Carboxyl terminus is essential for intracellular folding of chloramphenicol acetyltransferase

Misfolded proteins inhibit proliferation and promote stress-induced death in SV40-transformed mammalian cells

Protein misfolding is implicated in neurodegenerative diseases and occurs in aging. However, the contribution of the misfolded ensembles to toxicity remains largely unknown. Here we introduce 2 primate cell models of destabilized proteins devoid of specific cellular functions and interactors, as bona fide misfolded proteins, allowing us to isolate the gain-of-function of non-native structures. Both GFP-degron and a mutant chloramphenicol-acetyltransferase fused to GFP (GFP-Δ9CAT) form perinuclear aggregates, are degraded by the proteasome, and colocalize with and induce the chaperone Hsp70 (HSPA1A/B) in COS-7 cells. We find that misfolded proteins neither significantly compromise chaperone-mediated folding capacity nor induce cell death. However, they do induce growth arrest in cells that are unable to degrade them and promote stress-induced death upon proteasome inhibition by MG-132 and heat shock. Finally, we show that overexpression of all heat-shock factor-1 (HSF1) and Hsp70 proteins, as well as wild-type and deacetylase-deficient (H363Y) SIRT1, rescue survival upon stress, implying a noncatalytic action of SIRT1 in response to protein misfolding. Our study establishes a novel model and extends our knowledge on the mechanism of the function-independent proteotoxicity of misfolded proteins in dividing cells.

Fluorinated chloramphenicol acetyltransferase thermostability and activity profile: improved thermostability by a single-isoleucine mutant

A lysate-based thermostability and activity profile is described for chloramphenicol acetyltransferase (CAT) expressed in trifluoroleucine, T (CAT T). CAT and 13 single-isoleucine CAT mutants were expressed in medium supplemented with T and assayed for thermostability on cell lysates. Although fluorinated mutants, L82I T and L208I T, showed losses in thermostability, the L158I T fluorinated mutant demonstrated an enhanced thermostability relative to CAT T. Further characterization of L158I T suggested that T at position 158 contributed to a portion of the observed loss in thermostability upon global fluorination.

Mass-spectral analysis of human interferon-gamma and chloramphenicol acetyltransferase I produced in two Escherichia coli strains

Recombinant human interferon-gamma and chloramphenicol acetyltransferase I were isolated from two Escherichia coli strains, E. coli LE329 and E. coli XL1-blue and characterized by electrospray ionization mass spectrometry (ESI-MS). The ESI-MS analysis showed higher masses in comparison with the theoretically calculated for both proteins as well as unexpected molecular heterogeneity. The ESI-MS spectral patterns of the proteins depended on the host strain used and were more heterogenous for the proteins isolated from E. coli LE392. One of the proteins (human interferon-gamma obtained from E. coli XL1-blue) was further subjected to BrCN cleavage. The ESI-MS analysis of the polypeptide mixture revealed shift in the molecular mass for two peptides including the last 26 amino acids of the human interferon-gamma molecule.

Escherichia coli maltose-binding protein is uncommonly effective at promoting the solubility of polypeptides to which it is fused

Although it is usually possible to achieve a favorable yield of a recombinant protein in Escherichia coli, obtaining the protein in a soluble, biologically active form continues to be a major challenge. Sometimes this problem can be overcome by fusing an aggregation-prone polypeptide to a highly soluble partner. To study this phenomenon in greater detail, we compared the ability of three soluble fusion partners--maltose-binding protein (MBP), glutathione S-transferase (GST), and thioredoxin (TRX)--to inhibit the aggregation of six diverse proteins that normally accumulate in an insoluble form. Remarkably, we found that MBP is a far more effective solubilizing agent than the other two fusion partners. Moreover, we demonstrated that in some cases fusion to MBP can promote the proper folding of the attached protein into its biologically active conformation. Thus, MBP seems to be capable of functioning as a general molecular chaperone in the context of a fusion protein. A model is proposed to explain how MBP promotes the solubility and influences the folding of its fusion partners.

Biogenesis and topology of integral membrane proteins: characterization of lactose permease-chloramphenicol acetyltransferase hybrids

Use of beta-lactamase in gene fusions to study membrane protein topology permits exploitation of its biological activity to select for positive (external) hybrids on ampicillin agar plates. When the enzyme is attached to cytoplasmic loops of a membrane protein, it is not secreted and is therefore unable to confer ampicillin resistance. In this study, we examine the use of the cytoplasmic enzyme chloramphenicol acetyltransferase (Cat) as a complement to the use of periplasmic beta-lactamase, in gene fusion studies. This enzyme is responsible for chloramphenicol resistance in Escherichia coli. We show that Cat confers substantial antibiotic resistance when fused to cytoplasmic loops of lactose permease. As expected, periplasmically exposed Cat is enzymatically active in vitro but unable to confer significant chloramphenicol resistance, presumably because of the absence of acetylcoenzyme A in the periplasm. Therefore, Cat may serve as a topogenic sensor in gene fusion studies. The new Cat fusion approach is discussed with regard to its potential use for selecting E. coli mutants which are defective in the assembly of membrane proteins.

The position of the heterologous domain can influence the solubility and proteolysis of beta-galactosidase fusion proteins in E. coli

The VP1 protein (23 kDa) of the foot-and-mouth disease virus has been produced in MC1061 and BL21 E. coli strains as beta-galactosidase fusion proteins, joined to either the amino and/or the carboxy termini of the bacterial enzyme. In BL21, devoid of La protease, all the recombinant fusion proteins are produced at higher yields than in MC1061, and occur mainly as inclusion bodies. The fusion of VP1 at the carboxy terminus yields a protease-sensitive protein whose degradation releases a stable, enzymatically active polypeptide indistinguishable from the native beta-galactosidase. On the contrary, when the same viral domain is fused to the amino terminus, the resulting chimeric protein is resistant to proteolysis even in the soluble form. These data demonstrate that the position of the heterologous domain in beta-galactosidase fusion proteins would not be irrelevant since it can dramatically influence properties of biotechnological interest such as solubility and proteolytic resistance.

Role of the N-terminal 118 amino acids in the processing of the rat renal mitochondrial glutaminase precursor

Rat renal mitochondrial glutaminase (GA) is synthesized as a 74-kDa cytosolic precursor that is translocated into mitochondria and processed via a 72-kDa intermediate to yield a 3:1 ratio of mature 66- and 68-kDa subunits, respectively. The 66-kDa subunit is derived by removal of a 72-amino-acid presequence. The structural determinants necessary for translocation and proteolytic processing were further delineated by characterizing the processing of different chimeric constructs formed by fusing various segments of the N-terminal sequence of the GA precursor to chloramphenicol acetyl transferase (CAT). GA1-118 CAT is translocated and processed in isolated rat liver mitochondria or cleaved by purified mitochondrial processing peptidase (MPP) to yield an intermediate peptide and two mature subunits that are analogous to the products of processing of the GA precursor. The two reactions also occur with kinetics which are similar to those observed for processing of the GA precursor. Thus, all of the information required for the translocation and synthesis of the mature subunits of GA reside in the N-terminal 118 amino acids of the GA precursor. In contrast, GA1-72 CAT, a construct that contains the GA presequence fused to CAT, is apparently translocated and processed less efficiently. It yields only two peptides that are analogous to the intermediate and 68 kDa forms of GA. In addition, GA1-31 CAT associates with mitochondria but is not proteolytically processed and GA1-31,73-118 CAT is slowly translocated and processed to a single peptide that is analogous to the 66 kDa form of GA. The latter results suggest that the MPP cleavage reactions which yield the GA intermediate and the 66-kDa subunit depend primarily on information that is present C-terminal to the respective sites of cleavage.