More Like this

1. Crystal Structure of a ligand-bound LacY–Nanobody Complex

   https://doi.org/10.1073/pnas.1801774115  

   Kumar, Hemant; Finer-Moore, Janet S.; Jiang, Xiaoxu; Smirnova, Irina; Kasho, Vladimir; Pardon, Els; Steyaert, Jan; Kaback, H. Ronald; Stroud, Robert M. (August 2018, Proceedings of the National Academy of Sciences)

   The lactose permease of Escherichia coli (LacY), a dynamic polytopic membrane transport protein, catalyzes galactoside/H + symport and operates by an alternating access mechanism that exhibits multiple conformations, the distribution of which is altered by sugar-binding. Camelid nanobodies were made against a double-mutant Gly46 → Trp/Gly262 → Trp (LacY WW ) that produces an outward-open conformation, as opposed to the cytoplasmic open-state crystal structure of WT LacY. Nanobody 9047 (Nb9047) stabilizes WT LacY in a periplasmic-open conformation. Here, we describe the X-ray crystal structure of a complex between LacY WW , the high-affinity substrate analog 4-nitrophenyl-α- d -galactoside (NPG), and Nb9047 at 3-Å resolution. The present crystal structure demonstrates that Nb9047 binds to the periplasmic face of LacY, primarily to the C-terminal six-helical bundle, while a flexible loop of the Nb forms a bridge between the N- and C-terminal halves of LacY across the periplasmic vestibule. The bound Nb partially covers the vestibule, yet does not affect the on-rates or off-rates for the substrate binding to LacY WW , which implicates dynamic flexibility of the Nb–LacY WW complex. Nb9047-binding neither changes the overall structure of LacY WW with bound NPG, nor the positions of side chains comprising the galactoside-binding site. The current NPG-bound structure exhibits a more occluded periplasmic vestibule than seen in a previous structure of a (different Nb) apo-LacY WW /Nb9039 complex that we argue is caused by sugar-binding, with major differences located at the periplasmic ends of transmembrane helices in the N-terminal half of LacY. 

   more » « less
2. It takes two to tango: The dance of the permease

   https://doi.org/10.1085/jgp.201912377  

   Kaback, H. Ronald; Guan, Lan (July 2019, The Journal of General Physiology)

   The lactose permease (LacY) of Escherichia coli is the prototype of the major facilitator superfamily, one of the largest families of membrane transport proteins. Structurally, two pseudo-symmetrical six-helix bundles surround a large internal aqueous cavity. Single binding sites for galactoside and H + are positioned at the approximate center of LacY halfway through the membrane at the apex of the internal cavity. These features enable LacY to function by an alternating-access mechanism that can catalyze galactoside/H + symport in either direction across the cytoplasmic membrane. The H + -binding site is fully protonated under physiological conditions, and subsequent sugar binding causes transition of the ternary complex to an occluded intermediate that can open to either side of the membrane. We review the structural and functional evidence that has provided new insight into the mechanism by which LacY achieves active transport against a concentration gradient. 

   more » « less
3. Arg302 governs the pK _a of Glu325 in LacY

   https://doi.org/10.1073/pnas.1820744116  

   Grytsyk, Natalia; Santos Seiça, Ana Filipa; Sugihara, Junichi; Kaback, H. Ronald; Hellwig, Petra (February 2019, Proceedings of the National Academy of Sciences)

   Lactose permease is a paradigm for the major facilitator superfamily, the largest family of ion-coupled membrane transport proteins known at present. LacY carries out the coupled stoichiometric symport of a galactoside with an H⁺, using the free energy released from downhill translocation of H⁺to drive accumulation of galactosides against a concentration gradient. In neutrophilicEscherichia coli, internal pH is kept at ∼7.6 over the physiological range, but the apparent pK (pK^app) for galactoside binding is 10.5. Surface-enhanced infrared absorption spectroscopy (SEIRAS) demonstrates that the high pK_ais due to Glu325 (helix X), which must be protonated for LacY to bind galactoside effectively. Deprotonation is also obligatory for turnover, however. Here, we utilize SEIRAS to study the effect of mutating residues in the immediate vicinity of Glu325 on its pK_a. The results are consistent with the idea that Arg302 (helix IX) is important for deprotonation of Glu325. 

   more » « less
4. Na+,K+-ATPase with Disrupted Na+ Binding Sites I and III Binds Na+ with Increased Affinity at Site II and Undergoes Na+-Activated Phosphorylation with ATP

   https://doi.org/10.3390/biom14010135  

   Nielsen, Hang N.; Holm, Rikke; Sweazey, Ryan; Andersen, Jens Peter; Artigas, Pablo; Vilsen, Bente (January 2024, Biomolecules)

   Na+,K+-ATPase actively extrudes three cytoplasmic Na+ ions in exchange for two extracellular K+ ions for each ATP hydrolyzed. The atomic structure with bound Na+ identifies three Na+ sites, named I, II, and III. It has been proposed that site III is the first to be occupied and site II last, when Na+ binds from the cytoplasmic side. It is usually assumed that the occupation of all three Na+ sites is obligatory for the activation of phosphoryl transfer from ATP. To obtain more insight into the individual roles of the ion-binding sites, we have analyzed a series of seven mutants with substitution of the critical ion-binding residue Ser777, which is a shared ligand between Na+ sites I and III. Surprisingly, mutants with large and bulky substituents expected to prevent or profoundly disturb Na+ access to sites I and III retain the ability to form a phosphoenzyme from ATP, even with increased apparent Na+ affinity. This indicates that Na+ binding solely at site II is sufficient to promote phosphorylation. These mutations appear to lock the membrane sector into an E1-like configuration, allowing Na+ but not K+ to bind at site II, while the cytoplasmic sector undergoes conformational changes uncoupled from the membrane sector. 

   more » « less
5. Purification and Biochemical Characterization of the DNA Binding Domain of the Nitrogenase Transcriptional Activator NifA from Gluconacetobacter diazotrophicus

   https://doi.org/10.1007/s10930-023-10158-w  

   Standke, Heidi G; Kim, Lois; Owens, Cedric P (December 2023, The Protein Journal)

   Abstract NifA is a σ⁵⁴activator that turns on bacterial nitrogen fixation under reducing conditions and when fixed cellular nitrogen levels are low. The redox sensing mechanism in NifA is poorly understood. In α- and β-proteobacteria, redox sensing involves two pairs of Cys residues within and immediately following the protein’s central AAA⁺domain. In this work, we examine if an additional Cys pair that is part of a C(X)₅ C motif and located immediately upstream of the DNA binding domain of NifA from the α-proteobacteriumGluconacetobacter diazotrophicus(Gd) is involved in redox sensing. We hypothesize that the Cys residues’ redox state may directly influence the DNA binding domain’s DNA binding affinity and/or alter the protein’s oligomeric sate. Two DNA binding domain constructs were generated, a longer construct (2C-DBD), consisting of the DNA binding domain with the upstream Cys pair, and a shorter construct (NC-DBD) that lacks the Cys pair. TheK_dof NC-DBD for its cognate DNA sequence (nifH-UAS) is equal to 20.0 µM. TheK_dof 2C-DBD for nifH-UAS when the Cys pair is oxidized is 34.5 µM. Reduction of the disulfide bond does not change the DNA binding affinity. Additional experiments indicate that the redox state of the Cys residues does not influence the secondary structure or oligomerization state of the NifA DNA binding domain. Together, these results demonstrate that the Cys pair upstream of the DNA binding domain ofGd-NifA does not regulate DNA binding or domain dimerization in a redox dependent manner. 

   more » « less