Markus Eser scite author profile

Hsp33, a member of a newly discovered heat shock protein family, was found to be a very potent molecular chaperone. Hsp33 is distinguished from all other known molecular chaperones by its mode of functional regulation. Its activity is redox regulated. Hsp33 is a cytoplasmically localized protein with highly reactive cysteines that respond quickly to changes in the redox environment. Oxidizing conditions like H2O2 cause disulfide bonds to form in Hsp33, a process that leads to the activation of its chaperone function. In vitro and in vivo experiments suggest that Hsp33 protects cells from oxidants, leading us to conclude that we have found a protein family that plays an important role in the bacterial defense system toward oxidative stress.

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Redox Switch of Hsp33 Has a Novel Zinc-binding Motif

Jakob¹,

Eser²,

Bardwell³

2000

Journal of Biological Chemistry

178

166

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The chaperone activity of the heat shock protein Hsp33 is regulated by reversible disulfide bond formation. Oxidized Hsp33 is active, and reduced Hsp33 is inactive. We show that zinc binding is essential for the function of this redox switch. Our results reveal that Hps33 contains a new, high affinity (K a > 10 17 M ؊1 ), zincbinding motif in the form Cys-X-Cys-X 27-32 -Cys-X-X-Cys. All four conserved cysteines within this motif act to coordinate a single zinc atom. Experiments where reduced wild type Hsp33 is reconstituted with cobalt or cadmium demonstrate that the metal-coordinating cysteines are present as highly reactive thiolate anions. This ionization may allow for the fast and successful activation of the chaperone function of Hsp33 upon incubation in oxidizing agents.

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A tetravalent bispecific TandAb (CD19/CD3), AFM11, efficiently recruits T cells for the potent lysis of CD19⁺tumor cells

Reusch

Duell

Ellwanger

et al. 2015

mAbs

120

109

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To harness the potent tumor-killing capacity of T cells for the treatment of CD19 C malignancies, we constructed AFM11, a humanized tetravalent bispecific CD19/CD3 tandem diabody (TandAb) consisting solely of Fv domains. The molecule exhibits good manufacturability and stability properties. AFM11 has 2 binding sites for CD3 and 2 for CD19, an antigen that is expressed from early B cell development through differentiation into plasma cells, and is an attractive alternative to CD20 as a target for the development of therapeutic antibodies to treat B cell malignancies. Comparison of the binding and cytotoxicity of AFM11 with those of a tandem scFv bispecific T cell engager (BiTE) molecule targeting the same antigens revealed that AFM11 elicited more potent in vitro B cell lysis. Though possessing high affinity to CD3, the TandAb mediates serial-killing of CD19 C cells with little dependence of potency or efficacy upon effector:target ratio, unlike the BiTE. The advantage of the TandAb over the BiTE was most pronounced at lower effector:target ratios. AFM11 mediated strictly targetdependent T cell activation evidenced by CD25 and CD69 induction, proliferation, and cytokine release, notwithstanding bivalent CD3 engagement. In a NOD/scid xenograft model, AFM11 induced dose-dependent growth inhibition of Raji tumors in vivo, and radiolabeled TandAb exhibited excellent localization to tumor but not to normal tissue. After intravenous administration in mice, half-life ranged from 18.4 to 22.9 h. In a human ex vivo B-cell chronic lymphocytic leukemia study, AFM11 exhibited substantial cytotoxic activity in an autologous setting. Thus, AFM11 may represent a promising therapeutic for treatment of CD19 C malignancies with an advantageous safety risk profile and anticipated dosing regimen.

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Compounds targeting disulfide bond forming enzyme DsbB of Gram-negative bacteria

et al. 2015

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In bacteria, disulfide bonds confer stability on many proteins exported to the cell envelope or beyond. These proteins include numerous bacterial virulence factors. Thus, bacterial enzymes that promote disulfide bond formation represent targets for compounds inhibiting bacterial virulence. Here, we describe a novel target- and cell-based screening methodology for identifying compounds that inhibit the disulfide bond-forming enzymes E. coli DsbB (EcDsbB) or M. tuberculosis VKOR (MtbVKOR). MtbVKOR can replace EcDsbB although the two are not homologues. Initial screening of 51,487 compounds yielded six specifically inhibiting EcDsbB. These compounds share a structural motif and do not inhibit MtbVKOR. A medicinal chemistry approach led us to select related compounds some of which are much more effective DsbB inhibitors than those found in the screen. These compounds inhibit purified DsbB and prevent anaerobic E. coli growth. Furthermore, these compounds inhibit all but one of the DsbBs of nine other gram-negative pathogenic bacteria tested.

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Disulfide bond formation by exported glutaredoxin indicates glutathione's presence in the E. coli periplasm

Eser

Masip

Kadokura

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Organisms have evolved elaborate systems that ensure the homeostasis of the thiol redox environment in their intracellular compartments. In Escherichia coli, the cytoplasm is kept under reducing conditions by the thioredoxins with the help of thioredoxin reductase and the glutaredoxins with the small molecule glutathione and glutathione reductase. As a result, disulfide bonds are constantly resolved in this compartment. In contrast to the cytoplasm, the periplasm of E. coli is maintained in an oxidized state by DsbA, which is recycled by DsbB. Thioredoxin 1, when exported to the periplasm turns from a disulfide bond reductase to an oxidase that, like DsbA, is dependent on DsbB. In this study we set out to investigate whether a subclass of the thioredoxin superfamily, the glutaredoxins, can become disulfide bond-formation catalysts when they are exported to the periplasm. We find that glutaredoxins can promote disulfide bond formation in the periplasm. However, contrary to the behavior of thioredoxin 1 in this environment, the glutaredoxins do so independently of DsbB. Furthermore, we show that glutaredoxin 3 requires the glutathione biosynthesis pathway for its function and can oxidize substrates with only a single active-site cysteine. Our data provides in vivo evidence suggesting that oxidized glutathione is present in the E. coli periplasm in biologically significant concentrations.protein oxidation ͉ monothiol ͉ SRP

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Markus Eser

Chaperone Activity with a Redox Switch

Redox Switch of Hsp33 Has a Novel Zinc-binding Motif

A tetravalent bispecific TandAb (CD19/CD3), AFM11, efficiently recruits T cells for the potent lysis of CD19⁺tumor cells

Compounds targeting disulfide bond forming enzyme DsbB of Gram-negative bacteria

Disulfide bond formation by exported glutaredoxin indicates glutathione's presence in the E. coli periplasm

Contact Info

Product

Resources

About

Markus Eser

Chaperone Activity with a Redox Switch

Redox Switch of Hsp33 Has a Novel Zinc-binding Motif

A tetravalent bispecific TandAb (CD19/CD3), AFM11, efficiently recruits T cells for the potent lysis of CD19+tumor cells

Compounds targeting disulfide bond forming enzyme DsbB of Gram-negative bacteria

Disulfide bond formation by exported glutaredoxin indicates glutathione's presence in the E. coli periplasm

Contact Info

Product

Resources

About

A tetravalent bispecific TandAb (CD19/CD3), AFM11, efficiently recruits T cells for the potent lysis of CD19⁺tumor cells