Specific interactions by the N-terminal arm inhibit self-association of the AraC dimerization domain

Deletion of the regulatory N-terminal arms of the AraC protein from its dimerization domain fragments increases the susceptibility of the dimerization domain to form a series of higher order polymers by indefinite self-association. We investigated how the normal presence of the arm inhibits this self-association. One possibility is that arms can act as an entropic bristles to interfere with the approach of other macromolecules, thereby decreasing collision frequencies. We examined the repulsive effect of flexible arms by measuring the rate of trypsin cleavage of a specially constructed ubiquitin-arm protein. Adding an arm to ubiquitin or increasing its length produced only a modest repulsive effect. This suggests that arms such as the N-terminal arm of AraC do not reduce self-association by entropic exclusion. We consequently tested the hypothesis that the arm on AraC reduces self-association by binding to the core of the dimerization domain even in the absence of arabinose. The behaviors of dimerization domain mutants containing deletions or alterations in the N-terminal arms substantiate this hypothesis. Apparently, interactions between the N-terminal arm and the dimerization domain core position the arm to interfere with the protein-protein contacts necessary for self-association.     

Understanding the basis of a class of paradoxical mutations in AraC through simulations

Most mutations at position 15 in the N‐terminal arm of the regulatory protein AraC leave the protein incapable of responding to arabinose and inducing the proteins required for arabinose catabolism. Mutations at other positions of the arm do not have this behavior. Simple energetic analysis of the interactions between the arm and bound arabinose do not explain the uninducibility of AraC with mutations at position 15. Extensive molecular dynamics (MD) simulations, carried out largely on the Open Science Grid, were done of the wild‐type protein with and without bound arabinose and of all possible mutations at position 15, many of which were constructed and measured for this work. Good correlation was found for deviation of arm position during the simulations and inducibility as measured in vivo of the same mutant proteins. Analysis of the MD trajectories revealed that preservation of the shape of the arm is critical to inducibility. To maintain the correct shape of the arm, the strengths of three interactions observed to be strong in simulations of the wild‐type AraC protein need to be preserved. These interactions are between arabinose and residue 15, arabinose and residues 8–9, and residue 13 and residue 15. The latter interaction is notable because residues L9, Y13, F15, W95, and Y97 form a hydrophobic cluster which needs to be preserved for retention of the correct shape. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Mutational analysis of hydrophobic domain interactions in gamma B-crystallin from bovine eye lens.

gamma B-crystallin is a monomeric member of the beta gamma-superfamily of vertebrate eye lens proteins. It consists of two similar domains with all-beta Greek key topology associating about an approximate two-fold axis. At pH 2, with urea as the denaturant, the domains show independent equilibrium unfolding transitions, suggesting different intrinsic stabilities. Denaturation experiments using recombinant one- or two-domain proteins showed that the N-terminal domain on its own exhibits unaltered intrinsic stability but contributes significantly to the stability of its C-terminal partner. It has been suggested that docking of the domains is determined by a hydrophobic interface that includes phenylalanine at position 56 of the N-terminal domain. In order to test this hypothesis, F56 was substituted by site-directed mutagenesis in both complete gamma B-crystallin and its isolated N-terminal domain. All mutations destabilize the N-terminal domain to about the same extent but affect the C-terminal domain in a different way. Replacement by the small alanine side chain or the charged aspartic acid residue results in a significant destabilization of the C-terminal domain, whereas the more bulky tryptophan residue causes only a moderate decrease in stability. In the mutants F56A and F56D, equilibrium unfolding transitions obtained by circular dichroism and intrinsic fluorescence differ, suggesting a more complex denaturation behavior than the one observed for gamma B wild type. These results confirm how mutations in one crystallin domain can affect the stability of another when they occur at the interface. The results strongly suggest that size, hydrophobicity, and optimal packing of amino acids involved in these interactions are critical for the stability of gamma B-crystallin.     

Biochemical and physiological properties of the DNA binding domain of AraC protein

Intact AraC protein is poorly soluble and difficult to purify, whereas its dimerization domain is the opposite. Unexpectedly, the DNA binding domain of AraC proved also to be soluble in cells when overproduced and is easily purified to homogeneity. The DNA binding affinity of the DNA binding domain for its binding site could not be measured by electrophoretic mobility shift because of its rapid association and dissociation rates, but its affinity could be measured with a fluorescence assay and was found to have a dissociation constant of 1 x 10(-8)M in 100 mM KCl. The binding of monomers of the DNA binding domain to adjacent half-sites occurs without substantial positive or negative cooperativity. A simple analysis relates the DNA binding affinities of monomers of DNA binding domain and normal dimeric AraC protein.     

Analysis of amino acid substitutions in AraC variants that respond to triacetic acid lactone

The Escherichia coli regulatory protein AraC regulates expression of ara genes in response to l ‐arabinose. In efforts to develop genetically encoded molecular reporters, we previously engineered an AraC variant that responds to the compound triacetic acid lactone (TAL). This variant (named “AraC‐TAL1”) was isolated by screening a library of AraC variants, in which five amino acid positions in the ligand‐binding pocket were simultaneously randomized. Screening was carried out through multiple rounds of alternating positive and negative fluorescence‐activated cell sorting. Here we show that changing the screening protocol results in the identification of different TAL‐responsive variants (nine new variants). Individual substituted residues within these variants were found to primarily act cooperatively toward the gene expression response. Finally, X‐ray diffraction was used to solve the crystal structure of the apo AraC‐TAL1 ligand‐binding domain. The resolved crystal structure confirms that this variant takes on a structure nearly identical to the apo wild‐type AraC ligand‐binding domain (root‐mean‐square deviation 0.93 Å), suggesting that AraC‐TAL1 behaves similar to wild‐type with regard to ligand recognition and gene regulation. Our results provide amino acid sequence–function data sets for training and validating AraC modeling studies, and contribute to our understanding of how to design new biosensors based on AraC.     

嗜热四膜虫异染色质蛋白Tcd1磷酸化位点的突变分析

四膜虫异染色质蛋白Tcd1在有性生殖时期特异表达,在大核基因组重排以及修复过程中发挥作用。磷酸化蛋白质组学分析表明,Tcd1存在3个磷酸化位点：S301,S303和S535。然而,Tcd1磷酸化修饰与其功能的关系并不清楚。本研究对TCD1基因的3个磷酸化位点进行了模拟磷酸化和模拟去磷酸化定点突变,获得模拟磷酸化突变基因TCD1S301D (TCD1S1D)、TCD1S301DS303D (TCD1S2D)与TCD1S301DS303DS535D (TCD1S3D) 和模拟去磷酸化的突变基因TCD1S301A (TCD1S1A)、TCD1S301AS303A (TCD1S2A)与TCD1S301AS303AS535A (TCD1S3A)。分别构建了不同突变体的过表达载体,转化四膜虫细胞并筛选获得不同突变体细胞株。Western印迹分析表明,Tcd1S1D、Tcd1S2D、Tcd1S3D与Tcd1S1A、Tcd1S2A和Tcd1S3A在四膜虫有性生殖期表达。免疫荧光定位分析发现,Tcd1S1D点状定位于细胞质中,Tcd1S2D在有性生殖初期点状定位于细胞质中,在新大核上形成均匀的定位,Tcd1S3D无法定位于亲本大核上,只是均匀定位于新大核上。Tcd1S2A和Tcd1S3A在新大核形成异常的块状定位,并且与异染色质蛋白Pdd1不能共定位。结果表明,Tcd1不同位点的磷酸化和去磷酸化修饰的动态变化决定了其在四膜虫细胞中的定位模式。     

Mutational analysis of the BRAF gene in human tumor cells

Genes of the RAF family, which mediate cellular responses to growth signals, encode kinases that are regulated by RAS and participate in the RAS, RAF, mitogen/extracellular signal-regulated kinase, extracellular signal-regulated kinase and mitogen-activated protein kinase pathway. As BRAF is a serine/threonine kinase that is commonly activated by somatic point mutation, it may provide possible diagnostic and therapeutic targets in human malignant tumors. We analyzed exon 15 of the BRAF gene for mutations in 58 lung, 12 breast, six kidney, 14 cervical, four endometrial and 10 ovarian carcinoma cell lines by PCR-SSCP and direct sequencing. The T1796A transversion was found in one (2.9%) of 34 small cell lung carcinoma and one (8.3%) of 12 breast carcinoma cell lines, resulting in a valine-to-glutamate substitution at residue 599 (V599E). One (4.2%) of 24 non-small cell lung carcinoma cell line showed the C1786G transversion, leading to a leucine-to-valine substitution at residue 596 (L596V). No BRAF point mutations were found in any of the other cell lines examined. Our present results suggest that BRAF may not be a frequent target of mutations involved in the pathogenesis of human lung, breast, kidney, cervical, endometrial and ovarian carcinomas.     

Mutational reversions during adaptive protein evolution

Adaptation is often regarded as the sequential fixation of individually, intrinsically beneficial mutations. Contrary to this expectation, we find a surprisingly large number of evolutionary trajectories on which natural selection first favors a mutation, then favors its removal, and later still favors its ultimate restoration during the course of antibiotic resistance evolution. The existence of reversion trajectories implies that natural selection may not follow the most parsimonious path separating two alleles, even during adaptation. Altogether, this discovery highlights the unusual and potentially circuitous routes natural selection can follow during adaptation.     

Mutational analysis of phenylalanine beta 85 in the valine beta 6 acceptor pocket during hemoglobin S polymerization.

Hemoglobin (Hb) S containing Leu, Ala, Thr, or Trp substitutions at beta 85 were made and expressed in yeast in an effort to evaluate the role of Phe-beta 85 in the acceptor pocket during polymerization of deoxy Hb S. The four Hb S variants have the same electrophoretic mobility as Hb S, and these beta 85 substitutions do not significantly affect heme-globin interactions and tetramer helix content. Hb S containing Trp-beta 85 had decreased oxygen affinity, whereas those with Leu-, Ala-, and Thr-beta 85 had increased oxygen affinity. All four supersaturated beta 85 variants polymerized with a delay time as does deoxy Hb S. This is in contrast to deoxy Hb S containing Phe-beta 88, Ala-beta 88, Glu-beta 88, or Glu-beta 85, which polymerized with no clear delay time (Adachi K, Konitzer P, Paulraj CG, Surrey S, 1994, J Biol Chem 269:17477-17480; Adachi K, Reddy LR, Surrey S, 1994, J Biol Chem 269:31563-31566). Leu substitution at beta 85 accelerated deoxy Hb S polymerization, whereas Ala, Thr, or Trp substitution inhibited polymerization. The length of the delay time and total polymer formed for these beta 85 Hb S variants depended on hemoglobin concentration in the same fashion as for deoxy Hb S: the higher the concentration, the shorter the delay time and the more polymer formed. Critical concentrations required for polymerization of deoxy Hb SF veta 85L, Hb SF beta 85A, Hb SF beta 85T, and Hb SF beta 85W are 0.65-, 2.2-, 2.5- and 3-fold higher, respectively, than Hb S.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutational activity in cell line WEHI-231

The cell line WEHI-231 expresses activation-induced cytidine deaminase (AID), the enzyme that mediates hypermutation and immunoglobulin class switch recombination in activated B cells. Although both the cDNA sequence and protein expression of AID appear normal, the frequency of mutation at the endogenous immunoglobulin locus is low. In this report, we have tested the mutational activity of the cell line with three different indicator constructs. The first construct measures a composite rate of transversions of C to G and C to A, respectively. The second construct measures only transversion from C to G. The third measures the canonical AID activity, from C to U, which after cell replication can result in a C to T transition. We found that in WEHI-231, the C to G activity is 32- to 37-times lower than in the hypermutating cell line 18–81. The C to T activity is also much reduced, but only 12-fold. We suggest that the WEHI-231 lacks an activity that subverts the faithful repair of incipient C to U mutations.     

Structural segments and residue propensities in protein-RNA interfaces: comparison with protein-protein and protein-DNA complexes

The interface of a protein molecule that is involved in binding another protein, DNA or RNA has been characterized in terms of the number of unique secondary structural segments (SSSs), made up of stretches of helix, strand and non-regular (NR) regions. On average 10-11 segments define the protein interface in protein-protein (PP) and protein-DNA (PD) complexes, while the number is higher (14) for protein-RNA (PR) complexes. While the length of helical segments in PP interaction increases with the interface area, this is not the case in PD and PR complexes. The propensities of residues to occur in the three types of secondary structural elements (SSEs) in the interface relative to the corresponding elements in the protein tertiary structures have been calculated. Arg, Lys, Asn, Tyr, His and Gln are preferred residues in PR complexes; in addition, Ser and Thr are also favoured in PD interfaces.