CHARACTERIZATION OF A NEW PUTATIVE ELAV-LIKE BINDING PROTEIN IN ACINETOBACTER BAUMANNII

Ciani, Caterina

06 April 2022

Post-transcriptional regulations (PTRs) have always been considered features of organisms with higher complexity. However recently, the interest toward the post- transcriptional mechanisms in prokaryotes increased. The bacterial proteome is much more complex compared to the genome size, suggesting a tight and articulate regulation of proteins production, extremely important for the bacterial adaptation to an always changing environment. Bacterial PTRs are responsible of modulation of mRNA stability and decay, translation initiation and elongation, modulation of the access of ribosome to the ribosome binding site and control of termination of the transcript. The main actors in the PTRs are small non-coding RNA (responsible of the inhibition of the transcription) and RNA binding proteins (RBPs), which modulate the translation and half-life of the mRNA. RBPs, are particularly of my interest since I wanted to find a possible orthologous of the eukaryotic Elav-like (Elavl) family of proteins in Acinetobacter baumannii. Elav-like proteins are present in all metazoans and are characterized by two highly conserved sequences: RNP-1 (a quite well conserved hexamer) and RNP-2 (a really well conserved octamer) that are responsible of binding to the mRNA. Each species has a different number of Elavl paralogous that is totally independent from the complexity of the organisms, suggesting a more ancient origin. In particular, I focused on the human paralog HuR (human antigen R). HuR is characterized by three RNA Recognition motif (RRM) -domains, is ubiquitously expressed and is mainly localized into the nucleus (where it is responsible of maturation of the mRNA), but under stress stimuli, can shuttle into the cytoplasm where protect the target mRNA from degradation, by binding AU/U rich sequences (ARE sequences). Its high concentration into the cytoplasm can lead to the overexpression of oncogenes and pro-tumorigenic factors. The choice of Acinetobacter baumannii comes from the increasing worldwide concern toward this pathogen that is becoming multidrug resistant. Indeed, in Italy, more the 50% of nosocomial infections are caused by A. baumannii. I found a putative protein (AB-Elavl), composed by a single RRM domain endowed with similar features of the eukaryotic RRM domain as the presence of a quite well conserved RNP-2 and a less conserved RNP-1. I expressed this protein with recombinant tools and confirmed the production of the protein in the host by western blot and mass spectrometry. I evaluated the binding activity of AB-Elavl testing the EC50 and the Kd with different biochemical assays (EMSA, AlphaScreen and HTRF- FRET) toward three different RNA sequences, in order to test the specificity. By X- RAY and NMR, I confirmed the folded structure that can be overlapped to the HuR’s one and the interaction with the probes tested, highlighting the presence of binding, but with different specificity. I also tested some small molecules developed for interfering in the binding of HuR with the target sequence and found a possible compound able to interact with AB-Elavl, by disrupting the binding with the target probe. All these results suggest an ancient origin of the metazoans’ Elavl family of proteins that probably share a common ancestor with AB-Elavl. More studies should be performed to better understand the role of AB-Elavl in A. baumannii as well as in other bacteria. In fact, I found the presence of other ARE sequence-binding proteins also in Pseudomonas aeruginosa. Interesting would be to check the presence of this protein in all the multidrug resistant ESKAPE bacteria.

RRM domain, Elav-like

Biochemical Characterization of Proteins that Interact with RNA

Ye, Xuan

January 2020

No description available.

Biochemistry

Bringing Actin-Specific Bacterial ADP-Ribosylating Toxins to a Physiological Context: the Role of Actin Binding Proteins

Dong, Songyu

January 2022

No description available.

Biochemistry

Actin

Actin binding protein

Bacterial toxin

ADP-ribosylating toxin

Investigating the interaction between rPvDBPII and duffy antigen on human erythrocytes

Krishnan, Sushma

03 June 2015

No description available.

Parasitology

plasmodium vivax

malaria

duffy antigen

duffy binding protein

Synthetic Nucleic Acid Capable of Post-Polymerization Functionalization and Evolution:

Wu, Kevin B.

January 2023

Thesis advisor: Jia Niu / Thesis advisor: Abhishek Chatterjee / The functions of natural nucleic acids such as DNA and RNA have transcended from serving as the primary information carrier in cells and have emerged as a new class of functional material with applications encompassing medicine, diagnosis, and research tools. While the vulnerability of natural nucleic acids to nuclease degradation as well as the lack of chemical functionality have imposed a significant constraint on their ever-expanding applications, scientists have put in the effort to develop new classes of synthetic nucleic acids (XNAs) to overcome current limitations. In this dissertation, we will describe the development of a novel XNA oligonucleotide structure, the “click handle-modified FANA” (cmFANA), as the next-generation nucleic acid-based biopolymer that is capable of post-polymerization functionalization and evolution. In this dissertation, we divide our graduate research into three chapters: the development of the essential building block for cmFANA and the synthesis of cmFANA oligonucleotide as Chapter 1; the evolution and application of cmFANA as a sugar-presenting affinity reagent that targets disease-related Carbohydrate-Binding Proteins (CBPs) as Chapter 2; and other collaboration projects as Chapter 3. Together, we described a highly potential XNA structure that goes beyond established impressions of nucleic acids and carries the ability to be a versatile platform technology. / Thesis (PhD) — Boston College, 2023. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

aptamer

bioorthogonal conjugation

Carbohydrate-Binding Protein

nucleic acid

oligonucleotide

XNA

Polyomavirus Enhancer Binding Proteins PEA1, PEA2, and PEA3: Functional Analysis by In Vitro Transcription / In Vitro Analysis of Polyomavirus Enhancer Binding Proteins

Yong, Carl

11 1900

The polyomavirus enhancer consists of functionally redundant DNA sub-elements. One such sub-element, element 2, comprises a region with contiguous binding sites, or motifs, for at least three nuclear factors, designated as PEA1, PEA2, and PEA3. Although little is known of PEA2, PEA1 is presumed to be a murine homolog of human transcription activator protein 1 (AP-1), and PEA3 has recently been shown to be encoded by a member of the Ets family of oncogenes. The contributions of each factor to enhancer function are not understood. A cell-free system was devised to assay the individual abilities of the DNA motifs recognized by PEA1, PEA2, and PEA3 to confer transcriptional activation upon a minimal promoter. The motifs were cloned and tested as monomers, as multiple tandem copies, and in paired combinations. The results of these in vitro studies indicate that the PEA1 motif behaves as a low affinity AP-1 binding site; that PEA1 and PEA3, but not PEA2, activate transcription; and that both the PEA1 and PEA3 motifs act synergistically. Band shift titration experiments demonstrated that neither PEA1 nor PEA3 bound to their DNA motifs co-operatively, indicating that synergistic activation of transcription by these factors is not due to cooperative binding. Finally, additional in vitro transcription experiments suggest that PEA1 and PEA3 may co-operate with each other to stimulate transcription. A current model proposes that the minimal sub-units of enhancer structure are small (8-10 base pair) DNA motifs, called enhansons, that act synergistically. I propose that the motifs for PEA1 and PEA3, but not PEA2, are enhansons of the polyomavirus enhancer. / Thesis / Master of Science (MS)

polyomavirus

binding protein

functional analysis

in vitro transcription

PEA1

PEA2

PEA3

Genetic and Immunological Analyses of a Brucella abortus Protein Exhibiting Lectin-like Properties

Vemulapalli, Tracy H.

16 February 2000

Brucella abortus is a facultative, intracellular zoonotic pathogen, which can cause undulant fever in humans and abortion in cattle. Despite all of the progress in brucellosis research, there are still many unanswered questions regarding the molecular mechanisms involved in the pathogenesis of Brucella infections. To better understand the Brucella antigens involved in virulence and/or immunity, genetic and immunologic characterization of a 16 kDa protein of B. abortus was performed. Using PCR methods, the gene encoding the 16 kDa protein was cloned and sequenced. PCR and Southern blot analysis revealed that the gene is conserved among the 6 nomen species of Brucella. Overexpression of this protein in B. abortus vaccine strain RB51 was achieved using Brucella groE and sodC promoters as well as its own promoter. Protection and clearance studies were performed in mice to determine the role of this protein in Brucella immunity and pathogenesis. Inoculation with either strain RB51 overexpressing the 16 kDa protein or a DNA vaccine encoding the 16 kDa protein gene failed to provide significant protection. No difference was noted between the splenic clearance of B. abortus strain 2308 and its recombinant overexpressing the 16 kDa protein. A mutant of strain 2308 (2308D16) was created by disrupting the 16 kDa protein's gene with a chloramphenicol resistance cassette. Western blot analysis indicated that the O antigen profile of strain 2308D16 differed from that of strain 2308. Mice cleared strain 2308D16 faster than strain 2308 indicating the potential attenuation of the disruption mutant. Purified 16 kDa protein was obtained by overexpressing it in E. coli via the pRSET expression system. Western blotting results initially identified this protein as an immunoglobulin-binding protein. Hemagglutination assay revealed that the 16 kDa protein exhibits lectin-like properties. Preliminary studies using hemagglutination inhibition identified mannose as a possible sugar to which the 16 kDa protein can interact. The lectin-like properties exhibited by the 16 kDa protein appears to influence smooth lipopolysaccharide production, and thereby may be involved in virulence. / Master of Science

Brucella abortus

immunoglobulin-binding protein

lectin-like protein

THE CELLULAR NUCLEIC ACID BINDING PROTEIN IN AGING AND DISEASE

Webb, Robin

01 January 2013

The ZNF9 gene on chromosome 3 encodes the cellular nucleic acid binding protein (CNBP), a ubiquitously expressed, 177 amino acid (≈19.5kDa) protein that is highly conserved among vertebrates. The function of the protein is largely unknown, however an expansion in the first intron of the protein results in myotonic dystrophy type 2 (DM2), a multisystemic disease featuring cardiac arrhythmia, muscle wasting, cataracts, and a range of neuropathologies. Remarkably, we recently discovered that CNBP is involved in regulating the activity of β-secretase, the enzyme that produces the first cleavage event in the generation of the amyloid-β peptide (Aβ). The progressive fibrillization and deposition of Aβ is widely believed to be the primary causal factor in the development of Alzheimer’s disease (AD), and AD-like pathology in individuals with Down syndrome (DS). DS provides a unique model for evaluating how these factors change in the aged brain as compared to young brain, and how such changes affect the proportion of DS patients with AD. In the AD brain, both BACE1 and BACE2 increased from an early stage of disease; in DS brains, BACE1 significantly decreased (p<0.04) with age, whereas BACE2 was unchanged, even though the gene for BACE2 is located within the DS obligate region of chromosome 21. BACE1 and BACE2 activity levels were highly correlated in this series (r2 = 0.95), indicating that there may be a higher degree of shared regulation than previously believed. This implicates regulators of BACE as potentially critical for the development of AD, and our data suggests that CNBP may be one such regulator. In AD, CNBP increases early in the disease process, a change that does not occur in the normal aging process or in DS. CNBP and BACE protein levels were correlated in these cases (p<0.001), while there was no relationship between CNBP and age, or CNBP and Aβ, in either the human or mouse brain, indicating that CNBP does not increase as a consequence of normal aging. Thirty day overexpression of CNBP following adeno-associated viral delivery in murine gastrocnemius muscle resulted in an increase in BACE1 protein (p<0.01) and a consequential increase in Aβ production (p<0.01). Other experiments indicated that CNBP overexpression did not affect the half-life of BACE1 mRNA or protein, but resulted in an increase in BACE1 translation. These data indicate that CNBP is an important regulator of β-secretase, and may play an important role in the onset and progression of AD.

Alzheimer’s disease

Cellular Nucleic Acid Binding Protein

Translational Regulation

Down syndrome

RNA binding protein

Molecular and Cellular Neuroscience

Molecular Biology

Stabilité conformationnelle et dépliement de la protéine MalE : Étude par nanopore et par spectroscopie RMN / Conformationnal stability and unfolding of the maltose binding protein

Merstorf, Céline

15 December 2011

Nous avons étudié le couplage dépliement-transport de la Maltose Binding Protein (MBP ou MalE), une protéine périplasmique d'E. Coli et d'un mutant instable, le MalE219, en fonction de la concentration d'un agent dénaturant, le chlorure de guanidium (GdnHCl) à l'échelle de la molécule unique. La technique utilisée est basée sur la détection électrique du transport de macromolécules à travers un nanopore protéique (l'Aérolysine d'Aeromonas Hydrophila) inséré dans une bicouche lipidique plane. Les résultats obtenus ont été comparés à ceux obtenus lors d'une précédente étude réalisée à travers un autre nanopore protéique, l'alpha-hémolysine du Staphylocoque doré, de géométrie et de charge nette différente. Nous avons montré l'existence de temps courts et longs de blocage du courant associés à des protéines dépliées ou partiellement repliées. La fréquence des blocages du courant permet d'obtenir la fraction de protéine dépliée passant à travers le pore en fonction de la concentration en GdnHCl. Les courbes de dénaturation obtenues avec les deux pores montrent un comportement sigmoïdale très similaire. Le type de pore n'influence donc pas la dénaturation des protéines, mais uniquement leur dynamique de transport. En revanche, la courbe de dénaturation du mutant instable présente un déplacement vers les concentrations plus faibles en GdnHCl. Il a été montré également que la présence du maltose comme ligand sur le MalE219 stabilise nettement sa structure. Pour La MBP, les temps de blocages longs diminuent avec l'augmentation de la concentration de GdnHCl montrant une dynamique de transition vitreuse . Cette technique est appropriée à l'étude du dépliement et des changements de conformation de protéines, mais ne permet pas d'obtenir des informations structurales sur les états intermédiaires de repliement. Ainsi, la spectroscopie RMN a été utilisée pour tenter de caractériser ces états intermédiaires de repliement, notamment par la méthode d'échange proton-deutérium. Elle consiste à suivre les cinétiques d'échange des résidus de la protéine sur des spectres 2D 1H-15N HSQC à différentes concentrations de GdnHCl.Ainsi 180 résidus sur les 370 que compte la MBP ont été suivis lors de la dénaturation en présence de GdnHCl. Les deux hélices en C-terminal sont très accessibles au solvant et se dénaturent facilement. La MBP est composée de deux domaines globulaires, le domaine N-ter et le domaine C-ter. Les éléments de structures secondaires situés dans la zone intermédiaire entre les deux domaines (principalement des brins β) sont particulièrement affectés par l'agent dénaturant. D'autres structures secondaires dans les domaines globulaires sont très protégées et plutôt stables. Il est donc proposé que les protéines partiellement dépliées s'insèrent dans le pore par l'extrémité C-terminal et que des parties de structuration tertiaire restent stable entraînant le blocage du pore. / We study the unfolding-transport mechanism of the Maltose Binding Protein (MBP or MalE), a periplasm protein of E. Coli and a destabilised variant, the MalE219, as the function of the concentration of denaturing agent, Guanidine Hydrochloride(GdnHCl) at the single molecule level. The technique is based on the electrical detection of the macromolecule transport through a nanometer-scale channel, Aerolysin channel, inserted into a planar lipid bilayer. Results obtained were compared to previous data with another channel, the alpha-Hemolysin. Both channels have different geometry and net charge.We show that we can distinguish unfolded states from partially folded ones with aerolysin pore.Unfolded proteins induce short current blockades, their duration is constant as a function of the concentration of denaturing agent. Partially folded proteins exhibit long blockades whose life times decrease as the concentration of GdnHCl increase, this indicates a possible glassy dynamics.The frequency of the short current blockades increases as the concentration of denaturing agent increases, following a sigmoidal denaturation curve.The unfolding curve of native MBP with Aerolysin pore is similar to the one previously measured with Hemolysin channel. The denaturation curve of the destabilized variant obtained with Aerolysin is shifted towards lower value of GdnHCl concentration in agreement with bulk measurements. We show also that the addition of maltose stabilizes the structure of MalE219. This nanopore recording technique is also suitable for the study of unfolding and conformation changes of proteins.In order to obtain structural informations that nanopore recording cannot provides, the structure of MBP along its denaturation curve was studied by NMR spectroscopy. The Hydrogen-exchange method known to be sensitive to folding intermediates was specially used. It consists in tracking hydrogen-deuterium exchange rates for amino on the 2D 1H-15N HSQC spectra.Thus, 180 residus of 370 for MBP was followed during denaturation in the presence of GdnHCl. The two last helices in C-terminal of MBP are accessible to the solvent and are denaturated easily. MBP is a two domains protein, N-ter domain and C-ter domain. It was found out that the C- and D-domain of MBP (mainly alpha-helices) could be relatively stable in presence of denaturing agent and that beta strands which make the link between the two domains would be affected by the denaturing agent. It was proposed that partially unfolded proteins enter the pore by the C-terminal end and that stable tertiary structure still present block the pore.

Repliement

Dépliement

Proteine

Technique nanopore

Maltose binding Protein

Folding

Unfolding

Protein

Nanopore recording technique

Maltose Binding Protein

GABP regulation of the murine GABPa/ATPsynthase coupling factor six and human glutathione reductase promoters

Patton, John David,

January 2005

Thesis (Ph. D.)--University of Missouri-Columbia, 2005. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Vita. "December 2005" Includes bibliographical references.