Solution structure and metal ion binding sites of the human CPEB3 ribozyme's P4 domain

Three ribozymes are known to occur in humans, the CPEB3 ribozyme, the CoTC ribozyme, and the hammerhead ribozyme. Here, we present the NMR solution structure of a well-conserved motif within the CPEB3 ribozyme, the P4 domain. In addition, we discuss the binding sites and impact of Mg2+ and [Co(NH3)6]3+, a spectroscopic probe for [Mg(H2O)6]2+, on the structure. The well-defined P4 region is a hairpin closed with a UGGU tetraloop that shows a distinct electrostatic surface potential and a characteristic, strongly curved backbone trajectory. The P4 hairpin contains two specific Mg2+ binding sites: one outer-sphere binding site close to the proposed CPEB3 ribozyme active site with potential relevance for maintaining a compact fold of the ribozyme core, and one inner-sphere binding site, probably stabilizing the tetraloop structure. The structure of the tetraloop resembles an RNase III recognition structure, as previously described for an AGUU tetraloop. The detailed knowledge of the P4 domain and its metal ion binding preferences thus brings us closer to understanding the importance of Mg2+ binding for the CPEB3 ribozyme's fold and function in the cell

Solution structure and metal ion binding sites of the human CPEB3 ribozyme’s P4 domain

Three ribozymes are known to occur in humans, the CPEB3 ribozyme, the CoTC ribozyme, and the hammerhead ribozyme. Here, we present the NMR solution structure of a well-conserved motif within the CPEB3 ribozyme, the P4 domain. In addition, we discuss the binding sites and impact of Mg2+ and [Co(NH3)6]3+, a spectroscopic probe for [Mg(H2O)6]2+, on the structure. The well-defined P4 region is a hairpin closed with a UGGU tetraloop that shows a distinct electrostatic surface potential and a characteristic, strongly curved backbone trajectory. The P4 hairpin contains two specific Mg2+ binding sites: one outer-sphere binding site close to the proposed CPEB3 ribozyme active site with potential relevance for maintaining a compact fold of the ribozyme core, and one inner-sphere binding site, probably stabilizing the tetraloop structure. The structure of the tetraloop resembles an RNase III recognition structure, as previously described for an AGUU tetraloop. The detailed knowledge of the P4 domain and its metal ion binding preferences thus brings us closer to understanding the importance of Mg2+ binding for the CPEB3 ribozyme’s fold and function in the cell

unexpected impact of the number of glutamine residues on metal complex stability

The emerging question which this study aims to answer is: what impact do glutamines have on the stability of metal–peptide complexes? We focused our attention on the N-terminal domain of Hpn and Hpn-like proteins from Helicobacter pylori. Cu2+ and Ni2+ complexes of the model peptides MAHHE-NH2, MAHHEEQ-NH2, MAHHEQQ-NH2 and MAHHEQQHQA-NH2 were studied by means of different thermodynamic and spectroscopic techniques, as well as through molecular modelling computation. Experimental results, in very good agreement with theoretical findings, lead to the not obvious conclusion that the stability of metal complexes distinctly increases with the number of glutamine residues present in the peptide, although glutamine side-chains do not directly take part in coordination. This peculiar finding allows one to look at polyglutamine sequences, not only the ones present in some bacterial chaperones but also those involved in several neurodegenerative diseases, from a new perspective

Secondary structure confirmation and localization of Mg2+ions in the mammalian CPEB3 ribozyme

Most of today's knowledge of the CPEB3 ribozyme, one of the few small self-cleaving ribozymes known to occur in humans, is based on comparative studies with the hepatitis delta virus (HDV) ribozyme, which is highly similar in cleavage mechanism and probably also in structure. Here we present detailed NMR studies of the CPEB3 ribozyme in order to verify the formation of the predicted nested double pseudoknot in solution. In particular, the influence of Mg2+, the ribozyme's crucial cofactor, on the CPEB3 structure is investigated. NMR titrations, Tb3+-induced cleavage, as well as stoichiometry determination by hydroxyquinoline sulfonic acid fluorescence and equilibrium dialysis, are used to evaluate the number, location, and binding mode of Mg2+ ions. Up to eight Mg2+ ions interact site-specifically with the ribozyme, four of which are bound with high affinity. The global fold of the CPEB3 ribozyme, encompassing 80%–90% of the predicted base pairs, is formed in the presence of monovalent ions alone. Low millimolar concentrations of Mg2+ promote a more compact fold and lead to the formation of additional structures in the core of the ribozyme, which contains the inner small pseudoknot and the active site. Several Mg2+ binding sites, which are important for the functional fold, appear to be located in corresponding locations in the HDV and CPEB3 ribozyme, demonstrating the particular relevance of Mg2+ for the nested double pseudoknot structure

CHAPTER 6. Prion DiseaseMechanisms and Metal Involvement in Neurodegenerative Diseases

Prion diseases (derived either from infection, germline mutations or most often occurring sporadically), both in humans and animals, are fatal neurodegenerative disorders characterized by progressive brain degeneration. It is widely accepted that they are caused by protein‐only infectious agents propagating disease by inducing protein conformational changes. The molecular mechanism of prion pathologies is not yet entirely understood but some aspects seem to be generally accepted, such as spongiform degeneration, non‐classical inflammation of the brain, progressive neuron loss, accumulation of protein aggregates and synaptic alterations.</jats:p

The zinc-binding fragment of HypA from Helicobacter pylori: a tempting site also for nickel ions

HypA, a nickel accessory protein from H. pylori, binds a zinc ion in it's structural site, a loop with two conserved CXXC motifs (Ac-ELECKDCSHVFKPNALDYGVCEKCHS-NH(2)). There are at least three hypotheses on the binding mode of this ion. In this paper, we try to understand how Zn(2+) binds to this fragment and why Ni(2+), a metal with quite a high affinity towards thiolic sites, doesn't compete with zinc in the binding to this motif. Potentiometric titrations, mass spectrometry, NMR, UV-Vis and CD spectroscopy help us to compare the coordination modes in both metal complexes and discuss their thermodynamic stabilities

Specific metal ion binding sites in unstructured regions of proteins

In this review, we summarise the most recent findings on some very effective binding sites (e.g. ATCUN motif, poly-His, poly-Cys, or Met-containing sequences) for biologically relevant metals in proteins and peptides. In addition, the influence of the specific sequence on the binding stability, besides the donor atoms, is described (e.g. Pro residues as in PrP or poly-Gln sequences). It is well-known that some disorders are connected with proteins which need metal ions for biological activity. Often metal ions coordinate to binding sites located in loops or unstructured regions of those proteins. These rather recent discoveries make metal ion binding to proteins slightly more enigmatic than in the case of an insertion of metal into an “organized” site. Although in the latter cases, we still may need chaperons helping to select the proper metal ion, some selectivity is provided by the pre-organized structure of the donor site itself in the protein. The metal ion binding usually exerts a distinct impact on the binding pocket structure due to the secondary or tertiary structure donors from the residues being often very far away in the peptide sequence. Recently, several metallo-proteins were discovered whose structures are rather disordered (e.g. α-synuclein, prions or β-amyloid peptide involved in Alzheimer disease). Also some specific metal chaperons, consisting of long poly-His sequences being very effective binders of metals, do not show any specific secondary structure. Examples of these might be bacterial nickel accessory proteins, involved in the complicated pathway of metal uptake, delivery and regulation in microorganisms. Recently, several findings were reported on the homeostasis of nickel in Helicobacter pylori, a Gram-negative bacterium that colonizes the gastric mucosa in humans, and is the causative agent of acute and chronic gastritis, peptic ulcer disease, gastric carcinoma, and gastric lymphoma. The homeostasis of nickel is crucial for the survival of this bacterium in the extremely acidic environment of the stomach; the metal is delivered to urease and hydrogenase by a set of accessory proteins. Zinc often plays a structural or regulatory role in those nickel chaperones. It can also be one of the metal ion which interferes with the homeostasis of Ni2+ , since the affinity of the two metals towards His- and Cys- rich sequences can sometimes be comparable

Coordination of Ni2+ and Cu2+ to metal ion binding domains of E. coli SlyD protein

6The C-terminal region of Escherichia coli SlyD is unstructured and extremely rich in potential metal-binding amino acids, especially in histidine residues. SlyD is able to bind two to seven nickel ions per molecule, in a variety of coordination geometries and coordination numbers. This protein contributes to the insertion of nickel into the hydrogenase precursor protein and it has a peptidyl-prolyl cis/trans-isomerase activity which can be regulated through nickel ions. This inspired us to undertake systematic studies on the coordination ability of two histidine-rich peptides from the C-terminus of the SlyD protein with nickel. Also, it is known that histidine-rich regions are part of a Cu2 + binding domain involved in copper uptake under conditions of metal starvation in vivo in other bacteria. For this reason we decided to examine the complex formation of Ac-AHGHVHGAHDHHHD-NH2 and Ac-GHGHDHGHEHG-NH2 fragments with copper ions, which are also reference metal ions in this study. Experiments were performed in a DMSO/water 30:70 solvent. The Ac-AHGHVHGAHDHHHD-NH2 and Ac-GHGHDHGHEHG-NH2 fragments were synthesized and their interactions with Ni2 + and Cu2 + ions were studied by potentiometric, mass spectrometric, UV–vis, CD, EPR, and NMR spectroscopic techniques in solution. The results show that the Ac-GHGHDHGHEHG-NH2 fragment forms equimolar complexes with both nickel and copper ions. At physiological pH, the metal ion is bound only through nitrogens from imidazole sidechain of histidine residues. On the contrary, Ac-AHGHVHGAHDHHHD-NH2 binds 2 metal ions per molecule, at pH range 5 to 7, even if the 1:2 metal:peptide ratios were used. NMR studies indicate the involvement of all His residues in this pH-range in metal binding of the latter peptide. At higher pH, the stoichiometry changes to 1:1 and the His residues are displaced by amide nitrogens.reservedmixedDanuta, Witkowska; Valensin, Daniela; Magdalena Rowinska Zyrek, ; Anna, Karafova; Wojciech, Kamysz; Henryk, KozlowskiDanuta, Witkowska; Valensin, Daniela; Magdalena Rowinska, Zyrek; Anna, Karafova; Wojciech, Kamysz; Henryk, Kozlowsk