Crystal structure of human AUH protein, a single-stranded RNA binding homolog of enoyl-CoA hydratase.

BACKGROUND: The AU binding homolog of enoyl-CoA hydratase (AUH) is a bifunctional protein that has two distinct activities: AUH binds to RNA and weakly catalyzes the hydration of 2-trans-enoyl-coenzyme A (enoyl-CoA). AUH has no sequence similarity with other known RNA binding proteins, but it has considerable sequence similarity with enoyl-CoA hydratase. A segment of AUH, named the R peptide, binds to RNA. However, the mechanism of the RNA binding activity of AUH remains to be elucidated. RESULTS: We determined the crystal structure of human AUH at 2.2 A resolution. AUH adopts the typical fold of the enoyl-CoA hydratase/isomerase superfamily and forms a hexamer as a dimer of trimers. Interestingly, the surface of the AUH hexamer is positively charged, in striking contrast to the negatively charged surfaces of the other members of the superfamily. Furthermore, wide clefts are uniquely formed between the two trimers of AUH and are highly positively charged with the Lys residues in alpha helix H1, which is located on the edge of the cleft and contains the majority of the R peptide. A mutational analysis showed that the lysine residues in alpha helix H1 are essential to the RNA binding activity of AUH. CONCLUSIONS: Alpha helix H1 exposes a row of Lys residues on the solvent-accessible surface. These characteristic Lys residues are named the "lysine comb." The distances between these Lys residues are similar to those between the RNA phosphate groups, suggesting that the lysine comb may continuously bind to a single-stranded RNA. The clefts between the trimers may provide spaces sufficient to accommodate the RNA bases.     

Biochemical characterization of human 3-methylglutaconyl-CoA hydratase and its role in leucine metabolism

The metabolic disease 3-methylglutaconic aciduria type I (MGA1) is characterized by an abnormal organic acid profile in which there is excessive urinary excretion of 3-methylglutaconic acid, 3-methylglutaric acid and 3-hydroxyisovaleric acid. Affected individuals display variable clinical manifestations ranging from mildly delayed speech development to severe psychomotor retardation with neurological handicap. MGA1 is caused by reduced or absent 3-methylglutaconyl-coenzyme A (3-MG-CoA) hydratase activity within the leucine degradation pathway. The human AUH gene has been reported to encode for a bifunctional enzyme with both RNA-binding and enoyl-CoA-hydratase activity. In addition, it was shown that mutations in the AUH gene are linked to MGA1. Here we present kinetic data of the purified gene product of AUH using different CoA-substrates. The best substrates were (E)-3-MG-CoA (V(max) = 3.9 U.mg(-1), K(m) = 8.3 microM, k(cat) = 5.1 s(-1)) and (E)-glutaconyl-CoA (V(max) = 1.1 U.mg(-1), K(m) = 2.4 microM, k(cat) = 1.4 s(-1)) giving strong evidence that the AUH gene encodes for the major human 3-MG-CoA hydratase in leucine degradation. Based on these results, a new assay for AUH activity in fibroblast homogenates was developed. The only missense mutation found in MGA1 phenotypes, c.719C>T, leading to the amino acid exchange A240V, produces an enzyme with only 9% of the wild-type 3-MG-CoA hydratase activity.     

The association of Alu repeats with the generation of potential AU-rich elements (ARE) at 3' untranslated regions.

Background  

A significant portion (about 8% in the human genome) of mammalian mRNA sequences contains AU (Adenine and Uracil) rich elements or AREs at their 3' untranslated regions (UTR). These mRNA sequences are usually stable. However, an increasing number of observations have been made of unstable species, possibly depending on certain elements such as Alu repeats. ARE motifs are repeats of the tetramer AUUU and a monomer A at the end of the repeats ((AUUU)_nA). The importance of AREs in biology is that they make certain mRNA unstable. Proto-oncogene, such as c-fos, c-myc, and c-jun in humans, are associated with AREs. Although it has been known that the increased number of ARE motifs caused the decrease of the half-life of mRNA containing ARE repeats, the exact mechanism is as of yet unknown. We analyzed the occurrences of AREs and Alu and propose a possible mechanism for how human mRNA could acquire and keep AREs at its 3' UTR originating from Alu repeats.     

3-Methylglutaconic aciduria type I is caused by mutations in AUH

3-Methylglutaconic aciduria type I is an autosomal recessive disorder clinically characterized by various symptoms ranging from delayed speech development to severe neurological handicap. This disorder is caused by a deficiency of 3-methylglutaconyl-CoA hydratase, one of the key enzymes of leucine degradation. This results in elevated urinary levels of 3-methylglutaconic acid, 3-methylglutaric acid, and 3-hydroxyisovaleric acid. By heterologous expression in Escherichia coli, we show that 3-methylglutaconyl-CoA hydratase is encoded by the AUH gene, whose product had been reported elsewhere as an AU-specific RNA-binding protein. Mutation analysis of AUH in two patients revealed a nonsense mutation (R197X) and a splice-site mutation (IVS8-1G-->A), demonstrating that mutations in AUH cause 3-methylglutaconic aciduria type I.     

紫外交联合并串联亲和纯化高效鉴定蛋白复合物组分的RNA结合活性

RNA结合蛋白在RNA的生成与代谢中发挥着重要作用.我们在近年报道的PAR-CLIP(photoactivatableribonucleoside-enhanced crosslinking and immunoprecipitation)技术的基础上建立了一套快速、有效鉴定RNA结合蛋白的实验方法:以串联亲和纯化替代一步免疫沉淀获得高纯度蛋白-RNA复合物;将Sypro Ruby蛋白染色与RNA放射自显影相结合判断复合物中哪种或哪些组分为RNA结合蛋白,该方法命名为紫外交联合并的串联亲和纯化(cross-linkingand tandem affinity purification,CLiTAP).运用该方法对布氏锥虫的三种锌指蛋白ZC3H7、ZC3H34和ZC3H5进行分析,发现ZC3H7作为帽结合蛋白复合物的核心组分具有很强的RNA结合能力;ZC3H34结合RNA能力较弱,但其互作蛋白具有强的RNA结合活性;相比之下,ZC3H5及其复合物组分皆无RNA结合活性.这些结果表明,CLiTAP与蛋白质鉴定方法相结合,能够有效鉴定靶蛋白复合物中的RNA结合蛋白种类,也为进一步定位RNA结合位点、研究RNA结合蛋白的结构及作用机制奠定了基础.     

A Nucleolar PUF RNA-binding Protein with Specificity for a Unique RNA Sequence

PUF proteins are a conserved group of sequence specific RNA-binding proteins that bind to RNA in a modular fashion. The RNA-binding domain of PUF proteins typically consists of eight clustered Puf repeats. Plant genomes code for large families of PUF proteins that show significant variability in their predicted Puf repeat number, organization, and amino acid sequence. Here we sought to determine whether the observed variability in the RNA-binding domains of four plant PUFs results in a preference for nonclassical PUF RNA target sequences. We report the identification of a novel RNA binding sequence for a nucleolar Arabidopsis PUF protein that contains an atypical RNA-binding domain. The Arabidopsis PUM23 (APUM23) binding sequence was 10 nucleotides in length, contained a centrally located UUGA core element, and had a preferred cytosine at nucleotide position 8. These RNA sequence characteristics differ from those of other PUF proteins, because all natural PUFs studied to date bind to RNAs that contain a conserved UGU sequence at their 5′ end and lack specificity for cytosine. Gel mobility shift assays validated the identity of the APUM23 binding sequence and supported the location of 3 of the 10 predicted Puf repeats in APUM23, including the cytosine-binding repeat. The preferred 10-nucleotide sequence bound by APUM23 is present within the 18S rRNA sequence, supporting the known role of APUM23 in 18S rRNA maturation. This work also reveals that APUM23, an ortholog of yeast Nop9, could provide an advanced structural backbone for Puf repeat engineering and target-specific regulation of cellular RNAs.     

RNA-binding activity of hepatitis delta antigen involves two arginine-rich motifs and is required for hepatitis delta virus RNA replication.

Hepatitis delta antigen (HDAg) is an RNA-binding protein with binding specificity for hepatitis delta virus (HDV) RNA (J. H. Lin, M. F. Chang, S. C. Baker, S. Govindarajan, and M. M. C. Lai, J. Virol. 64:4051-4058, 1990). By amino acid sequence homology search, we have identified within its RNA-binding domain two stretches of an arginine-rich motif (ARM), which is present in many prokaryotic and eukaryotic RNA-binding proteins. The first one is KERQDHRRRKA and the second is EDEKRERRIAG, and they are separated by 29 amino acids. Deletion of either one of these ARM sequences resulted in the total loss of the in vitro RNA-binding activity of HDAg. Thus, HDAg is different from other RNA-binding proteins in that it requires two ARM-like sequences for its RNA-binding activity. Replacement of the spacer sequence between the two ARMs with a shorter stretch of sequence also reduced RNA binding in vitro. Furthermore, site-specific mutations of the basic amino acid residues in both ARMs resulted in the total loss or reduction of RNA-binding activity. The biological significance of the RNA-binding activity was studied by examining the trans-activating activity of the RNA-binding mutants. The plasmids expressing HDAgs with various mutations in the RNA-binding motifs were cotransfected with a replication-defective HDV dimer cDNA construct into COS cells. It was found that all the HDAg mutants which had lost the in vitro RNA-binding activity also lost the ability to complement the defect of HDV RNA replication. We conclude that the trans-activating function of HDAg requires its binding to HDV RNA.     

The translation initiation factor eIF-4B contains an RNA-binding region that is distinct and independent from its ribonucleoprotein consensus sequence.

eIF-4B is a eukaryotic translation initiation factor that is required for the binding of ribosomes to mRNAs and the stimulation of the helicase activity of eIF-4A. It is an RNA-binding protein that contains a ribonucleoprotein consensus sequence (RNP-CS)/RNA recognition motif (RRM). We examined the effects of deletions and point mutations on the ability of eIF-4B to bind a random RNA, to cooperate with eIF-4A in RNA binding, and to enhance the helicase activity of eIF-4A. We report here that the RNP-CS/RRM alone is not sufficient for eIF-4B binding to RNA and that an RNA-binding region, located between amino acids 367 and 423, is the major contributor to RNA binding. Deletions which remove this region abolish the ability of eIF-4B to cooperate with eIF-4A in RNA binding and the ability to stimulate the helicase activity of eIF-4A. Point mutations in the RNP-CS/RRM had no effect on the ability of eIF-4B to cooperate with eIF-4A in RNA binding but significantly reduced the stimulation of eIF-4A helicase activity. Our results indicate that the carboxy-terminal RNA-binding region of eIF-4B is essential for eIF-4B function and is distinct from the RNP-CS/RRM.     

Creating hetero-11-mers composed of wild-type and mutant subunits to study RNA binding to TRAP.

TRAP (trp RNA-binding attenuation protein) is an RNA-binding protein that regulates expression of the tryptophan biosynthetic genes in Bacillus subtilis by binding to RNA targets that contain multiple GAG and UAG repeats. TRAP is composed of 11 identical subunits arranged symmetrically in a ring. The secondary structure of the protein consists entirely of antiparallel beta-sheets, beta-turns, and loops. We show here that the TRAP 11-mer can be reversibly denatured into unfolded monomers by guanidine hydrochloride. Removing the denaturant allows the protein to spontaneously renature into fully functional 11-mers. Based on this finding, we developed a subunit mixing method to hybridize wild-type and mutant subunits into heteromeric 11-mers by denaturation followed by subunit mixing renaturation. This method allows the study of subunit cooperativity in protein-ligand interaction such as RNA binding. Our data further support and extend the previously proposed two-step model for RNA binding to TRAP by showing that the initiation of binding requires at least one fully active subunit in the protein combined with one fully functional repeat in the RNA. The initiation complex tethers the RNA on the protein, thus allowing cooperative interaction with the remainder of the repeats.     

Purification and properties of agmatine ureohydrolyase, a putrescine biosynthetic enzyme in Escherichia coli.

The putrescine biosynthetic enzyme agmatine ureohydrolase (AUH) (EC 3.5.3.11) catalyzes the conversion of agmatine to putrescine in Escherichia coli. AUH was purified approximately 1,600-fold from an E. coli strain transformed with the plasmid pKA5 bearing the speB gene encoding the enzyme. The purification procedure included ammonium sulfate precipitation, heat treatment, and DEAE-sephacel column chromatography. The molecular mass of nondenatured AUH is approximately 80,000 daltons as determined by gel-sieving column chromatography, while on denaturing polyacrylamide gels, the molecular mass is approximately 38,000 daltons; thus, native AUH is most likely a dimer. A radiolabeled protein extracted from minicells carrying the pKA5 plasmid comigrated with the purified AUH in both sodium dodecyl sulfate-polyacrylamide and native polyacrylamide gels. The pI of purified AUH is between 8.2 and 8.4, as determined by either chromatofocusing or isoelectric focusing. The Km of purified AUH for agmatine is 1.2 mM; the pH optimum is 7.3. Neither the numerous ions and nucleotides tested nor polyamines affected AUH activity in vitro. EDTA and EGTA [ethylene glycol-bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid] at 1 mM inactivated AUH activity by 53 and 74%, respectively; none of numerous divalent cations tested restored AUH activity. Ornithine inhibited AUH activity noncompetitively (Ki = 6 X 10(-3) M), while arginine inhibited AUH activity competitively (Ki = 9 X 10(-3) M).     

The mechanism of RNA binding to TRAP: initiation and cooperative interactions

The trp RNA-binding Attenuation Protein (TRAP) from Bacillus subtilis is an 11-subunit protein that binds a series of 11 GAG and UAG repeats separated by two to three-spacer nucleosides in trp leader mRNA. The structure of TRAP bound to an RNA containing 11 GAG repeats shows that the RNA wraps around the outside of the protein ring with each GAG interacting with the protein in nearly identical fashion. The only direct hydrogen bond interactions between the protein and the RNA backbone are to the 2'-hydroxyl groups on the third G of each repeat. Replacing all 11 of these guanosines with deoxyriboguanosine eliminates measurable binding to TRAP. In contrast, a single riboguanosine in an otherwise entirely DNA oligonucleotide dramatically stabilizes TRAP binding, and facilitates the interaction of the remaining all-DNA portion with the protein. Studies of TRAP binding to RNAs with between 2 and 11 GAGs, UAGs, AAGs, or CAGs showed that the stability of a TRAP-RNA complex is not directly proportional to the number of repeats in the RNA. These studies also showed that the effect of the identity of the residue in the first position of the triplet, with regard to binding to TRAP, is dependent on the number of repeats in the RNA. Together these data support a model in which TRAP binds to RNA by first forming an initial complex with a small subset of the repeats followed by a cooperative interaction with the remaining triplets.