Dihydrogen driven cofactor recycling for use in bio-catalysed asymmetric organic synthesis

Lonsdale, Thomas

January 2017

Asymmetric reductions are used to produce chiral molecules, which are important precursors for the pharmaceutical industry. Bio catalytic reductions often display high enantioselectivity without the cost and toxicity associated with metal catalysis. However, unlike metal catalysts which use H₂ directly, many useful redox-enzymes require the hydride donor NADH. NADH is expensive; therefore for a bio-catalytic process to be viable it must be recycled, usually by using a sacrificial carbon based substrate, generating super-stoichiometric amounts of waste. Two different methods for H₂-driven NADH recycling are explored in this project: using soluble hydrogenases (SH) and, carbon particles modified with a hydrogenase and an NAD⁺-reductase moiety. The conductive carbon particles allow electrons from H₂-oxidation to be channelled from the hydrogenase to the NAD⁺ reductase for reduction of NAD⁺. This project focuses on four main areas. The first looks at using the enzyme-modified particles for the production of high value chiral amines. A yield of >98% was achieved using the enzyme-modified particles with an L alanine dehydrogenase for H₂ driven conversion of pyruvate to L-alanine. Moreover, a faster rate of reaction was demonstrated with the L-alanine dehydrogenase immobilised on particles versus with the L-alanine dehydrogenase in solution. The second section focuses on elevated temperature NADH recycling: an SH and an NAD⁺-reductase from a thermophilic organism were characterised. The NAD+-reductase was subsequently used as part of a system for recycling NADH at >35 °C. When demonstrated in combination with an enoate-reductase a 62 % yield was obtained for the reduction of 2 methyl 2 cyclopentenone. In the third strand SHs and enzyme-modified particles were investigated as recycling systems for NADH analogues. In summary, this thesis expands the scope for application of H₂-driven biocatalytic reduction reactions.

Electrochemical Regeneration of Cofactors Using a Novel Cuprous Oxide Derived Cathode

Kadowaki, Jonathan

19 June 2019

No description available.

Materials Science

Chemistry

Mechanical Engineering

NADPH

NADH

cofactor regeneration

photoelectrochemistry

electrochemistry

bioelectrochemistry

materials

Development of a Thioredoxin-Based Cofactor Regeneration System for NADPH-Dependent Oxidoreductases

Zhang, Ningning, Müller, Beatrice, Ørtoft Kirkeby, Tanja, Kara, Selin, Loderer, Christoph

02 February 2024

Nicotinamide cofactor-dependent oxidoreductases have become a valuable tool for the synthesis of high value chiral compounds. The feasibility of biocatalytic processes involving these enzymes stands and falls with the efficiency of the regeneration of cofactors. In this study, we describe a novel NADPH regeneration method based on the natural thioredoxin electron delivery system. Thioredoxin 1 (Trx1) and thioredoxin reductase (TR) from Thermus thermophilus were characterized for the dithiol-dependent reduction of NADP+, revealing good catalytic activities and a particularly remarkable thermostability. The TR/Trx1 system was then coupled with two representative NADPH-dependent oxidoreductases, alcohol dehydrogenase and cyclohexanone monooxygenase. Reaction conditions for both systems were optimized for reaction yield and selectivity. The results demonstrate the feasibility of the TR/Trx1-system for its application as NADPH regeneration system.

info:eu-repo/classification/ddc/540

ddc:540

RNP Remodeling and Cofactor Modulation by the DEAD-box Protein Ded1p

Bowers, Heath Andrew

January 2009

No description available.

Biochemistry

Molecular Biology

DEAD-box proteins

DExH/D proteins

Ded1p

eIF4G

cofactor

RNPase

helicase

The role of the p300/CBP complex components in the regulation of apoptosis under hypoxia

Xenaki, Georgia

January 2008

Posttranslational modifications are of great importance in the mediation of transcriptional effects, necessary for signalling in cancer. A characteristic example of such modifications is acetylation of the p53 tumour suppressor, a transcription factor involved in several crucial cellular functions including cell-cycle arrest and apoptosis. p53 is stabilised under hypoxic and DNA damaging-conditions. However, only in the latter scenario is p53 fully capable of inducing the expression of its proapoptotic targets through acetylation. The hypoxia inducible factor 1 (HIF-1) transcription factor is stabilised at low oxygen levels to mediate a cellular adaptive response under these conditions, promoting cell survival. As these two opposing transcription factors share a common transcriptional regulator, p300/CBP, this study focused on deciphering the p300/CBP complex components under differential stress to determine its composition required for cellular responses elicited in response to DNA damage or hypoxia, in an effort to investigate a possible link between differential posttranslational modifications and the resulting cell fate. Hence, the aim of this study was to investigate the roles of p300/CBP components in dictating transcriptional regulation of both HIF-1 and p53 in hypoxic conditions. To carry out this study, the proapoptotic BID gene was the system used, as its promoter contains a p53 response element and a HIF-1 response element (HRE). The p300/CBP associated factors PCAF and Strap were appointed as potent candidates for posttranslational modifications under differential conditions, as they are stress-responsive cofactors. Under DNA damage, PCAF acetylates p53 at K320 and Strap augments p300 binding to p53, both of which amplify the p53 response. Evidence from this study demonstrates that under hypoxia-mimicking conditions PCAF-mediated p53 acetylation at K320 is reduced to a greater extent compared to p300/CBP acetylation at K382. The limited amounts of acetylated p53 at K320 are preferentially recruited to the promoter of the cell cycle arrest p21WAF-1/CIP-1 gene that appears to be unaffected by hypoxia, but fail to be recruited to the BID promoter, rendering p53 incapable of upregulating proapoptotic BID in hypoxic conditions. In addition, under the same conditions, PCAF was found to acetylate, and direct HIF-1 to a particular subset of its targets, leading to alterations in the net physiological effect. Moreover, the intrinsic acetyl transferase activity of PCAF was shown to increase the stability of HIF-1. An additional role was attributed to PCAF in relation to apoptosis, albeit from another angle. BID protein translocation to the cytoplasm in hypoxic conditions was facilitated by ectopically expressed PCAF.Strap was found to be preferentially recruited to the HRE of the BID promoter in hypoxic conditions, and to exert a transrepression effect that appeared to be p53-dependent. Strap also interacted with specific PCAF isoforms depending on the type of cellular stress. Contrary to PCAF, ectopically expressed Strap did not have any effect on BID subcellular distribution. This study has provided additional insight in the mechanisms by which cofactors are involved in cell fate, either by affecting activity and stability of HIF-1 and p53, or having a direct effect on Bcl-2 member subcellular distribution.

616.99407

Study of complement regulatory factor H based on Forster resonance energy transfer and investigation of disease-linked genetic variants

Pechtl, Isabell C.

January 2010

The plasma protein complement factor H (fH, 155 kDa) regulates the activity of the alternative pathway of complement activation. Factor H is monomeric, and its 20 CCP modules are arranged in a predominantly elongated conformation, joined by linking sequences that vary in length, with the longest linkers occurring in the central portion of the molecule. CCP modules 1 through 4 of fH host its capacity to act as a cofactor for fI-mediated proteolytic degradation of C3b and its ability to accelerate the decay of the C3 convertase, C3bBb, thereby regulating the so-called tick-over activation of the alternative pathway. Mutations in this part of fH might compromise its function and lead to underregulation of the alternative pathway. It is hypothesized that this can cause predisposition to diseases such as atypical haemolytic uraemic syndrome (aHUS) and age-related macular degeneration (AMD). In the current work, the known disease-associated mutations R53H and R78G were compared to wild-type in terms of fluid-phase cofactor assays, C3b-binding affinity and the ability to accelerate the decay of the convertase. In addition, the protective variant, I62, was also inspected because its protective role might be explained by an increased regulatory activity. The second, linked, aim of this project was to employ Forster resonance energy transfer (FRET) to study the link between conformation and function in fH. FRET is valuable for obtaining long-distance restraints up to a maximum of 100 °A and is therefore particularly useful for inferring domain orientations within multidomain proteins. This approach to measure long-range inter- and intramolecular distances is a convenient way to complement NMR-based structural investigations, which rely on short-range restraints. It is also a valuable complement to X-ray crystallography since it is a solution technique that can be conducted under physiological conditions. By using site-directed mutagenesis in the current work, free cysteines were introduced into CCP modules 1-4 at strategic points, which were then used for attachment of fluorescent tags. C3 possesses an internal thioester which can be labelled with a fluorophore upon activation to C3b. Intermolecular FRET measurements were thus undertaken to gain information about the interaction between the two proteins that is crucial for understanding functional activity. The CCP modules in the centre of fH may be responsible for introducing a bend into fH that brings the N-teminus close to the C-terminus (the latter is important for host versus non-host discrimination) joined by the longest linkers occurring in the whole molecule. This coincidence of two relatively small CCP modules, 12 and 13, with the highest number of eight amino acids between them, is hypothesised to reflect some unique architectural features. To explore the structural details of this portion of fH by FRET, single-labelled cysteine mutants were further modifed to provide a recognition site for transglutaminase (TGase), which can be enzymatically labeled with a second fluorophore. This stoichiometrically-labelled protein was used for intramolecular FRET studies.

572.6

New approaches for cofactor recycling : application to chemical synthesis and electrochemical devices

Reeve, Holly A.

January 2015

The work in this Thesis addresses the challenges associated with using redox enzymes for chemical synthesis. The use of enzymes as catalysts in the synthesis of fine chemicals is becoming more wide spread, in part due their ability to catalyse reactions with incredible selectivity under relatively mild conditions. In particular, enzymes are useful for selective reduction of ketones to enantiomerically pure alcohols or amines, and partial oxidations of alkanes to alcohols. However, a key limitation to exploiting redox enzymes in these reaction pathways is the requirement for a specialised electron source, usually the expensive nicotinamide cofactors NADH or NADPH. Existing cofactor regeneration methods use a second enzyme with a sacrificial substrate which is oxidised to generate a stoichiometric waste product; this complicates isolation of the desired product and prevents the environmental benefits of biocatalysis from being fully realised. In order to provide clean and efficient biocatalytic routes, improved recycling methods for these cofactors are crucial. This Thesis develops two novel methods for in situ cofactor recycling. The first is an electro-enzymatic system; an NAD⁺-reductase enzyme is shown to use electrons directly from an electrode for supply of NADH to a co-immobilised cofactor-dependent enzyme. The second uses a hydrogenase, NAD⁺ reductase and cofactor-dependent enzyme immobilised on conducting particles for H₂-driven NADH regeneration. This relies on the thermodynamically favourable reduction of NAD⁺ by H₂ when the hydrogenase and NAD⁺-reductase are in electronic contact, provided by the conducting particle. The electro-enzymatic approach to NAD⁺ reduction is then adapted for electrochemical devices; an enzyme catalysed fuel cell and a self-powered biosensor were considered.

572

Busca por inibidores seletivos de Sirtuína 2 de T. cruzi empregando técnicas de planejamento de fármacos baseadona estrutura do receptor / Search for selective inhibitors of T. cruzi Sirtuin 2 employing drug design techniques based on receptor structure

Ferreira, Glaucio Monteiro

12 December 2018

A doença de Chagas, causada pelo parasita Trypanosoma cruzi, acomete entre 6 a 8 milhões de pessoas em todo o mundo. Conhecida como tripanossomíase americana, por ter sido considerada endêmica apenas na América Latina, esta doença, se espalhou para outros continentes devido aos movimentos migratórios se tornando um problema de sáude mundial. Estima-se que 56.000 novos casos e cerca de 12.000 mortes por complicações relacionadas à doença de Chagas anualmente. A quimioterapia disponível para o tratamento é composta apenas por dois fármacos, nifurtimox e benznidazol, no entanto são pouco eficazes na fase crônica da doença. Estes fármacos apresentarem, ainda, efeitos adversos graves e resistência por parte de algumas cepas do parasita. Diante deste panorama, é iminente a necessidade da busca de novos fármacos contra T. cruzi. Para a busca racional de novos quimiterapicos antiparasitários é fundamental a identificação e caracterização de vias metabólicas essenciais à sobrevivência dos parasitas. Assim, a enzima sirtuína 2 - Silent Information Regulator 2 (Sir2), tem importante papel para a infecção por T. cruzi, pois está totalmente envolvida no seu ciclo celular do parasita. Esta é uma enzima NAD+ dependente da classe III histona desacetilases, e se mostra como um interessante alvo bioquímico para o desenvolvimento de antichagásicos. A disponibilidade do sequenciamento genômico da Sir2 nos permite utilizar estratégias de planejamento de fármaco baseado no receptor (SBDD - Structure Based Drug Design) na identificação de candidatos a fármacos para essa doença. Entre as técnicas modernas de SBDD utilizadas, a triagem virtual possibilita identificar e selecionar inibidores enzimáticos potentes e seletivos para o alvo escolhido. Assim, neste trabalho, foi construído por meio da técnica de modelagem comparativa o modelo da enzima Sir2 de T. cruzi. Uma simulação por dinâmica molecular de 200ns, foi realizada para averiguar a estabilidade do modelo obtido. Diante da estabilização do modelo a partir de 100ns, o mesmo foi validado utilizando análise de clusters, RMSD (Root-mean-square Deviation) e análises de frequência de ligações de hidrogênio com o Cofator (NAD+) e os aminoácidos do sítio de catálise foram observadas, estes passos de simulação e validação foram realizados no programa DESMOND. Com o modelo robusto, os campos de interações moleculares (MIFs) foram gerados no programa GRID (Molecular Discovery v2.1) com o intuito de elucidar as regiões favoráveis a interação com a enzima em relação a propriedades físico-químicas da Sir2. A partir dos MIFs favoráveis a Sir2 de T. cruzi foi possível a construção de dois modelos farmacofóricos, o qual se baseou nas interações do Cofator (NAD+) e o sítio de catálise (Nicotinamida). O mesmo foi apliacdo como filtro para Triagem Virtual no programa UNITY da plataforma SYBYL X 2.0, utilizando os bancos de dados ZINC15 e GSK. A triagem resultou na seleção de 8 compostos candidatos a inibidores. Destes foram adquiridos 6 compostos por serem considerados mais promissores devido a complementariedade molecular. Estes foram testados contra a enzima de T. cruzi Sri2. Após o ensaio foi possível avaliar a potência de 4 compostos, sendo o composto CDMS-01 (IC50 = 39,9uM) o mais promissor que será submetido à processos de otimização molecular. / Chagas disease, caused by the parasite Trypanosoma cruzi, affects between 6 and 8 million people worldwide. Also known as American trypanosomiasis, because it is considered endemic only in Latin America, but has spread to other continents due to migratory movements. It is estimated that 56,000 new cases and about 12,000 deaths from complications related to Chagas disease annually. The chemotherapy available for treatment consists of only two drugs, nifurtimox and benznidazole, however these are poorly effective in the chronic phase. These drugs also have serious adverse effects and resistance from strains of the parasite. Faced with this scenario, the need to search for new drugs against T. cruzi is imminent. For the drug planning for new antiparasitic chemotherapics, the identification and characterization of metabolic pathways essential to the survival of parasites is fundamental. Therewith, the sirtuin 2 - Silent Information Regulator 2 (Sir2) enzyme has an important role for T. cruzi infection, since Sir2 in the parasite is totally involved in its cell cycle. This is an NAD+-dependent enzyme of class III histone deacetylases, and it shows an interesting biochemical target for the development of antichagasic. The availability of Sir2 genomic sequencing allows us to use SBDD (Structure Based Drug Design) strategies in identifying drug candidates for this disease. Among the modern techniques of SBDD used, virtual screening makes it possible to identify and select potent and selective enzyme inhibitors for the chosen target. The model of the T. cruzi Sir2 enzyme was constructed using the comparative modeling technique. A molecular dynamics simulation of 200ns was performed to ascertain the stability of the obtained model. Considering the stabilization of the model from 100ns, it was validated using cluster analysis, Root-mean-square Deviation (RMSD) and hydrogen bond frequency analyzes with Cofator (NAD+) and the amino acids of the catalysis site were observed, these simulation and validation steps were performed in the DESMOND program. With the robust model, the molecular interaction fields (MIFs) were generated in the GRID program (Molecular Discovery v2.1) in order to elucidate the regions favorable to the interaction with the enzyme in relation to the physicalchemical properties of Sir2. From the MIFs favorable to Sir2 of T. cruzi it was possible to construct two pharmacophoric models, which was based on the interactions of Cofator (NAD+) and the catalysis site (Nicotinamide). It was also applied as a Virtual screening filter in the UNITY program of the SYBYL X 2.0 platform, using the ZINC15 and GSK databases. Screening resulted in the selection of 8 inhibitor candidate compounds. Six compounds were obtained from the screening, because they were considered more promising, and were tested against T. cruzi Sri2 enzyme. After the assay it was possible to evaluate the potency of 4 compounds, the most promising compound being CDMS-01 (IC50 = 39.9 µM) that will be submitted to molecular optimization processes.

Cofactor (NAD+)

Cofator (NAD+)

Dinâmica molecular (DM)

Drug planning

Molecular dynamics (DM)

Planejamento de fármacos

SBDD

SBDD

Sirtuin 2

Sirtuína 2

Busca por inibidores seletivos de Sirtuína 2 de T. cruzi empregando técnicas de planejamento de fármacos baseadona estrutura do receptor / Search for selective inhibitors of T. cruzi Sirtuin 2 employing drug design techniques based on receptor structure

Glaucio Monteiro Ferreira

12 December 2018

A doença de Chagas, causada pelo parasita Trypanosoma cruzi, acomete entre 6 a 8 milhões de pessoas em todo o mundo. Conhecida como tripanossomíase americana, por ter sido considerada endêmica apenas na América Latina, esta doença, se espalhou para outros continentes devido aos movimentos migratórios se tornando um problema de sáude mundial. Estima-se que 56.000 novos casos e cerca de 12.000 mortes por complicações relacionadas à doença de Chagas anualmente. A quimioterapia disponível para o tratamento é composta apenas por dois fármacos, nifurtimox e benznidazol, no entanto são pouco eficazes na fase crônica da doença. Estes fármacos apresentarem, ainda, efeitos adversos graves e resistência por parte de algumas cepas do parasita. Diante deste panorama, é iminente a necessidade da busca de novos fármacos contra T. cruzi. Para a busca racional de novos quimiterapicos antiparasitários é fundamental a identificação e caracterização de vias metabólicas essenciais à sobrevivência dos parasitas. Assim, a enzima sirtuína 2 - Silent Information Regulator 2 (Sir2), tem importante papel para a infecção por T. cruzi, pois está totalmente envolvida no seu ciclo celular do parasita. Esta é uma enzima NAD+ dependente da classe III histona desacetilases, e se mostra como um interessante alvo bioquímico para o desenvolvimento de antichagásicos. A disponibilidade do sequenciamento genômico da Sir2 nos permite utilizar estratégias de planejamento de fármaco baseado no receptor (SBDD - Structure Based Drug Design) na identificação de candidatos a fármacos para essa doença. Entre as técnicas modernas de SBDD utilizadas, a triagem virtual possibilita identificar e selecionar inibidores enzimáticos potentes e seletivos para o alvo escolhido. Assim, neste trabalho, foi construído por meio da técnica de modelagem comparativa o modelo da enzima Sir2 de T. cruzi. Uma simulação por dinâmica molecular de 200ns, foi realizada para averiguar a estabilidade do modelo obtido. Diante da estabilização do modelo a partir de 100ns, o mesmo foi validado utilizando análise de clusters, RMSD (Root-mean-square Deviation) e análises de frequência de ligações de hidrogênio com o Cofator (NAD+) e os aminoácidos do sítio de catálise foram observadas, estes passos de simulação e validação foram realizados no programa DESMOND. Com o modelo robusto, os campos de interações moleculares (MIFs) foram gerados no programa GRID (Molecular Discovery v2.1) com o intuito de elucidar as regiões favoráveis a interação com a enzima em relação a propriedades físico-químicas da Sir2. A partir dos MIFs favoráveis a Sir2 de T. cruzi foi possível a construção de dois modelos farmacofóricos, o qual se baseou nas interações do Cofator (NAD+) e o sítio de catálise (Nicotinamida). O mesmo foi apliacdo como filtro para Triagem Virtual no programa UNITY da plataforma SYBYL X 2.0, utilizando os bancos de dados ZINC15 e GSK. A triagem resultou na seleção de 8 compostos candidatos a inibidores. Destes foram adquiridos 6 compostos por serem considerados mais promissores devido a complementariedade molecular. Estes foram testados contra a enzima de T. cruzi Sri2. Após o ensaio foi possível avaliar a potência de 4 compostos, sendo o composto CDMS-01 (IC50 = 39,9uM) o mais promissor que será submetido à processos de otimização molecular. / Chagas disease, caused by the parasite Trypanosoma cruzi, affects between 6 and 8 million people worldwide. Also known as American trypanosomiasis, because it is considered endemic only in Latin America, but has spread to other continents due to migratory movements. It is estimated that 56,000 new cases and about 12,000 deaths from complications related to Chagas disease annually. The chemotherapy available for treatment consists of only two drugs, nifurtimox and benznidazole, however these are poorly effective in the chronic phase. These drugs also have serious adverse effects and resistance from strains of the parasite. Faced with this scenario, the need to search for new drugs against T. cruzi is imminent. For the drug planning for new antiparasitic chemotherapics, the identification and characterization of metabolic pathways essential to the survival of parasites is fundamental. Therewith, the sirtuin 2 - Silent Information Regulator 2 (Sir2) enzyme has an important role for T. cruzi infection, since Sir2 in the parasite is totally involved in its cell cycle. This is an NAD+-dependent enzyme of class III histone deacetylases, and it shows an interesting biochemical target for the development of antichagasic. The availability of Sir2 genomic sequencing allows us to use SBDD (Structure Based Drug Design) strategies in identifying drug candidates for this disease. Among the modern techniques of SBDD used, virtual screening makes it possible to identify and select potent and selective enzyme inhibitors for the chosen target. The model of the T. cruzi Sir2 enzyme was constructed using the comparative modeling technique. A molecular dynamics simulation of 200ns was performed to ascertain the stability of the obtained model. Considering the stabilization of the model from 100ns, it was validated using cluster analysis, Root-mean-square Deviation (RMSD) and hydrogen bond frequency analyzes with Cofator (NAD+) and the amino acids of the catalysis site were observed, these simulation and validation steps were performed in the DESMOND program. With the robust model, the molecular interaction fields (MIFs) were generated in the GRID program (Molecular Discovery v2.1) in order to elucidate the regions favorable to the interaction with the enzyme in relation to the physicalchemical properties of Sir2. From the MIFs favorable to Sir2 of T. cruzi it was possible to construct two pharmacophoric models, which was based on the interactions of Cofator (NAD+) and the catalysis site (Nicotinamide). It was also applied as a Virtual screening filter in the UNITY program of the SYBYL X 2.0 platform, using the ZINC15 and GSK databases. Screening resulted in the selection of 8 inhibitor candidate compounds. Six compounds were obtained from the screening, because they were considered more promising, and were tested against T. cruzi Sri2 enzyme. After the assay it was possible to evaluate the potency of 4 compounds, the most promising compound being CDMS-01 (IC50 = 39.9 µM) that will be submitted to molecular optimization processes.

Cofator (NAD+)

Dinâmica molecular (DM)

Planejamento de fármacos

SBDD

Sirtuína 2

Cofactor (NAD+)

Drug planning

Molecular dynamics (DM)

SBDD

Sirtuin 2

Synthesis and Characterization of Five New Tetrakis(N-phenylacetamidato) Dirhodium(II) Amine Complexes and One Molybdenum Cofactor Described Crystallographically

Harris, Cragin K

01 May 2015

Six new crystal structures were determined using a Rigaku Mercurcy 375/MCCD(XtaLab mini) diffractometer. The structure of a molybdenum cofactor was solved resulting in an R1 (R1 = Σ ||Fo| - |Fc|| / Σ |Fo|) of 3.61% despite the presence of a disordered DMSO molecule. New Tetrakis(N-phenylacetamidato) Dirhodium(II) complexes were synthesized and characterized. Two 2,2-cis-[Rh2(NPhCOCH3)4]•(C3H4N2)x where x= 1 or 2 were successfully crystallized and solved with R1 values below 5%. Additional studies were conducted via NMR to observe formation of both products. Three potential catalysts were synthesized starting with 3,1-[Rh2(NPhCOCH3)4]. The resulting compounds were a mono adduct 3,1-[Rh2(NPhCOCH3)4]•(C3H4N2), and two dimer of dimers complexes with amine bridges 3,1-[Rh2(NPhCOCH3)4]2•(C8H6N2) and 3,1-[Rh2(NPhCOCH3)4]2•(C10H8N2). All three complexes were crystallized and solved with R1 values less than 10%. Additional NMR studies were conducted to elucidate solid and solution phase structures and to determine the possibility of additional amine bonds forming.

X-ray Crystallography

Dirhodium(II)

Phenylacetamide

Molybdenum

Cofactor

Catalyst

Imidazole

4

4-Bipyridine

1

5-Naphthyridine

Inorganic Chemistry