Carolyn S. Sevier

The Genetic Landscape of a Cell

Making Connections Genetic interaction profiles highlight cross-connections between bioprocesses, providing a global view of cellular pleiotropy, and enable the prediction of genetic network hubs. Costanzo et al. (p. 425) performed a pairwise fitness screen covering approximately one-third of all potential genetic interactions in yeast, examining 5.4 million gene-gene pairs and generating quantitative profiles for ∼75% of the genome. Of the pairwise interactions tested, about 3% of the genes investigated interact under the conditions tested. On the basis of these data, a reference map for the yeast genetic network was created. A genome-wide interaction map of yeast identifies genetic interactions, networks, and function. A genome-scale genetic interaction map was constructed by examining 5.4 million gene-gene pairs for synthetic genetic interactions, generating quantitative genetic interaction profiles for ~75% of all genes in the budding yeast, Saccharomyces cerevisiae. A network based on genetic interaction profiles reveals a functional map of the cell in which genes of similar biological processes cluster together in coherent subsets, and highly correlated profiles delineate specific pathways to define gene function. The global network identifies functional cross-connections between all bioprocesses, mapping a cellular wiring diagram of pleiotropy. Genetic interaction degree correlated with a number of different gene attributes, which may be informative about genetic network hubs in other organisms. We also demonstrate that extensive and unbiased mapping of the genetic landscape provides a key for interpretation of chemical-genetic interactions and drug target identification.

Formation and transfer of disulphide bonds in living cells

Protein disulphide bonds are formed in the endoplasmic reticulum of eukaryotic cells and the periplasmic space of prokaryotic cells. The main pathways that catalyse the formation of protein disulphide bonds in prokaryotes and eukaryotes are remarkably similar, and they share several mechanistic features. The recent identification of new redox-active proteins in humans and yeast that mechanistically parallel the more established redox-active enzymes indicates that there might be further uncharacterized redox pathways throughout the cell.

Ero1 and redox homeostasis in the endoplasmic reticulum.

Living cells must be able to respond to physiological and environmental fluctuations that threaten cell function and viability. A cellular event prone to disruption by a wide variety of internal and external perturbations is protein folding. To ensure protein folding can proceed under a range of conditions, the cell has evolved transcriptional, translational, and posttranslational signaling pathways to maintain folding homeostasis during cell stress. This review will focus on oxidative protein folding in the endoplasmic reticulum (ER) and will discuss the features of the main facilitator of biosynthetic disulfide bond formation, Ero1. Ero1 plays an essential role in setting the redox potential in the ER and regulation of Ero1 activity is central to maintain redox homeostasis and proper ER folding activity.

Modulation of Cellular Disulfide-Bond Formation and the ER Redox Environment by Feedback Regulation of Ero1

Introduction of disulfide bonds into proteins entering the secretory pathway is catalyzed by Ero1p, which generates disulfide bonds de novo, and Pdi1p, which transfers disulfides to substrate proteins. A sufficiently oxidizing environment must be maintained in the endoplasmic reticulum (ER) to allow for disulfide formation, but a pool of reduced thiols is needed for isomerization of incorrectly paired disulfides. We have found that hyperoxidation of the ER is prevented by attenuation of Ero1p activity through noncatalytic cysteine pairs. Deregulated Ero1p mutants lacking certain cysteines show increased enzyme activity, a decreased lag phase in kinetic assays, and growth defects in vivo. We hypothesize that noncatalytic cysteine pairs in Ero1p sense the level of potential substrates in the ER and correspondingly modulate Ero1p activity as part of a homeostatic regulatory system governing the thiol-disulfide balance in the ER.

A new FAD-binding fold and intersubunit disulfide shuttle in the thiol oxidase Erv2p.

Erv2p is an FAD-dependent sulfhydryl oxidase that can promote disulfide bond formation during protein biosynthesis in the yeast endoplasmic reticulum. The structure of Erv2p, determined by X-ray crystallography to 1.5 Å resolution, reveals a helix-rich dimer with no global resemblance to other known FAD-binding proteins or thiol oxidoreductases. Two pairs of cysteine residues are required for Erv2p activity. The first (Cys-Gly-Glu-Cys) is adjacent to the isoalloxazine ring of the FAD. The second (Cys-Gly-Cys) is part of a flexible C-terminal segment that can swing into the vicinity of the first cysteine pair in the opposite subunit of the dimer and may shuttle electrons between substrate protein dithiols and the FAD-proximal disulfide.

A flavoprotein oxidase defines a new endoplasmic reticulum pathway for biosynthetic disulphide bond formation

Ero1 and Pdi1 are essential elements of the pathway for the formation of disulphide bonds within the endoplasmic reticulum (ER). By screening for alternative oxidation pathways in Saccharomyces cerevisiae, we identified ERV2 as a gene that when overexpressed can restore viability and disulphide bond formation to an ero1-1 mutant strain. ERV2 encodes a luminal ER protein of relative molecular mass 22,000. Purified recombinant Erv2p is a flavoenzyme that can catalyse O2-dependent formation of disulphide bonds. Erv2p transfers oxidizing equivalents to Pdi1p by a dithiol–disulphide exchange reaction, indicating that the Erv2p-dependent pathway for disulphide bond formation closely parallels that of the previously identified Ero1p-dependent pathway.

Balanced Ero1 activation and inactivation establishes ER redox homeostasis

Both autonomous oxidation and Pdi1p regulate Ero1p’s disulfide bonding–generating activity in response to ER redox levels to optimize oxidative protein folding.

Oxidative Activity of Yeast Ero1p on Protein Disulfide Isomerase and Related Oxidoreductases of the Endoplasmic Reticulum

The sulfhydryl oxidase Ero1 oxidizes protein disulfide isomerase (PDI), which in turn catalyzes disulfide formation in proteins folding in the endoplasmic reticulum (ER). The extent to which other members of the PDI family are oxidized by Ero1 and thus contribute to net disulfide formation in the ER has been an open question. The yeast ER contains four PDI family proteins with at least one potential redox-active cysteine pair. We monitored the direct oxidation of each redox-active site in these proteins by yeast Ero1p in vitro. In this study, we found that the Pdi1p amino-terminal domain was oxidized most rapidly compared with the other oxidoreductase active sites tested, including the Pdi1p carboxyl-terminal domain. This observation is consistent with experiments conducted in yeast cells. In particular, the amino-terminal domain of Pdi1p preferentially formed mixed disulfides with Ero1p in vivo, and we observed synthetic lethality between a temperature-sensitive Ero1p variant and mutant Pdi1p lacking the amino-terminal active-site disulfide. Thus, the amino-terminal domain of yeast Pdi1p is on a preferred pathway for oxidizing the ER thiol pool. Overall, our results provide a rank order for the tendency of yeast ER oxidoreductases to acquire disulfides from Ero1p.

Redox signaling via the molecular chaperone BiP protects cells against endoplasmic reticulum-derived oxidative stress

Oxidative protein folding in the endoplasmic reticulum (ER) has emerged as a potentially significant source of cellular reactive oxygen species (ROS). Recent studies suggest that levels of ROS generated as a byproduct of oxidative folding rival those produced by mitochondrial respiration. Mechanisms that protect cells against oxidant accumulation within the ER have begun to be elucidated yet many questions still remain regarding how cells prevent oxidant-induced damage from ER folding events. Here we report a new role for a central well-characterized player in ER homeostasis as a direct sensor of ER redox imbalance. Specifically we show that a conserved cysteine in the lumenal chaperone BiP is susceptible to oxidation by peroxide, and we demonstrate that oxidation of this conserved cysteine disrupts BiPs ATPase cycle. We propose that alteration of BiP activity upon oxidation helps cells cope with disruption to oxidative folding within the ER during oxidative stress. DOI: http://dx.doi.org/10.7554/eLife.03496.001

The prokaryotic enzyme DsbB may share key structural features with eukaryotic disulfide bond forming oxidoreductases

Three different classes of thiol‐oxidoreductases that facilitate the formation of protein disulfide bonds have been identified. They are the Ero1 and SOX/ALR family members in eukaryotic cells, and the DsbB family members in prokaryotic cells. These enzymes transfer oxidizing potential to the proteins PDI or DsbA, which are responsible for directly introducing disulfide bonds into substrate proteins during oxidative protein folding in eukaryotes and prokaryotes, respectively. A comparison of the recent X‐ray crystal structure of Ero1 with the previously solved structure of the SOX/ALR family member Erv2 reveals that, despite a lack of primary sequence homology between Ero1 and Erv2, the core catalytic domains of these two proteins share a remarkable structural similarity. Our search of the DsbB protein sequence for features found in the Ero1 and Erv2 structures leads us to propose that, in a fascinating example of structural convergence, the catalytic core of this integral membrane protein may resemble the soluble catalytic domain of Ero1 and Erv2. Our analysis of DsbB also identified two new groups of DsbB proteins that, based on sequence homology, may also possess a catalytic core similar in structure to the catalytic domains of Ero1 and Erv2.