Protein-protein interactions in high molecular weight forms of the transformation-related phosphoprotein p53

Roles of Nucleic Acids in Protein Folding, Aggregation, and Disease

The role of nucleic acids in protein folding and aggregation is an area of continued research, with relevance to understanding both basic biological processes and disease. In this review, we provide an overview of the trajectory of research on both nucleic acids as chaperones and their roles in several protein misfolding diseases. We highlight key questions that remain on the biophysical and biochemical specifics of how nucleic acids have large effects on multiple proteins' folding and aggregation behavior and how this pertains to multiple protein misfolding diseases.

Evidence of a Prion-Like Transmission of p53 Amyloid in Saccharomyces cerevisiae

Loss of p53 function is largely responsible for the occurrence of cancer in humans. Aggregation of mutant p53 has been found in multiple cancer cell types, suggesting a role of aggregation in loss of p53 function and cancer development. The p53 protein has recently been hypothesized to possess a prion-like conformation, although experimental evidence is lacking. Here, we report that human p53 can be inactivated upon exposure to preformed fibrils containing an aggregation-prone sequence-specific peptide, PILTIITL, derived from p53, and the inactive state was found to be stable for many generations. Importantly, we provide evidence of a prion-like transmission of these p53 aggregates. This study has significant implications for understanding cancer progression due to p53 malfunctioning without any loss-of-function mutation or occurrence of transcriptional inactivation. Our data might unlock new possibilities for understanding the disease and will lead to rational design of p53 aggregation inhibitors for the development of drugs against cancer.

Expanding the prion concept to cancer biology: dominant-negative effect of aggregates of mutant p53 tumour suppressor

p53 is a key protein that participates in cell-cycle control, and its malfunction can lead to cancer. This tumour suppressor protein has three main domains; the N-terminal transactivation domain, the CTD (C-terminal domain) and the core domain (p53C) that constitutes the sequence-specific DBD (DNA-binding region). Most p53 mutations related to cancer development are found in the DBD. Aggregation of p53 into amyloid oligomers and fibrils has been shown. Moreover, amyloid aggregates of both the mutant and WT (wild-type) forms of p53 were detected in tumour tissues. We propose that if p53 aggregation occurred, it would be a crucial aspect of cancer development, as p53 would lose its WT functions in an aggregated state. Mutant p53 can also exert a dominant-negative regulatory effect on WT p53. Herein, we discuss the dominant-negative effect in light of p53 aggregation and the fact that amyloid-like mutant p53 can convert WT p53 into more aggregated species, leading into gain of function in addition to the loss of tumour suppressor function. In summary, the results obtained in the last decade indicate that cancer may have characteristics in common with amyloidogenic and prion diseases.

Association of human immunodeficiency virus Nef protein with actin is myristoylation dependent and influences its subcellular localization

Human immunodeficiency virus (HIV) Nef functions are thought to be mediated via interactions with cellular proteins. Utilizing zone velocity sedimentation in glycerol gradients we found that recombinant HIV-1 Nef non-covalently associates with actin forming a high-molecular-mass complex of 150-300 kDa. This Nef/actin complex was present in human B and T lymphocytes but not in insect cells and was dependent on the N-terminal myristoylation of Nef, whereas the SH3-binding proline motif of Nef was not involved. Despite being myristoylated, HIV-2 Nef did not associate with actin. This might reflect differences in the subcellular localization of Nef since cell-fractionation experiments revealed that HIV-1 Nef was virtually exclusively localized in the cytoskeletal (detergent-insoluble) fraction whereas HIV-2 Nef had significantly reduced affinity for the cytoskeleton. Colocalization experiments in HIV-1-infected CD4+ fibroblasts revealed that Nef/actin complexes may also exist in HIV-infected cells. This novel interaction of HIV-1 Nef with actin provides insight into the association of Nef with cellular structures and reveals general differences in the interactions of the Nef proteins from HIV-1 and HIV-2.

Divalent metal ions induce conformational change in pure, human wild-type p53 tumor suppressor protein

The ability of wild-type and not mutant p53 to exert antiproliferative effects on normal cells may be related to a difference in the conformational state of the protein. We have used pure, human wild-type p53 and a panel of monoclonal antibodies whose epitopes map throughout the protein to assess whether divalent metal ions affect the conformation of p53. Our results show that the presence of Zn2+ ions at physiological concentrations, directly reduced or blocked accessibility of epitopes on pure wild-type p53, an effect which was reversed by chelating agents. Loss of epitope reactivity was maximal between the protein mid-region and C-terminus. Analytical sucrose density gradient ultracentrifugation studies also confirmed that Zn(2+)-induced conformational changes partially affected the pattern of p53 oligomerisation. The observed binding of pure p53 to a sequence-specific DNA motif was unaffected by the presence of added Zn2+ ions or metal chelating agents.

Biochemical characterisation of purified human wild-type p53 overexpressed in insect cells

Conditions for the overexpression of human wild-type p53 using a baculovirus construct were optimised in insect cells which produced up to 20 mg p53/1 culture. Milligram amounts of p53 were purified to apparent homogeneity using chromatography on double-stranded DNA-cellulose (approximately 58% yield) followed by immunoaffinity chromatography with an epitope elution step (up to 48% yields) at 4 degrees C. The M(r) of extracted p53 both from insect cell lysates and after purification was 54,000 by SDS/PAGE. Isoelectric focusing showed recombinant p53 to be an acidic protein, focusing at pI 6.0 under non-denaturing conditions. Expressed p53 at all stages of purification reacted by immunoblotting with specific p53 monoclonal antibodies, indicating the presence of intact epitopes at the C-terminus, N-terminus and central region of the protein. From ultracentrifugation studies, pure p53 exhibited significant oligomerisation, and sedimented broadly within the 7-12-S region of sucrose gradients. Pure p53 slowly precipitated out of solution at concentrations between 1-6 mg/ml even in the presence of 1% detergent. Using metal affinity chromatography, we have established that pure p53 binds the immobilised divalent ions Zn2+, Ni2+ and Co2+ with high affinity.

Increased salt concentration reversibly destabilizes p53 quaternary structure and sequence-specific DNA binding

Growth suppression by p53 correlates with sequence-specific DNA binding and is determined by tertiary and quaternary protein structures. Exposure to 300 mM NaCl did not affect p53 tertiary structure, but dissociated high-molecular-mass complexes with concomitant loss of specific DNA binding. Both effects were reversible. We conclude that high salt can reversibly destabilize the quaternary structure of p53 that is most efficient for sequence-specific DNA binding.