EXPLORATION OF SELECTIVE METAL DISULFIDE SYNTHESIS AND THE SYNTHESIS OF METALLODITHIOLENE COMPLEXES AS QUBIT SYSTEMS

16 May 2019

archives@tulane.edu / 1 / Malathy Pratheepkumar

Qubits, dithiolenes, disulfides

Organo-sulfur phosphorus chemistry

Foreman, Mark Russell StJohn

January 1998

P-organo-substituted dithiadiphosphetane disulfides have been prepared by the reaction of ferrocene and arenes with P4S10. Reaction of these compounds and Lawesson's reagent with alkenes, 2,3-dimethylbutadiene and other compounds gave organo-sulfur phosphorus compounds including 1,2-thiaphosphetane-2-sulfides such as P-ferrocenyl 1,2,5,5,7,8-hexamethyltricyclo[3,2,5,2,0]-3-thia-4-phospho-oct-7-ene-4-sulfide and a thiaphosphorine sulfide (P-ferrocenyl 4,5-dimethyl-3H,6H-1,2-thiaphosphinine-2-sulfide). Treatment of P-ferrocenyl thiaphosphorine sulfide with BuLi followed by carbon containing electrophiles (such as benzyl bromide or 2,4-dinitrochlorobenzene) gave ring-opened products. In addition treatment of dithiadiphosphetane disulfides with organic carbonyl compounds, including ketones, gave thiocarbonyl compounds. Platinum complexes were formed from the dithiadiphosphetane disulfides.

547

Dithiadiphosphetane disulfides

Novel strategies for the synthesis of unsymmetrical glycosyl disulfides

Ribeiro Morais, Goreti, Springett, Bradley R., Pauze, Martin, Schröder, Lisa, Northrop, Matthew, Falconer, Robert A.

02 February 2016

yes / Novel strategies for the efficient synthesis of unsymmetrical glycosyl disulfides are reported. Glycosyl disulfides are increasingly important as glycomimetics and molecular probes in glycobiology. Sialosyl disulfides are synthesised directly from the chlorosialoside Neu5Ac2Cl, proceeding via a thiol-disulfide exchange reaction between the sialosyl thiolate and symmetrical disulfides. This methodology was adapted and found to be successfully applicable to the synthesis of unsymmetrical glucosyl disulfides under mild conditions.

Conformational Analysis And Design Of Disulfides In Antiparallel β-Sheets And Helices

Indu, S

07 1900

Disulfides are the primary covalent interactions within a protein molecule that connect residues which are sequentially distant. Naturally occurring disulfides enhance the stability of the protein by destabilization of the unfolded state. Previous attempts to introduce disulfide bridges as a means to enhance protein stability have met with mixed results. Tools have been developed to predict potential sites for disulfide introduction. However, it must be noted that engineering disulfides is not a trivial task. The effect of the engineered disulfide on protein stability is difficult to predict. There have been few systematic studies carried out to study disulfides in the context of secondary structures. The work in this thesis is aimed at studying disulfides in two kinds of secondary structures- antiparallel β-sheets and helices. In particular, the focus in this thesis is on cross-strand disulfides in antiparallel β-sheets and intrahelical disulfides. The analysis of naturally occurring disulfides in these structural elements coupled with protein engineering studies in model proteins were used to understand the effects of introducing disulfides in helices and antiparallel β-sheets. Synopsis This thesis also includes studies carried out on molten globules of four periplasmic binding proteins of E.coli- Maltose binding protein (MBP), Leucine, isoleucine, valine binding protein (LIVBP), Leucine binding protein (LBP) and Ribose binding protein (RBP). Work carried out in the lab previously had shown that these molten globules can bind the ligands that the proteins do in their corresponding native states. The analysis of the thermodynamic data obtained for these molten globules by differential scanning calorimetry (DSC) studies and isothermal titration calorimetry (ITC) to characterize stability and ligand binding respectively are described in this thesis. To further study the structural features of molten globules by fluorescence resonance energy transfer (FRET), double cysteine mutants of MBP were constructed and characterized. The rationale behind the construction of these mutants and their characterization is reported. Chapter 1 gives an introduction to disulfides in proteins. Previous attempts at cataloguing and characterizing naturally occurring disulfides are described. An overview of studies carried out to determine the effects of removal of naturally occurring disulfides in proteins and the effect of engineered disulfides in different proteins is given. The various tools developed to predict potential disulfide sites are described. Chapter 1 also briefly discusses various aspects of molten globules and FRET. Chapters 2 and 3 involve studies with cross-strand disulfides occurring in antiparallel β-sheets. A detailed analysis on various stereochemical aspects of naturally occurring cross-strand disulfides is described in Chapter 2. The reasons for these disulfides to almost exclusively occur at non-hydrogen-bonded registered pairs have been explored with conformational analysis, modeling studies and energy calculations. In Chapter 3, the effect of engineering cross-strand disulfides in four model proteins- LBP, LIVBP, MBP and Top7 are described. The ease of formation of the introduced disulfides and their effects on protein stability are described. The proteins with engineered cross-strand disulfides at exposed positions were also examined for redox activity. Our studies have shown that in antiparallel strands, engineered disulfides at exposed NHB registered pairs provide a robust means of increasing protein stability. In Chapters 4 and 5, studies about intrahelical disulfides are described. In Chapter 4, the various conformational aspects of intrahelical disulfides occurring naturally are studied. Analysis of structures of proteins in conjunction with modeling studies show that all naturally occurring intrahelical residues bridge cysteines occurring between the N-Cap and 3rd residue of helices. To further explore conformational requirements for intrahelical disulfides, Cys pairs were introduced at N-terminal and interior of helices in a E.coli thioredoxin mutant lacking its active site disulfide. The ease of formation of the engineered disulfides, and their effects on protein stability were studied. The redox activity of the engineered disulfides was also examined. The studies demonstrated that intrahelical disulfides can only occur at the N-terminus of an α-helix and that the N-terminal CYS residue must adopt a non-helical backbone conformation. Although none of the engineered intrahelical disulfides increased the stability of the protein, they conferred mild redox activity. In Chapter 5, the ability of an engineered CXXC motif to bind Zn(II) is also explored. The effect of Zn(II) on the stability of the reduced and oxidized states of an engineered protein with a N-terminal intrahelical CXXC was ascertained. I have also shown that iminodiacetate (IDA) and nitrilotriacetate (NTA) resins charged with zinc can bind the protein CGPC 95-98 in reduced state. These Synopsis preliminary experiments on metal binding show that this property of CXXC motif could be exploited to develop a protein purification method. In Chapter 6, thermodynamic characterization of molten globules of four periplasmic binding proteins (LBP, LIVBP, MBP and RBP) is described. Studies had been previously carried out in the lab to characterize the stability and ligand binding of these molten globules. All four molten globules were found to bind their corresponding ligands without conversion to the native state. In Chapter 6, the estimation of ΔCp of unfolding and ligand binding from the DSC and ITC data is described. The binding of molten globules to their ligands and the ability to undego cooperative thermal unfolding indicated the presence of native protein-like tertiary contacts. To study the molten globule structure, we decided to construct double cysteine mutants of MBP for FRET studies. We decided to employ a strategy for differential labeling of the two cysteines with two different fluorophores based on the conformational differences between MBP in the ligand bound and free forms. Seven double cysteine mutants of MBP were made. The rationale behind the construction of these mutants and their preliminary characterization is described in the appendix to Chapter 6. The optimization of the differential labeling procedure of the MBP double mutants needs to be fine-tuned before further studies through FRET. The work described in this thesis has resulted in the following publications: 1.Prajapati RS, Indu S, Varadarajan R. Identification and thermodynamic characterization of molten globule states of periplasmic binding proteins. Biochemistry. 2007 (46):10339-52. 1 Indu S, Kumar ST, Thakurela S, Gupta M, Bhaskara RM, Ramakrishnan C, Varadarajan R. Disulfide conformation and design at helix N-termini. Proteins.2010 (78):1228-42. 2 Indu S, Kochat V, Thakurela S, Ramakrishnan C, Varadarajan R. Conformational analysis and design of cross-strand disulfides in antiparallel β-sheets. (Manuscript submitted)

Protein - Disulphides

Helices - Disulfides

Antiparallel β-sheets - Disulfides

Intrahelical Disulfides

Cross-Strand Disulfides

Molten Globules

Protein Stability

Disulfide Conformation

Biochemistry

Glycosyl disulfides: importance, synthesis and application to chemical and biological systems

Ribeiro Morais, Goreti, Falconer, Robert A.

16 November 2020

Yes / The disulfide bond plays an important role in the formation and stabilisation of higher order structures of peptides and proteins, while in recent years interest in this functional group has been extended to carbohydrate chemistry. Rarely found in nature, glycosyl disulfides have attracted significant attention as glycomimetics, with wide biological applications including lectin binding, as key components of dynamic libraries to study carbohydrate structures, the study of metabolic and enzymatic studies, and even as potential drug molecules. This interest has been accompanied and fuelled by the continuous development of new methods to construct the disulfide bond at the anomeric centre. Glycosyl disulfides have also been exploited as versatile intermediates in carbohydrate synthesis, particularly as glycosyl donors. This review focuses on the importance of the disulfide bond in glycobiology and in chemistry, evaluating the different methods available to synthesise glycosyl disulfides. Furthermore, we review the role of glycosyl disulfides as intermediates and/or glycosyl donors for the synthesis of neoglycoproteins and oligosaccharides, before finally considering examples of how this important class of carbohydrates have made an impact in biological and therapeutic contexts. / The authors thank the Institute of Cancer Therapeutics (University of Bradford) Doctoral Training Centre for financial support.

Glycosyl disulfides

Carbohydrate chemistry

Disulfide bonds

Glycobiology

Chemical Unfolding and Macromolecular Crowding of Alpha-1-Acid Glycoprotein

Shell, Elizabeth

13 July 2005

No description available.

Chemistry, Biochemistry

Macromolecular Crowding

Orosomucoid

Disulfides

Ligand

Exploring sequence-structure-function relationships in proteins using classification schemes

Cheek, Sara Anne.

January 2005

Thesis (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Not embargoed. Vita. Bibliography: 182-209.

Novel Biologically Active Chalcogenides : Synthesis And Applications

Sivapriya, K

07 1900

The thesis is divided in to five chapters. Chapter I: Synthesis of New thiolevomannosan derivatives In this chapter, a general and efficient method for the synthesis of conformationally locked thiosugars has been discussed. An unprecedented synthesis of a novel thioorthoester and its synthetic utility in glycosylation has been demonstrated. Chapter II: Studies on -Mannosidase Inhibitors The synthesis and evaluation of novel, conformationally locked glycomimic, thiolevomannosan and its analogs sulfoxide and sulfone starting from readily available D-mannose is discussed in this chapter. This is the first report of thiosugar derivatives with enhanced potency compared to kifunensine. Docking and biochemical studies have been discussed. Chapter III: Studies on Novel Cyclic Tetraselenides of Mannose In this chapter, the syntheses and structural properties of novel cyclic tetraselenides starting from mannose have been discussed. These tetraselenides are the first of their kind where all four selenium atoms are arranged in a cyclic manner as the backbone of mannose. X-ray structures have been reported for the tetraselenides. Chapter IV: Novel Chalcogenides of Uridine and Thymidine: Synthesis and Applications An efficient and simple method to synthesise disulfides and diselenides of thymidine and uridine derivatives has been demonstrated in this chapter. The utility of these disulfides in various ring opening reactions as well in Michael addition reactions has been demonstrated. Chapter V: Studies on New, Potent Urease Inhibitors In this chapter, a facile one-pot synthesis of thio and selenourea derivatives under mild conditions by the reaction of amines and commercially available Viehe’s iminium salt in the presence of benzyltriethylammonium tetrathiomolybdate as sulfur transfer reagent and tetraethylammonium tetraselenotungstate as selenium transfer reagent has been discussed. A few of the urea derivatives have shown potent inhibitor activity in the nanomolar range for jackbean urease.

Chalcogenides - Synthesis

Glycosylation

Thiosugars

Mannosidases

Tetraselenides

Ureases

Tetraselenides

Nucleosides - Synthesis

Thymidine Disulfides

Thymidine Diselenides

Uridine Disulfides

Mannose

Mannosidase Inhibitors

Urease Inhibitors

Thiolevomannosan Derivatives

Inorganic Chemistry

Small Molecule Activation with Main Group Complexes

Dureen, Meghan Adrienne

16 March 2011

The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles.

main group

small molecule activation

catalysts

ethylene polymerzation

alkynes

disulfides

0488

Small Molecule Activation with Main Group Complexes

Dureen, Meghan Adrienne

16 March 2011

The synthesis of monodentate biphenyl-amido proligands is reported as well as a series of complexes of lithium with these ligand systems. The solid-state molecular structure of these lithium amides are described as well as their use as synthons in the preparation of amido-arene aluminum complexes. Structural and spectroscopic data suggest that these species exhibit weak arene to metal donation. Attempts to generate aluminum cations from these species are detailed. A new synthetic route to titanium “constrained geometry” precatalysts was utilized to prepare a series of titanium complexes with similar pendant arene groups. The homopolymerization activity of these catalyst systems with ethylene and styrene is detailed. Combination of a sterically encumbered phosphine and large, electrophilic borane was used to effect heterolytic cleavage of disulfides to afford novel thiophosphoniumthioborate salts. A series of exchange reactions demonstrated the facile reversal of this reaction. Similar phosphine-borane systems are found to exhibit divergent reactivity with terminal alkynes, affording either phosphonium-alkynylborate salts from deprotonation or phosphonium-vinyl-borate zwitterions from addition. The scope of Lewis acid, Lewis base and alkyne combinations used to effect similar reactivity is detailed. It was found that the reaction of pyrroles, boranes, and alkynes formed similar addition products that were found to undergo further reactivity to afford C-vinyl pyrroles and nitrogen-boron bicyclic compounds. The synthesis of N-alkyl-bis(pentafluorophenyl)boryl amidinates is presented. The reactivity of these compounds with a variety of small molecules is reported. Reaction with CO2, CO, di-iso-propylcarbodiimide, tert-butyl isocyanide, and benzaldehyde as well as thermally-induced intramolecular rearrangement of these compounds affords a variety of novel nitrogen-boron heterocycles.

main group

small molecule activation

catalysts

ethylene polymerzation

alkynes

disulfides

0488