Chemoenzymatic Resolution in Dynamic Systems : Screening, Classification and Asymmetric Synthesis

Zhang, Yan

January 2013

This  thesis  is  divided  into  four  parts,  all  centered  around  Constitutional Dynamic  Chemistry  (CDC)  and  Dynamic  Kinetic  Resolution  (DKR)  using biocatalysts for selective transformations, and their applications in screening of bioactive compounds, organic synthesis, and enzyme classification.    In  part  one,  an  introduction  to  CDC  and  DKR  is  presented,  illustrating  the basic  concepts,  practical  considerations  and  potential  applications  of  such dynamic systems, thus providing the background information for the studies in the following chapters.   In part two, Dynamic Systemic Resolution (DSR), a concept based on CDC is exemplified.  With  enzyme-catalyzed  transformations  as  external  selection pressure,  optimal  structures  can  be  selected  and  amplified  from  the  system. This  concept  is  expanded  to  various  types  of  dynamic  systems  containing single, double cascade/parallel, and multiple reversible reactions. In addition, the  substrate  selectivity  and  catalytic  promiscuity  of  target  enzymes  are  also investigated.   In   part   three,   DKR   protocols   using   reversible   reactions   for   substrate racemizations  are  illustrated.  Biocatalysts  are  here  employed  for  asymmetric transformations,  resulting  in  efficient  synthetic  pathways  for  enantioenriched organic compounds.   Part  four  demonstrates  two  unique  applications  of  CDC:  one  resulting  in enzyme  classification  by  use  of  pattern  recognition  methodology;  the  other involving  enzyme  self-inhibition  through  in  situ  transformation  of  stealth inhibitors employing the catalytic activity of the target enzyme. / <p>QC 20130614</p>

constitutional dynamic chemistry

dynamic systemic resolution

dynamic kinetic resolution

enzyme catalysis

transesterification

enzyme promiscuity

asymmetric synthesis

pattern recognition

self-inhibition.

Dynamic Systems : Enzymatic Synthesis, Exchange Reactions and Applications in Materials Science

Zhang, Yang

January 2015

This thesis is divided into three parts, revolving around the developments of dynamic systems utilized in dynamic kinetic resolution (DKR) and constitutional dynamic chemistry (CDC). The first section gives an introduction to constitutional dynamics, the core concept of this thesis. Constitutional dynamics can be tuned through reversible interactions. Then, the basic principles of constitutional dynamics in DKR and CDC are discussed, along with their applications. The second section explores the asymmetric synthesis of oxazolidinone derivatives using lipase catalysis through kinetic resolution (KR) and dynamic kinetic resolution. In the first example, synthetic protocol to enantioenriched 5-phenyloxazolidin-2-ones is described, where a kinetically controlled carbamation is followed by lipase-catalyzed cyclization. In contrast to the 5-substituted species, the synthesis of 3-phenyloxazolidin-2-one derivatives could be achieved through lipase-catalyzed cascade O- and N- alkoxycarbonylations in one pot. Furthermore, this KR system could be coupled to a ruthenium-catalyzed racemization process of 1,2-aminoalcohols, thus providing an efficient DKR methodology for asymmetric transformations. The third section focuses on dynamic systems built through reversible covalent reactions. In the first example, a selective gelation process is described, and employed to resolve dynamic imine systems consisting of gelator candidates.  In the second example, reversible reactions with aldehyde enamines are presented, including enamine formation and exchange reactions. In particular, Bi(III) and Sc(III) were discovered to accelerate the enamine exchange reactions by 50-400 times, in which the equilibria could be reached within hours. The last example describes reversible nitroaldol reactions in aqueous media, where rapid and efficient equilibration was identified for selected structures in neutral phosphate buffer. / <p>QC 20150911</p>

constitutional dynamic chemistry

reversible reactions

kinetic resolution

dynamic kinetic resolution

enzyme catalysis

lipase

asymmetric synthesis

racemization

oxazolidinone

organogel

enamine

nitroaldol reaction.

Dynamic Systems: Evaluation, Screening and Synthetic Application

Sakulsombat, Morakot

January 2011

The research work reported in the thesis deals with the development of dynamic covalent systems and their applications in evaluation and screening of protein-ligands and enzyme inhibitors, as well as in synthetic methodologies. The thesis is divided into four parts as described below. In part one, synthetic methodologies to access 3-functionalized phthalides and 3-thioisoindolinones using the concept of cascade reactions are demonstrated. Efficient syntheses of the target products are designed and performed in one-pot process under mild reaction conditions.  In part two, phosphine-catalyzed disulfide metathesis for the generation of dynamic carbohydrate system in aqueous solution is demonstrated. In the presence of biological target (Concanavalin A), the optimal dynamic ligand is successfully identified in situ by the 1H STD-NMR spectroscopy. In part three, lipase-catalyzed resolutions of dynamic reversible systems using reversible cyanohydrin and hemithioacetal reactions in one-pot processes are demonstrated. The dynamic systems are generated under thermodynamic control in organic solution and subsequently resolved by lipase-mediated resolution under kinetic control. The resolution processes resulted in the lipase-selected substrates with high structural and stereochemical specificities. In the last part, dynamic fragment-based strategy is presented using β-galactosidase as a model target enzyme. Based on our previous study, the best dynamic inhibitor of β-galactosidase was identified using 1H STD-NMR technique from dynamic hemithioacetal systems. The structure of the dynamic inhibitor is tailored by fragment linking and optimization processes. The designed inhibitor structures are then synthesized and tested for inhibition activities against β-galactosidase. / QC 20110526

Organic chemistry

Organisk kemi

Dynamery založené na reverzibilní tvorbě hemiacetalové vazby / Dynamers based on the reversible formation of hemiacetals

Nosek, Vladimír

January 2015

This work deals with the design and synthesis of building blocks, usable for creating dynamic polymers based on the reversible formation of hemiacetals bond. Next part is focused on the study of the formation of hemiacetal between polyfunctional alcohols and trifluoromethylketones via NMR spectroscopy. Key words: constitutional dynamic chemistry, hemiacetals, trifluoromethylketones, diols and polyols

Metals in Dynamic Chemistry: Selection &amp; Catalysis

Timmer, Brian J.J.

January 2017

In the adaptation to the oxidative environment on earth, metals played a crucial role for the evolution of life. The presence of metals also allowed access to advanced functions due to their unique coordination sphere and reactivity. This thesis focused on exploiting these unique properties for further development of the field of dynamic chemistry – a field in which adaptation plays a central role as well. The first part of the thesis aimed to create a better understanding of multivalent effects in carbohydrate-lectin interactions. By reversible ligand coordination to zinc ions one of the nanoplatforms, the Borromean rings, could be selectively obtained. After carbohydrate functionalization the binding events were monitored by quartz crystal microbalance technology and compared to glycosylated fullerenes and dodecaamide cages. Overall, this investigation indicated that statistical and polyelectrolyte effects play a considerable role in the observed multivalent effects. The second part of the thesis aimed to design and synthesize a new catalyst for application in aqueous olefin metathesis. This afforded a ruthenium based catalyst that was applied in the self- and cross-metathesis of highly functionalized substrates, such as carbohydrates. In addition, it was shown that addition of a small amount of acetic acid prevented undesired double bond isomerization. The last part of the thesis aimed to explore new methods to discover transition metal catalysts. Dynamic exchange of directing groups generated a pool of potential substrates for C-H activation. Combining this pool of substrates with a pool of potential catalysts resulted in amplification of a reactive substrate/metal combination. By iterative deconvolution in combination with mass spectrometry, this “intermediate” could be identified from the mixture, proving applicability of this alternative approach to catalyst discovery. / <p>QC 20170809</p>

constitutional dynamic chemistry

selection

multivalent interactions

carbohydrates

quartz crystal microbalance

catalyst screening

aqueous olefin metathesis

C-H activation

Organic Chemistry

Organisk kemi