Reversible aggregation plays a crucial role on the folding landscape of p53 core domain

The role of tumor suppressor protein p53 in cell cycle control depends on its flexible and partially unstructured conformation, which makes it crucial to understand its folding landscape. Here we report an intermediate structure of the core domain of the tumor suppressor protein p53 (p53C) during equilibrium and kinetic folding/unfolding transitions induced by guanidinium chloride. This partially folded structure was undetectable when investigated by intrinsic fluorescence. Indeed, the fluorescence data showed a simple two-state transition. On the other hand, analysis of far ultraviolet circular dichroism in 1.0 M guanidinium chloride demonstrated a high content of secondary structure, and the use of an extrinsic fluorescent probe, 4,4'-dianilino-1,1' binaphthyl-5,5'-disulfonic acid, indicated an increase in exposure of the hydrophobic core at 1 M guanidinium chloride. This partially folded conformation of p53C was plagued by aggregation, as suggested by one-dimensional NMR and demonstrated by light-scattering and gel-filtration chromatography. Dissociation by high pressure of these aggregates reveals the reversibility of the process and that the aggregates have water-excluded cavities. Kinetic measurements show that the intermediate formed in a parallel reaction between unfolded and folded structures and that it is under fine energetic control. They are not only crucial to the folding pathway of p53C but may explain as well the vulnerability of p53C to undergo departure of the native to an inactive state, which makes the cell susceptible to malignant transformation.     

Tandem dimerization of the human p53 tetramerization domain stabilizes a primary dimer intermediate and dramatically enhances its oligomeric stability

Tetramerization of the human p53 tumor suppressor protein is required for its biological functions. However, cellular levels of p53 indicate that it exists predominantly in a monomeric state. Since the oligomerization of p53 involves the rate-limiting formation of a primary dimer intermediate, we engineered a covalently linked pair of human p53 tetramerization (p53tet) domains to generate a tandem dimer (p53tetTD) that minimizes the energetic requirements for forming the primary dimer. We demonstrate that p53tetTD self-assembles into an oligomeric structure equivalent to the wild-type p53tet tetramer and exhibits dramatically enhanced oligomeric stability. Specifically, the p53tetTD dimer exhibits an unfolding/dissociation equilibrium constant of 26 fM at 37 degrees C, or a million-fold increase in stability relative to the wild-type p53tet tetramer, and resists subunit exchange with monomeric p53tet. In addition, whereas the wild-type p53tet tetramer undergoes coupled (i.e. two-state) dissociation/unfolding to unfolded monomers, the p53tetTD dimer denatures via an intermediate that is detectable by differential scanning calorimetry but not CD spectroscopy, consistent with a folded p53tetTD monomer that is equivalent to the p53tet primary dimer. Given its oligomeric stability and resistance against hetero-oligomerization, dimerization of p53 constructs incorporating the tetramerization domain may yield functional constructs that may resist exchange with wild-type or mutant forms of p53.     

A split-ubiquitin-based assay detects the influence of mutations on the conformational stability of the p53 DNA binding domain in vivo

Many mutations in the human tumor suppressor p53 affect the function of the protein by destabilizing the structure of its DNA binding domain. To monitor the effects of those mutations in vivo the stability of the DNA binding domain of p53 and some of its mutants was investigated with the split-ubiquitin (split-Ub) method. The split-Ub-derived in vivo data on the relative stability of the mutants roughly correlate with the quantitative data from in vitro denaturation experiments as reported in the literature. A variation of this assay allows visualizing the difference in stability between the wild-type p53 core and the mutant p53(V143A) by a simple growth assay.     

Solvent-exposed residues located in the beta-sheet modulate the stability of the tetramerization domain of p53--a structural and combinatorial approach

The role of hydrophobic amino acids in the formation of hydrophobic cores as one of the major driving forces in protein folding has been extensively studied. However, the implication of neutral solvent-exposed amino acids is less clear and available information is scarce. We have used a combinatorial approach to study the structural relevance of three solvent-exposed residues (Tyr(327), Thr(329), and Gln(331)) located in thebeta-sheet of the tetramerization domain of the tumor suppressor p53 (p53TD). A conformationally defined peptide library was designed where these three positions were randomized. The library was screened for tetramer stability. A set of p53TD mutants containing putative stabilizing or destabilizing residue combinations was synthesized for a thermodynamic characterization. Unfolding experiments showed a wide range of stabilities, with T(m) values between 27 and 83 degrees C. Wild type p53TD and some highly destabilized and stabilized mutants were further characterized. Thermodynamic and biophysical data indicated that these proteins were folded tetramers, with the same overall structure, in equilibrium with unfolded monomers. An NMR study confirmed that the main structural features of p53TD are conserved in all the mutants analyzed. The thermodynamic stability of the different p53TD mutants showed a strong correlation with parameters that favor formation and stabilization of the beta-sheet. We propose that stabilization through hydrophobic interactions of key secondary structure elements might be the underlying mechanism for the strong influence of solvent-exposed residues in the stability of p53TD.     

Structure-based stability engineering of the mouse IgG1 Fab fragment by modifying constant domains

A semi-rational approach based on structural data was exploited in a search for CH1 and CL domains with improved intrinsic thermodynamic stabilities. Structural and amino acid level comparisons were carried out against known biophysically well-behaving and thermodynamically beneficial scFv and Fab fragments. A number of mutant Fab fragments were constructed by site-directed mutagenesis of regions in the CH1 and CL domains expected to be most sensitive under physical stress conditions. These mutations were located on three sites in the Fab constant domains; a mobile loop in the CH1 domain, residues surrounding the two largest solvated hydrophobic cavities located in the interface of the CH1 and CL domains and the hydrophobic core regions of both CH1 and CL. Expression levels of functional Fab fragments, denaturant-induced unfolding equilibria and circular dichroism spectroscopy were used to evaluate the relative stabilities of the wild-type and the mutant Fab fragments. The highest thermodynamic stability was reached through the mutation strategy, where the hydrophobicity and the packing density of the solvated hydrophobic cavity in the CH1/CL interface was increased by the replacement of the hydrophilic Thr178 in the CL domain by a more hydrophobic residue, valine or isoleucine. The midpoint of the transition curve from native to unfolded states of the protein, measured by fluorescence emission, occurred at concentrations of guanidine hydrochloride of 2.4 M and 2.6 M for the wild-type Fab and the most stable mutants, respectively. Our results illustrate that point mutations targeted to the CH1/CL interface were advantageous for the overall thermodynamic stability of the Fab fragment.     

FRET-based in vivo screening for protein folding and increased protein stability

Fluorescence resonance energy transfer (FRET) was used to establish a novel in vivo screening system that allows rapid detection of protein folding and protein variants with increased thermodynamic stability in the cytoplasm of Escherichia coli. The system is based on the simultaneous fusion of the green fluorescent protein (GFP) to the C terminus of a protein X of interest, and of blue-fluorescent protein (BFP) to the N terminus of protein X. Efficient FRET from BFP to GFP in the ternary fusion protein is observed in vivo only when protein X is folded and brings BFP and GFP into close proximity, while FRET is lost when BFP and GFP are far apart due to unfolding or intracellular degradation of protein X. The screening system was validated by identification of antibody V(L) intradomains with increased thermodynamic stabilities from expression libraries after random mutagenesis, bacterial cell sorting, and colony screening.     

Disruption of an intermonomer salt bridge in the p53 tetramerization domain results in an increased propensity to form amyloid fibrils

We describe in molecular detail how disruption of an intermonomer salt bridge (Arg337-Asp352) leads to partial destabilization of the p53 tetramerization domain and a dramatically increased propensity to form amyloid fibrils. At pH 4.0 and 37 degrees C, a p53 tetramerization domain mutant (p53tet-R337H), associated with adrenocortical carcinoma in children, readily formed amyloid fibrils, while the wild-type (p53tet-wt) did not. We characterized these proteins by equilibrium denaturation, 13C(alpha) secondary chemical shifts, (1H)-15N heteronuclear NOEs, and H/D exchange. Although p53tet-R337H was thermodynamically less stable, NMR data indicated that the two proteins had similar secondary structure and molecular dynamics. NMR derived pK(a) values indicated that at low pH the R337H mutation partially disrupted an intermonomer salt bridge. Backbone H/D exchange results showed that for at least a small population of p53tet-R337H molecules disruption of this salt bridge resulted in partial destabilization of the protein. It is proposed that this decrease in p53tet-R337H stability resulted in an increased propensity to form amyloid fibrils.     

Adaptive Evolution of p53 Thermodynamic Stability

The thermodynamic stability of a protein plays an important role during evolution and adaptation in order to maintain a folded and active conformation. p53 is a tumour suppressor involved in the regulation of numerous genes. Human p53 has an unusually low thermodynamic stability and is frequently inactivated by oncogenic missense mutations. Here, we examined the thermodynamic and kinetic stability of p53 DNA binding domains from selected invertebrate and vertebrate species by differential scanning calorimetry and equilibrium urea denaturation. There is a correlation in the apparent melting temperature of p53 with the body temperature of homeotherm vertebrates. We found that p53 from these organisms has a half-life for spontaneous unfolding at organismal body temperature of 10-20 min. We also found that p53 from invertebrates has higher stability, bearing more resemblance towards p63 and p73 from humans. Using structure-guided mutagenesis on the human p53 scaffold, we demonstrated that the amino acid changes on the protein surface and in the protein interior lead to the elevated stability of p53 orthologs. We propose a model in which the p53 DNA binding domain has been shaped by the complex interplay of different selective pressures and underwent adaptive evolution leading to pronounced effects on its stability. p53 from vertebrates has evolved to have a low thermodynamic stability and similarly short spontaneous half-life at organismal body temperature, which is related to function.     

Coevolution of a homing endonuclease and its host target sequence

We have determined the specificity profile of the homing endonuclease I-AniI and compared it to the conservation of its host gene. Homing endonucleases are encoded within intervening sequences such as group I introns. They initiate the transfer of such elements by cleaving cognate alleles lacking the intron, leading to their transfer via homologous recombination. Each structural homing endonuclease family has arrived at an appropriate balance of specificity and fidelity that avoids toxicity while maximizing target recognition and invasiveness. I-AniI recognizes a strongly conserved target sequence in a host gene encoding apocytochrome B and has fine-tuned its specificity to correlate with wobble versus nonwobble positions across that sequence and to the amount of degeneracy inherent in individual codons. The physiological target site in the host gene is not the optimal substrate for recognition and cleavage: at least one target variant identified during a screen is bound more tightly and cleaved more rapidly. This is a result of the periodic cycle of intron homing, which at any time can present nonoptimal combinations of endonuclease specificity and insertion site sequences in a biological host.     

p53 and PI3K/AKT signalings are up-regulated in flies with defects in the THO complex

The THO complex (THO) is an evolutionary conserved protein required for the formation of export-competent mRNP. The growing evidence indicates that the metazoan THO plays important roles in cell differentiation and cellular stress response. But the underlying mechanisms are poorly understood. Herein we examined the relevance of THO to cellular signaling pathways involved in cell differentiation and cellular stress response. When we examined the endogenous p53 level in the testis, it was sustained much longer during spermatogenesis in the THO mutant compared to that of wild-type. In flies with impaired THO, overexpression of p53 by eye-specific GAL4 not only enhanced p53-mediated retinal degeneration, but p53 level was also elevated compared to the control flies. Since the body size of the THO mutant flies was significantly larger than control flies, we also examined whether the PI3K/AKT signaling is enhanced in the mutant flies. The results showed that the endogenous level of phosphorylated AKT, which is the active form, was highly elevated in the THO mutants. Taken together our results suggested that both p53 and PI3K/AKT signalings are up-regulated in the flies with impaired THO.     

Expression of the sucrose binding protein from soybean: renaturation and stability of the recombinant protein

The sucrose binding protein (SBP) belongs to the cupin family of proteins and is structurally related to vicilin-like storage proteins. In this investigation, a SBP isoform (GmSBP2/S64) was expressed in E. coli and large amounts of the protein accumulated in the insoluble fraction as inclusion bodies. The renatured protein was studied by circular dichroism (CD), intrinsic fluorescence, and binding of the hydrophobic probes ANS and Bis-ANS. The estimated content of secondary structure of the renatured protein was consistent with that obtained by theoretical modeling with a large predominance of beta-strand structure (42%) over the alpha-helix (9.9%). The fluorescence emission maximum of 303 nm for SBP2 indicated that the fluorescent tryptophan was completely buried within a highly hydrophobic environment. We also measured the equilibrium dissociation constant (K(d)) of sucrose binding by fluorescence titration using the refolded protein. The low sucrose binding affinity (K(d)=2.79+/-0.22 mM) of the renatured protein was similar to that of the native protein purified from soybean seeds. Collectively, these results indicate that the folded structure of the renatured protein was similar to the native SBP protein. As a member of the bicupin family of proteins, which includes highly stable seed storage proteins, SBP2 was fairly stable at high temperatures. Likewise, it remained folded to a similar extent in the presence or absence of 7.6M urea or 6.7 M GdmHCl. The high stability of the renatured protein may be a reminiscent property of SBP from its evolutionary relatedness to the seed storage proteins.     

Hsp70 family member, mot-2/mthsp70/GRP75, binds to the cytoplasmic sequestration domain of the p53 protein

Hsp70 family member mot-2/mthsp70/GRP75/PBP74 was shown to bind to the tumor suppressor protein p53. In this study, by in vivo coimmunoprecipitation of mot-2 with p53 and its deletion mutants, the mot-2 binding site of p53 was mapped to its C-terminal amino acid residues 312-352, a region of p53 that includes its cytoplasmic sequestration domain. These data demonstrate that cytoplasmic sequestration and inactivation of p53 by mot-2 occurs by its binding to the cytoplasmic sequestration domain. Therefore, perturbation of mot-p53 interactions can be employed to abrogate cytoplasmic retention of wild-type p53 in tumors.     

Expression level of heterologous tat genes is crucial for in vivo reconstitution of a functional Tat translocase in Escherichia coli

The Tat system has the remarkable capacity of exporting proteins in folded conformation across the cytoplasmic membrane. The functional Tat translocase from Gram-negative bacteria consists of TatA, TatB and TatC proteins. To gain information about the species specificity of the Tat translocase, we cloned tat genes from Gram-negative pathogens Shigella flexneri 2a str. 301, Vibrio cholerae El Tor N16961, Pseudomonas aeruginosa PAO1, thermophilic Sulfolobus solfataricus P2, Thermus thermophilus HB8 and from three Magnetospirillum species (AMB-1, MS-1 and MSR-1), and assessed the capacity of these Tat systems to restore the Tat-dependent growth defect of Escherichia coli tat mutants. We found that whereas the tat genes from the thermophilic bacterial and archaeal species were not functional in E. coli, other tat genes could all complement the phenotype of the E. coli tat mutants. In addition, a chimera composed of the N-terminus of V. cholerae TatE and C-terminus of M. magneticum TatA was functional. Whereas the expression of the tatABC genes from P. aeruginosa and Magnetospirillum strains must be induced to obtain a functional Tat system, overproduction of the V. cholerae TatABC proteins abolished the complementation. The complementation impairment seemed to be correlated with increasing level of slow-migrating TatC isoforms. In vitro studies showed that slow-migrating TatC isoforms in the purified V. cholerae TatABC complex increased with storage time. Together these results showed that the Tat translocases from the Gram-negative bacteria are generally functional in E. coli and the expression level is crucial for in vivo reconstitution of a functional Tat translocase.     

Topors acts as a SUMO-1 E3 ligase for p53 in vitro and in vivo

Human Topors, which was originally identified as cellular binding partner of DNA topoisomerase I and of p53, has recently been shown to function as an ubiquitin E3 ligase for p53 in a manner dependent on its N'-terminally located RING finger. Here, we demonstrate that Topors also enhances the conjugation of the small ubiquitin-like modifier 1 (SUMO-1) to p53 in vivo and in a reconstituted in vitro system. The Topors SUMO-1 E3 ligase activity does not depend upon its RING finger motif. In HeLa cells, Topors induced p53 sumoylation was accompanied by an increase in endogenous p53 protein levels. Furthermore, Topors enhances the sumoylation of a variety of other, yet unidentified, cellular proteins.     

SOX11结合p53并上调其转录活性

目的:研究SOX11对p53转录活性的影响,并检测二者的体外相互作用。方法:在H1299(p53缺失)和H460(含野生型p53)2种细胞中分别过表达SOX11和p53,用双萤光素酶方法测定p53的转录活性;用大肠杆菌DH5α表达GST和GST-p53融合蛋白并将其纯化,用GST pull-down实验检测SOX11与p53在体外是否存在相互作用。结果:萤光素酶实验结果表明,在H1299和H460细胞中,过表达SOX11分别能促进外源p53和内源p53的转录活性;GST pull-down实验表明SOX11能在体外与p53发生相互作用。结论:SOX11能在体外与p53发生相互作用并促进p53的转录活性,为进一步研究p53的功能提供了新的线索。     

Dynamic localization of protein phosphatase type 1 in the mitotic cell cycle of Saccharomyces cerevisiae

Protein phosphatase type I (PP1), encoded by the single essential gene GLC7 in Saccharomyces cerevisiae, functions in diverse cellular processes. To identify in vivo subcellular location(s) where these processes take place, we used a functional green fluorescent protein (GFP)-Glc7p fusion protein. Time-lapse fluorescence microscopy revealed GFP-Glc7p localizes predominantly in the nucleus throughout the mitotic cell cycle, with the highest concentrations in the nucleolus. GFP-Glc7p was also observed in a ring at the bud neck, which was dependent upon functional septins. Supporting a role for Glc7p in bud site selection, a glc7-129 mutant displayed a random budding pattern. In alpha-factor treated cells, GFP-Glc7p was located at the base of mating projections, again in a septin-dependent manner. At the start of anaphase, GFP-Glc7p accumulated at the spindle pole bodies and remained there until cytokinesis. After anaphase, GFP-Glc7p became concentrated in a ring that colocalized with the actomyosin ring. A GFP-Glc7-129 fusion was defective in localizing to the bud neck and SPBs. Together, these results identify sites of Glc7p function and suggest Glc7p activity is regulated through dynamic changes in its location.