Tissue distribution and thyroid hormone regulation of Pept1 and Pept2 mRNA in rodents

Peptide transporters (Pept) have essential physiological functions and also transport various drugs. Information regarding tissue distribution and gene regulation of Pept in rodents is limited. The present study investigated the distribution of Pept1 and Pept2 mRNA in 19 tissues of male and female Sprague-Dawley rats and C57BL/6 mice, as well as thyroid hormone regulation of renal Pept expression in male rats, using the branched DNA signal amplification assay. Pept1 mRNA was not only highly expressed in small intestine, but also detectable in gonads of both species, kidney of rats, and large intestine of mice. Pept2 mRNA was the highest in kidney, followed by brain and lung. The present study offers the first evidence of considerable Pept2 mRNA expression in pituitary and reproductive organs (testis, prostate, ovary, and uterus). Interestingly, Pept2 mRNA expression in mouse prostate appeared to be much higher than that in rat prostate. Thyroidectomy increased Pept1 and Pept2 mRNA in male rat kidney; such increases were abolished by thyroid hormone replacement.     

Pathway of oxidative folding of secretory leucocyte protease inhibitor: an 8-disulfide protein exhibits a unique mechanism of folding

Secretory leucocyte protease inhibitor (SLPI) is a 107-amino acid protein with a high density of disulfide pairing (eight). The mechanism of oxidative folding of reduced and denatured SLPI has been investigated here. Despite an exceedingly large number of possible folding intermediates ( approximately 46 million disulfide isomers) and their potential to complicate the refolding process, oxidative folding of SLPI turns out to be surprisingly simple and efficient. Complete oxidative folding and a near-quantitative recovery of the native SLPI can be achieved in a simple buffer solution using air oxidation without any supplementing thiol catalyst or redox agent, a phenomenon that has not yet been observed with other disulfide proteins. Because of the heterogeneity and extensive overlapping of folding intermediates, identification of the predominant intermediate was unfeasible. Nonetheless, studies of reductive unfolding of native SLPI and oxidative folding of a six-disulfide variant of SLPI enable us to propose an underlying mechanism accounting for the unique folding efficiency of SLPI in the absence of a redox agent. Our studies indicate that oxidative folding of SLPI undergoes heterogeneous populations of one-, two-, three-, four-, five-, six-, and seven-disulfide isomers, including two nativelike isomers, SLPI-6A and SLPI-7A, as transient intermediates. Formation of the last two native disulfide bonds leading to the conversion of SLPI-6A --> SLPI-7A --> N-SLPI is relatively slow and represents the final stage of oxidative folding. Most importantly, free cysteines of SLPI-6A and SLPI-7A also act as a thiol catalyst in promoting the disulfide shuffling of diverse non-native intermediates accumulated along the folding pathway. This explains why a near-quantitative recovery of N-SLPI can be achieved in the absence of any thiol catalyst and redox agent. Properties of SLPI-6A and SLPI-7A were investigated and compared to those of other documented kinetic intermediates of oxidative folding. The correlation between the mechanism of SLPI folding and the three-dimensional structure of SLPI is also elaborated.     

Discovery of N-{[1-(propylsulfonyl)-4-pyridin-2-ylpiperidin-4-yl]methyl}benzamides as novel,selective and potent GlyT1 inhibitors

Employing an iterative analogue library approach, novel potent and selective glycine transporter 1 (GlyT1) inhibitors containing a 4-pyridin-2-ylpiperidine sulfonamide have been discovered. These inhibitors are devoid of time-dependent CYP inhibition activity and exhibit improved aqueous solubility versus the corresponding 4-phenylpiperidine analogues.     

Biomining with bacteriophage: selectivity of displayed peptides for naturally occurring sphalerite and chalcopyrite

During mineral processing, concentrates of sulfide minerals of economic interest are formed by froth flotation of fine ore particles. The method works well but recovery and selectivity can be poor for ores with complex mineralogy. There is considerable interest in methods that improve the selectivity of this process while avoiding the high costs of using flotation chemicals. Here we show the first application of phage biotechnology to the processing of economically important minerals in ore slurries. A random heptapeptide library was screened for peptide sequences that bind selectively to the minerals sphalerite (ZnS) and chalcopyrite (CuFeS2). After several rounds of enrichment, cloned phage containing the surface peptide loops KPLLMGS and QPKGPKQ bound specifically to sphalerite. Phage containing the peptide loop TPTTYKV bound to both sphalerite and chalcopyrite. By using an enzyme-linked immunosorbant assay (ELISA), the phage was characterized as strong binders compared to wild-type phage. Specificity of binding was confirmed by immunochemical visualization of phage bound to mineral particles but not to silica (a waste mineral) or pyrite. The current study focused primarily on the isolation of ZnS-specific phage that could be utilized in the separation of sphalerite from silica. At mining sites where sphalerite and chalcopyrite are not found together in natural ores, the separation of sphalerite from silica would be an appropriate enrichment step. At mining sites where sphalerite and chalcopyrite do occur together, more specific phage would be required. This bacteriophage has the potential to be used in a more selective method of mineral separation and to be the basis for advanced methods of mineral processing.     

Gdf6a is required for the initiation of dorsal–ventral retinal patterning and lens development

Dorsal–ventral patterning of the vertebrate retina is essential for accurate topographic mapping of retinal ganglion cell (RGC) axons to visual processing centers. Bone morphogenetic protein (Bmp) growth factors regulate dorsal retinal identity in vertebrate models, but the developmental timing of this signaling and the relative roles of individual Bmps remain unclear. In this study, we investigate the functions of two zebrafish Bmps, Gdf6a and Bmp4, during initiation of dorsal retinal identity, and subsequently during lens differentiation. Knockdown of zebrafish Gdf6a blocks initiation of retinal Smad phosphorylation and dorsal marker expression, while knockdown of Bmp4 produces no discernable retinal phenotype. These data, combined with analyses of embryos ectopically expressing Bmps, demonstrate that Gdf6a is necessary and sufficient for initiation of dorsal retinal identity. We note a profound expansion of ventral retinal identity in gdf6a morphants, demonstrating that dorsal BMP signaling antagonizes ventral marker expression. Finally, we demonstrate a role for Gdf6a in non-neural ocular tissues. Knockdown of Gdf6a leads to defects in lens-specific gene expression, and when combined with Bmp signaling inhibitors, disrupts lens fiber cell differentiation. Taken together, these data indicate that Gdf6a initiates dorsal retinal patterning independent of Bmp4, and regulates lens differentiation.     

Single‐molecule pair studies of the interactions of the α‐GalNAc (Tn‐antigen) form of porcine submaxillary mucin with soybean agglutinin

Mucins form a group of heavily O‐glycosylated biologically important glycoproteins that are involved in a variety of biological functions, including modulating immune response, inflammation, and adhesion. Mucins are also involved in cancer and metastasis and often express diagnostic cancer antigens. Recently, a modified porcine submaxillary mucin (Tn‐PSM) containing GalNAcα1‐O‐Ser/Thr residues was shown to bind to soybean agglutinin (SBA) with ～10⁶‐fold enhanced affinity relative to GalNAcα1‐O‐Ser, the pancarcinoma carbohydrate antigen. In this study, dynamic force spectroscopy is used to investigate molecular pairs of SBA and Tn‐PSM. A number of force jumps that demonstrate unbinding or rebinding events were observed up to a distance equal to 2.0 μm, consistent with the length of the mucin chain. The unbinding force increased from 103 to 402 pN with increasing force loading rate. The position of the activation barrier in the energy landscape of the interaction was 0.1 nm. The lifetime of the SBA–TnPSM complex in the absence of applied force was determined to be in the range 1.3–1.9 s. Kinetic parameters describing the rate of dissociation of other sugar lectin interactions are in the range 3.3 × 10^?3–2.5 × 10^?3 s. The long lifetime of the SBA‐TnPSM complex is compatible with a binding model in which lectin molecules “bind and jump” from α‐GalNAc residue to α‐GalNAc residue along the polypeptide chain of Tn‐PSM before dissociating. These findings have important implications for the molecular recognition properties of mucins. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 719–728, 2009. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com