FAM96A和FAM96B结构与功能的研究进展

96序列相似的家庭成员A和B（family with sequence similarity 96 member A and B,FAM96A和FAM96B）是属于MIP18（MMS19-interacting protein of 18 kD）家族的2个高度保守的同源蛋白,MIP18是与有丝分裂纺锤体相关的MMDX（MMS19-MIP18-XPD）复合体的亚基。研究表明,FAM96A和FAM96B在人胃肠道间质瘤、结肠癌、肝癌、胃癌和乳腺癌等多种肿瘤组织中的表达显著降低,提示其可能是作为潜在的抑癌基因参与肿瘤的发生发展,但目前关于FAM96A和FAM96B在肿瘤发生发展过程中的作用机理并不十分清楚。此外,研究发现FAM96A和FAM96B可通过与其他不同的蛋白质相互作用在体内发挥多种不同的功能。因此,就目前对于FAM96A和FAM96B结构和功能的研究所取得的进展进行了回顾与总结,并对其在肿瘤发生发展中的分子机制和相互作用蛋白鉴定的研究前景进行了展望,以期为临床上将FAM96A和FAM96B作为新的肿瘤诊断标志物和治疗靶点奠定基础,并为揭示二者在体内更多的新功能提供依据。     

人FAM92A1基因诱饵表达质粒的构建与鉴定

目的 构建人FAM92A1基因（hFAM92A1）的诱饵表达质粒pGBKT7-hFAM92A1并检测其蛋白表达、毒性和自激活作用.方法 PCR扩增hFAM92A1的基因编码序列并克隆入诱饵表达载体pGBKT7中,酶切和测序鉴定后,转化到酵母AHl09细胞中,Western印迹检测诱饵蛋白表达情况,同时检测诱饵蛋白的毒性和自激活作用.结果 成功构建FAM92A1基因的诱饵表达质粒pGBKT7-hFAM92A1,测序结果正确.Western印迹实验证实酵母细胞高表达诱饵蛋白hFAM92A1,诱饵蛋白没有自激活作用.结论 构建的诱饵表达质粒pGBKT7-hFAM92A1可用于下一步酵母双杂交系统实验,为进一步研究hFAM92A1功能奠定了基础.     

Identification of FAM96B as a novel prelamin A binding partner

Prelamin A accumulation causes nuclear abnormalities, impairs nuclear functions, and eventually promotes cellular senescence. However, the underlying mechanism of how prelamin A promotes cellular senescence is still poorly understood. Here we carried out a yeast two-hybrid screen using a human skeletal muscle cDNA library to search for prelamin A binding partners, and identified FAM96B as a prelamin A binding partner. The interaction of FAM96B with prelamin A was confirmed by GST pull-down and co-immunoprecipitation experiments. Furthermore, co-localization experiments by fluorescent confocal microscopy revealed that FAM96B colocalized with prelamin A in HEK-293 cells. Taken together, our data demonstrated the physical interaction between FAM96B and prelamin A, which may provide some clues to the mechanisms of prelamin A in premature aging.     

Identification of the Protease-Binding Domain in the N-Terminal Region of Influenza Virus A Matrix Protein M1

A region responsible for protease binding by influenza virus A matrix protein M1 was identified. Trypsin binding was observed with the N-proximal 9-kDa fragment obtained by cleaving M1 with formic acid. The binding was inhibited by monoclonal antibodies (mAb) to region 46–70 of M1 and by an antiserum to region 21–45, whereas mAb to the middle and C-terminal regions had no effect. Thus, the protease-binding domain was mapped to the N-terminal part of M1.     

A compound‐based computational approach for the accurate determination of hot spots

A plethora of both experimental and computational methods have been proposed in the past 20 years for the identification of hot spots at a protein–protein interface. The experimental determination of a protein–protein complex followed by alanine scanning mutagenesis, though able to determine hot spots with much precision, is expensive and has no guarantee of success while the accuracy of the current computational methods for hot‐spot identification remains low. Here, we present a novel structure‐based computational approach that accurately determines hot spots through docking into a set of proteins homologous to only one of the two interacting partners of a compound capable of disrupting the protein–protein interaction (PPI). This approach has been applied to identify the hot spots of human activin receptor type II (ActRII) critical for its binding toward Cripto‐I. The subsequent experimental confirmation of the computationally identified hot spots portends a potentially accurate method for hot‐spot determination in silico given a compound capable of disrupting the PPI in question. The hot spots of human ActRII first reported here may well become the focal points for the design of small molecule drugs that target the PPI. The determination of their interface may have significant biological implications in that it suggests that Cripto‐I plays an important role in both activin and nodal signal pathways.     

Interaction of serum amyloid A with human cystatin C—identification of binding sites

Serum amyloid A (SAA) is a multifunctional acute‐phase protein whose natural role seems to be participation in many physiologic and pathological processes. Prolonged increased SAA level in a number of chronic inflammatory and neoplastic diseases gives rise to reactive systemic amyloid A amyloidosis, where the N‐terminal 76‐amino acid residue‐long segment of SAA is deposited as amyloid fibrils. Recently, a specific interaction between SAA and the ubiquitous inhibitor of cysteine proteases—human cystatin C (hCC)—has been described. Here, we report further evidence corroborating this interaction, and the identification of the SAA and hCC binding sites in the SAA–hCC complex, using a combination of selective proteolytic excision and high‐resolution mass spectrometry. The shortest binding site in the SAA sequence was determined as SAA(86–104), whereas the binding site in hCC sequence was identified as hCC(96–102). Binding specificities of both interacting sequences were ascertained by affinity experiments (ELISA) and by registration of mass spectrum of SAA–hCC complex. Copyright © 2012 John Wiley & Sons, Ltd.     

Interaction of Human Replication Protein A with DNA Duplexes Containing Gaps of Varying Size

Replication protein A (RPA) is a heterotrimeric protein that has high affinity for single-stranded (ss) DNA and is involved in DNA replication, repair, and recombination in eukaryotic cells. Photoaffinity modification was employed in studying the interaction of human RPA with DNA duplexes containing various gaps, which are similar to structures arising during DNA replication and repair. A photoreactive dUMP derivative was added to the 3" end of a gap-flanking oligonucleotide with DNA polymerase , and an oligonucleotide containing a 5"-photoreactive group was chemically synthesized. The 5" end predominantly interacted with the large RPA subunit (p70) regardless of the gap size, whereas interactions of the 3" end with the RPA subunits depended both on the gap size and on the RPA concentration. Subunit p32 was mostly labeled in the case of a larger gap and a lower RPA concentration. The results confirmed the model of polar RPA–DNA interaction, which has been advanced earlier.     

Molecular dynamics simulation study on the interaction of collagen‐like peptides with gelatinase‐A (MMP‐2)

Although several models have been proposed for the interaction of collagen with gelatinase‐A (matrix metalloproteinases‐2 (MMP‐2)), the extensive role of each domain of gelatinase A in hydrolyzing the collagens with and without interruptions is still elusive. Molecular docking, molecular dynamics (MD) simulation, normal mode analysis (NMA) and framework rigidity optimized dynamics algorithm (FRODAN) based analysis were carried out to understand the function of various domains of MMP‐2 upon interaction with collagen like peptides. The results reveal that the collagen binding domain (CBD) binds to the C‐terminal of collagen like peptide with interruption. CBD helps in unwinding the loosely packed interrupted region of triple helical structure to a greater extent. It can be possible to speculate that the role of hemopexin (HPX) domain is to prevent further unwinding of collagen like peptide by binding to the other end of the collagen like peptide. The catalytic (CAT) domain then reorients itself to interact with the part of the unwound region of collagen like peptide for further hydrolysis. In conclusion the CBD of MMP‐2 recognizes the collagen and aids in unwinding the collagen like peptide with interruptions, and the HPX domain of MMP‐2 binds to the other end of the collagen allowing CAT domain to access the cleavage site. This study provides a comprehensive understanding of the structural basis of collagenolysis by MMP‐2. © 2013 Wiley Periodicals, Inc. Biopolymers 101: 779–794, 2014.     

Interaction of Replication Protein A and Flap Endonuclease 1 with DNA Duplexes Containing a Nick or a Flap

Nicks and flaps are intermediates in various processes of DNA metabolism, including replication and repair. Photoaffinity modification was employed in studying the interaction of the replication protein A (RPA) and flap endonuclease 1 (FEN-1) with DNA duplexes similar to structures arising during long-patch base excision repair. The proteins were also tested for effect on DNA polymerase (Pol) interaction with DNA. Using Pol, a photoreactive dTTP analog was added to the 3" end of an oligonucleotide flanking a nick or a flap in DNA intermediates. The character and intensity of protein labeling depended on the type of intermediates and on the presence of the phosphate or tetrahydrofuran at the 5" end of a nick or a flap. Photoaffinity labeling of Pol substantially (up to three times) increased in the presence of RPA or FEN-1. Various DNA substrates were used to study the effects of RPA and FEN-1 on Pol-mediated DNA synthesis with displacement of a downstream primer. In contrast to FEN-1, RPA had no effect on DNA repair synthesis by Pol during long-patch base excision repair.     

Complex formation dynamics of native and mutated pyrin's B30.2 domain with caspase‐1

Pyrin protein is the product of the MEFV gene, mutations in which cause manifestation of familial Mediterranean fever (FMF). Functions of pyrin are not completely clear. The secondary structure of the pyrin is represented with four domains and two motifs. Mutations p.M680I, p.M694V, p.M694I, p.K695R, p.V726A, and p.A744S, which are located in the B30.2 domain of pyrin protein, are responsible for manifestation of the most common and severe forms of FMF. All the domains and the motifs of pyrin, are directly or indirectly, involved in the protein–protein interaction with proteins of apoptosis and regulate the cascade of inflammatory reactions, which is impaired due to pyrin mutations. It is well known, that malfunction of the pyrin‐caspase‐1 complex is the main reason of inflammation during FMF. Complete tertiary structure of pyrin and the effects of mutations in it are experimentally not studied yet. The aim of this study was to identify possible effects of the abovementioned mutations in the B30.2 domain tertiary structure and to determine their potential consequences in formation of the B30.2‐caspase‐1 complex. Using in silico methods, it was found, that these mutations led to structural rearrangements in B30.2 domain tertiary structure, causing shifts of binding sites and altering the interaction energy between B30.2 and caspase‐1.     

Calorimetric and spectroscopic investigation of the interaction between the C‐terminal domain of Enzyme I and its ligands

Enzyme I initiates a series of phosphotransfer reactions during sugar uptake in the bacterial phosphotransferase system. Here, we have isolated a stable recombinant C-terminal domain of Enzyme I (EIC) of Escherichia coli and characterized its interaction with the N-terminal domain of Enzyme I (EIN) and also with various ligands. EIC can phosphorylate EIN, but their binding is transient regardless of the presence of phosphoenolpyruvate (PEP). Circular dichroism and NMR indicate that ligand binding to EIC induces changes near aromatic groups but not in the secondary structure of EIC. Binding of PEP to EIC is an endothermic reaction with the equilibrium dissociation constant (K_D) of 0.28 mM, whereas binding of the inhibitor oxalate is an exothermic reaction with K_D of 0.66 mM from calorimetry. The binding thermodynamics of EIC and PEP compared to that of Enzyme I (EI) and PEP reveals that domain–domain motion in EI can contribute as large as ∼−3.2 kcal/mol toward PEP binding.     

Importance of the interaction protein–protein of the CaM–PDE1A and CaM–MLCK complexes in the development of new anti‐CaM drugs

Protein–protein interactions play central roles in physiological and pathological processes. The bases of the mechanisms of drug action are relevant to the discovery of new therapeutic targets. This work focuses on understanding the interactions in protein–protein–ligands complexes, using proteins calmodulin (CaM), human calcium/calmodulin‐dependent 3′,5′‐cyclic nucleotide phosphodiesterase 1A active human (PDE1A), and myosin light chain kinase (MLCK) and ligands αII–spectrin peptide (αII–spec), and two inhibitors of CaM (chlorpromazine (CPZ) and malbrancheamide (MBC)). The interaction was monitored with a fluorescent biosensor of CaM (hCaM M124C–mBBr). The results showed changes in the affinity of CPZ and MBC depending on the CaM–protein complex under analysis. For the Ca²⁺–CaM, Ca²⁺–CaM–PDE1A, and Ca²⁺–CaM–MLCK complexes, CPZ apparent dissociation constants (K_ds) were 1.11, 0.28, and 0.55 μM, respectively; and for MBC K_ds were 1.43, 1.10, and 0.61 μM, respectively. In competition experiments the addition of calmodulin binding peptide 1 (αII–spec) to Ca²⁺–hCaM M124C–mBBr quenched the fluorescence (K_d = 2.55 ± 1.75 pM) and the later addition of MBC (up to 16 μM) did not affect the fluorescent signal. Instead, the additions of αII–spec to a preformed Ca²⁺–hCaM M124C–mBBr–MBC complex modified the fluorescent signal. However, MBC was able to displace the PDE1A and MLCK from its complex with Ca²⁺–CaM. In addition, docking studies were performed for all complexes with both ligands showing an excellent correlation with experimental data. These experiments may help to explain why in vivo many CaM drugs target prefer only a subset of the Ca²⁺–CaM regulated proteins and adds to the understanding of molecular interactions between protein complexes and small ligands. Copyright © 2013 John Wiley & Sons, Ltd.     

Structural studies of the C‐terminal 19‐peptide of serum amyloid A and its Pro→Ala variants interacting with human cystatin C

Serum amyloid A (SAA) is a multifunctional acute‐phase protein whose concentration in serum increases markedly following a number of chronic inflammatory and neoplastic diseases. Prolonged high SAA level may give rise to reactive systemic amyloid A (AA) amyloidosis, where the N‐terminal segment of SAA is deposited as amyloid fibrils. Besides, recently, well‐documented association of SAA with high‐density lipoprotein or glycosaminoglycans, in particular heparin/heparin sulfate (HS), and specific interaction between SAA and human cystatin C (hCC), the ubiquitous inhibitor of cysteine proteases, was proved. Using a combination of selective proteolytic excision and high‐resolution mass spectrometry, a hCC binding site in the SAA sequence was determined as SAA(86–104). The role of this SAA C‐terminal fragment as a ligand‐binding locus is still not clear. It was postulated important in native SAA folding and in pathogenesis of AA amyloidosis. In the search of conformational details of this SAA fragment, we did its structure and affinity studies, including its selected double/triple Pro→Ala variants. Our results clearly show that the SAA(86–104) 19‐peptide has rather unordered structure with bends in its C‐terminal part, which is consistent with the previous results relating to the whole protein. The results of affinity chromatography, fluorescent ELISA‐like test, CD and NMR studies point to an importance of proline residues on structure of SAA(86–104). Conformational details of SAA fragment, responsible for hCC binding, may help to understand the objective of hCC–SAA complex formation and its importance for pathogenesis of reactive amyloid A amyloidosis. Copyright © 2015 John Wiley & Sons, Ltd.     

Interaction between bound water molecules and local protein structures: A statistical analysis of the hydrogen bond structures around bound water molecules

Water molecules play an important role in protein folding and protein interactions through their structural association with proteins. Examples of such structural association can be found in protein crystal structures, and can often explain protein functionality in the context of structure. We herein report the systematic analysis of the local structures of proteins interacting with water molecules, and the characterization of their geometric features. We first examined the interaction of water molecules with a large local interaction environment by comparing the preference of water molecules in three regions, namely, the protein–protein interaction (PPI) interfaces, the crystal contact (CC) interfaces, and the non‐interfacial regions. High preference of water molecules to the PPI and CC interfaces was found. In addition, the bound water on the PPI interface was more favorably associated with the complex interaction structure, implying that such water‐mediated structures may participate in the shaping of the PPI interface. The pairwise water‐mediated interaction was then investigated, and the water‐mediated residue–residue interaction potential was derived. Subsequently, the types of polar atoms surrounding the water molecules were analyzed, and the preference of the hydrogen bond acceptor was observed. Furthermore, the geometries of the structures interacting with water were analyzed, and it was found that the major structure on the protein surface exhibited planar geometry rather than tetrahedral geometry. Several previously undiscovered characteristics of water–protein interactions were unfolded in this study, and are expected to lead to a better understanding of protein structure and function. Proteins 2016; 84:43–51. © 2015 Wiley Periodicals, Inc.