Annexin II is required for apical transport in polarized epithelial cells

The sorting of apical proteins comprises an initial recognition step in the trans Golgi network and a final partitioning of the apical pool of proteins into at least two different types of vesicular carriers. One criteria of these carriers is the association or non-association of the protein content with lipid rafts. We have previously characterized a population containing the raft-associated sucrase-isomaltase-carrying vesicles (SAVs) and another one, the non-raft-associated lactase-phlorizin hydrolase-carrrying vesicles (LAVs) that are targeted separately to the apical membrane. Here, we demonstrate biochemically and by employing confocal laser microscopy that the annexin II-S100A10 complex is a component of SAVs and is absent from LAVs. The unequivocal role of annexin II in the apical targeting of SI is clearly demonstrated when down-regulation of this protein by annexin II-specific small interfering RNA drastically decreases the apical delivery of SI in the epithelial cell line Madin-Darby canine kidney. The annexin II-S100A10 complex plays therefore a crucial role in routing SAVs to the apical membrane of epithelial cells.     

Cooperative binding promotes demand-driven recruitment of AnxA8 to cholesterol-containing membranes

The functionality of cellular membranes is critically determined by their lipid composition. Within the endolysosomal system, cholesterol is mainly found in more peripheral compartments. In contrast, cholesterol levels are low in late endosomes/lysosomes (LEL), and the occurrence of enlarged pools of this lipid is commonly linked to endolysosomal dysfunction. Here, we show that Annexin A8 (AnxA8), a member of the annexin family of Ca^2 +-dependent membrane-binding proteins, participates in the endosomal regulation of cholesterol homeostasis. Depletion of AnxA8 caused accumulation of cholesterol in LEL, and pharmacological inhibition of the LEL cholesterol export recruited AnxA8 to the cholesterol-laden LEL. Biophysical analysis revealed that cholesterol enhanced the Ca^2 +-dependent affinity of AnxA8 to lipid bilayers, and induced positive cooperativity of membrane binding. Our findings identify AnxA8 as a regulator of LEL cholesterol balance and point to altered membrane binding cooperativity induced by aberrant lipid composition in the target membrane as a means to control the demand-driven recruitment of this cytosolic regulatory protein.     

Conjugated estrogens in the endometrium during the estrous cycle in pigs

Estrogen metabolism results in the formation of inactive estrogen sulphates and glucuronides. Despite the lack of receptor binding, circulating conjugated estrogens might serve as a reservoir for the active form through the involvement of specific cleaving enzymes. In order to elucidate the potential role that estrogen conjugates play in the regulation of the estrous cycle, we determined the concentration of progesterone, estrogen and estrogen conjugates in serum and endometrial homogenates of cycling gilts. In addition, we determined the mRNA expression changes of enzymes (UDP glucuronosyltransferase (UGT), β-glucuronidase (GUSB), sulphotransferases (SULT) and steroid sulphatase (STS)) and transporters (multidrug resistance-associated protein (MRP), organic anion-transporting polypeptide (OATPs)) involved in the estrogen metabolism in the endometrium across the estrous cycle. GUSB displayed highest expression at estrous (day 0), decreasing expression during metestrus (day 3 and 6), minimal expression on day 10 and 12, and increasing expression towards proestrus (day 18), suggesting either a stimulation by estrogens or a negative impact of progesterone. The mRNA expression of the influx-transporter OATP1A2 significantly increased from day 0 to 6 and decreased again by day 10, while the efflux-transporters (MRP1, MRP2, and MDR1) displayed minimal expression at day 3 and 6. The mRNA expression of the UDP-glucuronsyltransferases followed a similar pattern, with minimal expression found at day 6. The analyses of the concentration of local and circulating steroid hormones points towards an interaction of the analyzed transporters and enzymes with steroid hormones, thereby possibly regulating the reservoir of active steroids contributing to the endometrial function.     

The influence of adrenergic nerves of the response of blood vessels in the rabbit ear to 2--phenylalanine-8-lysine vasopressin (Octapressin).

The blood vessels in the rabbit ear have been used to investigate the effects of octapressin on vascular smooth muscle. Continuous administration of this drug resulted in tachphlatis. Cocaine enhanced the response of the ear to octapressin; however, this potentiation was not evident when phentolamine was concurrently added to the perfusate. Denervation and reserpinisation of the ear also eliminated the potentiation of octapressin's response by cocaine. The results suggest that there is a small, indirect sympathomimetic component involved in octapressin's action on the vasculature.     

Importance of phospholipid bilayer integrity in the analysis of protein–lipid interactions

The integrity of supported phospholipid bilayer membranes is of crucial importance for the investigation of lipid–protein interactions. Therefore we recorded the formation of supported membranes on SiO₂ and mica by quartz crystal microbalance and controlled the integrity by atomic force microscopy. This study aims to analyze how membrane defects affect protein–lipid interactions. The experiments focused on a lipid mixture of POPC/DOPC/Chol/POPS/PI(4,5)P₂ (37:20:20:20:3) and the binding of the peripheral membrane associated protein annexin A2. We found that formation of a continuous undisturbed bilayer is an indispensable precondition for a reliable determination and quantification of lipid–protein-interactions. If membrane defects were present, protein adsorption causes membrane disruption and lipid detachment on a support thus leading to false determination of binding constants. Our results obtained for PI(4,5)P₂ and cholesterol containing supported membranes yield new knowledge to construct functional surfaces that may cover nanoporous substrates, form free standing membranes or may be used for lab-on-a-chip applications.     

Structural basis of the Ca(2+)-dependent association between S100C (S100A11) and its target, the N-terminal part of annexin I

Background: S100C (S100A11) is a member of the S100 calcium-binding protein family, the function of which is not yet entirely clear, but may include cytoskeleton assembly and dynamics. S100 proteins consist of two EF-hand calcium-binding motifs, connected by a flexible loop. Like several other members of the family, S100C forms a homodimer. A number of S100 proteins form complexes with annexins, another family of calcium-binding proteins that also bind to phospholipids. Structural studies have been undertaken to understand the basis of these interactions. Results: We have solved the crystal structure of a complex of calcium-loaded S100C with a synthetic peptide that corresponds to the first 14 residues of the annexin I N terminus at 2.3 A resolution. We find a stoichiometry of one peptide per S100C monomer, the entire complex structure consisting of two peptides per S100C dimer. Each peptide, however, interacts with both monomers of the S100C dimer. The two S100C molecules of the dimer are linked by a disulphide bridge. The structure is surprisingly close to that of the p11-annexin II N-terminal peptide complex solved previously. We have performed competition experiments to try to understand the specificity of the S100-annexin interaction. Conclusions: By solving the structure of a second annexin N terminus-S100 protein complex, we confirmed a novel mode of interaction of S100 proteins with their target peptides; there is a one-to-one stoichiometry, where the dimeric structure of the S100 protein is, nevertheless, essential for complex formation. Our structure can provide a model for a Ca(2+)-regulated annexin I-S100C heterotetramer, possibly involved in crosslinking membrane surfaces or organising membranes during certain fusion events.     

Cooperative adsorption of ezrin on PIP2-containing membranes

By means of the quartz crystal microbalance (QCM) and scanning force microscopy (SFM), the adsorption of ezrin, a member of the ezrin/radixin/moesin protein family, on l-alpha-phosphatidylinositol-4,5-bisphosphate (PIP(2)) containing solid-supported membranes was investigated. An increase in the PIP(2) content in 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) membranes resulted in an increased amount of bound ezrin strongly supporting the crucial role of PIP(2) for ezrin recruitment to membranes. No ezrin adsorption to membranes composed of pure POPC was detected. To characterize the binding process in more detail, the kinetics and reversibility of ezrin adsorption were investigated by the QCM technique, showing that the protein remains partly bound after rinsing with pure buffer, which we suspected to be a result of lateral interactions between the proteins. SFM images revealed the formation of two-dimensional ezrin clusters on PIP(2)-doped POPC membranes. Time-elapsed SFM images show that the growth of protein domains occurs from a few nucleation sites. The QCM data in conjunction with the results obtained by SFM led us to propose that the binding process of ezrin occurs in a positive cooperative manner. When lateral interactions of the proteins on the membrane were taken into account, we were able to simulate the kinetics obtained from time-resolved QCM readouts by employing a model developed by Minton. On the basis of the kinetic analysis, we were also able to reconstruct the adsorption isotherm.     

Gene–Environment Interactions at Nucleotide Resolution

Interactions among genes and the environment are a common source of phenotypic variation. To characterize the interplay between genetics and the environment at single nucleotide resolution, we quantified the genetic and environmental interactions of four quantitative trait nucleotides (QTN) that govern yeast sporulation efficiency. We first constructed a panel of strains that together carry all 32 possible combinations of the 4 QTN genotypes in 2 distinct genetic backgrounds. We then measured the sporulation efficiencies of these 32 strains across 8 controlled environments. This dataset shows that variation in sporulation efficiency is shaped largely by genetic and environmental interactions. We find clear examples of QTN:environment, QTN: background, and environment:background interactions. However, we find no QTN:QTN interactions that occur consistently across the entire dataset. Instead, interactions between QTN only occur under specific combinations of environment and genetic background. Thus, what might appear to be a QTN:QTN interaction in one background and environment becomes a more complex QTN:QTN:environment:background interaction when we consider the entire dataset as a whole. As a result, the phenotypic impact of a set of QTN alleles cannot be predicted from genotype alone. Our results instead demonstrate that the effects of QTN and their interactions are inextricably linked both to genetic background and to environmental variation.     

LaeA control of velvet family regulatory proteins for light-dependent development and fungal cell-type specificity

VeA is the founding member of the velvet superfamily of fungal regulatory proteins. This protein is involved in light response and coordinates sexual reproduction and secondary metabolism in Aspergillus nidulans. In the dark, VeA bridges VelB and LaeA to form the VelB-VeA-LaeA (velvet) complex. The VeA-like protein VelB is another developmental regulator, and LaeA has been known as global regulator of secondary metabolism. In this study, we show that VelB forms a second light-regulated developmental complex together with VosA, another member of the velvet family, which represses asexual development. LaeA plays a key role, not only in secondary metabolism, but also in directing formation of the VelB-VosA and VelB-VeA-LaeA complexes. LaeA controls VeA modification and protein levels and possesses additional developmental functions. The laeA null mutant results in constitutive sexual differentiation, indicating that LaeA plays a pivotal role in inhibiting sexual development in response to light. Moreover, the absence of LaeA results in the formation of significantly smaller fruiting bodies. This is due to the lack of a specific globose cell type (Hülle cells), which nurse the young fruiting body during development. This suggests that LaeA controls Hülle cells. In summary, LaeA plays a dynamic role in fungal morphological and chemical development, and it controls expression, interactions, and modification of the velvet regulators.