Human Disease-causing Mutations Disrupt an N-C-terminal Interaction and Channel Function of Bestrophin 1

Mutations in the human bestrophin 1 (hBest1) chloride channel cause Best vitelliform macular dystrophy. Although mutations in its transmembrane domains were found to alter biophysical properties of the channel, the mechanism for disease-causing mutations in its N and C termini remains elusive. We hypothesized that these mutations lead to channel dysfunction through disruption of an N-C-terminal interaction. Here, we present data demonstrating that hBest1 N and C termini indeed interact both in vivo and in vitro. In addition, using a spectrum-based fluorescence resonance energy transfer method, we showed that functional hBest1 channels in the plasma membrane were multimers. Disease-causing mutations in the N terminus (R19C, R25C, and K30C) and the C terminus (G299E, D301N, and D312N) caused channel dysfunction and disruption of the N-C interaction. Consistent with the functional and biochemical results, mutants D301N and D312N clearly reduced fluorescence resonance energy transfer signal, indicating that the N-C interaction was indeed perturbed. These results suggest that hBest1 functions as a multimer in the plasma membrane, and disruption of the N-C interaction by mutations leads to hBest1 channel dysfunction.Extensive evidence has shown that bestrophins are anion channels when expressed heterologously in cell lines (1–9) and represent a type of endogenous calcium-activated chlorine channel in several cell types (10–12). Mutations disrupting hBest1 channel function lead to Best vitelliform macular dystrophy (Best disease) (13). Bestrophin 1 channels have been reported to exist as oligomers (2, 14). Results from immunoprecipitation experiments suggested that hBest1 exists as tetramers or pentamers when expressed heterologously (2), whereas a hydrodynamic study based on the calculations of the molecular mass of the Best1-detergent complex concluded that native porcine Best1 channels are dimers (14). Besides the uncertainty about the subunit stoichiometry, it is still unclear how bestrophin subunits assemble and interact in functional channels.Understanding how disease-causing mutations might adversely affect the assembly and interaction of bestrophin subunits is important for elucidating the molecular mechanism underlying the Best disease. The hBest1 protein contains six transmembrane domains (TMD1–6) with intracellularly located N and C termini. There are three “hot spots” of disease-causing mutations in hBest1: the N-terminal region, TMD2, and the C terminus proximal to TMD6 (13, 15). Multiple lines of evidence support that mutations in TMD2 alter the biophysical properties of the channel (3, 4, 7). How mutations distributed around the N- and C-terminal regions cause Best disease is less clear, although strong evidence recently suggested that certain mutations in the C terminus disrupt hBest1 channel gating by Ca²⁺ (16). N-C-terminal interaction of multimeric channels has been demonstrated to be involved in the activation of many channel types including inward rectifier K⁺ channels (17) and cyclic nucleotide-gated channels (18–20). In the present study we tested the hypothesis that an interaction between the N and C termini plays an important role in normal hBest1 channel function, and weakening or disruption of this interaction by mutations leads to channel dysfunction.To test our hypothesis, we introduced disease-causing mutations into the N- or C-terminal regions of hBest1 expressed in HEK293 cells and tested the effects of mutations on subunit interaction and channel function with a combination of electrophysiological, biochemical, and optical methods. We found that these mutations not only disrupted channel function but also caused N- and C-terminal dissociation both in vitro and in vivo. The findings suggest a novel molecular mechanism for the mutations in hBest1 to cause human Best disease.     

Characterization of mesenchymal stem cells (MSCs) from human fetal lung: Potential differentiation of germ cells

Pluripotent mesenchymal stem-like cell lines were established from lungs of 3–4 months old aborted fetus. The cells present the high ex vivo expansion potential of MSC, a typical fibroblast-like morphology and proliferate up to 15 passages without displaying clear changes in morphology. Immunological localization and flow cytometry analyses showed that these cells are positive for OCT4, c-Kit, CD11, CD29, CD44, telomerase, CD106, CD105, CD166, and SSEA1, weakly expression or negative for SSEA1, SSEA3, SSEA4, CD34, CD105 and CD106. These cells can give rise to the adipogenic as evidenced by accumulation of lipid-rich vacuoles within cells identified by Oil-red O when they were induced with 0.5 mM isobutylmethylxanthine, 200 μM indomethacin, 10⁻⁶ M dexamethasone, and 10 μg/ml of insulin in high-glucose DMEM. Osteogenic lineage cells were generated in 0.1 μM dexamethasone, 50 μg/ml ascorbic acid, 10 mM β-glycerophosphate, which are shaped as the osteoblastic morphology, expression of alkaline phosphatase (AP), and the formation of a mineralized extracellular matrix identified by Alizarin Red staining. Neural cells are observed when the cultures were induced with 2-mercapometal, which are positive for nestin, NF-100, MBP and GFAP. Additionally, embryoid bodies (EBs) and sperm like cells are obtained in vitro differentiation of these lung MSCs induced with 10⁻⁵ M retinoic acid (RA). These results demonstrated that these MSCs are pluripotent and may provide an in vitro model to study germ-cell formation and also as a potential source of sperms for male infertility.     

Dietary fatty acid intake affects the risk of developing bone marrow lesions in healthy middle-aged adults without clinical knee osteoarthritis: a prospective cohort study

Introduction  

Fatty acids have been implicated in osteoarthritis (OA), yet the mechanism by which fatty acids affect knee structure and consequently the risk of knee OA has not been fully elucidated. Higher intakes of fatty acids have been shown to be associated with the risk of bone marrow lesions (BMLs) in a healthy population. The aim of this study was to examine the association between fatty acid consumption and the incidence of BMLs in healthy middle-aged adults without clinical knee OA.     

Effects of hydrophobicity and anions on self‐assembly of the peptide EMK16‐II

Effects of hydrophobic and electrostatic interactions on the self‐assembling process of the ionic‐complementary peptide EMK16‐II are investigated by atomic force microscopy imaging, circular dichroism spectra, light scattering, and chromatography. It is found that the hydrophobicity of the peptide promotes the aggregation in pure water even at a very low concentration, resulting in a much lower critical aggregation concentration than that of another peptide, EAK16‐II. The effect of anions in solution with different valences on electrostatic interactions is also important. Monovalent anions (Cl^? and Ac^?) with a proper concentration can facilitate the formation of peptide fibrils, with Cl^? of smaller size being more effective than Ac^? of larger size. However, only small amounts of fibrils, but plenty of large amorphous aggregates, are found when the peptide solution is incubated with multivalent anions, such as SO, C₆H₅O, and HPO. More importantly, by gel filtration chromatography, the citrate anion, which induces a similar effect on the self‐assembling process of EMK16‐II as that of SO and HPO, can interact with two or more positively charged residues of the peptide and reside in the amorphous aggregates. This implies a “salt bridge” effect of multivalent anions on the peptide self‐assembling process, which can interpret a previous puzzle why divalent cations inhibit the formation of ordered nanofibrils of the ionic‐complementary peptides. Thus, our results clarify the important effects of hydrophobic and electrostatic interactions on the self‐assembling process of the ionic‐complementary peptides. These are greatly helpful for us to understand the mechanism of peptides' self‐assembling process and protein folding and aggregation. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 318–329, 2010. This article was originally published online as an acceptedpreprint. The “Published Online” date corresponds to the preprintversion. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

N-terminal PH domain and C-terminal auto-inhibitory region of CKIP-1 coordinate to determine its nucleus-plasma membrane shuttling

The pleckstrin homology (PH) domain-containing protein casein kinase 2 interacting protein-1 (CKIP-1) plays an important role in regulation of bone formation and muscle differentiation. How CKIP-1 localization is determined remains largely unclear. We observed that isolated CKIP-1-PH domain was predominantly localized in the nucleus and the C-terminus of CKIP-1 counteracted its nuclear localization. The net charge of basic residues and a serine-rich motif within the PH domain plays a pivotal role in the localization switch of both full-length CKIP-1 and the isolated PH domain. We propose that the N-terminal PH domain and C-terminal auto-inhibitory region of CKIP-1 coordinate to determine its subcellular localization and the nucleus-plasma membrane shuttling.     

AZI基因被捕获的鉴定实验

目的 确立基因捕获细胞中被捕获的基因名称. 方法 Southern印迹确定合适的限制性内切酶,用质粒拯救（plasmid rescue）获得含有细胞染色体DNA的质粒,测序.结果 本次实验中,被捕获载体整合的基因是AZI基因. 结论质粒拯救方法能确立质粒整合细胞染色体上准确的位置.     

甘肃陇东旱塬不同树龄苹果园矿质氮的分布和积累特征

对甘肃陇东地区不同树龄苹果园土壤矿质氮的分布和积累特征进行了研究.结果表明：土壤铵态氮含量随着苹果树龄的增大呈上升趋势,2～3年生、5年生、10年生、15年生、20年生、22年生果园0～120 cm土层铵态氮含量分别为3.3、5.8、6.5、9.1、12.1和15.3 mg·kg^-1;不同树龄果园0～60 cm土层铵态氮含量大于60～120 cm土层.不同树龄果园硝态氮含量在0～40 cm土层相对较低,随土层深度增加,其含量迅速增加;随着种植年限增加,不同苹果园硝态氮累积量也呈显著增加趋势,22年生果园0～120 cm土层硝态氮累积量达到2602.5 kg·hm^-2.旱塬苹果园表现为土壤铵态氮呈浅层积累、而硝态氮呈深层积累的特征.