Intracellular distribution of a speech/language disorder associated FOXP2 mutant

Although a mutation (R553H) in the forkhead box (FOX)P2 gene is associated with speech/language disorder, little is known about the function of FOXP2 or its relevance to this disorder. In the present study, we identify the forkhead nuclear localization domains that contribute to the cellular distribution of FOXP2. Nuclear localization of FOXP2 depended on two distally separated nuclear localization signals in the forkhead domain. A truncated version of FOXP2 lacking the leu-zip, Zn2+ finger, and forkhead domains that was observed in another patient with speech abnormalities demonstrated an aggregated cytoplasmic localization. Furthermore, FOXP2 (R553H) mainly exhibited a cytoplasmic localization despite retaining interactions with nuclear transport proteins (importin alpha and beta). Interestingly, wild type FOXP2 promoted the transport of FOXP2 (R553H) into the nucleus. Mutant and wild type FOXP2 heterodimers in the nucleus or FOXP2 R553H in the cytoplasm may underlie the pathogenesis of the autosomal dominant speech/language disorder.     

Six X-linked agammaglobulinemia-causing missense mutations in the Src homology 2 domain of Bruton's tyrosine kinase: phosphotyrosine-binding and circular dichroism analysis

Src homology 2 (SH2) domains recognize phosphotyrosine (pY)-containing sequences and thereby mediate their association to ligands. Bruton's tyrosine kinase (Btk) is a cytoplasmic protein tyrosine kinase, in which mutations cause a hereditary immunodeficiency disease, X-linked agammaglobulinemia (XLA). Mutations have been found in all Btk domains, including SH2. We have analyzed the structural and functional effects of six disease-related amino acid substitutions in the SH2 domain: G302E, R307G, Y334S, L358F, Y361C, and H362Q. Also, we present a novel Btk SH2 missense mutation, H362R, leading to classical XLA. Based on circular dichroism analysis, the conformation of five of the XLA mutants studied differs from the native Btk SH2 domain, while mutant R307G is structurally identical. The binding of XLA mutation-containing SH2 domains to pY-Sepharose was reduced, varying between 1 and 13% of that for the native SH2 domain. The solubility of all the mutated proteins was remarkably reduced. SH2 domain mutations were divided into three categories: 1) Functional mutations, which affect residues presumably participating directly in pY binding (R307G); 2) structural mutations that, via conformational change, not only impair pY binding, but severely derange the structure of the SH2 domain and possibly interfere with the overall conformation of the Btk molecule (G302E, Y334S, L358F, and H362Q); and 3) structural-functional mutations, which contain features from both categories above (Y361C).     

FOXP3~+调节性T细胞

调节性T细胞是一类可以调节其他多种免疫细胞功能的T细胞亚型,其正常生理功能对体内免疫稳态维持必不可少。调节性T细胞功能失调与人类多种重大疾病,如自身免疫性疾病、感染性疾病、过敏性疾病、恶性肿瘤、移植排斥的发生、发展及治疗都密切相关。调节性T细胞可分为多种亚型,其中最重要也是目前研究最多的为表达叉头状家族转录因子FOXP3的天然调节性T细胞及诱导调节性T细胞。深入研究FOXP3+调节性T细胞的发育及功能的分子及细胞免疫学机制,将为重大免疫性疾病的临床治疗提供创新性线索。     

Revisiting the role of glycosylation in the structure of human IgG fc

Binding of the Fc domain of Immunoglobulin G (IgG) to Fcγ receptors on leukocytes can initiate a series of signaling events resulting in antibody-dependent cell-mediated cytotoxicity (ADCC) and other important immune responses. Fc domains lacking glycosylation at N297 have greatly diminished Fcγ receptor binding and lack the ability to initiate a robust ADCC response. Earlier structural studies of Fc domains with either full length or truncated N297 glycans led to the proposal that these glycans can stabilize an "open" Fc conformation recognized by Fcγ receptors. We determined the structure of an E. coli expressed, aglycosylated human Fc domain at 3.1 ? resolution and observed significant disorder in the C'E loop, a region critical for Fcγ receptor binding, as well as a decrease in distance between the C(H)2 domains relative to glycosylated Fc structures. However, comparison of the aglycosylated human Fc structure with enzymatically deglycosylated Fc structures revealed large differences in the relative orientations and distances between C(H)2 domains. To provide a better appreciation of the physiologically relevant conformation of the Fc domain in solution, we determined Radii of Gyration (R(g)) by small-angle X-ray scattering (SAXS) and found that the aglycosylated Fc displays a larger R(g) than glycosylated Fc, suggesting a more open C(H)2 orientation under these conditions. Moreover, the R(g) of aglycosylated Fc was reduced by mutations at the C(H)2-C(H)3 interface (E382V/M428I), which confer highly selective binding to FcγRI and novel biological activities.     

A Non-Active-Site SET Domain Surface Crucial for the Interaction of MLL1 and the RbBP5/Ash2L Heterodimer within MLL Family Core Complexes

The mixed lineage leukemia-1 (MLL1) enzyme is a histone H3 lysine 4 (H3K4) monomethyltransferase and has served as a paradigm for understanding the mechanism of action of the human SET1 family of enzymes that include MLL1–MLL4 and SETd1a,b. Dimethylation of H3K4 requires a sub-complex including WRAD (WDR5, RbBP5, Ash2L, and DPY-30), which binds to each SET1 family member forming a minimal core complex that is required for multiple lysine methylation. We recently demonstrated that WRAD is a novel histone methyltransferase that preferentially catalyzes H3K4 dimethylation in a manner that is dependent on an unknown non-active-site surface from the MLL1 SET domain. Recent genome sequencing studies have identified a number of human disease-associated missense mutations that localize to the SET domains of several MLL family members. In this investigation, we mapped many of these mutations onto the three-dimensional structure of the SET domain and noticed that a subset of MLL2 (KMT2D, ALR, MLL4)-associated Kabuki syndrome missense mutations map to a common solvent-exposed surface that is not expected to alter enzymatic activity. We introduced these mutations into the MLL1 SET domain and observed that all are defective for H3K4 dimethylation by the MLL1 core complex, which is associated with a loss of the ability of MLL1 to interact with WRAD or with the RbBP5/Ash2L heterodimer. Our results suggest that amino acids from this surface, which we term the Kabuki interaction surface or KIS, are required for formation of a second active site within SET1 family core complexes.     

Solution structure of the R3H domain from human Smubp-2

The R3H domain is a conserved sequence motif, identified in over 100 proteins, that is thought to be involved in polynucleotide-binding, including DNA, RNA and single-stranded DNA. In this work the 3D structure of the R3H domain from human Smubp-2 was determined by NMR spectroscopy. It is the first 3D structure determination of an R3H domain. The fold presents a small motif, consisting of a three-stranded antiparallel beta-sheet and two alpha-helices, which is related to the structures of the YhhP protein and the C-terminal domain of the translational initiation factor IF3. The similarities are non-trivial, as the amino acid identities are below 10%. Three conserved basic residues cluster on the same face of the R3H domain and could play a role in nucleic acid recognition. An extended hydrophobic area at a different site of the molecular surface could act as a protein-binding site. A strong correlation between conservation of hydrophobic amino acids and side-chain solvent protection indicates that the structure of the Smubp-2 R3H domain is representative of R3H domains in general.     

Structural implication for receptor oligomerization from functional reconstitution studies of mutant V2 vasopressin receptors

Previous studies have established that G-protein-coupled receptors (GPCRs) are composed of independent folding domains. Based on this findings we attempted to rescue the function of clinically relevant missense mutations (R137H, S167L, and R181C) within the N-terminal domain of the V2 vasopressin receptor (V2-R), by coexpressing mutated full-length (Y280C) and C-terminally truncated (E242X) receptor constructs in COS-7 cells. Coimmunoprecipitation and enzyme-linked immunosorbent assay studies demonstrated a specific association of E242X with full-length V2-Rs even in the presence of missense mutations. Systematic analysis of the structural requirements for the observed receptor/fragment association showed that N-terminal fragments containing at least transmembrane regions 1-3 interact with the full-length V2-R. Despite this specific interaction, no functional reconstitution was achieved for mutant V2-Rs following coexpression with E242X and Y280C. However, functional activity of R137H and R181C upon coexpression with E242X was regained by mutational disruption of the extracellular disulfide bond, which is highly conserved among GPCRs. Our data with the V2-R are consistent with a structural model in which class I GPCRs form contact oligomers by lateral interaction rather than by a domain-swapping mechanism.