Modulation of the enzymatic efficiency of ferredoxin‐NADP(H) reductase by the amino acid volume around the catalytic site

Abstract: Ferredoxin (flavodoxin)-NADP(H) reductases (FNRs, EC 1.18.1.2) are a widely distributed class of flavoenzymes that have non-covalently bound FAD cofactor as a redox center. FNRs participate in a wide variety of redox-based metabolic reactions, transferring electrons between obligatory one-and two-electron carriers and therefore functioning as a general electron splitter. In non-phototrophic bacteria and eukaryotes, the reaction is driven towards ferredoxin (Fd) reduction, providing reducing power for multiple … Show more

“…FNR is highly specific for NADP + /H versus NAD + /H and different studies have established a role for several FNR residues in determining coenzyme binding, specificity and enzymatic efficiency [114–120]. Three FNR regions appear to be mainly responsible for the interaction: 2′‐phospho‐AMP (2′P‐AMP) and pyrophosphate of the NADP + /H binding sites, and the position occupied by the C‐terminal residue where the nicotinamide portion of NADP + (NMN) is proposed to bind for hydride transfer [114–117,119]. S223 and Y235 at the An FNR 2′P‐AMP site are critical in determining the specificity and efficient coenzyme orientation [99,115,121].…”

“…The FNR protein portion has a dual role in this process by: (a) modulating the FAD midpoint potential to a value that makes the hydride transfer reversible, and (b) providing the environment for an efficient encoun-ter between the N5 of the flavin and the C4 of the nicotinamide. FNR is highly specific for NADP + ⁄ H versus NAD + ⁄ H and different studies have established a role for several FNR residues in determining coenzyme binding, specificity and enzymatic efficiency [114][115][116][117][118][119][120]. Three FNR regions appear to be mainly responsible for the interaction: 2¢-phospho-AMP (2¢P-AMP) and pyrophosphate of the NADP + ⁄ H binding sites, and the position occupied by the C-terminal residue where the nicotinamide portion of NADP + (NMN) is proposed to bind for hydride transfer [114][115][116][117]119].…”

“…S223 and Y235 at the AnFNR 2¢P-AMP site are critical in determining the specificity and efficient coenzyme orientation [99,115,121]. The 155-160 and 261-268 loops, which accommodate the coenzyme pyrophosphate portion, also confer specificity and the volume of residues in the latter loop fine-tunes FNR catalytic efficiency [114,116,119,120]. R100 (K166 in spFNR), situated at the FAD-binding domain, allows its guanidinium group to H-bond to the NADP + pyrophosphate, providing the necessary flexibility to address the NMN moiety of NADP + towards the active site [99,108,114].…”

Structural and mechanistic aspects of flavoproteins: photosynthetic electron transfer from photosystem I to NADP⁺

“…FNR is highly specific for NADP + /H versus NAD + /H and different studies have established a role for several FNR residues in determining coenzyme binding, specificity and enzymatic efficiency [114–120]. Three FNR regions appear to be mainly responsible for the interaction: 2′‐phospho‐AMP (2′P‐AMP) and pyrophosphate of the NADP + /H binding sites, and the position occupied by the C‐terminal residue where the nicotinamide portion of NADP + (NMN) is proposed to bind for hydride transfer [114–117,119]. S223 and Y235 at the An FNR 2′P‐AMP site are critical in determining the specificity and efficient coenzyme orientation [99,115,121].…”

“…The FNR protein portion has a dual role in this process by: (a) modulating the FAD midpoint potential to a value that makes the hydride transfer reversible, and (b) providing the environment for an efficient encoun-ter between the N5 of the flavin and the C4 of the nicotinamide. FNR is highly specific for NADP + ⁄ H versus NAD + ⁄ H and different studies have established a role for several FNR residues in determining coenzyme binding, specificity and enzymatic efficiency [114][115][116][117][118][119][120]. Three FNR regions appear to be mainly responsible for the interaction: 2¢-phospho-AMP (2¢P-AMP) and pyrophosphate of the NADP + ⁄ H binding sites, and the position occupied by the C-terminal residue where the nicotinamide portion of NADP + (NMN) is proposed to bind for hydride transfer [114][115][116][117]119].…”

“…S223 and Y235 at the AnFNR 2¢P-AMP site are critical in determining the specificity and efficient coenzyme orientation [99,115,121]. The 155-160 and 261-268 loops, which accommodate the coenzyme pyrophosphate portion, also confer specificity and the volume of residues in the latter loop fine-tunes FNR catalytic efficiency [114,116,119,120]. R100 (K166 in spFNR), situated at the FAD-binding domain, allows its guanidinium group to H-bond to the NADP + pyrophosphate, providing the necessary flexibility to address the NMN moiety of NADP + towards the active site [99,108,114].…”

Structural and mechanistic aspects of flavoproteins: photosynthetic electron transfer from photosystem I to NADP⁺

“…For unstable FNR mutants, longer induction periods (10-14 h) at low temperature (18-20ºC) are recommended. In these cases, lower inductor concentration (0.1 mM IPTG) gives better yields (Musumeci et al, 2008, Musumeci et al, 2011. Nevertheless, extremely long induction periods (20 h or more) are detrimental for the quality of the obtained FNR due to the incorporation of a modified flavin or an improper protein folding ( Figure 3A).…”

“…Inset: absorbance change at 515 nm plotted as function of NADP + concentration. C) Differential spectra elicited by NADP + binding to different FNR mutants (grey, yellow, cyan, red and blue corresponds to the spectra of wildtype, C266A, C266AL266A and C266M FNR forms respectively (Musumeci et al, 2008)).…”

The Plant–Type Ferredoxin-NADP+ Reductases

NADP(H) allosterically regulates the interaction between ferredoxin and ferredoxin‐NADP⁺ reductase