Amino acids stimulate cholecystokinin release through the Ca2+-sensing receptor.

Cholecystokinin (CCK) is produced by discrete endocrine cells in the proximal small intestine and is released following the ingestion of food. CCK is the primary hormone responsible for gallbladder contraction and has potent effects on pancreatic secretion, gastric emptying, and satiety. In addition to fats, digested proteins and aromatic amino acids are major stimulants of CCK release. However, the cellular mechanism by which amino acids affect CCK secretion is unknown. The Ca(2+)-sensing receptor (CaSR) that was originally identified on parathyroid cells is not only sensitive to extracellular Ca(2+) but is activated by extracellular aromatic amino acids. It has been postulated that this receptor may be involved in gastrointestinal hormone secretion. Using transgenic mice expressing a CCK promoter driven/enhanced green fluorescent protein (GFP) transgene, we have been able to identify and purify viable intestinal CCK cells. Intestinal mucosal CCK cells were enriched >200-fold by fluorescence-activated cell sorting. These cells were then used for real-time PCR identification of CaSR. Immunohistochemical staining with an antibody specific for CaSR confirmed colocalization of CaSR to CCK cells. In isolated CCK cells loaded with a Ca(2+)-sensitive dye, the amino acids phenylalanine and tryptophan, but not nonaromatic amino acids, caused an increase in intracellular Ca(2+) ([Ca(2+)](i)). The increase in [Ca(2+)](i) was blocked by the CaSR inhibitor Calhex 231. Phenylalanine and tryptophan stimulated CCK release from intestinal CCK cells, and this stimulation was also blocked by CaSR inhibition. Electrophysiological recordings from isolated CCK-GFP cells revealed these cells to possess a predominant outwardly rectifying potassium current. Administration of phenylalanine inhibited basal K(+) channel activity and caused CCK cell depolarization, consistent with changes necessary for hormone secretion. These findings indicate that amino acids have a direct effect on CCK cells to stimulate CCK release by activating CaSR and suggest that CaSR is the physiological mechanism through which amino acids regulate CCK secretion.

Plasma Donors in the Southwestern United States Positively Contribute to the Diverse Therapeutic Antibody Profile of Immune Globulin Products.

Human-plasma-derived immune globulin (IG) is used in augmentation therapy to provide protective levels of antibodies to patients with primary immune deficiency diseases (PIDD) and for prophylaxis against infectious diseases. To maintain the breadth of antibodies necessary for clinical protection, it is important to understand regional patterns of antibody seroprevalence in source plasma from which IG products are manufactured. In this study, source plasma from donation centers in various locations of the Southwestern quarter of the United States was surveyed for antibody titers to hepatitis A virus (HAV), measles virus (MeV), and cytomegalovirus (CMV). A broad range of anti-HAV Ig plasma titers was observed among these centers, with some centers exhibiting 3-5 times the titers of the others. Minor to no differences were observed for levels of anti-MeV and anti-CMV, respectively. Importantly, elevated anti-HAV Ig titers were broadly observed across plasma units obtained from the centers exhibiting high titers, indicative of a potential regional phenomenon among donors as opposed to few donors with singularly high titers. Plasma from these high-titer centers conferred significantly greater neutralization against HAV in vitro. The outcomes of this study give a glimpse of the antibody diversity inherent in human plasma used to manufacture IG products..

Preferred RNA binding sites for a threading intercalator revealed by in vitro evolution.

In pursuit of small molecules capable of controlling the function of RNA targets, we have explored the RNA binding properties of peptide-acridine conjugates (PACs). In vitro evolution (SELEX) was used to isolate RNAs capable of binding the PAC Ser-Val-Acr-Arg, where Acr is an acridine amino acid. The PAC binds RNA aptamers selectively and with a high degree of discrimination over DNA. PAC binding sites contain the base-paired 5'-CpG-3' sequence, a known acridine intercalation site. However, RNA structure flanking this sequence causes binding affinities to vary over 30-fold. The preferred site (K(D) = 20 nM) contains a base-paired 5'-CpG-3' step flanked on the 5' side by a 4 nt internal loop and the 3' side by a bulged U. Several viral 5'- and 3'-UTR RNA sequences that likely form binding sites for this PAC are identified.

Peptide quinoline conjugates: a new class of RNA-binding molecules.

[reaction: see text] A synthesis of 4,8-disubstituted 2-phenylquinoline amino acids is reported with the incorporation of one example into a peptide by solid-phase synthesis. The phenylquinoline-containing peptide binds an RNA target with nanomolar affinity (K(D) = 208 nM). The strategy can be used to prepare a variety of 2-substituted quinoline amino acids for alteration of affinity in intercalator peptides. Since quinolones represent an important class of antibacterials, these compounds may be useful in the discovery of new antibacterial agents.

Functional domain organization of human APOBEC3G.

Human APOBEC3 proteins exist in two forms containing either a single cytidine deaminase domain (CDA) or two CDAs. Strikingly, the proteins that are capable of effectively inhibiting the infectivity of Vif-deficient HIV-1 (HIV-1DeltaVif), such as APOBEC3G (A3G), contain two CDAs. In contrast, single-domain APOBEC3 proteins such as APOBEC3A (A3A) are weak inhibitors of HIV-1DeltaVif, even though A3A is an active cytidine deaminase and a potent inhibitor of retrotransposon mobility. Here, we demonstrate that the ability to bind to Gag and package into HIV-1 virions is entirely contained within the amino-terminal half of A3G. By changing three adjacent amino acids in A3A, to the sequence found in the N-terminal half of A3G, we were able to confer on A3A the ability to be efficiently incorporated into HIV-1 virions and to bind HIV-1 Gag. Nevertheless, this A3A mutant remained a weak inhibitor of HIV-1 infectivity, suggesting that segregation of the Gag-binding/virion incorporation and cytidine deaminase/virus-inhibition activities of APOBEC3 proteins into two tandem CDA regions promotes the efficient inhibition of retrovirus infectivity by APOBEC3 proteins.

RNA binding and thiolytic stability of a quinoline-containing helix-threading peptide.

Helix-threading peptides (HTPs) bind selectively to sites predisposed to intercalation in folded RNA molecules placing peptide functional groups into the dissimilar grooves of the duplex. Here we report the design and synthesis of new HTPs with quinoline as the intercalation domain. A quinoline-containing HTP is shown to bind selectively to duplex RNA binding sites. Furthermore, the affinity cleavage pattern generated using an EDTA.Fe modified derivative is consistent with minor groove localization of its N-terminus. This compound binds base-pair steps flanked by single nucleotide bulges on the 3' side on both strands, whereas bulges on the 5' side of the intercalation site do not support binding. Furthermore, unlike acridine HTPs, the quinoline compound is resistant to thiolytic degradation that leads to loss of RNA-binding activity. The RNA-binding selectivity and stability observed for quinoline-containing HTPs make them excellent candidates for further development as regulators of intracellular RNA function.

Binding of helix-threading peptides to E. coli 16S ribosomal RNA and inhibition of the S15-16S complex.

Helix-threading peptides (HTPs) constitute a new class of small molecules that bind selectively to duplex RNA structures adjacent to helix defects and project peptide functionality into the dissimilar duplex grooves. To further explore and develop the capabilities of the HTP design for binding RNA selectively, we identified helix 22 of the prokaryotic ribosomal RNA 16S as a target. This helix is a component of the binding site for the ribosomal protein S15. In addition, the S15-16S RNA interaction is important for the ordered assembly of the bacterial ribosome. Here we present the synthesis and characterization of helix-threading peptides that bind selectively to helix 22 of E. coli 16S RNA. These compounds bind helix 22 by threading intercalation placing the N termini in the minor groove and the C termini in the major groove. Binding is dependent on the presence of a highly conserved purine-rich internal loop in the RNA, whereas removal of the loop minimally affects binding of the classical intercalators ethidium bromide and methidiumpropyl-EDTAFe (MPEFe). Moreover, binding selectivity translates into selective inhibition of formation of the S15-16S complex.

Recognition of duplex RNA by helix-threading peptides.

Many important biological processes, from the interferon antiviral response to the generation of microRNA regulators of translation, involve duplex RNA. Small molecules capable of binding duplex RNA structures with high affinity and selectivity will be useful in regulating these processes and, as such, are valuable research tools and potentially therapeutic. In this paper, the synthesis and duplex RNA-binding properties of EDTA.Fe-modified peptide-intercalator conjugates (PICs) are described. Peptide appendages at the 4- and 9-positions of the planar acridine ring system render these PICs threading intercalators, directing the substituents into both grooves of double helical RNA simultaneously. Directed hydroxyl radical cleavage experiments conducted with varying RNA stem-loop structures indicate a preferred binding polarity with the N- and C-termini of the PIC in the minor and major grooves, respectively. However, this binding polarity is shown to be dependent on both the structure of the PIC and the RNA secondary structure adjacent to the intercalation site. Definition of the minimal RNA structure required for binding to one of these PICs led to the identification of an intercalation site in a pre-microRNA from Caenorhabditis elegans. Results presented will guide both rational design and combinatorial approaches for the generation of new RNA binding PICs and will continue to facilitate the identification of naturally occurring RNA targets for these small molecules.