length. However, it is unknown how this occurs in more complex environments. Here we find that the nuclear exosome subunit Rrp6p counteracts the in vitro and in vivo extension of mature pA tails by the noncanonical pA polymerase Trf4p. Moreover, PABP loading onto nascent pA tails is controlled by Rrp6p; while Pab1p is the major PABP, Nab2p only associates in the absence of Rrp6p. This is because Rrp6p can interact with Nab2p and displace it from pA tails, potentially leading to RNA turnover, as evidenced for certain pre-mRNAs. We suggest that a nuclear mRNP surveillance step involves targeting of Rrp6p by Nab2p-bound pA-tailed RNPs and that pre-mRNA abundance is regulated at this level.     

Isolation and characterization of canine secretory immunoglobulin M.

Canine secretory immunoglobulin M, isolated from both colostrum and bronchial secretions, contained the unique glycoprotein bound secretory component. The presence of this extra subunit accounted for the differences in size, quaternary structure, and antigenicity observed upon comparison of secretory immunoglobulin M with its serum counterpart. Approximately 90% of the isolated secretory immunoglobulin M contained covalently bound secretory component while, in the remainder of the population, secretory component was loosely attached and easily dissociated from the immunoglobulin. Following peptide bond cleavage with cyanogen bromide, the release of bound secretory component and J chain from secretory immunoglobulin M was not detected. Because cyanogen bromide cleavage of secretory immunoglobulin A results in the release of these subunits, differences in the primary structure of secretory immunoglobulin M and secretory immunoglobulin A must exist around the binding sites for secretory component and J chain.     

Structure of the human secretory immunoglobulin M core

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3′-Terminal addition to HeLa cell nuclear and cytoplasmic poly(A)

Examination of poly(A) labeling in the nucleus and cytoplasm of HeLa cells indicates: (1) in accord with previous conclusions (Jelinek et al., 1973) that the nucleus is the site of de novo synthesis of poly(A), (2) both a nuclear and cytoplasmic 3′-terminal addition to poly(A) is described confirming and extending reports by Brawerman (1976) and colleagues, and (3) apparently only molecules bearing poly(A) ~230 nucleotides or longer exit to the cytoplasm.     

Regulation of the nuclear poly(A)-binding protein by arginine methylation in fission yeast

Two structurally different poly(A)-binding proteins (PABP) bind the poly(A) tract of mRNAs in most mammalian cells: PABPC in the cytoplasm and PABP2/PABPN1 in the nucleus. Whereas yeast orthologs of the cytoplasmic PABP are characterized, a gene product homologous to mammalian PABP2 has not been identified in yeast. We report here the identification of a homolog of PABP2 as an arginine methyltransferase 1 (RMT1)-associated protein in fission yeast. The product of the Schizosaccharomyces pombe pab2 gene encodes a nonessential nuclear protein and demonstrates specific poly(A) binding in vitro. Consistent with a functional role in poly(A) tail metabolism, mRNAs from pab2-null cells displayed hyperadenylated 3'-ends. We also show that arginine residues within the C-terminal arginine-rich domain of Pab2 are modified by RMT1-dependent methylation. Whereas the arginine methylated and unmethylated forms of Pab2 behaved similarly in terms of subcellular localization, poly(A) binding, and poly(A) tail length control; Pab2 oligomerization levels were markedly increased when Pab2 was not methylated. Significantly, Pab2 overexpression reduced growth rate, and this growth inhibitory effect was exacerbated in rmt1-null cells. Our results indicate that the main cellular function of Pab2 is in poly(A) tail length control and support a biological role for arginine methylation in the regulation of Pab2 oligomerization.     

Polyadenylation of maternal mRNA during oocyte maturation: poly(A) addition in vitro requires a regulated RNA binding activity and a poly(A) polymerase.

Specific maternal mRNAs receive poly(A) during early development as a means of translational regulation. In this report, we investigated the mechanism and control of poly(A) addition during frog oocyte maturation, in which oocytes advance from first to second meiosis becoming eggs. We analyzed polyadenylation in vitro in oocyte and egg extracts. In vivo, polyadenylation during maturation requires AAUAAA and a U-rich element. The same sequences are required for polyadenylation in egg extracts in vitro. The in vitro reaction requires at least two separable components: a poly(A) polymerase and an RNA binding activity with specificity for AAUAAA and the U-rich element. The poly(A) polymerase is similar to nuclear poly(A) polymerases in mammalian cells. Through a 2000-fold partial purification, the frog egg and mammalian enzymes were found to be very similar. More importantly, a purified calf thymus poly(A) polymerase acquired the sequence specificity seen during frog oocyte maturation when mixed with the frog egg RNA binding fraction, demonstrating the interchangeability of the two enzymes. To determine how polyadenylation is activated during maturation, we compared polymerase and RNA binding activities in oocyte and egg extracts. Although oocyte extracts were much less active in maturation-specific polyadenylation, they contained nearly as much poly(A) polymerase activity. In contrast, the RNA binding activity differed dramatically in oocyte and egg extracts: oocyte extracts contained less binding activity and the activity that was present exhibited an altered mobility in gel retardation assays. Finally, we demonstrate that components present in the RNA binding fraction are rate-limiting in the oocyte extract, suggesting that fraction contains the target that is activated by progesterone treatment. This target may be the RNA binding activity itself. We propose that in spite of the many biological differences between them, nuclear polyadenylation and cytoplasmic polyadenylation during early development may be catalyzed by similar, or even identical, components.     

Study of human secretory immunoglobulin A. I. Obtaining monospecific antiserum to human secretory immunoglobulin A]

A method of obtaining monospecific antiserum to the human secretory IgA is described. Immunochemically pure secretory IgA (isolated from human colostrum by fractionation with ammonium sulfate and gel-filtration on Sephadex G-200) was used for immunization of rabbits or sheep. Heterologous antibodies were removed by adsorption with commercial gamma globulin, normal serum, the serum of a patient suffering from A-myeloma with the IgA polymere and purified lactoferrin. Monospecific antiserum to the secretory IgA gave a reaction of complete immunological identity with the secretory IgA and a free secretory component.     

Functional role of zinc in poly(A) synthesis catalyzed by nuclear poly(A) polymerase.

Three methods, chromatographic, spectrophotometric and tritium-release assay, were used and compared for the assay of deoxycytidylate methyltransferase. All three methods can be used for assay of this enzyme but the tritium-release assay appears to be the most simple and convenient. With the help of this assay the deoxycytidylate methyltransferase has been isolated and purified from sonically disrupted cells of Xp12-infected Xanthomonas oryzae. Using a procedure that involves fractionation with streptomycin sulfate and ammonium sulfate, filtration through Sephadex G-100 and chromatography on DEAE-cellulose, a 214-fold increase in specific activity was obtained. The enzyme displays a narrow pH optimum at 6.0 Among the buffers tested, 6-morpholinoethane sulfonate with the addition of Mg2 is the best. The enzyme can utilize dCMP as a substrate. The enzyme can also convert tetrahydrofolic acid into dihydrofolic acid. The Km value for dCMP is 31.3 micrometer and the Km value for tetrahydrofolic acid is 71.4 micrometer. There is no absolute requirement of ions for the activity of the enzyme; however, the presence of ions causes stimulating or inhibiting effects on enzyme activity that are dependent on the variety and concentration of ions used.     

Basketball exercise and secretory immunoglobulin A.

This study examined saliva levels of immunoglobulin A (IgA) before and after three games and three practice sessions during the basketball season. Saliva was collected from 27 prepubescent boys (10-12 years) in a small Fry league and 23 postpubescent boys (16-18 years) on a high school varsity team. Saliva samples were frozen for later assay using a standard enzyme-linked immunosorbent assay technique. IgA levels were significantly increased after games 1 and 3 in both age groups and after practice 3 in the high school athletes. Over the 2 months of saliva collections the pre-exercise IgA increased significantly with games 2 and 3 higher than game 1, and practice 3 higher than practices 1 and 2, in both age groups. These results indicate that basketball exercise can increase saliva IgA levels and that chronic exercise over the basketball season may increase the resting levels of IgA. These changes may give athletes more protection against respiratory infections both after exercise and in the resting state later in the season.     

Saltatory forward movement of a poly(A) polymerase during poly(A) tail addition

Vaccinia poly(A) polymerase (VP55) interacts with > or = 33-nucleotide (nt) primers via uridylates at two sites (-27/-26 and -10). It adds approximately 30-nt poly(A) tails with a rapid, processive burst in which the first few nt are added without substantial primer movement, and addition of the remaining adenylates is dependent upon a six-uridylate tract at the extreme 3' end of the primer and accompanied by polymerase translocation. Interaction of VP55 with 2-aminopurine (2-AP)-containing primers was associated with a 3-fold enhancement in 2-AP fluorescence. In stopped-flow experiments, fluorescence intensity changed with time during the polyadenylation burst in a manner dependent upon the position of 2-AP, indicating a non-uniform isomerization of the polymerase-primer complex with time consistent with a discontinuous (saltatory) translocation mechanism. Three distinct translocatory phases could be discerned: a -10(U)-binding site forward movement, a -27/-26(UU)-binding site jump to -10, then a -27/-26(UU)-binding site movement further downstream. Poly(A) tail elongation showed no apparent pauses during these isomerizations. Fluorescence changes during polyadenylation of 2-AP-containing primers with short preformed oligo(A) tails reinforced the above observations. Primers composed entirely of oligo(U) (apart from the 2-AP sensor), in which the polymerase modules might be most able to "slide" uniformly, also showed the characteristic saltatory pattern of translocation. These data indicate, for the first time, a discontinuous mode of translocation for a non-templated polymerase.     

mRNA degradation. A tale of poly(A) and multiprotein machines

The Escherichia coli RNA degradosome is a multiprotein complex containing an endoribonuclease, polynucleotide phosphorylase and a DEAD-box RNA helicase. A related complex has been described in the spinach chloroplast. The exosome and the mtEXO complex have recently been described in yeast and it is likely that related complexes also exist in animal cells. This research suggests the widespread existence of sophisticated machines for the efficient degradation of messenger RNA. The DEAD-box helicase in the degradosome can unwind regions of RNA structure that interfere with 3'-5' degradation. The polyadenylation of RNA 3' ends is also known to promote degradation by creating a 'toehold' for the degradation machinery. Much remains to be learned about the regulation of mRNA stability. The complexity of the degradation process, both in the eubacteria and in the eukaryotes, suggests that many steps are possible points of control.     

Identification of proteins associating with poly(A)-binding-protein mRNA.

Synthesis of poly(A)-binding protein is regulated at the translational level. We have investigated the binding of proteins to this mRNA on the premise that the protein(s) of the mRNP complex may be involved in regulating the expression of the mRNA. We found the first 243 nucleotides of the 5' untranslated region to contain sequences essential for RNP formation. A large, single-stranded bulge structure encompassing stretches rich in adenine nucleotides and a potential stem-loop domain appear to be the primary sites for protein binding. Removal of the 243-nucleotide segment results in a drastic reduction in protein binding and a concomitant increase in translational efficiency in vitro. We suggest that proteins binding to this region, including poly(A)-binding protein itself, may be essential for regulating translation of this mRNA.     

Extensive homology between poly(A)-containing mRNA and purified nominal poly(A)-lacking mRNA in mouse kidney

To investigate poly(A)-lacking mRNA in mouse kidney, we studied a fraction of renal mRNA that does not bind to oligo(dT)-cellulose but can be purified by benzoylated cellulose chromatography. Nominal poly(A)-lacking mRNA and poly(A)-containing mRNA have complete nucleotide sequence homology, suggesting that kidney does not contain mRNAs that are not represented in the polyadenylated RNA fraction. Translation products directed by nominal poly(A)-lacking mRNA and poly(A)-containing mRNA are qualitatively and quantitatively similar in one-dimensional polyacrylamide gels. [3H]cDNA transcribed from poly(A)-containing mRNA hybridizes with its template and with nominal poly(A)-lacking mRNA to the same extent (95%) and with the same kinetics; reaction of [3H]cDNA to nominal poly(A)-lacking mRNA with the two mRNA populations gives the same result. The extensive homology these two mRNA populations share is important to the interpretation of mRNA lifetime and to the analysis of authentic poly(A)-lacking mRNAs.