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1. Specific metallo-protein interactions and antimicrobial activity in Histatin-5, an intrinsically disordered salivary peptide

   https://doi.org/10.1038/s41598-019-52676-7  

   McCaslin, Tyler G.; Pagba, Cynthia V.; Yohannan, Jiby; Barry, Bridgette A. (November 2019, Scientific Reports)

   Abstract Histatin-5 (Hst-5) is an antimicrobial, salivary protein that is involved in the host defense system. Hst-5 has been proposed to bind functionally relevant zinc and copper but presents challenges in structural studies due to its disordered conformation in aqueous solution. Here, we used circular dichroism (CD) and UV resonance Raman (UVRR) spectroscopy to define metallo-Hst-5 interactions in aqueous solution. A zinc-containing Hst-5 sample exhibits shifted Raman bands, relative to bands observed in the absence of zinc. Based on comparison to model compounds and to a family of designed, zinc-binding beta hairpins, the alterations in the Hst-5 UVRR spectrum are attributed to zinc coordination by imidazole side chains. Zinc addition also shifted a tyrosine aromatic ring UVRR band through an electrostatic interaction. Copper addition did not have these effects. A sequence variant, H18A/H19A, was employed; this mutant has less potent antifungal activity, when compared to Hst-5. Zinc addition had only a small effect on the thermal stability of this mutant. Interestingly, both zinc and copper addition shifted histidine UVRR bands in a manner diagnostic for metal coordination. Results obtained with a K13E/R22G mutant were similar to those obtained with wildtype. These experiments show that H18 and H19 contribute to a zinc binding site. In the H18A/H19A mutant the specificity of the copper/zinc binding sites is lost. The experiments implicate specific zinc binding to be important in the antimicrobial activity of Hst-5. 

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2. Effect of the Tyr5 and His6 substituent groups on the zinc affinities and conformational structures of the acetyl-His1-Cys2-Gly3-Pro4-X5-X6-Cys7 heptapeptides

   https://doi.org/10.1016/j.ijms.2025.117458  

   Adomako, Richmond A; Owusu, Michael B; Oberdick, Rebekah; Senyah, Kwabena N; Asare, Perfect; Angel, Laurence A (July 2025, International Journal of Mass Spectrometry)

   In this study, we investigate the influence of the Tyr5 and His6 substituent groups on the zinc-binding affinities and conformational properties of a series of acetylated heptapeptides, acetyl-His1-Cys2-Gly3-Pro4-X5-X6-Cys7 focusing on the impacts where X5-X6 are either Tyr5-Gly6, Tyr5-His6, Gly5-Gly6, or Gly5-His6. Utilizing traveling-wave ion mobility-mass spectrometry and molecular modeling techniques we analyze the zinc binding interactions and peptide coordination behavior. The zinc binding peptides (ZBPs) relative zinc affinities were measured across pH 5 to pH 10 by monitoring the solution-phase formation of the [ZBP+Zn(II)] complex by utilizing native MS in negative ion mode to preserve the solution-phase binding of Zn(II) to the peptides. Furthermore, their relative gas-phase Zn(II) affinities were measured using competitive threshold collision-induced dissociation (TCID) of the [ZBP+Zn(II)+NTA] complex, by modeling the two competing dissociation channels: [ZBP+Zn(II)]- + NTA or [Zn(II)+NTA] + ZBP, where NTA is nitrilotriacetic acid. Our examinations also tested whether there was an effect of the formation of the [ZBP+Zn(II)+NTA] complexes from solutions at different pHs, before they are electrosprayed into the gas-phase for the TCID analyses. Both solution- and gas-phase measurements predicted the heptapeptide with the Gly5-His6 residues had the greatest zinc affinity and that the presence of Tyr5 and His6 altered the zinc affinity and induced distinct conformational changes due to changes in the coordination of the zinc. This research enhances our understanding of zinc-peptide interactions, with implications for the design of peptide-based metalloproteins, which may guide the design of novel ZBPs for therapeutic, biotechnological or environmental remediation applications. 

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3. Synaptic zinc inhibition of NMDA receptors depends on the association of GluN2A with the zinc transporter ZnT1

   https://doi.org/10.1126/sciadv.abb1515  

   Krall, Rebecca F.; Moutal, Aubin; Phillips, Matthew B.; Asraf, Hila; Johnson, Jon W.; Khanna, Rajesh; Hershfinkel, Michal; Aizenman, Elias; Tzounopoulos, Thanos (July 2020, Science Advances)

   The NMDA receptor (NMDAR) is inhibited by synaptically released zinc. This inhibition is thought to be the result of zinc diffusion across the synaptic cleft and subsequent binding to the extracellular domain of the NMDAR. However, this model fails to incorporate the observed association of the highly zinc-sensitive NMDAR subunit GluN2A with the postsynaptic zinc transporter ZnT1, which moves intracellular zinc to the extracellular space. Here, we report that disruption of ZnT1-GluN2A association by a cell-permeant peptide strongly reduced NMDAR inhibition by synaptic zinc in mouse dorsal cochlear nucleus synapses. Moreover, synaptic zinc inhibition of NMDARs required postsynaptic intracellular zinc, suggesting that cytoplasmic zinc is transported by ZnT1 to the extracellular space in close proximity to the NMDAR. These results challenge a decades-old dogma on how zinc inhibits synaptic NMDARs and demonstrate that presynaptic release and a postsynaptic transporter organize zinc into distinct microdomains to modulate NMDAR neurotransmission. 

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4. Photoinduced Electron Transfer in Axially Coordinated Supramolecular Zinc Tetrapyrrole Bis(styryl)BODIPY Donor‐Acceptor Conjugates

   https://doi.org/10.1002/cptc.202000221  

   Benitz, Alejandro; Thomas, Michael_B; de_Silva, Imesha; Nesterov, Vladimir_N; Verbeck, IV, Guido_F; D'Souza, Francis (November 2020, ChemPhotoChem)

   Abstract Photoinduced electron transfer (PET) in newly assembled dyads formedviametal‐ligand axial coordination of phenylimidazole‐functionalized bis(styryl)BODIPY (BODIPY(Im)₂) and zinc tetrapyrroles, that is, zinc tetratolylporphyrin (ZnP), zinc tetra‐t‐butyl phthalocyanine (ZnPc) and zinc tetra‐t‐butyl naphthalocyanine (ZnNc), in non‐coordinatingo‐dichlorobenzene (DCB) is investigated using both steady‐state and time‐resolved transient absorption techniques. The structure of the BODIPY(Im)₂was identified by using single crystal X‐ray structural analysis. The newly formed supramolecular dyads were fully characterized by spectroscopic, computational and electrochemical methods. The binding constants measured from optical absorption spectral studies were in the range of ∼10⁴ M⁻¹for the first zinc tetrapyrrole binding and suggested that the two imidazole entities of bis(styryl)BODIPY behave independently in the binding process. The energy level diagram established using spectral and electrochemical studies suggested PET to be thermodynamically unfavorable in the ZnP‐bearing complex while for ZnPc‐ and ZnNc‐bearing complexes such a process is possible when zinc tetrapyrrole is selectively excited. Consequently, occurrence of efficient PET in the latter two dyads was possible to establish from femtosecond transient absorption studies wherein the electron transfer products, that is, the radical cation of zinc tetrapyrrole and the radical anion of BODIPY(Im)₂, was possible to spectrally identify. From target analysis of the transient data, time constants of circa 3 ns for ZnPc^⋅+:BODIPY⋅⁻and circa 0.5 ns for ZnNc⋅⁺:BODIPY⋅⁻were obtained indicating persistence of the radical ion‐pair to some extent. The electron acceptor property of bis(styryl)BODIPY in donor‐acceptor conjugates is borne out from the present study. 

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5. Zn(II) Affinity and Structural Conformations of 2His‐2Cys Zinc Finger‐Like Motif Peptide Determined by Ion Mobility–Mass Spectrometry and PM6 Molecular Modeling

   https://doi.org/10.1002/jms.5113  

   Adomako, Richmond A.; Owusu, Michael B.; Oberdick, Rebekah K.; Senyah, Kwabena; Asare, Perfect; Spezia, Riccardo; Angel, Laurence A. (February 2025, Journal of Mass Spectrometry)

   ABSTRACT This study focuses on investigating the conformational structure and zinc(II) affinity of a zinc finger‐like motif (ZFM) peptide with the sequence acetyl‐His₁‐Cys₂‐Gly₃‐Pro₄‐Gly₅‐His₆‐Cys₇, where bold highlights the potential zinc(II) binding sites. Zinc fingers are crucial protein motifs known for their high specificity and affinity for zinc ions. The ZFM peptide's sequence contains the 2His‐2Cys zinc‐binding sites similar to those in natural zinc finger proteins but without the hydrophobic core, making it a valuable model for studying zinc(II)–peptide interactions. Previous research on related peptides showed that collision cross sections and B3LYP modeling predicted that the His‐2Cys‐carboxyl terminus coordination of zinc(II) was more stable than the 2His‐2Cys. Employing a comprehensive approach integrating ion mobility–mass spectrometry and theoretical modeling techniques, various zinc(II) binding modes of the ZFM have been thoroughly compared to ascertain their influence on the competitive threshold collision‐induced dissociation method for measuring the relative gas‐phase Zn(II) affinity of the ZFM peptide. The measured Zn(II) affinity of ZFM is greater than those measured recently for two peptides with similar primary structures, acetyl‐His₁‐Cys₂‐Gly₃‐Pro₄‐Gly₅‐Gly₆‐Cys₇and acetyl‐Asp₁‐His₂‐Gly₃‐Pro₄‐Gly₅‐Gly₆‐Cys₇, indicating the preference for the His₁‐Cys₂‐His₆‐Cys₇side groups for coordinating zinc(II) over the His‐2Cys‐carboxyl terminus or Asp‐His‐Cys‐carboxyl terminus in these related heptapeptides. 

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