Kerstin Galler

Analysis of Fe(III) Heme Binding to Cysteine-Containing Heme-Regulatory Motifs in Proteins

Regulatory heme binds to specific motifs in proteins and controls a variety of biochemical processes. Several of these proteins were recently shown to form complexes with ferric and/or ferrous heme via a cysteine residue as axial ligand. The objective of this study was to examine the heme-binding properties of a series of cysteine-containing peptides with focus on CP motif sequences. The peptides displayed different binding behavior upon Fe(III) heme application with characteristic wavelength shifts of the Soret band to 370 nm or 420-430 nm and in some cases to both wavelengths. Whereas for most of the peptides containing a cysteine only a shift to 420-430 nm was observed, CP-containing peptides exhibited a preference for a shift to 370 nm. Detailed structural investigation using Raman and NMR spectroscopy on selected representatives revealed different binding modes with respect to iron ion coordination, which reflected the results of the UV-vis studies. A predicted short sequence stretch derived from dipeptidyl peptidase 8 was additionally examined with respect to CP motif binding to heme on the peptide as well as on the protein level. The heme association was confirmed with the first solution structure of a CP-peptide-heme complex and, moreover, an inhibitory effect of Fe(III) heme on the enzymes activity. The relevance of both the use of model compounds to elucidate the molecular mechanism underlying regulatory heme binding and its potential for the investigation of regulatory heme control is discussed.

Role of the Chemical Environment beyond the Coordination Site: Structural Insight into Fe(III) Protoporphyrin Binding to Cysteine-Based Heme-Regulatory Protein Motifs.

The importance of heme as a transient regulatory molecule has become a major focus in biochemical research. However, detailed information about the molecular basis of transient heme–protein interactions is still missing. We report an in‐depth structural analysis of FeIII heme–peptide complexes by a combination of UV/Vis, resonance Raman, and 2D‐NMR spectroscopic methods. The experiments reveal insights both into the coordination to the central iron ion and into the spatial arrangement of the amino acid sequences interacting with protoporphyrin IX. Cysteine‐based peptides display different heme‐binding behavior as a result of the existence of ordered, partially ordered, and disordered conformations in the heme‐unbound state. Thus, the heme‐binding mode is clearly the consequence of the nature and flexibility of the residues surrounding the iron ion coordinating cysteine. Our analysis reveals scenarios for transient binding of heme to heme‐regulatory motifs in proteins and demonstrates that a thorough structural analysis is required to unravel how heme alters the structure and function of a particular protein.

Single cell analysis in native tissue: Quantification of the retinoid content of hepatic stellate cells

Hepatic stellate cells (HSCs) are retinoid storing cells in the liver: The retinoid content of those cells changes depending on nutrition and stress level. There are also differences with regard to a HSC’s anatomical position in the liver. Up to now, retinoid levels were only accessible from bulk measurements of tissue homogenates or cell extracts. Unfortunately, they do not account for the intercellular variability. Herein, Raman spectroscopy relying on excitation by the minimally destructive wavelength 785 nm is introduced for the assessment of the retinoid state of single HSCs in freshly isolated, unprocessed murine liver lobes. A quantitative estimation of the cellular retinoid content is derived. Implications of the retinoid content on hepatic health state are reported. The Raman-based results are integrated with histological assessments of the tissue samples. This spectroscopic approach enables single cell analysis regarding an important cellular feature in unharmed tissue.

Heme interacts with histidine- and tyrosine-based protein motifs and inhibits enzymatic activity of chloramphenicol acetyltransferase from Escherichia coli

BACKGROUND The occurrence of free organismal heme can either contribute to serious diseases or beneficially regulate important physiological processes. Research on transient binding to heme-regulatory motifs (HRMs) in proteins resulted in the discovery of numerous Cys-based, especially Cys-Pro (CP)-based motifs. However, the number of His- and Tyr-based protein representatives is comparatively low so far, which is in part caused by a lack of information regarding recognition and binding requirements. METHODS To understand transient heme association with such motifs on the molecular level, we analyzed a set of 44 His- and Tyr-based peptides using UV-vis, resonance Raman, cw-EPR and 2D NMR spectroscopy. RESULTS We observed similarities with Cys-based sequences with respect to their spectral behavior and complex geometries. However, significant differences regarding heme-binding affinities and sequence requirements were also found. Compared to Cys-based peptides and proteins all sequences investigated structurally display increased flexibility already in the free-state, which is also maintained upon heme association. The acquired knowledge allowed for identification and prediction of a His-based HRM in chloramphenicol acetyltransferase from Escherichia coli as potential heme-regulated protein. The enzymes heme-interacting capability was studied, and revealed an inhibitory effect of heme on the protein activity with an IC50 value of 57.69±4.37 μM. CONCLUSIONS It was found that heme inhibits a bacterial protein carrying a potential His-based HRM. This finding brings microbial proteins more into focus of regulation by free heme. GENERAL SIGNIFICANCE Understanding transient binding and regulatory action of heme with bacterial proteins, being crucial for survival, might promote new strategies for the treatment of bacterial infections.

Hepatic Vitamin A Content Investigation Using Coherent Anti‐Stokes Raman Scattering Microscopy

Standard techniques for examining the distribution of vitamin A in liver either require staining or lead to rapid photobleaching of the molecule. A potentially better alternative approach is to use coherent anti-Stokes Raman scattering (CARS) microscopy; a fast, label-free, non-disruptive imaging method that provides contrast based on molecular vibrations. This contribution evaluates the viability of CARS microscopy for imaging vitamin A within thick hepatic tissue under physiological conditions by tuning into its characteristic vibrational band in the fingerprint region. Additional information about the morphology and architecture of the tissue was acquired using second harmonic generation (SHG) and multi-photon excited fluorescence (MPEF) to help mapping the intra-lobular positions of the vitamin A droplets. We demonstrate the capability of our multimodal imaging framework to selectively image lipid-soluble vitamin A droplets deep in bulk liver tissue with a high contrast while co-registering a complementary morphological background that clearly visualizes hepatic lobules. The results obtained envisage the good prospect of the technique for in vivo studies assessing vitamin A distribution heterogeneity and how it is affected by the progression of hepatic diseases.