NMR Study of Structure and Orientation of S4-S5 Linker Peptides from Shaw Related Potassium Ion Channels in Micelles and Binding of ZNF29R Protein to HIV RREIIBTR RNA

Qu, Xiaoguang

28 May 2009

Potassium ion channels play a key role in the generation and propagation of action potentials. The S4-S5 linker peptide (L45) is believed to be responsible for the anesthetic/alcohol response of voltage-gated K+ channels. We investigated this region to define the structural basis of 1-alkanol binding site in dShaw2 K+ channel. L45 peptides derived from dShaw2 and hKv3.4 K+ channel, which, if part of the complete channel, demonstrate different sensitivity to 1-alcohols. Specifically, dShaw2 is alcohol sensitive and hKv3.4 is alcohol resistant. Structural analysis of L45 with NMR and CD suggested a direct correlation between alpha-helicity and the inhibition of dShaw2 channel by 1-butanol. We used CD and NMR to determine the structure of L45 peptides in micelles and vesicles. We measured spin-lattice relaxation time (T1) and determined the location and surface accessibility of L45 in micelles. These experiments confirm that L45 of dShaw2 adopts an α-helical conformation, partially buried in the membrane and parallel to the surface. The binding and accumulation of rev proteins to an internal loop of RRE (rev responsive element) of unspliced mRNA precursors is a key step of propagation of human immunodeficiency (HIV) virus. Molecules that interfere with this process can be expected to show anti-HIV activity. Our work is based on an assumption that zinc fingers could compete with rev proteins, therefore impeding the life cycle of HIV and stopping its infection. We studied the influence of different cations, anions, and the concentration of salts and osmolytes on the binding affinity with Polyacrylamide Gel Electrophoresis (PAGE) and Isothermal Titration Calorimetry (ITC). We conclude that the types of anions and/or cations and their concentrations affect the enthalpy and entropy of the binding interacitons. Using a gel assay, we confirm that there are three products in RNA-Protein reaction, and both EDTA and salts (and their concentrations) in the gel or samples interfere with RNA-protein complex mobility.

HIV

L45

Zinc finger protein

Potassium ion channel

Chemistry

Structure and Energetics of RNA - Protein Interactions for HIV RREIIB Targeting Zinc Finger Proteins.

Mishra, Subrata H

01 July 2008

RNA - protein interactions constitute a vital part of numerous biochemical processes. In the HIV life cycle, the interaction of the viral protein Rev and the Rev Responsive Element (RRE), a part of unspliced HIV RNA, is crucial for the propagation of infectious virions. Intervention of this interaction disrupts the viral life cycle. Rev - RRE interaction initially occurs at a high affinity binding site localized to a relatively small stem loop structure called RREIIB. This binding event has been well characterized by a variety of biochemical, enzymatic and structural studies. Our collaborators have previously demonstrated the efficacy of zinc finger proteins, generated by phage display, in the specific targeting of RREIIB. We have shown that the binding of these zinc finger proteins is restricted to the bulge in stem loop IIB that Rev also targets. Currently these proteins bind RREIIB with dissociation constants in the nanomolar range. We have employed a wide assortment of biophysical techniques such as gel shift assays, circular dichroism, isothermal titration calorimetry and NMR structural studies to further investigate this interaction. Several mutants of the zinc finger protein and the RNA were also studied to delineate the parts of the protein secondary structure as well as the role of specific side chains in this interaction. We have generated a solution structure of the RREIIBTR RNA bound zinc finger protein, ZNF29G29R, which displayed the highest affinity to this RNA. This has allowed us to shed further light on the molecular basis of this RNA - protein interaction and provides input for further refinement in our structure guided phage display.

HIV

RRE

RNA

zinc finger

NMR

thermodynamics

Chemistry

Molecular and biochemical characterization of the human zinc transport proteins hZip1 & hZip2 /

Gaither, L. Alex

January 2001

Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.

Molecular and biochemical characterization of the human zinc transport proteins hZip1 & hZip2

Gaither, L. Alex

January 2001

Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.

Structural characterization of C-terminal zinc finger domain of XIAP associated factor 1 (XAF1) and its interaction studies with XIAP

Cho, Chi-kong, Lawrence., 曹智剛.

January 2011

published_or_final_version / Chemistry / Doctoral / Doctor of Philosophy

Zinc-finger proteins.

Tumor suppressor proteins.

Apoptosis - Molecular aspects.

Zinc-finger transcription factors and the response of non-myelinating Schwann cells to axonal injury

Ellerton, Elaine Louise

29 August 2008

Not available / text

Sympathetic nervous system

Myelination

Nerves, Peripheral--Regeneration

Zinc-finger proteins

Designed zinc finger proteins as novel therapeutics inhibiting the transcription of hepatitis B and duck hepatitis B viruses

Zimmerman, Kimberley Anne

Unknown Date

No description available.

hepatitis B

zinc finger protein

cccDNA

inhibition

duck hepatitis B

Functional Domains and Target Genes of the Hindsight Zinc-finger Protein

Ming, Liang

19 June 2014

The Drosophila hindsight (hnt) gene encodes a C2H2-type zinc-finger (ZNF) protein crucial for epithelial morphogenesis. The human HNT homologue, RREB1, functions as a transcriptional modulator and regulates several tumor suppressor genes. HNT’s functional motifs, target genes and its regulatory abilities have not been elucidated. Here I showed that the C-terminal region of HNT containing the last five of 14 ZNFs (ZNF 10-14) binds in vitro to DNA-elements similar to those identified for RREB-1. I then mapped HNT’s endogenous binding sites on polytene chromosomes and focus on two, at 4C and 60C, which are associated with the hnt and nervy (nvy) loci, respectively. Sequence analysis of the bound fragments shows conservation of motifs similar to those bound by HNT in vitro. Data from both hnt loss- and gain-of-function experiments show that HNT attenuates the transcription of the hnt and nvy genes in several tissues and developmental stages. I show that the identified HNT C-terminal DNA binding domain ZNF 10-14 is not required for these regulatory functions. I further delineate the minimal functional motifs of HNT in transcriptional regulation and show that its ninth ZNF in isolation has a repressive activity and is sufficient to confer many regulatory functions of HNT. On the other hand, mutation of ZNF 9 in the context of the full-length protein indicates that it is not necessary for HNT functions. Interestingly, ZNF 9 has been lost from HNT vertebrate homologues. I propose two redundant mechanisms of transcriptional regulation by HNT: one is mediated by the potential protein-interaction abilities of ZNF 9; another is through cooperation of other ZNF motifs of HNT; the DNA binding abilities conferred by the C-terminal five fingers may be essential for the latter mechanism.

Drosophila

Hindsight

Zinc-finger

transcriptional regulation

nervy

RREB-1

0369

Functional Domains and Target Genes of the Hindsight Zinc-finger Protein

Ming, Liang

19 June 2014

The Drosophila hindsight (hnt) gene encodes a C2H2-type zinc-finger (ZNF) protein crucial for epithelial morphogenesis. The human HNT homologue, RREB1, functions as a transcriptional modulator and regulates several tumor suppressor genes. HNT’s functional motifs, target genes and its regulatory abilities have not been elucidated. Here I showed that the C-terminal region of HNT containing the last five of 14 ZNFs (ZNF 10-14) binds in vitro to DNA-elements similar to those identified for RREB-1. I then mapped HNT’s endogenous binding sites on polytene chromosomes and focus on two, at 4C and 60C, which are associated with the hnt and nervy (nvy) loci, respectively. Sequence analysis of the bound fragments shows conservation of motifs similar to those bound by HNT in vitro. Data from both hnt loss- and gain-of-function experiments show that HNT attenuates the transcription of the hnt and nvy genes in several tissues and developmental stages. I show that the identified HNT C-terminal DNA binding domain ZNF 10-14 is not required for these regulatory functions. I further delineate the minimal functional motifs of HNT in transcriptional regulation and show that its ninth ZNF in isolation has a repressive activity and is sufficient to confer many regulatory functions of HNT. On the other hand, mutation of ZNF 9 in the context of the full-length protein indicates that it is not necessary for HNT functions. Interestingly, ZNF 9 has been lost from HNT vertebrate homologues. I propose two redundant mechanisms of transcriptional regulation by HNT: one is mediated by the potential protein-interaction abilities of ZNF 9; another is through cooperation of other ZNF motifs of HNT; the DNA binding abilities conferred by the C-terminal five fingers may be essential for the latter mechanism.

Drosophila

Hindsight

Zinc-finger

transcriptional regulation

nervy

RREB-1

0369

Investigating the interactions between Wilms' tumor suppressor protein and the protein ligands par4, p53, Ciao 1 and U2AF65

Weiss, Tristen Carla

18 February 2010

Wilms' tumor suppressor protein (WTI) is a key regulatory factor involved in controlling the development and normal physiology of the genitourinary tract. Mutations within WT1 result in multiple syndromes affecting the kidney and gonads with the most severe effects being Wilms' tumor, a pediatric kidney cancer. The WTI protein is composed of two distinct functional domains; the amino terminus is a proline and glutamine rich regulatory domain, while the carboxyl terminus is a DNA binding domain which contains four C2H2 zinc fingers. Although the zinc finger motif is small in size, proteins containing zinc fingers are extremely diverse in their functions. The functional diversity of WT1 is exemplified through its interactions with a wide range of ligands, such as DNA, RNA and proteins. The interaction between WT1 and DNA has been well characterized, while the interactions with RNA and proteins still require intensive investigation. Recent studies have identified a diverse group of WT1 protein partners but the characterization of the protein-protein interactions has been limited and inconclusive. Therefore, the experiments conducted in this study focused on investigating the mechanism of interaction between WTI with the protein ligands Ciao 1, p53, par4, and U2AF65. To identify which WTI zinc finger(s) are critical in protein binding, a series of finger swap and deletion mutant proteins were created using site directed mutagenic PCR. The effects the mutant proteins had on the protein interactions were analyzed qualitatively using GST pulldown assays. Two different approaches were used for the GST pulldown assays. The first approach utilized bacterially expressed and purified proteins. None of the mutant WTI proteins exhibited a decrease in protein binding in these assays. Numerous pulldown trials involving various zinc fmger proteins revealed non-specific protein-protein interactions were occurring. The second approach employed in vitro translated 35S-labelled proteins. The results from these assays demonstrate a clear role for WT lzf3, and a possible role for WTI zf4 in the WT 1-par4 interaction. The replacement of WT 1 zinc fingers 3 and 4 with those from YY1 caused a distinct reduction in binding to par4 which was exclusive for the WT1-par4 interaction. YY1 is a transcription factor from yeast that contains four C2H2 type zinc fingers. A decrease in binding between the chimeric proteins WTI :YY1 and the protein partners Ciao 1 and U2AF65 was also observed, although to a much lesser extent. This difference in binding ability may indicate that the interactions between WT1 and its protein ligands involve different zinc fingers.

Zinc-finger proteins