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1. Catalytic Activity of the Archetype from Group 4 of the FTR-like Ferredoxin:Thioredoxin Reductase Family Is Regulated by Unique S = 7/2 and S = 1/2 [4Fe–4S] Clusters

   https://doi.org/10.1021/acs.biochem.3c00651  

   Prakash, Divya; Xiong, Jin; Chauhan, Shikha S; Walters, Karim A; Kruse, Hannah; Yennawar, Neela; Golbeck, John H; Guo, Yisong; Ferry, James G (June 2024, Biochemistry)

   Thioredoxin reductases (TrxR) activate thioredoxins (Trx) that regulate the activity of diverse target proteins essential to prokaryotic and eukaryotic life. However, very little is understood of TrxR/Trx systems and redox control in methanogenic microbes from the domain Archaea (methanogens), for which genomes are abundant with annotations for ferredoxin:thioredoxin reductases [Fdx/thioredoxin reductase (FTR)] from group 4 of the widespread FTR-like family. Only two from the FTR-like family are characterized: the plant-type FTR from group 1 and FDR from group 6. Herein, the group 4 archetype (AFTR) from Methanosarcina acetivorans was characterized to advance understanding of the family and TrxR/Trx systems in methanogens. The modeled structure of AFTR, together with EPR and Mössbauer spectroscopies, supports a catalytic mechanism similar to plant-type FTR and FDR, albeit with important exceptions. EPR spectroscopy of reduced AFTR identified a transient [4Fe−4S]1+ cluster exhibiting a mixture of S = 7/2 and typical S = 1/2 signals, although rare for proteins containing [4Fe−4S] clusters, it is most likely the on-pathway intermediate in the disulfide reduction. Furthermore, an active site histidine equivalent to residues essential for the activity of plant-type FTR and FDR was found dispensable for AFTR. Finally, a unique thioredoxin system was reconstituted from AFTR, ferredoxin, and Trx2 from M. acetivorans, for which specialized target proteins were identified that are essential for growth and other diverse metabolisms. 

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2. Structure of human MUTYH and functional profiling of cancer-associated variants reveal an allosteric network between its [4Fe-4S] cluster cofactor and active site required for DNA repair

   https://doi.org/10.1038/s41467-025-58361-w  

   Trasviña-Arenas, Carlos H; Dissanayake, Upeksha C; Tamayo, Nikole; Hashemian, Mohammad; Lin, Wen-Jen; Demir, Merve; Hoyos-Gonzalez, Nallely; Fisher, Andrew J; Cisneros, G Andrés; Horvath, Martin P; et al (April 2025, Nature Communications)

   Abstract MUTYH is a clinically important DNA glycosylase that thwarts mutations by initiating base-excision repair at 8-oxoguanine (OG):A lesions. The roles for its [4Fe-4S] cofactor in DNA repair remain enigmatic. Functional profiling of cancer-associated variants near the [4Fe-4S] cofactor reveals that most variations abrogate both retention of the cofactor and enzyme activity. Surprisingly, R241Q and N238S retained the metal cluster and bound substrate DNA tightly, but were completely inactive. We determine the crystal structure of human MUTYH bound to a transition state mimic and this shows that Arg241 and Asn238 build an H-bond network connecting the [4Fe-4S] cluster to the catalytic Asp236 that mediates base excision. The structure of the bacterial MutY variant R149Q, along with molecular dynamics simulations of the human enzyme, support a model in which the cofactor functions to position and activate the catalytic Asp. These results suggest that allosteric cross-talk between the DNA binding [4Fe-4S] cofactor and the base excision site of MUTYH regulate its DNA repair function. 

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3. Pyruvate formate-lyase activating enzyme: The catalytically active 5′-deoxyadenosyl radical caught in the act of H-atom abstraction

   https://doi.org/10.1073/pnas.2314696120  

   Lundahl, Maike N; Yang, Hao; Broderick, William E; Hoffman, Brian M; Broderick, Joan B (November 2023, Proceedings of the National Academy of Sciences)

   Enzymes of the radicalS-adenosyl-l-methionine (radical SAM, RS) superfamily, the largest in nature, catalyze remarkably diverse reactions initiated by H-atom abstraction. Glycyl radical enzyme activating enzymes (GRE-AEs) are a growing class of RS enzymes that generate the catalytically essential glycyl radical of GREs, which in turn catalyze essential reactions in anaerobic metabolism. Here, we probe the reaction of the GRE-AE pyruvate formate-lyase activating enzyme (PFL-AE) with the peptide substrate RVSG₇₃₄YAV, which mimics the site of glycyl radical formation on the native substrate, pyruvate formate-lyase. Time-resolved freeze-quench electron paramagnetic resonance spectroscopy shows that at short mixing times reduced PFL-AE + SAM reacts with RVSG₇₃₄YAV to form the central organometallic intermediate, Ω, in which the adenosyl 5′C is covalently bound to the unique iron of the [4Fe–4S] cluster. Freeze-trapping the reaction at longer times reveals the formation of the peptide G₇₃₄• glycyl radical product. Of central importance, freeze-quenching at intermediate times reveals that the conversion of Ω to peptide glycyl radical is not concerted. Instead, homolysis of the Ω Fe–C5′ bond generates the nominally “free” 5′-dAdo• radical, which is captured here by freeze-trapping. During cryoannealing at 77 K, the 5′-dAdo• directly abstracts an H-atom from the peptide to generate the G₇₃₄• peptide radical trapped in the PFL-AE active site. These observations reveal the 5′-dAdo• radical to be a well-defined intermediate, caught in the act of substrate H-atom abstraction, providing new insights into the mechanistic steps of radical initiation by RS enzymes. 

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4. The critical role of a conserved lysine residue in periplasmic nitrate reductase catalyzed reactions

   https://doi.org/10.1007/s00775-024-02057-x  

   Giri, Nitai C; Mintmier, Breeanna; Radhakrishnan, Manohar; Mielke, Jonathan W; Wilcoxen, Jarett; Basu, Partha (June 2024, JBIC Journal of Biological Inorganic Chemistry)

   Periplasmic nitrate reductase NapA from Campylobacter jejuni (C. jejuni) contains a molybdenum cofactor (Moco) and a 4Fe–4S cluster and catalyzes the reduction of nitrate to nitrite. The reducing equivalent required for the catalysis is transferred from NapC → NapB → NapA. The electron transfer from NapB to NapA occurs through the 4Fe–4S cluster in NapA. C. jejuni NapA has a conserved lysine (K79) between the Mo-cofactor and the 4Fe–4S cluster. K79 forms H-bonding interactions with the 4Fe–4S cluster and connects the latter with the Moco via an H-bonding network. Thus, it is conceivable that K79 could play an important role in the intramolecular electron transfer and the catalytic activity of NapA. In the present study, we show that the mutation of K79 to Ala leads to an almost complete loss of activity, suggesting its role in catalytic activity. The inhibition of C. jejuni NapA by cyanide, thiocyanate, and azide has also been investigated. The inhibition studies indicate that cyanide inhibits NapA in a non-competitive manner, while thiocyanate and azide inhibit NapA in an uncompetitive manner. Neither inhibition mechanism involves direct binding of the inhibitor to the Mo-center. These results have been discussed in the context of the loss of catalytic activity of NapA K79A variant and a possible anion binding site in NapA has been proposed. 

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5. Functional Relationships of Two NFU Proteins in Maintaining the Abundances of Mitochondrial Iron–Sulfur Proteins

   https://doi.org/10.1002/pld3.70081  

   Zhao, Jun; Satyanarayan, Manasa B; VanSlambrouck, Joshua T; Kolstoe, Alexander J; Voyt, Michael J; James, Glory O; Yu, Fei; Lu, Yan (May 2025, Plant Direct)

   ABSTRACT Iron–sulfur clusters are involved in many biological processes, including photosynthetic electron transport in the chloroplast and respiratory electron transport in the mitochondrion. Iron–sulfur cluster biosynthesis requires iron–sulfur carriers such as nitrogen‐fixation‐subunit‐U [NFU]‐type proteins. TheArabidopsis thaliananuclear genome encodes two mitochondrion‐targeted NFU proteins: NFU4 and NFU5, previously reported to have a primary role in the biosynthesis of the lipoate cofactor, mediated by the 4Fe–4S enzyme lipoyl synthase. Through in vitro reconstitution and spectroscopic analysis, we found that recombinant NFU4 and NFU5 proteins had UV–visible features characteristic of 4Fe–4S clusters. In addition, we confirmed that double homozygous, complete loss‐of‐functionnfu4 nfu5mutants had an embryo‐lethal phenotype. To investigate the functional relationship between NFU4 and NFU5, we generated sesquimutants that were homozygous loss‐of‐function for one gene and heterozygous for the other, which appeared slightly smaller thannfu4‐2,nfu4‐4, andnfu5‐1single mutants. This suggests that the simultaneous decrease in levels of NFU4 and NFU5 proteins may have an additive effect on plant growth. Quantitative reverse transcription PCR showed that theNFU4transcript was absent in mutants homozygous fornfu4‐2andnfu4‐4and that theNFU5transcript level was substantially reduced in thenfu5‐1single mutant or sesquimutants. Consistent with the transcript data, the abundances of NFU4 and NFU5 proteins were either virtually absent or substantially reduced in the corresponding single mutants and sesquimutants. Immunoblot analysis showed that mostnfu4andnfu5‐1single, double, and sesquimutants had significant reductions in the levels of mitochondrial 4Fe–4S proteins, such as aconitase (ACO) and biotin synthase 2 (BIO2; note that BIO2 also contains a 2Fe–2S cluster). In addition,nfu4 nfu5sesquimutants showed substantial reductions in the protein level of the 75‐kDa subunit of respiratory complex I (CI75), which contains one 2Fe–2S cluster and two 4Fe–4S clusters. These observations indicate that NFU4 and NFU5 are important in maintaining the levels of mitochondrial 4Fe–4S proteins. Such observations are also consistent with the hypothesis that NFU4 and NFU5 may serve as iron–sulfur carriers and may play a role in the transfer of 4Fe–4S clusters to recipient apoproteins, such as ACO and CI75, during the biogenesis and maturation of mitochondrial 4Fe–4S clusters. 

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