Cell Wall/Surface Proteome of Candida albicans: its Application in Rapid Identification of Yeast Species by Mass Signature and Characterization by in vitro and in vivo Chemical Labelings

Qian, Jiang

14 May 2010

Candida albicans is an opportunistic fungal pathogen that may cause mucutaneous infection and/or disseminated candidasis if the host defense system is impaired (such as those in HIV patients). Cell surface of C. albicans is the frontier where initial interplay between host-pathogen takes place and therefore is of great importance in understanding the mechanism of hostpathogen interaction. MALDI-TOF-MS analysis of intact fungal cells yielded mass signatures for rapid species differentiation, strain grouping and yeast morphogenesis monitoring. Cell surface biotinylations at low temperature (4°C), enzymatic digestion of the intact fungal cell surface proteins ("whole cell shaving"), biotin-avidin affinity enrichment of biotinylated peptides, liquid chromatography mass spectrometry (LC-MS) based proteomic approach were employed for unambiguous identification of cell wall/cell wall associated proteins and the exposed peptide segments of these proteins. SILAC (Stable Isotope Labeling by Amino acids in Cell Culture) based CWP quantification analyses were performed to monitor CWP accumulation level change in response to hyphae induction. Information on surface exposed peptide segments and regulation of cell wall/surface protein during morphogenesis provided new candidates to the pool of potential peptide targets for protective vaccine development. A New type of "fluorous" (fluorinated alkane) affinity gained popularity due to its low level nonspecific protein/peptide binding. Fluorous labeling reagents that target primary amine groups in proteins/peptides were synthesized and characterized. The acid labile linker in the labeling reagents allows cleavage of the bulky fluorous tag moiety and the long oligo ethylene glycol (OEG) spacer after fluorous affinity purification. Upon collision induced decomposition, the labeled peptide ion yielded a characteristic fragment that could be retrieved from the residual portion of fluorous affinity tag, and serve as a marker to indicate that the relevant peptide had been successfully labeled. Results showed that both the protein/peptide labeling and affinity enrichment/separation process were highly efficient.

Candida albicans

Yeast differentiation

MALDI-TOF MS

Fluorous labeling reagent

LC-MS

Cell surface proteome

Surface biotinylation

SILAC

Design, Synthesis and Evaluation of Novel Diazirine Photolabels with Improved Ambient Light Stability and Fluorous-Based Enrichment Capacity

Kumar, Arun Babu

01 January 2012

Photoaffinity labeling is a quintessential technique in studying and analyzing the interaction between a ligand and receptor. Diazirines are one of the important photo-labile moieties used in photoaffinity labeling due to their superior photo labeling characteristics. Herein, we report the investigations we conducted with diazirine photolabels on (a) photochemical aspects leading to enhancement of their ambient light stability and (b) equipping them with fluorous tags to enable fluorous enrichment of labeled proteins. Furthermore, we report a pilot study to develop BACE-1 inhibitors, which have potential to be developed into photoaffinity probes. 3-Trifluoromethyl-3-phenyldiazirine offers good selectivity and protection against pseudolabeling but due to its photo lability, it undergoes decomposition even under ambient light. Thus the laboratory handling, including synthesis, of 3-trifluoromethyl-3-phenyldiazirine is cumbersome and restricted under constant darkness. Herein, we have designed, synthesized and evaluated two photolabels with enhanced stability to ambient light conditions in addition to the good selectivity and protection against pseudolabeling as offered by 3-trifluoromethyl-3-phenyldiazirine. It was also found that the aqueous solubility, a vital physical property for a photolabel, was also improved in the modified ambient light stable photolabels. Fluorous tags have found wide use in synthetic applications; herein we explore the possibility of its application in photoaffinity studies. We designed, synthesized and conducted photoactivation studies on two fluorous diazirine photolabels. The photoactivation studies unraveled an unanticipated photoreaction when the fluorous tag was directly connected to the diazirine ring, yielding a fluorous alkene. The more practical photolabel of the two was chosen as the target specific photoaffinity labeling moiety for fluorous proteomics. Upon conducting photolabeling experiments under various conditions, we found that the strong hydrophobic character of the fluorous tag renders the photoaffinity label insoluble in aqueous solutions and significantly alters the binding mode and affinity of the photoaffinity label to its target receptor. A library of 1,3-disubstituted 2-propanols was combinatorially prepared and tested as small molecule inhibitors of β-secretase (BACE-1). The initial screening of the 1,3-disubstituted 2-propanol library revealed a few low micromolar inhibitors for BACE-1. The compound that showed the best activity was chosen for further SAR studies, which resulted in a potent BACE-1 inhibitor with nanomolar inhibition. Investigation on the selectivity of these compounds for BACE-1 inhibition over cathepsin D revealed that these compound series possess very high selectivity. Furthermore, the physicochemical properties study showed that these compounds possessed the calculated parameters advantageous to cross the blood-brain barrier (BBB).

3-Trifluoromethyl-3-phenyl diazirine

BACE-1

Beta-secretase

Fluorous tag

Photoaffinity labeling

Proteomics

American Studies

Arts and Humanities

Organic Chemistry

Studies of Platinum Polyynyl Complexes: Elaboration of Novel "Click" Cycloadducts and Fluorous and Polygon Based Platinum Polyyndiyl Systems

Clough, Melissa Catherine 1985-

14 March 2013

The major directions of this dissertation involve (1) the syntheses and characterization of molecular polygons incorporating sp1hybridized carbon linkers and L2Pt corners (L2 = cis-1,3-diphosphine), (2) the development of protected carbon chain complexes featuring fluorous phosphine ligands and (3) click reactions of metal terminal polyynyl complexes and further metallations of the resulting triazole rings. A brief overview is provided in Chapter I. Chapter II details the syntheses of molecular squares containing bidendate diphosphine ligands of the formula R2C(CH2PPh2)2 where R = Me, Et, n-Bu, n-Dec, Bn, and p-tolCH2 (general designation dppp*), in which the R2 groups are intended to circumvent the solubility issues encountered by others. Their syntheses involve double substitutions of the dimesylate compounds R2C(CH2OMs)2 using KPPh2. Building blocks of the formulae (dppp*)PtCl2 and (dppp*)Pt((C≡C)2H)2 are synthesized and characterized, including one crystal structure of the latter. The target complexes are accessed by reactions of (dppp*)PtCl2 with (dppp*)Pt((C≡C)2H)2 under Sonogashira type conditions. Six new squares of the formula [(R2C(CH2PPh2)2)Pt(C≡C)2]4 are characterized including two crystal structures. Further topics include approaches to higher homologues and cyclocarbon synthesis. Chapter III focuses on carbon chain complexes bearing fluorous phosphine ligands of the formula P((CH2)mRfn)3 (Rfn = (CF2)n-1CF3; m/n = 2/8, 3/8, and 3/10). Precursors of the formula trans-(C6F5)((Rfn(CH2)m)3P)2PtCl are synthesized and characterized, including one crystal structure, which reveals phase separation of the fluorous and non-fluorous domains. Reactions with butadiyne give trans-(C6F5)((Rfn(CH2)m)3P)2Pt(C≡C)2H. Oxidative homocouplings afford the target complexes trans,trans-(C6F5)((Rfn(CH2)m)3P)2Pt(C≡C)4(C6F5)(P((CH2)mRfn)3)2Pt. Cyclic voltammetry indicates irreversible oxidations of the title compounds, in contrast to partially reversible oxidations of non-fluorous analogues. Chapter IV focuses on multimetallic complexes achieved by click reactions in metal coordination spheres. The copper catalyzed click reaction between trans-(C6F5)(p-tol3P)2Pt(C≡C)2H (1) and (η5-C5H4N3)Re(CO)3 affords the bimetallic 1,2,3-triazole trans-C6F5)(p1tol3P)2PtC≡CC=CHN((η51C5H4)Re(CO)3)N=N. Further reactions with Re(CO)5OTf and Re(CO)5Br give trimetallated adducts, which represent the first species of this type. An alternative route to a trimetallic complex involves the twofold cycloaddition of the diazide (η5-C5H4N3)2Fe and 1, giving (η5-C5H4NN=N-C(trans-(C≡C)Pt(Pp-tol3)2(C6F5)=CH)2Fe. The crystal structures of the di and trimetallic complexes are compared, but attempts to achieve a fourth metallation involving the =CH groups are unsuccessful. However, when the triazolium salt [trans-(C6F5)(p-tol3P)2PtC≡CC=CHN(CH2C6H5)N=N(Me)]+ I– is treated with Ag2O and [Rh(COD)Cl]2, a =CRh adduct is obtained. The success of =CH metallation is correlated to the 1H NMR chemical shift, indicative of an electronic effect.

electrochemistry

cyclic voltammetry

multimetallic complexes

copper catalyzed reaction

synthesis

carbon allotrope

polyyne

cyclocarbon

triazole

self assembly

molecular polygon

click chemistry

fluorous

crystallography

organometallic

chemistry

Microwave-Assisted Synthesis of C₂-Symmetric HIV-1 Protease Inhibitors : Development and Applications of <i>In Situ</i> Carbonylations and other Palladium(0)-Catalyzed Reactions

Wannberg, Johan

January 2005

<p>The HIV protease is an essential enzyme for HIV replication and constitutes an important target in the treatment of HIV/AIDS. Efficient combination therapies using inhibitors of the reverse transcriptase and protease enzymes have led many to reevaluate HIV infections from a terminal condition to a chronic-but-manageable disease in the developed world. Unfortunately, the emergence of drug resistant viral strains and severe treatment-related adverse effects limit the benefits of current anti-HIV/AIDS drugs for many patients. Furthermore, less than one in ten patients infected with HIV in low- and middle-income countries have access to proper treatment. These important shortcomings highlight the need for new, cost effective anti-HIV/AIDS drugs with unique properties.</p><p>Microwave heating has recently emerged as a productivity-enhancing tool for the medicinal chemist. Reaction times can often be reduced from hours to minutes or seconds and chemistry previously considered impractical or unattainable can now be accessed.</p><p>In this thesis, the search for unique HIV-1 protease inhibitors and the development and application of new microwave-promoted synthetic methods useful in small-scale medicinal chemistry applications are presented. Protocols for rapid amino- and hydrazidocarbonylations were developed. Mo(CO)₆ was used as a solid source of carbon monoxide, enabling a safe, efficient and simple way to exploit carbonylation chemistry without the direct use of toxic carbon monoxide gas. The aminocarbonylation methodology was applied in the synthesis of two series of new HIV-1 protease inhibitors. A biological evaluation suggested that <i>ortho</i>-substitution of P1 and/or P1’ benzyl side chains might provide a new approach to HIV-1 protease inhibitors with novel properties. To assess the scope and limitations of the <i>ortho</i>-substitution concept, a new series of compounds exhibiting fair potency was prepared by various microwave-heated, palladium-catalyzed coupling reactions. Finally, computer modeling was applied to rationalize the binding-modes and structure-activity relationships of these HIV-1 protease inhibitors.</p>

Pharmaceutical chemistry

HIV

protease inhibitors

palladium

carbonylations

molybdenum hexacarbonyl

dihydropyrimidone

DHPM

microwave

cross-coupling

diazylhydrazines

carbon monoxide

synthesis

C2-symmetric

HIV-1 protease inhibitors

aminocarbonylation

fluorous

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Microwave-Assisted Synthesis of C2-Symmetric HIV-1 Protease Inhibitors : Development and Applications of In Situ Carbonylations and other Palladium(0)-Catalyzed Reactions

Wannberg, Johan

January 2005

The HIV protease is an essential enzyme for HIV replication and constitutes an important target in the treatment of HIV/AIDS. Efficient combination therapies using inhibitors of the reverse transcriptase and protease enzymes have led many to reevaluate HIV infections from a terminal condition to a chronic-but-manageable disease in the developed world. Unfortunately, the emergence of drug resistant viral strains and severe treatment-related adverse effects limit the benefits of current anti-HIV/AIDS drugs for many patients. Furthermore, less than one in ten patients infected with HIV in low- and middle-income countries have access to proper treatment. These important shortcomings highlight the need for new, cost effective anti-HIV/AIDS drugs with unique properties. Microwave heating has recently emerged as a productivity-enhancing tool for the medicinal chemist. Reaction times can often be reduced from hours to minutes or seconds and chemistry previously considered impractical or unattainable can now be accessed. In this thesis, the search for unique HIV-1 protease inhibitors and the development and application of new microwave-promoted synthetic methods useful in small-scale medicinal chemistry applications are presented. Protocols for rapid amino- and hydrazidocarbonylations were developed. Mo(CO)6 was used as a solid source of carbon monoxide, enabling a safe, efficient and simple way to exploit carbonylation chemistry without the direct use of toxic carbon monoxide gas. The aminocarbonylation methodology was applied in the synthesis of two series of new HIV-1 protease inhibitors. A biological evaluation suggested that ortho-substitution of P1 and/or P1’ benzyl side chains might provide a new approach to HIV-1 protease inhibitors with novel properties. To assess the scope and limitations of the ortho-substitution concept, a new series of compounds exhibiting fair potency was prepared by various microwave-heated, palladium-catalyzed coupling reactions. Finally, computer modeling was applied to rationalize the binding-modes and structure-activity relationships of these HIV-1 protease inhibitors.

Pharmaceutical chemistry

HIV

protease inhibitors

palladium

carbonylations

molybdenum hexacarbonyl

dihydropyrimidone

DHPM

microwave

cross-coupling

diazylhydrazines

carbon monoxide

synthesis

C2-symmetric

HIV-1 protease inhibitors

aminocarbonylation

fluorous

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Modification de surfaces de téflon et de SiO2 par adsorption de complexes de cuivre(II)- carboxylates perfluorés / Élaboration de surfaces auto-adaptatives, hydrophiles et coordinantes appliquées à la préparation de couches minces de porphyrines

Motreff-Zeisser, Artur

21 October 2010

Le développement de méthodologies permettant de fonctionnaliser aisément les surfaces est un domaine en plein essor. Nous avons synthétisé et caractérisé de nouveaux complexes de cuivre(II)-carboxylates hautement fluorophiles qui ont été utilisés pour modifier des surfaces. Ces complexes possèdent à l'état solide une très grande affinité pour l'eau, l'hydratation induisant un changement radical des propriétés magnétiques du solide. Ces complexes fluorophiles s'adsorbent très fortement sur le Téflon ou sur le verre pour conduire à des surfaces hydrophiles et coordinantes. En utilisant la chimie de coordination, les surfaces ont ensuite été fonctionnalisées. Des monocouches et des couches minces de porphyrines ont été obtenues sur le verre et sur le téflon puis caractérisées, notamment grâce à leurs propriétés optiques. / The development of methodologies to easily functionalize surfaces is a fast growing field. We have synthesized and characterized new highly fluorophilic copper(II)-carboxylate complexes that have been employed to modify surfaces. In the solid state, these complexes exhibit a high affinity for water, the hydration process inducing dramatic modifications of their magnetic properties. These fluorophilic complexes are strongly adsorbed on teflon or glass to afford hydrophilic and coordinating surfaces. Using coordination chemistry, the surfaces can than be functionalized. Porphyrins monolayers and thin layers have been prepared on glass and teflon and characterized, in particular by their optical properties.

Modification de surfaces

SiO2

Surface auto-adaptative

Monocouche de porphyrine

Chimie de coordination

Éponge magnétique

Fluoreux

Adsorption

Téflon

Complexe de cuivre(II)-carboxylates

Surface modification

Porphyrin monolayer

Fluorous

Teflon

SiO2

Coordination chemistry

Adsorption

Copper(II)-carboxylate complexe

Self-adaptative surface

Magnetic sponge