Graduate Student Women's Perceptions of Faculty Careers: The Critical Role of Departmental Values and Support in Career Choice.

While the number of women in undergraduate and graduate chemistry programs has increased in recent years, women remain under-represented and excluded in the ranks of faculty in chemistry higher education. This marginalization results from not only fewer women being offered faculty positions but also fewer women applying for these positions. To investigate the reasons why faculty positions are causing so many women to turn elsewhere for employment, a survey was designed based on the literature themes surrounding women's career choices, interviews with the current graduate student women in chemistry programs, and our previous work. The survey was grounded in social cognitive career theory (SCCT), and data were analyzed through a QuantCrit lens. Despite the existing literature focusing on the impact of having children on women's career decisions, the desire to have children did not appear among either the top priorities or the most important factors in predicting whether any of the 130 survey respondents were interested in a faculty career. Instead, faculty career interest was related to themes of overwork, high expectations from departments, and expected department emphasis on research despite an individual's interest in teaching and mentoring. Furthermore, women expressed a strong interest in maintaining work-life balance but low expectations for their ability to obtain a position that would allow it. They also reported a desire to work for a department that values mental health and diversity and supports its community members but similarly low expectations for their ability to find a department that shares these values. These themes suggest that chemistry departments must make fundamental changes regarding what is tangibly valued and rewarded within their systems if they wish to reduce the exclusion of women in faculty positions.

Porphyrin-Cored Polymer Nanoparticles: Macromolecular Models for Heme Iron Coordination.

Porphyrin-cored polymer nanoparticles (PCPNs) were synthesized and characterized to investigate their utility as heme protein models. Created using collapsible heme-centered star polymers containing photodimerizable anthracene units, these systems afford model heme cofactors buried within hydrophobic, macromolecular environments. Spectroscopic interrogations demonstrate that PCPNs display redox and ligand-binding reactivity similar to that of native systems and thus are potential candidates for modeling biological heme iron coordination.

Geometric and electrostatic study of the [4Fe-4S] cluster of adenosine-5'-phosphosulfate reductase from broken symmetry density functional calculations and extended X-ray absorption fine structure spectroscopy.

Adenosine-5'-phosphosulfate reductase (APSR) is an iron-sulfur protein that catalyzes the reduction of adenosine-5'-phosphosulfate (APS) to sulfite. APSR coordinates to a [4Fe-4S] cluster via a conserved CC-X(~80)-CXXC motif, and the cluster is essential for catalysis. Despite extensive functional, structural, and spectroscopic studies, the exact role of the iron-sulfur cluster in APS reduction remains unknown. To gain an understanding into the role of the cluster, density functional theory (DFT) analysis and extended X-ray fine structure spectroscopy (EXAFS) have been performed to reveal insights into the coordination, geometry, and electrostatics of the [4Fe-4S] cluster. X-ray absorption near-edge structure (XANES) data confirms that the cluster is in the [4Fe-4S](2+) state in both native and substrate-bound APSR while EXAFS data recorded at ~0.1 Å resolution indicates that there is no significant change in the structure of the [4Fe-4S] cluster between the native and substrate-bound forms of the protein. On the other hand, DFT calculations provide an insight into the subtle differences between the geometry of the cluster in the native and APS-bound forms of APSR. A comparison between models with and without the tandem cysteine pair coordination of the cluster suggests a role for the unique coordination in facilitating a compact geometric structure and "fine-tuning" the electronic structure to prevent reduction of the cluster. Further, calculations using models in which residue Lys144 is mutated to Ala confirm the finding that Lys144 serves as a crucial link in the interactions involving the [4Fe-4S] cluster and APS.

NMR and XAS reveal an inner-sphere metal binding site in the P4 helix of the metallo-ribozyme ribonuclease P.

Functionally critical metals interact with RNA through complex coordination schemes that are currently difficult to visualize at the atomic level under solution conditions. Here, we report a new approach that combines NMR and XAS to resolve and characterize metal binding in the most highly conserved P4 helix of ribonuclease P (RNase P), the ribonucleoprotein that catalyzes the divalent metal ion-dependent maturation of the 5' end of precursor tRNA. Extended X-ray absorption fine structure (EXAFS) spectroscopy reveals that the Zn(2+) bound to a P4 helix mimic is six-coordinate, with an average Zn-O/N bond distance of 2.08 A. The EXAFS data also show intense outer-shell scattering indicating that the zinc ion has inner-shell interactions with one or more RNA ligands. NMR Mn(2+) paramagnetic line broadening experiments reveal strong metal localization at residues corresponding to G378 and G379 in B. subtilis RNase P. A new "metal cocktail" chemical shift perturbation strategy involving titrations with , Zn(2+), and confirm an inner-sphere metal interaction with residues G378 and G379. These studies present a unique picture of how metals coordinate to the putative RNase P active site in solution, and shed light on the environment of an essential metal ion in RNase P. Our experimental approach presents a general method for identifying and characterizing inner-sphere metal ion binding sites in RNA in solution.

The interaction of mitochondrial iron with manganese superoxide dismutase.

Superoxide dismutase 2 (SOD2) is one of the rare mitochondrial enzymes evolved to use manganese as a cofactor over the more abundant element iron. Although mitochondrial iron does not normally bind SOD2, iron will misincorporate into Saccharomyces cerevisiae Sod2p when cells are starved for manganese or when mitochondrial iron homeostasis is disrupted by mutations in yeast grx5, ssq1, and mtm1. We report here that such changes in mitochondrial manganese and iron similarly affect cofactor selection in a heterologously expressed Escherichia coli Mn-SOD, but not a highly homologous Fe-SOD. By x-ray absorption near edge structure and extended x-ray absorption fine structure analyses of isolated mitochondria, we find that misincorporation of iron into yeast Sod2p does not correlate with significant changes in the average oxidation state or coordination chemistry of bulk mitochondrial iron. Instead, small changes in mitochondrial iron are likely to promote iron-SOD2 interactions. Iron binds Sod2p in yeast mutants blocking late stages of iron-sulfur cluster biogenesis (grx5, ssq1, and atm1), but not in mutants defective in the upstream Isu proteins that serve as scaffolds for iron-sulfur biosynthesis. In fact, we observed a requirement for the Isu proteins in iron inactivation of yeast Sod2p. Sod2p activity was restored in mtm1 and grx5 mutants by depleting cells of Isu proteins or using a dominant negative Isu1p predicted to stabilize iron binding to Isu1p. In all cases where disruptions in iron homeostasis inactivated Sod2p, we observed an increase in mitochondrial Isu proteins. These studies indicate that the Isu proteins and the iron-sulfur pathway can donate iron to Sod2p.

Ferrous human cystathionine beta-synthase loses activity during enzyme assay due to a ligand switch process.

Cystathionine beta-synthase (CBS) is a pyridoxal-5'-phosphate-dependent enzyme that catalyzes the condensation of serine and homocysteine to form cystathionine. Mammalian CBS also contains a heme cofactor that has been proposed to allosterically regulate enzyme activity via the heme redox state, with FeII CBS displaying approximately half the activity of FeIII CBS in vitro. The results of this study show that human FeII CBS spontaneously loses enzyme activity over the course of a 20 min enzyme assay. Both the full-length 63-kDa and truncated 45-kDa form of CBS slowly and irreversibly lose activity upon reduction to the FeII form. Additionally, electronic absorption spectroscopy reveals that FeII CBS undergoes a heme ligand exchange to FeII CBS424 when the enzyme is incubated at 37 degrees C and pH 8.6. The addition of enzyme substrates or imidazole has a moderate effect on the rate of the ligand switch, but does not prevent conversion to the inactive species. Time-dependent spectroscopic data describing the conversion of FeII CBS to FeII CBS424 were fitted to a three-state kinetic model. The resultant rate constants were used to fit assay data and to estimate the activity of FeII CBS prior to the ligand switch. Based on this fit it appears that FeII CBS initially has the same enzyme activity as FeIII CBS, but FeII CBS loses activity as the ligand switch proceeds. The slow and irreversible loss of FeII CBS enzyme activity in vitro resembles protein denaturation, and suggests that a simple regulatory mechanism based on the heme redox state is unlikely.

The heme of cystathionine beta-synthase likely undergoes a thermally induced redox-mediated ligand switch.

Cystathionine beta-synthase (CBS) is a pyridoxal-5'-dependent enzyme that catalyzes the condensation of homocysteine and serine to form cystathionine. Human CBS is unique in that heme is also required for maximal activity, although the function of heme in this enzyme is presently unclear. The study presented herein reveals that the heme of human CBS undergoes a coordination change upon reduction at elevated temperatures. We have termed this new species "CBS424" and demonstrate that its formation is likely irreversible when pH 9 Fe(III) CBS is reduced at moderately elevated temperatures (approximately 40 degrees C and higher) or when pH 9 Fe(II) CBS is heated to similar temperatures. Spectroscopic techniques, including resonance Raman, electronic absorption, and variable temperature/variable field magnetic circular dichroism spectroscopy, provide strong evidence that CBS424 is coordinated by two neutral donor ligands. It appears likely that the native cysteine(thiolate) heme ligand is displaced by an endogenous neutral donor upon conversion to CBS424. This behavior is consistent with other six-coordinate, cysteine(thiolate)-ligated heme centers, which seek to avoid this coordination structure in the Fe(II) state. Functional assays show that CBS424 is inactive and suggest that the ligand switch is responsible for eliminating enzyme activity. When this investigation is taken together with other functional studies of CBS, it provides strong evidence that coordination of Cys52 to the heme iron is crucial for full activity in this enzyme. We hypothesize that cysteine displacement may serve as a mechanism for CBS inactivation and that second-sphere interactions of the Cys52 thiolate with surrounding residues are responsible for communicating the heme ligand displacement to the CBS active site.

The redox behavior of the heme in cystathionine beta-synthase is sensitive to pH.

Human cystathionine beta-synthase (CBS) is a unique pyridoxal-5'-phosphate-dependent enzyme in which heme is also present as a cofactor. Because the function of heme in this enzyme has yet to be elucidated, the study presented herein investigated possible relationships between the chemistry of the heme and the strong pH dependence of CBS activity. This study revealed, via study of a truncation variant, that the catalytic core of the enzyme governs the pH dependence of the activity. The heme moiety was found to play no discernible role in regulating CBS enzyme activity by sensing changes in pH, because the coordination sphere of the heme is not altered by changes in pH over a range of pH 6-9. Instead, pH was found to control the equilibrium amount of ferric and ferrous heme present after reaction of CBS with one-electron reducing agents. A variety of spectroscopic techniques, including resonance Raman, magnetic circular dichroism, and electron paramagnetic resonance, demonstrated that at pH 9 Fe(II) CBS is dominant while at pH 6 Fe(III) CBS is favored. At low pH, Fe(II) CBS forms transiently but reoxidizes by an apparent proton-gated electron-transfer mechanism. Regulation of CBS activity by the iron redox state has been proposed as the role of the heme moiety in this enzyme. Given that the redox behavior of the CBS heme appears to be controlled by pH, interplay of pH and oxidation state effects must occur if CBS activity is redox regulated.