Anke Licht

HSP70 mediates dissociation and reassociation of the 26S proteasome during adaptation to oxidative stress.

We report an entirely new role for the HSP70 chaperone in dissociating 26S proteasome complexes (into free 20S proteasomes and bound 19S regulators), preserving 19S regulators, and reconstituting 26S proteasomes in the first 1-3h after mild oxidative stress. These responses, coupled with direct 20S proteasome activation by poly(ADP ribose) polymerase in the nucleus and by PA28αβ in the cytoplasm, instantly provide cells with increased capacity to degrade oxidatively damaged proteins and to survive the initial effects of stress exposure. Subsequent adaptive (hormetic) processes (3-24h after stress exposure), mediated by several signal transduction pathways and involving increased transcription/translation of 20S proteasomes, immunoproteasomes, and PA28αβ, abrogate the need for 26S proteasome dissociation. During this adaptive period, HSP70 releases its bound 19S regulators, 26S proteasomes are reconstituted, and ATP-stimulated proteolysis is restored. The 26S proteasome-dependent, and ATP-stimulated, turnover of ubiquitinylated proteins is essential for normal cell metabolism, and its restoration is required for successful stress adaptation.

Protein oxidation and proteolysis in RAW264.7 macrophages: effects of PMA activation.

Macrophages are stimulable cells able to increase the production of reactive oxygen and nitrogen species dramatically for a short period of time. Free radicals and other oxidants are able to oxidize the intracellular protein pool. These oxidized proteins are selectively recognized and degraded by the intracellular proteasomal system. We used the mouse macrophage-like cell line RAW264.7 to test whether macrophagial cells are able to increase their protein turnover after oxidative stress and whether this is accompanied by an increased protein oxidation. Macrophagial cells are particularly susceptible to bolus additions of hydrogen peroxide and peroxynitrite. In further experiments we activated RAW264.7 cells with PMA to test whether the production of endogenous oxidants has analogous effects. A clear dependence of the protein turnover and protein oxidation on the oxidative burst could be measured. In further experiments the role of the proteasomal system in the selective removal of oxidized proteins could be revealed exploring the proteasome specific inhibitor lactacystin. Therefore, although oxidants are able to attack the intracellular protein pool in macrophages, these cells are able to remove oxidized proteins selectively and protect the intracellular protein pool from oxidation.

Conformational plasticity of the type I maltose ABC importer

ATP-binding cassette (ABC) transporters couple the translocation of solutes across membranes to ATP hydrolysis. Crystal structures of the Escherichia coli maltose importer (MalFGK2) in complex with its substrate binding protein (MalE) provided unprecedented insights in the mechanism of substrate translocation, leaving the MalE–transporter interactions still poorly understood. Using pulsed EPR and cross-linking methods we investigated the effects of maltose and MalE on complex formation and correlated motions of the MalK2 nucleotide-binding domains (NBDs). We found that both substrate-free (open) and liganded (closed) MalE interact with the transporter with similar affinity in all nucleotide states. In the apo-state, binding of open MalE occurs via the N-lobe, leaving the C-lobe disordered, but upon maltose binding, closed MalE associates tighter to the transporter. In both cases the NBDs remain open. In the presence of ATP, the transporter binds both substrate-free and liganded MalE, both inducing the outward-facing conformation trapped in the crystal with open MalE at the periplasmic side and NBDs tightly closed. In contrast to ATP, ADP–Mg2+ alone is sufficient to induce a semiopen conformation in the NBDs. In this nucleotide-driven state, the transporter binds both open and closed MalE with slightly different periplasmic configurations. We also found that dissociation of MalE is not a required step for substrate translocation since a supercomplex with MalE cross-linked to MalG retains the ability to hydrolyze ATP and to transport maltose. These features of MalE–MalFGK2 interactions highlight the conformational plasticity of the maltose importer, providing insights into the ATPase stimulation by unliganded MalE.

ATP binding cassette systems: structures, mechanisms, and functions

ATP-binding cassette (ABC) systems are found in all three domains of life and in some giant viruses and form one of the largest protein superfamilies. Most family members are transport proteins that couple the free energy of ATP hydrolysis to the translocation of solutes across a biological membrane. The energizing module is also used to drive non-transport processes associated, e.g., with DNA repair and protein translation. Many ABC proteins are of considerable medical importance. In humans, dysfunction of at least eighteen out of 49 ABC transporters is associated with disease, such as cystic fibrosis, Tangier disease, adrenoleukodystrophy or Stargardt’s macular degeneration. In prokaryotes, ABC proteins confer resistance to antibiotics, secrete virulence factors and envelope components, or mediate the uptake of a large variety of nutrients. Canonical ABC transporters share a common structural organization comprising two transmembrane domains (TMDs) that form the translocation pore and two nucleotide-binding domains (NBDs) that bind and hydrolyze ATP. In this Mini-Review, we summarize recent structural and biochemical data obtained from both prokaryotic and eukaryotic model systems.

Determinants of substrate specificity and biochemical properties of the sn-glycerol-3-phosphate ATP binding cassette transporter (UgpB-AEC2 ) of Escherichia coli.

Under phosphate starvation conditions, Escherichia coli can utilize sn‐glycerol‐3‐phosphate (G3P) and G3P diesters as phosphate source when transported by an ATP binding cassette importer composed of the periplasmic binding protein, UgpB, the transmembrane subunits, UgpA and UgpE, and a homodimer of the nucleotide binding subunit, UgpC. The current knowledge on the Ugp transporter is solely based on genetic evidence and transport assays using intact cells. Thus, we set out to characterize its properties at the level of purified protein components. UgpB was demonstrated to bind G3P and glycerophosphocholine with dissociation constants of 0.68 ± 0.02 μM and 5.1 ± 0.3 μM, respectively, while glycerol‐2‐phosphate (G2P) is not a substrate. The crystal structure of UgpB in complex with G3P was solved at 1.8 Å resolution and revealed the interaction with two tryptophan residues as key to the preferential binding of linear G3P in contrast to the branched G2P. Mutational analysis validated the crucial role of Trp‐169 for G3P binding. The purified UgpAEC2 complex displayed UgpB/G3P‐stimulated ATPase activity in proteoliposomes that was neither inhibited by phosphate nor by the signal transducing protein PhoU or the phosphodiesterase UgpQ. Furthermore, a hybrid transporter composed of MalFG–UgpC could be functionally reconstituted while a UgpAE–MalK complex was unstable.

Mode of Interaction of the Signal-Transducing Protein EIIAGlc with the Maltose ABC Transporter in the Process of Inducer Exclusion

Enzyme IIA(Glc) (EIIA(Glc)) of the phosphoenolpyruvate phosphotransferase system for the uptake of glucose in Escherichia coli and Salmonella inhibits the maltose ATP-binding cassette transporter (MalE-FGK2) by interaction with the nucleotide-binding and -hydrolyzing subunit MalK, a process termed inducer exclusion. We have investigated binding of EIIA(Glc) to the MalK dimer by cysteine cross-linking in proteoliposomes. The results prove that the binding site I of EIIA(Glc) is contacting the N-terminal subdomain of MalK while the binding site II is relatively close to the C-terminal (regulatory) subdomain, in agreement with a crystal structure [ Chen , S. , Oldham , M. L. , Davidson , A. L. , and Chen , J. ( 2013 ) Nature 499 , 364 - 368 ]. Moreover, EIIA(Glc) was found to bind to the MalK dimer regardless of its conformational state. Deletion of the amphipathic N-terminal peptide of EIIA(Glc), which is required for inhibition, reduced formation of cross-linked products. Using a spin-labeled transporter variant and EPR spectroscopy, we demonstrate that EIIA(Glc) arrests the transport cycle by inhibiting the ATP-dependent closure of the MalK dimer.

Inducer exclusion in Firmicutes: insights into the regulation of a carbohydrate ATP binding cassette transporter from Lactobacillus casei BL23 by the signal transducing protein P-Ser46-HPr.

Catabolite repression is a mechanism that enables bacteria to control carbon utilization. As part of this global regulatory network, components of the phosphoenolpyruvate:carbohydrate phosphotransferase system inhibit the uptake of less favorable sugars when a preferred carbon source such as glucose is available. This process is termed inducer exclusion. In bacteria belonging to the phylum Firmicutes, HPr, phosphorylated at serine 46 (P‐Ser46‐HPr) is the key player but its mode of action is elusive. To address this question at the level of purified protein components, we have chosen a homolog of the Escherichia coli maltose/maltodextrin ATP‐binding cassette transporter from Lactobacillus casei (MalE1‐MalF1G1K12) as a model system. We show that the solute binding protein, MalE1, binds linear and cyclic maltodextrins but not maltose. Crystal structures of MalE1 complexed with these sugars provide a clue why maltose is not a substrate. P‐Ser46‐HPr inhibited MalE1/maltotetraose‐stimulated ATPase activity of the transporter incorporated in proteoliposomes. Furthermore, cross‐linking experiments revealed that P‐Ser46‐HPr contacts the nucleotide‐binding subunit, MalK1, in proximity to the Walker A motif. However, P‐Ser46‐HPr did not block binding of ATP to MalK1. Together, our findings provide first biochemical evidence that P‐Ser‐HPr arrests the transport cycle by preventing ATP hydrolysis at the MalK1 subunits of the transporter.