Hypermethylation of 28S ribosomal RNA in ß-thalassemia trait carriers.

Ribosome biogenesis is the process of synthesis of the cellular ribosomes which mediate protein translation. Integral with the ribosomes are four cytoplasmic ribosomal RNAs (rRNAs) which show extensive post-transcriptional modifications including 2'-O-methylation and pseudouridylation. Several hereditary hematologic diseases including Diamond-Blackfan anemia have been shown to be associated with defects in ribosome biogenesis. Thalassemia is the most important hematologic inherited genetic disease worldwide, and this study examined the post-transcriptional ribose methylation status of three specific active sites of the 28S rRNA molecule at positions 1858, 4197 and 4506 of ß-thalassemia trait carriers and normal controls. Samples from whole blood and cultured erythroid cells were examined. Results showed that site 4506 was hypermethylated in ß-thalassemia trait carriers in both cohorts. Expression of fibrillarin, the ribosomal RNA methyltransferase as well as snoRNAs were additionally quantified by RT-qPCR and evidence of dysregulation was seen. Hemoglobin E trait carriers also showed evidence of dysregulation. These results provide the first evidence that ribosome biogenesis is dysregulated in ß-thalassemia trait carriers.

cCMP and cUMP: emerging second messengers.

The cyclic purine nucleotides cAMP and cGMP are established second messengers. By contrast, the existence of the cyclic pyrimidine nucleotides cytidine 3',5'-cyclic monophosphate (cCMP) and uridine 3',5'-cyclic monophosphate (cUMP) has been controversial for decades. The recent development of highly sensitive mass spectrometry (MS) methods allowed precise quantitation and unequivocal identification of cCMP and cUMP in cells. Importantly, cCMP and cUMP generators, effectors, cleaving enzymes, and transporters have now been identified. Here, I discuss evidence in support of cCMP and cUMP as bona fide second messengers, the emerging therapeutic implications of cCMP and cUMP signaling, and important unresolved questions for this field.

Highly conserved base A55 of 16S ribosomal RNA is important for the elongation cycle of protein synthesis.

Accurate decoding of mRNA requires the precise interaction of protein factors and tRNAs with the ribosome. X-ray crystallography and cryo-electron microscopy have provided detailed structural information about the 70S ribosome with protein factors and tRNAs trapped during translation. Crystal structures showed that one of the universally conserved 16S rRNA bases, A55, in the shoulder domain of the 30S subunit interacts with elongation factors Tu and G (EF-Tu and EF-G, respectively). The exact functional role of A55 in protein synthesis is not clear. We changed A55 to U and analyzed the effect of the mutation on the elongation cycle of protein synthesis using functional assays. Expression of 16S rRNA with the A55U mutation in cells confers a dominant lethal phenotype. Additionally, ribosomes with the A55U mutation in 16S rRNA show substantially reduced in vitro protein synthesis activity. Equilibrium binding studies showed that the A55U mutation considerably inhibited the binding of the EF-Tu·GTP·tRNA ternary complex to the ribosome. Furthermore, the A55U mutation slightly inhibited the peptidyl transferase reaction, the binding of EF-G·GTP to the ribosome, and mRNA-tRNA translocation. These results indicate that A55 is important for fine-tuning the activity of the ribosome during the elongation cycle of protein synthesis.

Structural and functional characterization of NikO, an enolpyruvyl transferase essential in nikkomycin biosynthesis.

Nikkomycins are peptide-nucleoside compounds with fungicidal, acaricidal, and insecticidal properties because of their strong inhibition of chitin synthase. Thus, they are potential antibiotics especially for the treatment of immunosuppressed patients, for those undergoing chemotherapy, or after organ transplants. Although their chemical structure has been known for more than 30 years, only little is known about their complex biosynthesis. The genes encoding for proteins involved in the biosynthesis of the nucleoside moiety of nikkomycins are co-transcribed in the same operon, comprising the genes nikIJKLMNO. The gene product NikO was shown to belong to the family of enolpyruvyl transferases and to catalyze the transfer of an enolpyruvyl moiety from phosphoenolpyruvate to the 3'-hydroxyl group of UMP. Here, we report activity and inhibition studies of the wild-type enzyme and the variants C130A and D342A. The x-ray crystal structure revealed differences between NikO and its homologs. Furthermore, our studies led to conclusions concerning substrate binding and preference as well as to conclusions about inhibition/alkylation by the antibiotic fosfomycin.

The Leishmania donovani UMP synthase is essential for promastigote viability and has an unusual tetrameric structure that exhibits substrate-controlled oligomerization.

The final two steps of de novo uridine 5'-monophosphate (UMP) biosynthesis are catalyzed by orotate phosphoribosyltransferase (OPRT) and orotidine 5'-monophosphate decarboxylase (OMPDC). In most prokaryotes and simple eukaryotes these two enzymes are encoded by separate genes, whereas in mammals they are expressed as a bifunctional gene product called UMP synthase (UMPS), with OPRT at the N terminus and OMPDC at the C terminus. Leishmania and some closely related organisms also express a bifunctional enzyme for these two steps, but the domain order is reversed relative to mammalian UMPS. In this work we demonstrate that L. donovani UMPS (LdUMPS) is an essential enzyme in promastigotes and that it is sequestered in the parasite glycosome. We also present the crystal structure of the LdUMPS in complex with its product, UMP. This structure reveals an unusual tetramer with two head to head and two tail to tail interactions, resulting in two dimeric OMPDC and two dimeric OPRT functional domains. In addition, we provide structural and biochemical evidence that oligomerization of LdUMPS is controlled by product binding at the OPRT active site. We propose a model for the assembly of the catalytically relevant LdUMPS tetramer and discuss the implications for the structure of mammalian UMPS.

Effects of phosphate limitation on expression of genes involved in pyrimidine synthesis and salvaging in Arabidopsis.

Arabidopsis seedlings grown for 14 d without phosphate (P) exhibited stunted growth and other visible symptoms associated with P deficiency. RNA contents in shoots decreased nearly 90%, relative to controls. In shoots, expression of Pht1;2, encoding an inducible high-affinity phosphate transporter, increased threefold, compared with controls, and served as a molecular marker for P limitation. Transcript levels for five enzymes (aspartate transcarbamoylase, ATCase, EC 2.1.3.2; carbamoyl phosphate synthetase, CPSase, EC 6.3.5.5); UMP synthase, EC 2.4.1.10, EC 4.1.1.23; uracil phosphoribosyltransferase, UPRTase, EC 2.4.2.9; UMP kinase, EC 2.7.1.14) increased 2-10-fold in response to P starvation in shoots. These enzymes, which utilize phosphorylated intermediates at putative regulated steps in de novo synthesis and salvaging pathways leading to UMP and pyrimidine nucleotide formation, appear to be coordinately regulated, at the level of gene expression. This response may facilitate pyrimidine nucleotide synthesis under P limitation in this plant. Expression of P-dependent and P-independent phosphoribosyl pyrophosphate (PRPP) synthases (PRS2 and PRS3, respectively) which provide PRPP, the phosphoribosyl donor in UMP synthesis via both de novo and salvaging pathways, was differentially regulated in response to P limitation. PRS2 mRNA levels increased twofold in roots and shoots of P-starved plants, while PRS3 was constitutively-expressed. PRS3 may play a novel role in providing PRPP to cellular metabolism under low P availability.

AU-rich transient response transcripts in the human genome: expressed sequence tag clustering and gene discovery approach.

Transient response genes regulate critical biological responses that include cell proliferation, signal transduction events, and responses to exogenous agents such as inflammatory stimuli, microbes, and radiation. An important feature that ensures a timely response is the short half-life of the messenger RNA (mRNA), which is thought to be predominantly mediated by adenylate uridylate-rich sequence elements (AREs) in the 3' untranslated region (3' UTR). The repertoire and extent of transient response genes in the human genome are not known. We used a computational approach to delineate those genes that code for transient ARE mRNAs. We utilized a 3' UTR-specific ARE motif to retrieve and cluster 3'-end ESTs using a refined extraction protocol. With the availability of the entire human genome, we were able to utilize ARE EST clusters for further mining and computational prediction of ARE genes. The described approaches led to the finding of more than 1500 ARE genes in the human genome. In particular, "hidden" ARE mRNAs and alternative forms due to 3'UTR completeness, variant polyadenylation, and splicing were uncovered.

A novel principle for conferring selectivity to poly(A)-binding proteins: interdependence of two ATP synthase beta-subunit mRNA-binding proteins.

Based on electrophoretic mobility-shift assays and UV cross-linking experiments, we present evidence in the present work for the existence of two mammalian cytosolic proteins that selectively interact with the 3'-untranslated region of the mRNA coding for the catalytic beta-subunit of mitochondrial ATP synthase (beta-mtATPase). One of the proteins, beta-mtATPase mRNA-binding protein (BARB)1, is a novel poly(A)-binding protein that specifically binds the poly(A) tail of the beta-mtATPase transcript. BARB1 achieves this mRNA selectivity through its interaction with a second protein, BARB2, that binds the beta-mtATPase mRNA through a 22-bp element with a uridylate core, located 75 bp upstream of the poly(A) tail. Conversely, in the absence of BARB1, BARB2 is still able to bind the beta-mtATPase mRNA, but does so with lower affinity. Thus the interaction between BARB1 and BARB2 and beta-mtATPase mRNA involves the formation of a complex between the two BARB proteins. We conclude that BARB1 and BARB2 selectively bind the 3'-untranslated region of beta-mtATPase mRNA in a novel and interdependent manner. The complex between these two proteins may be involved in post-transcriptional regulation of gene expression.

A highly specific terminal uridylyl transferase modifies the 3'-end of U6 small nuclear RNA.

HeLa cell extracts contain significant amounts of terminal uridylyl transferase (TUTase) activity. In a template-independent reaction with labeled UTP, these enzymes are capable of modifying a broad spectrum of cellular RNA molecules in vitro . However, fractionation of cell extracts by gel filtration clearly separated two independent activities. In addition to a non-specific enzyme, an additional terminal uridylyl transferase has been identified that is highly specific for cellular and in vitro synthesized U6 small nuclear RNA (snRNA) molecules. This novel TUTase enzyme was also able to select as an efficient substrate U6 snRNA species from higher eucaryotes. In contrast, no labeling was detectable with purified fission yeast RNA. Using synthetic RNAs containing different amounts of transcribed 3'-end UMP residues, high resolution gel electrophoresis revealed that U6 snRNA species with three terminal U nucleotides served as the optimal substrate for the transferase reaction. The 3'-end modification of the optimal synthetic substrate was identical to that observed with endogenous U6 snRNA isolated from HeLa cells. Therefore, we conclude that the specific addition of UMP residues to 3'-recessed U6 snRNA molecules reflects a recycling process, ensuring the functional regeneration for pre-mRNA splicing of this snRNA.

Differential expression of BMP receptors in early mouse development.

Bone morphogenetic proteins (BMPs) are members of the transforming growth factor-beta family of polypeptide signaling molecules. They function via binding to two types of transmembrane serine/threonine kinase receptors, type I and type II receptors, that are both necessary for signaling. The expression patterns of the type II BMP receptor (BMPR-II) and three type I BMP receptors (ActR-I, BMPR-IA and BMPR-IB) were examined in preimplantation embryos by means of heminested reverse transcription-polymerase chain reaction (RT-PCR). BMPR-II mRNA was detected in one-cell, two-cell and blastocyst stage embryos. ActR-I exhibited a similar expression pattern. BMPR-IA mRNA however was only detected in blastocysts, whereas BMPR-IB transcripts were detected at all stages from the one-cell zygote to the uncompacted morula, but not in the compacted morula and blastocyst. If translated into proteins, this suggests that different receptor complexes can be formed at different developmental stages. Transcripts for BMPs were not detected in preimplantation embryos, but were detected in the maternal tissues surrounding the embryos. BMPR-II, BMPR-IA and BMPR-IB mRNAs were also detected in undifferentiated and differentiated embryonal carcinoma and embryonic stem cells. In postimplantation embryos BMPR-II transcripts were first detected from 6.0 days post coitum. In situ hybridization analysis revealed that BMPR-II mRNA is ubiquitously expressed in the entire embryo at least until midgestation.

A temperature-sensitive defect of enterovirus 70 is located at the uridylylation of the genome-linked protein VPg in vitro.

The temperature-sensitive phenotype of enterovirus 70 (EV70) was examined by use of an in-vitro RNA replication system derived from a membrane fraction (crude replication complex, CRC) of EV70-infected HeLa cells. This system was capable of synthesizing the nucleotidyl proteins VPg-pU and VPg-pUpU. Formation of these nucleotidyl proteins was completely abolished when the in-vitro reaction was performed at the nonpermissive temperature for virus replication. Considering our previous observation that the defective stage of the temperature-sensitive growth of EV70 resides in the initiation step of RNA transcription in vivo, it is most likely that the lack of uridylylation of VPg at the restricted temperature in vitro is directly involved in the temperature-sensitive defect of virus growth in vivo.