RNA-binding properties and translation repression in vitro by germ cell-specific MSY2 protein

The large amount of MSY2 protein, a mouse germ cell-specific Y-box protein, in oocytes and its degradation by the late two-cell stage suggest that MSY2 may stabilize and/or regulate the translation of maternal mRNAs. We report here the ability of bacterially expressed recombinant MSY2 protein to bind to mRNA and repress translation in vitro. Although MSY2 displays some sequence specificity in binding to short RNA sequences derived from the 3' untranslated region (UTR) of the protamine 1 (Prm1) mRNA, as determined by both gel shift and filter binding assays, essentially no sequence specificity is observed when full-length Prm1 mRNA is used. The binding of MSY2 is approximately 10-fold greater to the full-length Prm1 mRNA than to a 37-nucleotide sequence derived from the 3' UTR, and gel shift assays indicate that multiple MSY2 molecules bind to a single Prm1 mRNA. MSY2 binding to luciferase mRNA at ratios of protein to mRNA that are likely to exist in the oocyte also leads to a moderate inhibition of protein synthesis in vitro. Given the abundance of MSY2 in mouse oocytes (2% of total oocyte protein), these data suggest that MSY2 packages mRNAs in vivo with relatively little sequence specificity, which may lead to both stabilization and translation repression of maternal mRNAs.     

Translational repression by MSY4 inhibits spermatid differentiation in mice

In developing male germ cells, newly synthesized protamine mRNAs are stored for up to 7 days before translational activation. Translational repression of protamine 1 (Prm1) mRNA requires sequences present in its 3' untranslated region (UTR) and substantial evidence suggests a role for the murine Y-box protein MSY4 in this process. To determine if MSY4 can mediate translational repression in vivo, we generated transgenic mice in which the temporal window of MSY4 expression was extended during spermatogenesis. Expression of MSY4 disrupted the normal completion of spermatogenesis and caused dominant sterility. Immunocytochemical analysis of several markers, including the protamines, indicated that MSY4 prevented normal activation of translation. mRNAs whose translation was inhibited contained at least one MSY4 RNA recognition site, suggesting sequence-dependent translational repression. Altered translational activation resulted in defective processing of protamine 2 and severe defects in sperm morphogenesis. These results suggest that MSY4 plays an active role in translational repression of several mRNAs in differentiating spermatids.     

The mouse Y-box protein, MSY2, is associated with a kinase on non-polysomal mouse testicular mRNAs

In male germ cells many mRNAs are sequestered by proteins into translationally silent messenger ribo-nucleoprotein (mRNP) particles. These masked paternal mRNAs are stored and translated at specific times of germ cell development. Little is known about the mammalian testicular mRNA masking proteins bound to non-polysomal mRNAs. In this report, the major proteins binding to non-polysomal testicular mRNAs were isolated and analyzed. The two predominant proteins identified were: a Y-box protein (MSY2), the mammalian homolog to the Xenopus oocyte masking protein FRGY2/mRNP3+4, and a poly(A) binding protein. A kinase activity was also found associated with these non-polysomal RNAs. The kinase co-immunoprecipitates with MSY2 and phosphorylates MSY2 in vitro. The MSY2 associated kinase is not casein kinase 2, the kinase believed to phosphorylate mRNP3+4 in oocytes, but a yet unidentified kinase. MSY2 was found to be phosphorylated in vivo and MSY2 dephosphorylation led to a decrease in its affinity to bind RNA as judged by northwestern blotting. Therefore, testicular masked mRNAs may be regulated by the phosphorylation state of MSY2. Reconstitution experiments in which non-polysomal mRNA-binding proteins are dissociated from their RNAs and allowed to bind to exogenous mRNAs suggest that MSY2 binds RNA in a sequence-independent fashion. Furthermore, association of the non-polysomal derived proteins to exogenous non-specific mRNAs led to their translational repression in vitro.     

Requirement for RNA-binding activity of MSY2 for cytoplasmic localization and retention in mouse oocytes

MSY2, a mouse germ cell-specific Y-box protein, is implicated in the global regulation of the stability and/or translation of maternal mRNAs in the mouse oocyte. We report here that in the oocyte approximately 75% of MSY2 protein is associated with a Triton-insoluble preparation, whereas in either male germ cells or when exogenously expressed in transfected somatic cells almost all MSY2 is soluble. This retention in the oocyte, which is unlikely mediated either by microfilaments or by microtubules, markedly decreases beyond the two-cell stage of development. By microinjecting mutant MSY2-EGFP chimeric mRNAs into mouse oocytes and then assaying the expressed protein's localization by laser-scanning confocal microscopy, we find that an intact cold-shock domain (CSD), containing two RNA-binding motifs, is required to localize MSY2 to the oocyte cytoplasm. In addition, an additional basic/aromatic amino acid island (B/A), which can also interact with RNA, in the C-terminal tail domain is necessary to retain MSY2 following Triton permeabilization. Intact mRNA appeared required for this retention, since RNase A treatment of Triton-permeabilized oocytes or microinjection of RNase A into the oocyte released essentially all of the endogenous MSY2 protein. Furthermore, there is a positive correlation between the ability of the mutant MSY2-EGFP protein to remain associated with the Triton-insoluble preparations and its increased affinity for RNA, as determined by RNA electrophoretic mobility shift assays. These results suggest that binding of intact maternal mRNA by MSY2 is required for its cytoplasmic retention.     

Binding of the La autoantigen to the 5' untranslated region of a chimeric human translation elongation factor 1A reporter mRNA inhibits translation in vitro.

Human translation elongation factor 1A (EF1A) is a member of a large class of mRNAs, including ribosomal proteins and other translation elongation factors, which are coordinately translationally regulated under various conditions. Each of these mRNAs contains a terminal oligopyrimidine tract (TOP) that is required for translational control. A human growth hormone (hGH) expression construct containing the promoter region and 5' untranslated region (UTR) of EF1A linked to the hGH coding region (EF1A/hGH) was translationally repressed following rapamycin treatment in similar fashion to endogenous EF1A in human B lymphocytes. Mutation of two nucleotides in the TOP motif abolished the translational regulation. Gel mobility shift assays showed that both La protein from human B lymphocyte cytoplasmic extracts as well as purified recombinant La protein specifically bind to an in vitro-synthesized RNA containing the 5' UTR of EF1A mRNA. Moreover, extracts prepared from rapamycin-treated cells showed increased binding activity to the EF1A 5' UTR RNA, which correlates with TOP mRNA translational repression. In an in vitro translation system, recombinant La dramatically decreased the expression of EF1A/hGH construct mRNA, but not mRNAs lacking an intact TOP element. These results indicate that TOP mRNA translation may be modulated through La binding to the TOP element.     

Characterization of a specific interaction between Escherichia coli thymidylate synthase and Escherichia coli thymidylate synthase mRNA.

Previous studies have shown that human TS mRNA translation is controlled by a negative autoregulatory mechanism. In this study, an RNA electrophoretic gel mobility shift assay confirmed a direct interaction between Escherichia coli (E.coli) TS protein and its own E.coli TS mRNA. Two cis-acting sequences in the E.coli TS mRNA protein-coding region were identified, with one site corresponding to nucleotides 207-460 and the second site corresponding to nucleotides 461-807. Each of these mRNA sequences bind TS with a relative affinity similar to that of the full-length E.coli TS mRNA sequence (IC50 = 1 nM). A third binding site was identified, corresponding to nucleotides 808-1015, although its relative affinity for TS (IC50 = 5.1 nM) was lower than that of the other two cis-acting elements. E.coli TS proteins with mutations in amino acids located within the nucleotide-binding region retained the ability to bind RNA while proteins with mutations at either the nucleotide active site cysteine (C146S) or at amino acids located within the folate-binding region were unable to bind TS mRNA. These studies suggest that the regions on E.coli TS defined by the folate-binding site and/or critical cysteine sulfhydryl groups may represent important RNA binding domains. Further evidence is presented which demonstrates that the direct interaction with TS results in in vitro repression of E.coli TS mRNA translation.     

Multiple binding sites for cellular proteins in the 3' end of Sindbis alphavirus minus-sense RNA.

The 3' end of Sindbis virus minus-sense RNA was tested for its ability to bind proteins in mosquito cell extracts, using labeled riboprobes that represented different parts of this region. We found four domains in the first 250 nucleotides that could bind the same 50- and 52-kDa proteins, three with high affinity and one with low affinity, whereas tested domains outside this region did not bind these proteins. The first binding domain was found in the first 60 nucleotides, which represents the complement of the 5'-nontranslated region, the second in the next 60 nucleotides, the third in the following 60 nucleotides, and the fourth between nucleotides 194 and 249 (all numbering is 3' to 5'). The relative binding constants, Kr, of the first, second, and fourth sites were similar, whereas that of domain 2 was fivefold less. Deletion mapping of the first domain showed that the first 10 nucleotides were critical for binding. Deletion of nucleotides 2 to 4, deletion or replacement of nucleotide 5, or deletion of the first 15 nucleotides was deleterious for binding, deletion of nucleotides 10 to 15, 26 to 40, or 41 to 55 had little effect on the binding, and deletion of nucleotides 15 to to 25 increased the binding affinity. We also found that the corresponding riboprobes derived from two other alphaviruses, Ross River virus and Semliki Forest virus, and from rubella virus were also able to interact with the 50- and 52-kDa proteins. The Kr value for the Semliki Forest virus probe was similar to that for the Sindbis virus probe, while that for the Ross River virus probe was four times greater. The rubella virus probe was bound only weakly, consistent with the fact that mosquito cells are not permissive for rubella virus replication. We suggest that the binding of the 50- and 52-kDa proteins to the 3' end of alphavirus minus-sense RNA represents an important step in the initiation of RNA replication.     

RNA binding specificity of hnRNP A1: significance of hnRNP A1 high-affinity binding sites in pre-mRNA splicing.

Pre-mRNA is processed as a large complex of pre-mRNA, snRNPs and pre-mRNA binding proteins (hnRNP proteins). The significance of hnRNP proteins in mRNA biogenesis is likely to be reflected in their RNA binding properties. We have determined the RNA binding specificity of hnRNP A1 and of each of its two RNA binding domains (RBDs), by selection/amplification from pools of random sequence RNA. Unique RNA molecules were selected by hnRNP A1 and each individual RBD, suggesting that the RNA binding specificity of hnRNP A1 is the result of both RBDs acting as a single RNA binding composite. Interestingly, the consensus high-affinity hnRNP A1 binding site, UAGGGA/U, resembles the consensus sequences of vertebrate 5' and 3' splice sites. The highest affinity 'winner' sequence for hnRNP A1 contained a duplication of this sequence separated by two nucleotides, and was bound by hnRNP A1 with an apparent dissociation constant of 1 x 10(-9) M. hnRNP A1 also bound other RNA sequences, including pre-mRNA splice sites and an intron-derived sequence, but with reduced affinities, demonstrating that hnRNP A1 binds different RNA sequences with a > 100-fold range of affinities. These experiments demonstrate that hnRNP A1 is a sequence-specific RNA binding protein. UV light-induced protein-RNA crosslinking in nuclear extracts demonstrated that an oligoribonucleotide containing the A1 winner sequence can be used as a specific affinity reagent for hnRNP A1 and an unidentified 50 kDa protein. We also show that this oligoribonucleotide, as well as two others containing 5' and 3' pre-mRNA splice sites, are potent inhibitors of in vitro pre-mRNA splicing.     

Visualization of the reconstituted FRGY2-mRNA complexes by electron microscopy

Xenopus oocytes store large quantities of translationally dormant mRNA in the cytoplasm as storage messenger ribonucleoprotein particles (mRNPs). The Y-box proteins, mRNP3 and FRGY2/mRNP4, are major RNA binding components of maternal storage mRNPs in oocytes. In this study, we show that the FRGY2 proteins form complexes with mRNA, which leads to mRNA stabilization and translational repression. Visualization of the FRGY2-mRNA complexes by electron microscopy reveals that FRGY2 packages mRNA into a compact RNP. Our results are consistent with a model that the Y-box proteins function in packaging of mRNAs to store them stably for a long time in the oocyte cytoplasm.     

An eight-nucleotide sequence in the potato virus X 3' untranslated region is required for both host protein binding and viral multiplication.

Gel retardation and UV-cross-linking techniques were used to demonstrate that two tobacco proteins, with approximate molecular masses of 28 and 32 kDa, bind to a site within the 3' region of potato virus X (PVX) genomic RNA. The protein binding is specific, in that a 50-fold excess of unlabeled probe prevents formation of the complexes but no reduction is observed with a 2,000-fold molar excess of yeast tRNA. Complex formation is inhibited by poly(U) but is relatively unaffected by poly(A), poly(G), or poly(C-I). PVX RNA-host protein complex formation occurs in vitro at salt concentrations up to 400 mM. Deletion mapping indicates that the proteins bind within the 3' untranslated region (UTR) of PVX genomic RNA and that an 8-nucleotide U-rich sequence (5'-UAUUUUCU) is required for the binding. Deletion of the 8-nucleotide U-rich region from the 3' UTR of a sensitive PVX reporter virus that carries the luciferase gene in place of the PVX coat protein gene results in a more than 70,000-fold reduction in luciferase expression in tobacco protoplasts. RNA probes carrying the sequence GCGC in place of the central four contiguous uridines of the 8-nucleotide U-rich motif fail to bind host protein at detectable levels, and the same mutation, when introduced into the PVX reporter virus, eliminates viral multiplication. Mutations of 1 or 2 nucleotides within the same four uridines reduced both binding of host proteins and replication of reporter virus. These results indicate that the 8-nucleotide U-rich motif within the PVX 3' UTR is important for some aspect of viral multiplication and suggest that host protein binding plays a role in the process.     

Cold shock domain family members YB-1 and MSY4 share essential functions during murine embryogenesis

Three cold shock domain (CSD) family members (YB-1, MSY2, and MSY4) exist in vertebrate species ranging from frogs to humans. YB-1 is expressed throughout embryogenesis and is ubiquitously expressed in adult animals; it protects cells from senescence during periods of proliferative stress. YB-1-deficient embryos die unexpectedly late in embryogenesis (embryonic day 18.5 [E18.5] to postnatal day 1) with a runting phenotype. We have now determined that MSY4, but not MSY2, is also expressed during embryogenesis; its abundance declines substantially from E9.5 to E17.5 and is undetectable on postnatal day 1(adult mice express MSY4 in testes only). Whole-mount analysis revealed similar patterns of YB-1 and MSY4 RNA expression in E11.5 embryos. To determine whether MSY4 delays the death of YB-1-deficient embryos, we created and analyzed MSY4-deficient mice and then generated YB-1 and MSY4 double-knockout embryos. MSY4 is dispensable for normal development and survival, but the testes of adult mice have excessive spermatocyte apoptosis and seminiferous tubule degeneration. Embryos doubly deficient for YB-1 and MSY4 are severely runted and die much earlier (E8.5 to E11.5) than YB-1-deficient embryos, suggesting that MSY4 indeed shares critical cellular functions with YB-1 in the embryonic tissues where they are coexpressed.     

The N- and C-terminal RNA recognition motifs of splicing factor Prp24 have distinct functions in U6 RNA binding

Prp24 is an essential yeast U6 snRNP protein with four RNA recognition motifs (RRMs) that facilitates the association of U4 and U6 snRNPs during spliceosome assembly. Genetic interactions led to the proposal that RRMs 2 and 3 of Prp24 bind U6 RNA, while RRMs 1 and 4 bind U4 RNA. However, the function of each RRM has yet to be established through biochemical means. We compared the binding of recombinant full-length Prp24 and truncated forms lacking RRM 1 or RRM 4 with U6 RNA. Contrary to expectations, we found that the N-terminal segment containing RRM 1 is important for high-affinity binding to U6 RNA and for discrimination between wild-type U6 RNA and U6 with point mutations in the 3' intramolecular stem-loop. In contrast, deletion of RRM 4 and the C terminus did not significantly alter the affinity for U6 RNA, but resulted in the formation of higher order Prp24.U6 complexes. Truncation and internal deletion of U6 RNA mapped three Prp24-binding sites, with the central site providing most of the affinity for Prp24. A newly identified temperature-sensitive lethal point mutation in RRM 1 is exacerbated by mutations in the U6 RNA telestem, as is a mutation in RRM 2, but not one in RRM 3. We propose that RRMs 1 and 2 of yeast Prp24 bind the same central site in U6 RNA that is bound by the two RRMs of human Prp24, and that RRMs 3 and 4 bind lower affinity flanking sites, thereby restricting the stoichiometry of Prp24 binding.     

An intronic splicing enhancer binds U1 snRNPs to enhance splicing and select 5' splice sites

Intronic G triplets are frequently located adjacent to 5' splice sites in vertebrate pre-mRNAs and have been correlated with splicing efficiency and specificity via a mechanism that activates upstream 5' splice sites in exons containing duplicated sites (26). Using an intron dependent upon G triplets for maximal activity and 5' splice site specificity, we determined that these elements bind U1 snRNPs via base pairing with U1 RNA. This interaction is novel in that it uses nucleotides 8 to 10 of U1 RNA and is independent of nucleotides 1 to 7. In vivo functionality of base pairing was documented by restoring activity and specificity to mutated G triplets through compensating U1 RNA mutations. We suggest that the G-rich region near vertebrate 5' splice sites promotes accurate splice site recognition by recruiting the U1 snRNP.