M. Beissinger scite author profile

The Escherichia coli GroE chaperones assist protein folding under conditions where no spontaneous folding occurs. To achieve this, the cooperation of GroEL and GroES, the two protein components of the chaperone system, is an essential requirement. While in many cases GroE simply suppresses unspeci®c aggregation of non-native proteins by encapsulation, there are examples where folding is accelerated by GroE.Using maltose-binding protein (MBP) as a substrate for GroE, it had been possible to de®ne basic requirements for catalysis of folding. Here, we have analyzed key steps in the interaction of GroE and the MBP mutant Y283D during catalyzed folding. In addition to high temperature, high ionic strength was shown to be a restrictive condition for MBP Y283D folding. In both cases, the complete GroE system (GroEL, GroES and ATP) compensates the deceleration of MBP Y283D folding. Combining kinetic folding experiments and electron microscopy of GroE particles, we demonstrate that at elevated temperatures, symmetrical GroE particles with GroES bound to both ends of the GroEL cylinder play an important role in the ef®cient catalysis of MBP Y283D refolding. In principle, MBP Y283D folding can be catalyzed during one encapsulation cycle. However, because the commitment to reach the native state is low after only one cycle of ATP hydrolysis, several interaction cycles are required for catalyzed folding.

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Sequence‐Specific Resonance Assignments of the ¹H‐NMR Spectra and Structural Characterization in Solution of the HIV‐1 Transframe Protein p6*

Beissinger

Paulus

Bayer

et al. 1996

European Journal of Biochemistry

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The frameshift protein p6* encoded directly upstream of the protease in the human immunodeficiency virus type 1 (HIV-1) pol reading frame is thought to be a natural inhibitor of protease activation and to play a role in the polyprotein processing of Gag and Gag-Pol precursors. To allow structural characterization of the p6* transframe protein, the p6* coding region was cloned into the vector pGEX-KG and expressed in Escherichiu coli as a fusion protein with glutathione S-transferase (GST) under the control of the tuc promoter. Thrombin cleavage of the construct resulted in a 70-amino-acid polypeptide which is extended by two additional residues at the N-terminus compared to the natural p6* sequence. The native purification procedure including an affinity and a size-exclusion chromatography step yielded sufficient amounts of highly pure protein suitable for NMR spectroscopy. Fluorescence, circular dichroism and 'H-NMR spectroscopy were applied to characterize the structure of the protein. Two-dimensional NMR spectra provided essentially complete sequence-specific resonance assignments at pH 5.9. Although there is evidence for a helix-forming tendency in the N-terminus of the protein, the experiments indicate that p6* has no overall stable secondary or tertiary structure with the single tryptophan exposed in aqueous solution. However, the results reported herein open the way to characterize further the interaction of p6* with the HIV-1 protease in structural and functional in vitro studies.

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Solution structure of cytochrome c6 from the thermophilic cyanobacterium Synechococcus elongatus

Beissinger

1998

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Cytochrome c 6 is a small, soluble electron carrier between the two membrane-bound complexes cytochrome b 6 f and photosystem I (PSI) in oxygenic photosynthesis. We determined the solution structure of cytochrome c 6 from the thermophilic cyanobacterium Synechococcus elongatus by NMR spectroscopy and molecular dynamics calculations based on 1586 interresidual distance and 28 dihedral angle restraints. The overall fold exhibits four α-helices and a small antiparallel β-sheet in the vicinity of Met58, one of the axial heme ligands. The flat hydrophobic area in this cytochrome c 6 is conserved in other c 6 cytochromes and even in plastocyanin of higher plants. This docking region includes the site of electron transfer to PSI and possibly to the cytochrome b 6 f complex. The binding of cytochrome c 6 to PSI in green algae involves interaction of a negative patch with a positive domain of PSI. This positive domain has not been inserted at the evolutionary level of cyanobacteria, but the negatively charged surface region is already present in S.elongatus cytochrome c 6 and may thus have been optimized during evolution to improve the interaction with the positively charged cytochrome f. As the structure of PSI is known in S.elongatus, the reported cytochrome c 6 structure can provide a basis for mutagenesis studies to delineate the mechanism of electron transfer between both.

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M. Beissinger

Mutations that Stabilize Folding Intermediates of Phage P22 Tailspike Protein: Foldingin Vivoandin Vitro, Stability, and Structural Context

Catalysis, Commitment and Encapsulation during GroE-mediated Folding

Sequence‐Specific Resonance Assignments of the ¹H‐NMR Spectra and Structural Characterization in Solution of the HIV‐1 Transframe Protein p6*

Solution structure of cytochrome c6 from the thermophilic cyanobacterium Synechococcus elongatus

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M. Beissinger

Mutations that Stabilize Folding Intermediates of Phage P22 Tailspike Protein: Foldingin Vivoandin Vitro, Stability, and Structural Context

Catalysis, Commitment and Encapsulation during GroE-mediated Folding

Sequence‐Specific Resonance Assignments of the 1H‐NMR Spectra and Structural Characterization in Solution of the HIV‐1 Transframe Protein p6*

Solution structure of cytochrome c6 from the thermophilic cyanobacterium Synechococcus elongatus

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Sequence‐Specific Resonance Assignments of the ¹H‐NMR Spectra and Structural Characterization in Solution of the HIV‐1 Transframe Protein p6*