犬传染性肝炎病毒Hexon蛋白Loop1、Loop2基因的克隆与表达

腺病毒主要的中和抗原表位位于六邻体蛋白Loop1、Loop2上,目前的研究主要集中在人腺病毒,犬传染性肝炎病毒（即犬腺病毒Ⅰ型）尚未见报道。本次研究参考Genebank发表的基因序列设计引物,提取ICHV基因组DNA,分别PCR扩增六邻体蛋白（Hexon）的Loop1、Loop2基因片段,用T4酶连接在一起,克隆入原核表达载体pET28a中,测序显示本室保存病毒分离株Loop1与CLL株、RI261株和TorontoA26/61株核苷酸序列同源性分别为100%、100%和83.8%;Loop2与CLL株、RI261株和TorontoA26/61株核苷酸序列同源性分别为88.1%、88.1%和99.3%,推导的氨基酸序列同源性分别为93.6%、93.6%和98.6%。转化BL21工程菌,实现了重组Loop蛋白在大肠杆菌中的高效表达,分子质量约为36kDa,并且利用镍柱纯化重组蛋白,纯度达95%以上。用重组蛋白免疫BALB/c小鼠后,以间接ELISA法测定血清抗病毒抗体效价达1：320以上,western blot鉴定免疫血清与ICHV特异性结合。本实验为建立新的犬传染性肝炎病毒基因工程产品奠定了良好的基础。     

犬传染性肝炎病毒Hexon蛋白Loop1、Loop2基因的克隆与表达

犬传染性肝炎病毒（ICHV）主要的中和抗原表位位于六邻体蛋白Loop1、Loop2上。本次研究参考Genebank发表的基因序列设计引物,提取ICHV基因组DNA,,分别PCR扩增六邻体蛋白（Hexon）的Loop1、Loop2基因片段,用T4酶连接在一起,克隆入原核表达载体pET28a中,测序显示本室保存病毒分离株Loop1与CLL株、RI261株和Toronto A26/61株核苷酸序列同源性分别为100%、100%和83.8%;Loop2与CLL株、RI261株和Toronto A26/61株核苷酸序列同源性分别为88.1%、88.1%和99.3%,推导的氨基酸序列同源性分别为93.6%、93.6%和98.6%。转化BL21工程菌,实现了重组Loop蛋白在大肠杆菌中的高效表达,其表达的重组蛋白以包涵体形式存在,分子量约为36kDa,并且利用镍柱纯化重组蛋白,纯度达95%以上。本实验为建立新的犬传染性肝炎病毒基因工程产品奠定了良好的基础。     

Loop C and the mechanism of acetylcholine receptor–channel gating

Agonist molecules at the two neuromuscular acetylcholine (ACh) receptor (AChR) transmitter-binding sites increase the probability of channel opening. In one hypothesis for AChR activation (“priming”), the capping of loop C at each binding site transfers energy independently to the distant gate over a discrete structural pathway. We used single-channel analyses to examine the experimental support for this proposal with regard to brief unliganded openings, the effects of loop-C modifications, the effects of mutations to residues either on or off the putative pathway, and state models for describing currents at low [ACh]. The results show that (a) diliganded and brief unliganded openings are generated by the same essential, global transition; (b) the radical manipulation of loop C does not prevent channel opening but impairs agonist binding; (c) both on- and off-pathway mutations alter gating by changing the relative stability of the open-channel conformation by local interactions rather than by perturbing a specific site–gate communication link; and (d) it is possible to estimate directly the rate constants for agonist dissociation from and association to both the low and high affinity forms of the AChR-binding site by using a cyclic kinetic model. We conclude that the mechanism of energy transfer between the binding sites and the gate remains an open question.     

Molecular Basis for the Structural Stability of an Enclosed β-Barrel Loop

We present molecular dynamics simulation studies of the structural stability of an enclosed loop in the β domain of the Escherichia coli O157:H7 autotransporter EspP. Our investigation revealed that, in addition to its excellent resistance to thermal perturbations, EspP loop 5 (L5) also has remarkable mechanical stability against pulling forces along the membrane norm. These findings are consistent with the experimental report that EspP L5 helps to maintain the permeability barrier in the outer membrane. In contrast to the major secondary structure elements of globular proteins such as ubiquitin, whose resistance to thermal and mechanical perturbations depends mainly on backbone hydrogen bonds and hydrophobic interactions, the structural stability of EspP L5 can be attributed mainly to geometric constraints and side-chain interactions dominated by hydrogen bonds. Examination of B-factors from available high-resolution structures of membrane-embedded β barrels indicates that most of the enclosed loops have stable structures. This finding suggests that loops stabilized by geometric constraints and side-chain interactions might be used more generally to restrict β-barrel channels for various functional purposes.     

Probing the Structural Role of an αβ Loop of Maltose-binding Protein by Mutagenesis: Heat-shock Induction by Loop Variants of the Maltose-binding Protein that Form Periplasmic Inclusion Bodies

The maltose-binding protein (MBP) ofEscherichia coliis the periplasmic receptor of the maltose transport system. Previous studies have identified amino acid substitutions in an α/β loop of the structure of MBP that are critical for thein vivofolding. To probe genetically the structural role of this surface loop, we generated a library in which the corresponding codons 32 and 33 ofmalEwere mutagenized. The maltose phenotype, which correlates with a biologically active structure of MBP in the periplasm, indicated a considerable variability in the loop residues compatible with a correctin vivofolding pathway of the protein. By the same genetic screens, we characterized loop-variant MBPs associated with a defective periplasmic folding pathway and aggregated into inclusion bodies. Heat-shock induction with production of misfolded loop variants was examined using bothlon-lacZandhtrA-lacZfusions. We found that the extent of formation of inclusion bodies in the periplasm ofE. coli, from misfolded loop variant MBPs, correlated with the level of heat-shock response regulated by the alternate heat-shock σ factor, σ²⁴.     

The EF Loop in Green Proteorhodopsin Affects Conformation and?Photocycle dynamics

The proteorhodopsin family consists of retinal proteins of marine bacterial origin with optical properties adjusted to their local environments. For green proteorhodopsin, a highly specific mutation in the EF loop, A178R, has been found to cause a surprisingly large redshift of 20 nm despite its distance from the chromophore. Here, we analyze structural and functional consequences of this EF loop mutation by time-resolved optical spectroscopy and solid-state NMR. We found that the primary photoreaction and the formation of the K-like photo intermediate is almost pH-independent and slower compared to the wild-type, whereas the decay of the K-intermediate is accelerated, suggesting structural changes within the counterion complex upon mutation. The photocycle is significantly elongated mainly due to an enlarged lifetime of late photo intermediates. Multidimensional MAS-NMR reveals mutation-induced chemical shift changes propagating from the EF loop to the chromophore binding pocket, whereas dynamic nuclear polarization-enhanced ¹³C-double quantum MAS-NMR has been used to probe directly the retinylidene conformation. Our data show a modified interaction network between chromophore, Schiff base, and counterion complex explaining the altered optical and kinetic properties. In particular, the mutation-induced distorted structure in the EF loop weakens interactions, which help reorienting helix F during the reprotonation step explaining the slower photocycle. These data lead to the conclusion that the EF loop plays an important role in proton uptake from the cytoplasm but our data also reveal a clear interaction pathway between the EF loop and retinal binding pocket, which might be an evolutionary conserved communication pathway in retinal proteins.     

Loop–loop interaction in an adenine-sensing riboswitch: A molecular dynamics study

Riboswitches are mRNA-based molecules capable of controlling the expression of genes. They undergo conformational changes upon ligand binding, and as a result, they inhibit or promote the expression of the associated gene. The close connection between structural rearrangement and function makes a detailed knowledge of the molecular interactions an important step to understand the riboswitch mechanism and efficiency. We have performed all-atom molecular dynamics simulations of the adenine-sensing add A-riboswitch to study the breaking of the kissing loop, one key tertiary element in the aptamer structure. We investigated the aptamer domain of the add A-riboswitch in complex with its cognate ligand and in the absence of the ligand. The opening of the hairpins was simulated using umbrella sampling using the distance between two loops as the reaction coordinate. A two-step process was observed in all the simulated systems. First, a general loss of stacking and hydrogen bond interactions is seen. The last interactions that break are the two base pairs G37-C61 and G38-C60, but the break does not affect the energy profile, indicating their pivotal role in the tertiary structure formation but not in the structure stabilization. The junction area is partially organized before the kissing loop formation and residue A24 anchors together the loop helices. Moreover, when the distance between the loops is increased, one of the hairpins showed more flexibility by changing its orientation in the structure, while the other conserved its coaxial arrangement with the rest of the structure.     

Mechanism of Chromosomal Boundary Action: Roadblock,Sink, or Loop?

Boundary elements or insulators subdivide eukaryotic chromosomes into a series of structurally and functionally autonomous domains. They ensure that the action of enhancers and silencers is restricted to the domain in which these regulatory elements reside. Three models, the roadblock, sink/decoy, and topological loop, have been proposed to explain the insulating activity of boundary elements. Strong predictions about how boundaries will function in different experimental contexts can be drawn from these models. In the studies reported here, we have designed assays that test these predictions. The results of our assays are inconsistent with the expectations of the roadblock and sink models. Instead, they support the topological loop model.     

The Circadian System of Ruin Lizards: A Seasonally Changing Neuroendocrine Loop?

Previous studies have shown that the amplitude of daily melatonin production in cultured ruin lizard pineal organs explanted in the summer is significantly higher than that from organs explanted in the winter. To test whether seasonal photoperiodic changes are decoded autonomously by the pineal gland, pineals explanted in summer were cultured in vitro and exposed to changes between winter and summer photoperiods. The changes in photoperiod duration did not affect the daily profiles of in vitro melatonin production. The discrepancy between the present in vitro results and those from lizards exposed to winter or summer photoperiods before pineal explantation supports the view that circadian information entering the pineal gland via its innervation is involved in determining seasonal changes of melatonin production in ruin lizards. We further examined whether a central component of the circadian system of ruin lizards, specifically the retinae of the lateral eyes, expresses similar seasonal changes in function as does the pineal gland. We did not find any difference between summer and autumn‐winter in the effectiveness of either bilateral retinalectomy or optic nerve lesion—at the level of the optic chiasm—in altering circadian locomotor behavior in constant conditions. Both surgical procedures mostly induced a shortening of the free‐running period of the locomotor rhythm of similar magnitude in all seasons. Thus, the retinae do not appear to participate in the seasonal reorganization of the circadian system in ruin lizards.     

The μ1 72-96 Loop Controls Conformational Transitions during Reovirus Cell Entry

The reovirus outer capsid protein μ1 forms a lattice surrounding the viral core. In the native state, μ1 determines the environmental stability of the viral capsid. Additionally, during cell entry, μ1 undergoes structural rearrangements that facilitate delivery of the viral cores across the membrane. To determine how the capsid-stabilizing functions of μ1 impinge on the capacity of μ1 to undergo conformational changes required for cell entry, we characterized viruses with mutations engineered at charged residues within the μ1 loop formed by residues 72 to 96 (72-96 loop). This loop is proposed to stabilize the capsid by mediating interactions between neighboring μ1 trimers and between trimers and the core. We found that mutations at Glu89 (E89) within this loop produced viruses with compromised efficiency for completing their replication cycle. ISVPs of E89 mutants converted to ISVP*s more readily than those of wild-type viruses. The E89 mutants yielded revertants with second-site substitutions within regions that mediate interaction between μ1 trimers at a site distinct from the 72-96 loop. These viruses also contained changes in regions that control interactions within μ1 trimers. Viruses containing these second-site changes displayed restored plaque phenotypes and were capable of undergoing ISVP-to-ISVP* conversion in a regulated manner. These findings highlight regions of μ1 that stabilize the reovirus capsid and demonstrate that an enhanced propensity to form ISVP*s in an unregulated manner compromises viral fitness.     

野牦牛（Bos grunniens mutus）mtDNA D\|Loop区的遗传多样性

为从分子水平上评价野牦牛(Bos grunniens mutus)的遗传多样性,对6头野牦公牛线粒体DNA D-loop 区全序列进行了克隆和测定(GenBank登录号为:FJ548840～FJ548845),结合GenBank中已刊登的2条野牦牛的相应序列,使用BioEdit 7 0 9、DnaSP 4.10.1、Arlequin 3.11等生物信息学软件,对全部8条序列开展了比对分析,确定了多态位点与单倍型数目,计算了核苷酸多样度和单倍型多样度.结果表明8条野牦牛线粒体DNA D-loop 区全序列长度在891～894 bp之间,其中A、T、G和C 4种核苷酸的平均含量分别为32.68%、28.65%、13.46%和25.21%,A+T的平均含量为61.33%.排除4处核苷酸的插入或缺失后,共检测到39处转换和颠换位点,占分析序列总长度的4.38%,其中包括4处单一多态位点和35处简约信息位点.依据序列间核苷酸变异共确定了7种单倍型,单倍型多样度(h)为0.9643,核苷酸多样度(π)为0.02144,提示野牦牛群体具有丰富的遗传多样性.     

Innate-Like Control of Human iNKT Cell Autoreactivity via the Hypervariable CDR3β Loop

Invariant Natural Killer T cells (iNKT) are a versatile lymphocyte subset with important roles in both host defense and immunological tolerance. They express a highly conserved TCR which mediates recognition of the non-polymorphic, lipid-binding molecule CD1d. The structure of human iNKT TCRs is unique in that only one of the six complementarity determining region (CDR) loops, CDR3β, is hypervariable. The role of this loop for iNKT biology has been controversial, and it is unresolved whether it contributes to iNKT TCR:CD1d binding or antigen selectivity. On the one hand, the CDR3β loop is dispensable for iNKT TCR binding to CD1d molecules presenting the xenobiotic alpha-galactosylceramide ligand KRN7000, which elicits a strong functional response from mouse and human iNKT cells. However, a role for CDR3β in the recognition of CD1d molecules presenting less potent ligands, such as self-lipids, is suggested by the clonal distribution of iNKT autoreactivity. We demonstrate that the human iNKT repertoire comprises subsets of greatly differing TCR affinity to CD1d, and that these differences relate to their autoreactive functions. These functionally different iNKT subsets segregate in their ability to bind CD1d-tetramers loaded with the partial agonist α-linked glycolipid antigen OCH and structurally different endogenous β-glycosylceramides. Using surface plasmon resonance with recombinant iNKT TCRs and different ligand-CD1d complexes, we demonstrate that the CDR3β sequence strongly impacts on the iNKT TCR affinity to CD1d, independent of the loaded CD1d ligand. Collectively our data reveal a crucial role for CDR3β for the function of human iNKT cells by tuning the overall affinity of the iNKT TCR to CD1d. This mechanism is relatively independent of the bound CD1d ligand and thus forms the basis of an inherent, CDR3β dependent functional hierarchy of human iNKT cells.     

CPC乙酰化酶底物结合区域Loop上脯氨酸对其催化特性的影响

低温CPC乙酰化酶在7-ACA的生物合成中具有重要作用和显著的优势,开发低温CPC乙酰化酶具有重大的经济价值。为了获得在低温下具有更高催化活性的CPC乙酰化酶,在前期的研究基础上,以先前获得的CA IIIM为亲本,借助分子对接的手段确定了它的底物结合区域,并利用py MOL软件找出了底物结合区域Loop上关键的脯氨酸残基,分析后将选定的脯氨酸用甘氨酸进行替换。借助p ET32a质粒在E.coli BL21(DE3)中进行了可溶性表达研究,除P272G外,其它突变体均实现了可溶性表达。P238G、P582G和P679G在13℃对CPC的催化活性分别为1.25、1.04和1.38U/mg,较亲本的0.85 U/mg有了显著的提高。此外,分别考察了亲本及突变体的温度稳定性,它们之间无明显的差异。然后,在13℃下进行了7-ACA低温生物合成的研究,结果表明反应24 h后CPC的转化率也能达到80%以上。由此可见在CPC乙酰化酶冷适应性改造方面取得了较为理想的结果,为进一步的改造及应用奠定了坚实的基础,也为其它低温酶的创制提供了可资借鉴的经验。     

删除Loop区域表面不稳定氨基酸提高 (R)-ω-转氨酶热稳定性

手性胺是一类具有重要价值的医药及精细化工中间体,如何实现手性胺类化合物的不对称合成是目前人们普遍关注的一个焦点问题。ω-转氨酶(ω-Transaminase,ω-TA)是一类能直接合成对映体手性胺的天然生物催化剂。相比于(S)-ω-TA,(R)-ω-TA的研究较少,但其需求量随着手性胺类药物的发展日趋增大。提高具有潜在应用价值的(R)-ω-TA的热稳定性,将有利于手性胺的制备。本文利用Py MOL软件和YASARA软件预测来源于土曲霉Aspergillus terreus的(R)-ω-TA中具有高温度因子(B-factor)的Loop区域,通过定点突变对Loop区域表面不稳定氨基酸逐步进行删除获得突变酶。结果表明,突变酶R131del和突变酶P132-E133del半失活温度分别为41.1℃和39.4℃,比野生酶提高了2.6℃和0.9℃;在40℃下的半衰期分别为15.0 min和10.0 min,为野生酶的2.2倍和1.5倍。此外,在400 K和10 ns的分子模拟条件下,突变酶R131del在Loop区域的均方根涨落(Root mean square fluctuation,RMSF)比野生型低,突变酶P132-E133del在Loop区域增加了4个氢键。本研究通过删除(R)-ω-转氨酶Loop区域表面不稳定氨基酸提高了该蛋白的热稳定性,同时也为其他酶热稳定性的理性设计提供了方法学指导。     

Role of the Actin Ala-108–Pro-112 Loop in Actin Polymerization and ATPase Activities

Actin plays fundamental roles in a variety of cell functions in eukaryotic cells. The polymerization-depolymerization cycle, between monomeric G-actin and fibrous F-actin, drives essential cell processes. Recently, we proposed the atomic model for the F-actin structure and found that actin was in the twisted form in the monomer and in the untwisted form in the filament. To understand how the polymerization process is regulated (Caspar, D. L. (1991) Curr. Biol. 1, 30–32), we need to know further details about the transition from the twisted to the untwisted form. For this purpose, we focused our attention on the Ala-108–Pro-112 loop, which must play crucial roles in the transition, and analyzed the consequences of the amino acid replacements on the polymerization process. As compared with the wild type, the polymerization of P109A was accelerated in both the nucleation and the elongation steps, and this was attributed to an increase in the frequency factor of the Arrhenius equation. The multiple conformations allowed by the substitution presumably resulted in the effective formation of the collision complex, thus accelerating polymerization. On the other hand, the A108G mutation reduced the rates of both nucleation and elongation due to an increase in the activation energy. In the cases of polymerization acceleration and deceleration, each functional aberration is attributed to a distinct elementary process. The rigidity of the loop, which mediates neither too strong nor too weak interactions between subdomains 1 and 3, might play crucial roles in actin polymerization.     

Protective Role of Commensals against Clostridium difficile Infection via an IL-1β-Mediated Positive-Feedback Loop

Clostridium difficile is a Gram-positive obligate anaerobic pathogen that causes pseudomembranous colitis in antibiotic-treated individuals. Commensal bacteria are known to have a significant role in the intestinal accumulation of C. difficile after antibiotic treatment, but little is known about how they affect host immunity during C. difficile infection. In this article, we report that C. difficile infection results in translocation of commensals across the intestinal epithelial barrier that is critical for neutrophil recruitment through the induction of an IL-1β-mediated positive-feedback loop. Mice lacking ASC, an essential mediator of IL-1β and IL-18 processing and secretion, were highly susceptible to C. difficile infection. ASC(-/-) mice exhibited enhanced translocation of commensals to multiple organs after C. difficile infection. Notably, ASC(-/-) mice exhibited impaired CXCL1 production and neutrophil influx into intestinal tissues in response to C. difficile infection. The impairment in neutrophil recruitment resulted in reduced production of IL-1β and CXCL1 but not IL-18. Importantly, translocated commensals were required for ASC/Nlrp3-dependent IL-1β secretion by neutrophils. Mice lacking IL-1β were deficient in inducing CXCL1 secretion, suggesting that IL-1β is the dominant inducer of ASC-mediated CXCL1 production during C. difficile infection. These results indicate that translocated commensals play a crucial role in CXCL1-dependent recruitment of neutrophils to the intestine through an IL-1β/NLRP3/ASC-mediated positive-feedback mechanism that is important for host survival and clearance of translocated commensals during C. difficile infection.     

Tetramerization and Cooperativity in Plasmodium falciparum Glutathione S-Transferase Are Mediated by Atypic Loop 113�C119

Glutathione S-transferase of Plasmodium falciparum (PfGST) displays a peculiar dimer to tetramer transition that causes full enzyme inactivation and loss of its ability to sequester parasitotoxic hemin. Furthermore, binding of hemin is modulated by a cooperative mechanism. Site-directed mutagenesis, steady-state kinetic experiments, and fluorescence anisotropy have been used to verify the possible involvement of loop 113–119 in the tetramerization process and in the cooperative phenomenon. This protein segment is one of the most prominent structural differences between PfGST and other GST isoenzymes. Our results demonstrate that truncation, increased rigidity, or even a simple point mutation of this loop causes a dramatic change in the tetramerization kinetics that becomes at least 100 times slower than in the native enzyme. All of the mutants tested have lost the positive cooperativity for hemin binding, suggesting that the integrity of this peculiar loop is essential for intersubunit communication. Interestingly, the tetramerization process of the native enzyme that occurs rapidly when GSH is removed is prevented not only by GSH but even by oxidized glutathione. This result suggests that protection by PfGST against hemin is independent of the redox status of the parasite cell. Because of the importance of this unique segment in the function/structure of PfGST, it could be a new target for the development of antimalarial drugs.Approximately two million deaths in the world per year are caused by Plasmodium falciparum, the parasite responsible for tropical malaria (1, 2). In the last years, increasing interest has been developing for the peculiar glutathione S-transferase (PfGST)³ expressed by this parasite. Expressed in almost all living organisms, GSTs represent a large superfamily of multifunctional detoxifying enzymes that are able to conjugate GSH to a lot of toxic electrophilic compounds, thus facilitating their excretion. Many other protection roles of GSTs have been described, including the enzymatic reduction of organic peroxides (3–5), the inactivation of the proapoptotic JNK through a GST·JNK complex (6), and the protection of the cell from excess nitric oxide (7). The mammalian cytosolic GSTs are dimeric proteins grouped into eight species-independent classes termed Alpha, Kappa, Mu, Omega, Pi, Sigma, Theta, and Zeta on the basis of sequence similarity, immunological reactivity, and substrate specificity (3, 8–11). PfGST is one of the most abundant proteins expressed by P. falciparum (from 1 to 10%, i.e. from 0.1 to 1 mm) (12), and different from what occurs in many organisms, it is the sole GST isoenzyme expressed by this parasite. Despite its structural similarity to the Mu class GST, this specific isoenzyme cannot be assigned to any known GST class (13). The interest in this enzyme is due to its particular protective role in the parasite. In fact, in addition to the usual GST activity that promotes the conjugation of GSH to electrophilic centers of toxic compounds, this protein efficiently binds hemin, and thus it could protect the parasite (that resides in the erythrocytes) from the parasitotoxic effect of this heme by-product (14). Specific compounds that selectively inhibit its catalytic activity or hemin binding could be promising candidates as antimalarial drugs. In this context, the discovery of structural or mechanistic properties of this enzyme that are not found in other GSTs may be important for designing selective inhibitors that are toxic to the parasite but harmless for the host cells. Two properties never observed in other members of the GST superfamily are of particular interest. The first property is that this enzyme, in the absence of GSH, is inactivated in a short time and loses its ability to bind hemin (15). Recent studies indicated that the inactivation process is related to a dimer to tetramer transition (13, 16, 17). The second property is the strong positive homotropic phenomenon that modulates the affinity of the two subunits for hemin (15). The x-ray crystal structure of PfGST, solved by two different groups (13, 18), provides insights into this effect. From a structural point of view, the most intriguing differences of PfGST when compared with other GSTs are a more solvent-exposed H-site and an atypic extra loop connecting helix α-4 and helix α-5 (residues 113–119; see also Fig. 1) that could be involved in the dimer-dimer interaction. Actually, in the absence of ligands, two biological dimers form a tetramer, and these homodimers are interlocked with each other by loop 113–119 of one homodimer, which occupies an H-site of the other homodimer (13, 18). Upon binding of S-hexylglutathione, loop 113–119 rearranges; residues Asn-114, Leu-115, and Phe-116 form an additional coil in helix α-4; and the side chains of Asn-111, Phe-116, and Tyr-211 flip into the H-site of the same dimer (17, 18). The changed course of residues 113–119 in the liganded enzyme prevents the interlocking of the dimers.Open in a separate windowFIGURE 1.A, structural changes of loop 113–119 occurring in the dimer (light blue model and yellow loop; Protein Data Bank code 2AAW) to tetramer (blue model and orange loop; Protein Data Bank code 1OKT) transition. Red spheres indicate the amino acids replaced in this study to obtain mutants A, B, and C. B, model of hemin·PfGST complex obtained by docking simulation using the crystal structure for Protein Data Bank code 1Q4J (15). Hemin is shown in red, loop 113–119 is in orange, and GSH is shown as yellow sticks.In this paper, by means of site-directed mutagenesis, fluorescence anisotropy, kinetic studies, and size exclusion chromatography, we check the influence of selected mutations of this atypic loop in the tetramerization process and the possible involvement of this protein segment in the cooperative phenomenon that characterizes hemin binding. In addition we describe that the tetramerization process is inhibited not only by GSH but even by GSSG. This finding suggests that hemin binding of PfGST is independent of the redox status of the cell. Finally, we demonstrate that the presence of GSH (or GSSG) in the active site is not essential for hemin binding, but this interaction only requires an active dimeric conformation.     

A Residue in Loop 9 of the ��2-Subunit Stabilizes the Closed State of the GABAA Receptor

In γ-aminobutyric acid type A (GABA_A) receptors, the structural elements that couple ligand binding to channel opening remain poorly defined. Here, site-directed mutagenesis was used to determine if Loop 9 on the non-GABA binding site interface of the β2-subunit may be involved in GABA_A receptor activation. Specifically, residues Gly¹⁷⁰-Gln¹⁸⁵ of the β2-subunit were mutated to alanine, co-expressed with wild-type α1- and γ2S-subunits in human embryonic kidney (HEK) 293 cells and assayed for their activation by GABA, the intravenous anesthetic propofol and the endogenous neurosteroid pregnanolone using whole cell macroscopic recordings. Three mutants, G170A, V175A, and G177A, produced 2.5-, 6.7-, and 5.6-fold increases in GABA EC₅₀ whereas one mutant, Q185A, produced a 5.2-fold decrease in GABA EC₅₀. None of the mutations affected the ability of propofol or pregnanolone to potentiate a submaximal GABA response, but the Q185A mutant exhibited 8.3- and 3.5-fold increases in the percent direct activation by propofol and pregnanolone, respectively. Mutant Q185A receptors also had an increased leak current that was sensitive to picrotoxin, indicating an increased gating efficiency. Further Q185E, Q185L, and Q185W substitutions revealed a strong correlation between the hydropathy of the amino acid at this position and the GABA EC₅₀. Taken together, these results indicate that β2 Loop 9 is involved in receptor activation by GABA, propofol, and pregnanolone and that β2(Q185) participates in hydrophilic interactions that are important for stabilizing the closed state of the GABA_A receptor.     

Cryptic Determinant of α4β7 Binding in the V2 Loop of HIV-1 gp120

The peptide segment of the second variable loop of HIV-1 spanning positions 166–181 harbors two functionally important sites. The first, spanning positions 179–181, engages the human α4β7 integrin receptor which is involved in T-cell gut-homing and may play a role in human immunodeficiency virus (HIV)-host cell interactions. The second, at positions 166–178, is a major target of anti-V2 antibodies elicited by the ALVAC/AIDSVAX vaccine used in the RV144 clinical trial. Notably, these two sites are directly adjacent, but do not overlap. Here, we report the identity of a second determinant of α4β7 binding located at positions 170–172 of the V2 loop. This segment – tripeptide QRV^170–172– is located within the second site, yet functionally affects the first site. The absence of this segment abrogates α4β7 binding in peptides bearing the same sequence from position 173–185 as the V2 loops of the RV144 vaccines. However, peptides exhibiting V2 loop sequences from heterologous HIV-1 strains that include this QRV^170–172 motif bind the α4β7 receptor on cells. Therefore, the peptide segment at positions 166–178 of the V2 loop of HIV-1 viruses appears to harbor a cryptic determinant of α4β7 binding. Prior studies show that the anti-V2 antibody response elicited by the RV144 vaccine, along with immune pressure inferred from a sieve analysis, is directed to this same region of the V2 loop. Accordingly, the anti-V2 antibodies that apparently reduced the risk of infection in the RV144 trial may have functioned by blocking α4β7-mediated HIV-host cell interactions via this cryptic determinant.