Evaluation of oligonucleotides containing two novel 2'-O-methyl modified nucleotide monomers: a 3'-C-allyl and a 2'-O,3'-C-linked bicyclic derivative.

The two ribo-configured nucleosides 1-(3-C-allyl-2-O-methyl-beta-D-ribo-pentofuranosyl)thymine 3 and (1S,5R,6R,8R)-5-hydroxy-6-(hydroxymethyl)-1-methoxy-8-(thymin-1-yl )- 2,7-dioxabicyclo[3.3.0]octane 6 have been transformed into their corresponding phosphoramidites, 5 and 8 respectively, and used as building blocks for the synthesis of modified oligonucleotides. The oligonucleotides were shown to hybridize with decreased binding affinity towards complementary single stranded DNA and RNA.     

Chemical and biological approaches synergize to ameliorate protein-folding diseases

Loss-of-function diseases are often caused by a mutation in a protein traversing the secretory pathway that compromises the normal balance between protein folding, trafficking, and degradation. We demonstrate that the innate cellular protein homeostasis, or proteostasis, capacity can be enhanced to fold mutated enzymes that would otherwise misfold and be degraded, using small molecule proteostasis regulators. Two proteostasis regulators are reported that alter the composition of the proteostasis network in the endoplasmic reticulum through the unfolded protein response, increasing the mutant folded protein concentration that can engage the trafficking machinery, restoring function to two nonhomologous mutant enzymes associated with distinct lysosomal storage diseases. Coapplication of a pharmacologic chaperone and a proteostasis regulator exhibits synergy because of the former's ability to further increase the concentration of trafficking-competent mutant folded enzymes. It may be possible to ameliorate loss-of-function diseases by using proteostasis regulators alone or in combination with a pharmacologic chaperone.     

Binding and release of cholesterol in the Osh4 protein of yeast

Sterols have been shown experimentally to bind to the Osh4 protein (a homolog of the oxysterol binding proteins) of Saccharomyces cerevisiae within a binding tunnel, which consists of antiparallel beta-sheets that resemble a beta-barrel and three alpha-helices of the N-terminus. This and other Osh proteins are essential for intracellular transport of sterols and ultimately cell life. Molecular dynamics (MD) simulations are used to study the binding of cholesterol to Osh4 at the atomic level. The structure of the protein is stable during the course of all MD simulations and has little deviation from the experimental crystal structure. The conformational stability of cholesterol within the binding tunnel is aided in part by direct or water-mediated interactions between the 3-hydroxyl (3-OH) group of cholesterol and Trp(46), Gln(96), Tyr(97), Asn(165), and/or Gln(181) as well as dispersive interactions with Phe(42), Leu(24), Leu(39), Ile(167), and Ile(203). These residues along with other nonpolar residues in the binding tunnel and lid contribute nearly 75% to the total binding energy. The strongest and most populated interaction is between Gln(96) and 3-OH with a cholesterol/Gln(96) interaction energy of -4.5 +/- 1.0 kcal/mol. Phe(42) has a similar level of attraction to cholesterol with -4.1 +/- 0.3 kcal/mol. A MD simulation without the N-terminus lid that covers the binding tunnel resulted in similar binding conformations and binding energies when compared with simulations with the full-length protein. Steered MD was used to determine details of the mechanism used by Osh4 to release cholesterol to the cytoplasm. Phe(42), Gln(96), Asn(165), Gln(181), Pro(211), and Ile(206) are found to direct the cholesterol as it exits the binding tunnel as well as Lys(109). The mechanism of sterol release is conceptualized as a molecular ladder with the rungs being amino acids or water-mediated amino acids that interact with 3-OH.     

Purification and characterization of two trypsin-like enzymes from the digestive tract of anchovy Engraulis encrasicholus

1. Two trypsin-like enzymes, designated Trypsin A and B, were purified from the pyloric caeca and intestine of anchovy by (NH4)2SO4 fractionation, affinity chromatography (Benzamidine-Sepharose-6B) and ion exchange chromatography (DEAE-Sepharose). 2. Both trypsins catalyzed the hydrolysis of N-benzoyl-DL-arginine p-nitroanilide (BAPNA), p-tosyl-L-arginine methyl ester (TAME), casein and myofibrillar protein and they were inhibited by several well established trypsin-inhibitors. 3. The enzymes had mol. wts of 27,000 (Trypsin A) and 28,000 (Trypsin B). Their isoelectric points were about 4.9 (Trypsin A) and 4.6 (Trypsin B) and they had similar amino acid composition. 4. The enzymes had a pH optimum of 8-9 for the hydrolysis of BAPNA and of 9.5 for the digestion of casein and myofibrillar protein. Their activity and stability were affected by calcium ions. 5. Trypsins A and B resemble other fish trypsins in their mol. wt, pI, kinetic properties and the instability at low pH and they are similar to bovine trypsin in their dependence of Ca2+ for activity and stability.