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Q I was with my friend when I spotted this really hot guy. He spotted my friend. After that, they flirted day in and day out. But when he asked her out, she said no. Then he and I flirted. We made out once, and then he started calling me. But after I started calling him, he wanted nothing to do with me. He won't even talk to me online. The worst part is, we go to the same temple. What should I do?

Taylor, who earned national recognition as a finalist on \"Dancing With the Stars,\" would have been an intriguing option for a Bears team in dire need of an improved pass rush.

This book presents an economic survey of international capital mobility from the late nineteenth century to the present. The authors examine the theory and empirical evidence surrounding the fall and rise of integration in the world market. A discussion of institutional developments focuses on capital controls and the pursuit of macroeconomic policy objectives in shifting monetary regimes. The Great Depression emerges as the key turning point in recent history of international capital markets, and offers important insights for contemporary policy debates. Its principal legacy is that the return to a world of global capital is marked by great unevenness in outcomes regarding both risks and rewards of capital market integration. More than in the past, foreign investment flows largely from rich countries to other rich countries. Yet most financial crises afflict developing countries, with costs for everyone.

Black is Beautiful identifies and explores the most significant philosophical issues that emerge from the aesthetic dimensions of black life, providing a long-overdue synthesis and the first extended philosophical treatment of this crucial subject. * The first extended philosophical treatment of an important subject that has been almost entirely neglected by philosophical aesthetics and philosophy of art * Takes an important step in assembling black aesthetics as an object of philosophical study * Unites two areas of scholarship for the first time – philosophical aesthetics and black cultural theory, dissolving the dilemma of either studying philosophy, or studying black expressive culture * Brings a wide range of fields into conversation with one another– from visual culture studies and art history to analytic philosophy to musicology – producing mutually illuminating approaches  that challenge some of the basic suppositions of each * Well-balanced, up-to-date, and beautifully written as well as inventive and insightful * Winner of The American Society of Aesthetics Outstanding Monograph Prize 2017

The mechanisms regulating community composition and local dominance of trees in species-rich forests are poorly resolved, but the importance of interactions with soil microbes is increasingly acknowledged. Here, we show that tree seedlings that interact via root-associated fungal hyphae with soils beneath neighbouring adult trees grow faster and have greater survival than seedlings that are isolated from external fungal mycelia, but these effects are observed for species possessing ectomycorrhizas (ECM) and not arbuscular mycorrhizal (AM) fungi. Moreover, survival of naturally-regenerating AM seedlings over ten years is negatively related to the density of surrounding conspecific plants, while survival of ECM tree seedlings displays positive density dependence over this interval, and AM seedling roots contain greater abundance of pathogenic fungi than roots of ECM seedlings. Our findings show that neighbourhood interactions mediated by beneficial and pathogenic soil fungi regulate plant demography and community structure in hyperdiverse forests. Associations with mycorrhizal fungi can affect the outcome of plant competition in complex ways. Here the authors use a decade-long field survey and two hyphal exclusion experiments to reveal a critical role of underground fungal networks in facilitating seedling growth and fitness of ectomycorrhizal plants but not arbuscular mycorrhizal plants.

Flapping flight is the most energetically demanding form of sustained forwards locomotion that vertebrates perform. Flock dynamics therefore have significant implications for energy expenditure. Despite this, no studies have quantified the biomechanical consequences of flying in a cluster flock or pair relative to flying solo. Here, we compared the flight characteristics of homing pigeons (Columba livia) flying solo and in pairs released from a site 7 km from home, using high-precision 5 Hz global positioning system (GPS) and 200 Hz tri-axial accelerometer bio-loggers. As expected, paired individuals benefitted from improved homing route accuracy, which reduced flight distance by 7% and time by 9%. However, realising these navigational gains involved substantial changes in flight kinematics and energetics. Both individuals in a pair increased their wingbeat frequency by 18% by decreasing the duration of their upstroke. This sharp increase in wingbeat frequency caused just a 3% increase in airspeed but reduced the oscillatory displacement of the body by 22%, which we hypothesise relates to an increased requirement for visual stability and manoeuvrability when flying in a flock or pair. The combination of the increase in airspeed and a higher wingbeat frequency would result in a minimum 2.2% increase in the total aerodynamic power requirements if the wingbeats were fully optimised. Overall, the enhanced navigational performance will offset any additional energetic costs as long as the metabolic power requirements are not increased above 9%. Our results demonstrate that the increases in wingbeat frequency when flying together have previously been underestimated by an order of magnitude and force reinterpretation of their mechanistic origin. We show that, for pigeons flying in pairs, two heads are better than one but keeping a steady head necessitates energetically costly kinematics.

ABCG2 is a constitutively expressed ATP-binding cassette (ABC) transporter that protects many tissues against xenobiotic molecules. Its activity affects the pharmacokinetics of commonly used drugs and limits the delivery of therapeutics into tumour cells, thus contributing to multidrug resistance. Here we present the structure of human ABCG2 determined by cryo-electron microscopy, providing the first high-resolution insight into a human multidrug transporter. We visualize ABCG2 in complex with two antigen-binding fragments of the human-specific, inhibitory antibody 5D3 that recognizes extracellular loops of the transporter. We observe two cholesterol molecules bound in the multidrug-binding pocket that is located in a central, hydrophobic, inward-facing translocation pathway between the transmembrane domains. Combined with functional in vitro analyses, our results suggest a multidrug recognition and transport mechanism of ABCG2, rationalize disease-causing single nucleotide polymorphisms and the allosteric inhibition by the 5D3 antibody, and provide the structural basis of cholesterol recognition by other G-subfamily ABC transporters. The structure of human ABCG2 bound to an inhibitory antibody using cryo-electron microscopy, representing the first high-resolution structural data of a human multidrug transporter. Structure of a human multi-drug transporter ABCG2 is an ATP-binding cassette (ABC) transporter sometimes referred to as the breast cancer resistance protein. It is a multi-drug transporter that protects many tissues from foreign molecules and as such it has a key role in the effectiveness of commonly used oral drugs. It is also important in cancer treatments for the potential exploitation of the delivery of therapeutics to tumour cells. Here the authors present the structure of human ABCG2 bound to an inhibitory antibody, obtained using cryo-electron microscopy. This represents the first high-resolution structural data of a human multi-drug transporter. Two cholesterol molecules are bound to the multidrug binding pocket between the transmembrane domains, providing key information on substrate recognition by other ABC transporters.

ABCG2 is a transporter protein of the ATP-binding-cassette (ABC) family that is expressed in the plasma membrane in cells of various tissues and tissue barriers, including the blood–brain, blood–testis and maternal–fetal barriers 1 – 4 . Powered by ATP, it translocates endogenous substrates, affects the pharmacokinetics of many drugs and protects against a wide array of xenobiotics, including anti-cancer drugs 5 – 12 . Previous studies have revealed the architecture of ABCG2 and the structural basis of its inhibition by small molecules and antibodies 13 , 14 . However, the mechanisms of substrate recognition and ATP-driven transport are unknown. Here we present high-resolution cryo-electron microscopy (cryo-EM) structures of human ABCG2 in a substrate-bound pre-translocation state and an ATP-bound post-translocation state. For both structures, we used a mutant containing a glutamine replacing the catalytic glutamate (ABCG2 EQ ), which resulted in reduced ATPase and transport rates and facilitated conformational trapping for structural studies. In the substrate-bound state, a single molecule of estrone-3-sulfate (E 1 S) is bound in a central, hydrophobic and cytoplasm-facing cavity about halfway across the membrane. Only one molecule of E 1 S can bind in the observed binding mode. In the ATP-bound state, the substrate-binding cavity has collapsed while an external cavity has opened to the extracellular side of the membrane. The ATP-induced conformational changes include rigid-body shifts of the transmembrane domains, pivoting of the nucleotide-binding domains (NBDs), and a change in the relative orientation of the NBD subdomains. Mutagenesis and in vitro characterization of transport and ATPase activities demonstrate the roles of specific residues in substrate recognition, including a leucine residue that forms a ‘plug’ between the two cavities. Our results show how ABCG2 harnesses the energy of ATP binding to extrude E 1 S and other substrates, and suggest that the size and binding affinity of compounds are important for distinguishing substrates from inhibitors. Cryo-electron microscopy structures of the ABCG2 protein in ATP- and substrate-bound states reveal the location of substrate binding, conformational changes required for substrate translocation and how inhibitors might be distinguished from substrates.