PEGylation of protein-based MRI contrast agents improves relaxivities and biocompatibilities

Magnetic resonance imaging (MRI) has emerged as a leading diagnostic technique in clinical and preclinical settings. However, the application of MRI to assess specific disease markers for diagnosis and monitoring drug effect has been severely hampered by the lack of desired contrast agents with high relaxivities, and optimized in vivo retention time. We have reported the development of protein-based MRI contrast agents (ProCA1) by rational design of Gd^3 + binding sites into a stable protein resulting in significantly increased longitudinal (r₁) and transverse (r₂) relaxivities compared to Gd-DTPA. Here, we report a further improvement of protein contrast agents ProCA1 for in vivo imaging by protein modification with various sizes of polyethylene glycol (PEG) chain. PEGylation results in significant increases of both r₁ and r₂ relaxivities (up to 200%), and these high relaxivities persist even at field strengths up to 9.4 T. In addition, our experimental results demonstrate that modified contrast agents have significant improvement of in vivo MR imaging and biocompatibilities including dose efficiency, protein solubility, blood retention time and decreased immunogenicity. Such improvement can be important to the animal imaging and pre-clinical research at high or ultra-high field where there is an urgent need for molecular imaging probes and optimized contrast agent.     

Clinical dextran purified by fractional ultrafiltration coupled with water washing

Dextran with extremely narrow molecular weight distribution (MWD) is demanded for clinical use. To elucidate the effect of fractional ultrafiltration on the purification of clinical dextran, a range of ultrafiltration membranes with 100, 30, 5 and 1 kDa molecular weight cut-off (MWCO) were applied. High Performance Gel Permeation Chromatography (HPGPC) analysis indicated that the MWD of ultrafiltrated dextran fractions are wide, with polydispersity index (D) between 2.2 and 5.4, suggesting that the MWD of dextran is hard to be strictly controlled by fractional ultrafitration. However, when coupled with water washing during ultrafiltration process, the homogeneity of dextran was greatly improved. An ultrafiltration fraction of 5-30 kDa (Mw ≈ 35 kDa) with narrow MWD (D = 1.2) was obtained after 5 times of water washing. The results show that fractional ultrafiltration coupled with water washing can be used as a simple and effective method to improve the quality of clinical dextran.     

The Werner Syndrome Protein Promotes CAG/CTG Repeat Stability by Resolving Large (CAG)n/(CTG)n Hairpins

Expansion of CAG/CTG repeats causes certain neurological and neurodegenerative disorders, and the formation and subsequent persistence of stable DNA hairpins within these repeats are believed to contribute to CAG/CTG repeat instability. Human cells possess a DNA hairpin repair (HPR) pathway, which removes various (CAG)(n) and (CTG)(n) hairpins in a nick-directed and strand-specific manner. Interestingly, this HPR system processes a (CTG)(n) hairpin on the template DNA strand much less efficiently than a (CAG)(n) hairpin on the same strand (Hou, C., Chan, N. L., Gu, L., and Li, G. M. (2009) Incision-dependent and error-free repair of (CAG)(n)/(CTG)(n) hairpins in human cell extracts. Nat. Struct. Mol. Biol. 16, 869-875), suggesting the involvement of an additional component for (CTG)(n) HPR. To identify this activity, a functional in vitro HPR assay was used to screen partially purified HeLa nuclear fractions for their ability to stimulate (CTG)(n) HPR. We demonstrate here that the stimulating activity is the Werner syndrome protein (WRN). Although WRN contains both a 3'→5' helicase activity and a 3'→5' exonuclease activity, the stimulating activity was found to be the helicase activity, as a WRN helicase mutant failed to enhance (CTG)(n) HPR. Consistently, WRN efficiently unwound large (CTG)(n) hairpins and promoted DNA polymerase δ-catalyzed DNA synthesis using a (CTG)(n) hairpin as a template. We, therefore, conclude that WRN stimulates (CTG)(n) HPR on the template DNA strand by resolving the hairpin so that it can be efficiently used as a template for repair or replicative synthesis.     

Maplexins, new α-glucosidase inhibitors from red maple (Acer rubrum) stems

Thirteen gallic acid derivatives including five new gallotannins, named maplexins A-E, were isolated from red maple (Acer rubrum) stems. The compounds were identified by spectral analyses. The maplexins varied in number and location of galloyl groups attached to 1,5-anhydro-d-glucitol. The isolates were evaluated for α-glucosidase inhibitory and antioxidant activities. Maplexin E, the first compound identified with three galloyl groups linked to three different positions of 1,5-anhydro-d-glucitol, was 20 fold more potent than the α-glucosidase inhibitory drug, Acarbose (IC(50)=8 vs 160 μM). Structure-activity related studies suggested that both number and position of galloyls attached to 1,5-anhydro-d-glucitol were important for α-glucosidase inhibition.     

Vitamins A & D inhibit the growth of mycobacteria in radiometric culture

Background

The role of vitamins in the combat of disease is usually conceptualized as acting by modulating the immune response of an infected, eukaryotic host. We hypothesized that some vitamins may directly influence the growth of prokaryotes, particularly mycobacteria.

Methods

The effect of four fat-soluble vitamins was studied in radiometric Bactec® culture. The vitamins were A (including a precursor and three metabolites,) D, E and K. We evaluated eight strains of three mycobacterial species (four of M. avium subspecies paratuberculosis (MAP), two of M. avium and two of M. tb. complex).

Principal Findings

Vitamins A and D cause dose-dependent inhibition of all three mycobacterial species studied. Vitamin A is consistently more inhibitory than vitamin D. The vitamin A precursor, β-carotene, is not inhibitory, whereas three vitamin A metabolites cause inhibition. Vitamin K has no effect. Vitamin E causes negligible inhibition in a single strain.

Significance

We show that vitamin A, its metabolites Retinyl acetate, Retinoic acid and 13-cis Retinoic acid and vitamin D directly inhibit mycobacterial growth in culture. These data are compatible with the hypothesis that complementing the immune response of multicellular organisms, vitamins A and D may have heretofore unproven, unrecognized, independent and probable synergistic, direct antimycobacterial inhibitory activity.     

Pan-pathway based interaction profiling of FDA-approved nucleoside and nucleobase analogs with enzymes of the human nucleotide metabolism

To identify interactions a nucleoside analog library (NAL) consisting of 45 FDA-approved nucleoside analogs was screened against 23 enzymes of the human nucleotide metabolism using a thermal shift assay. The method was validated with deoxycytidine kinase; eight interactions known from the literature were detected and five additional interactions were revealed after the addition of ATP, the second substrate. The NAL screening gave relatively few significant hits, supporting a low rate of "off target effects." However, unexpected ligands were identified for two catabolic enzymes guanine deaminase (GDA) and uridine phosphorylase 1 (UPP1). An acyclic guanosine prodrug analog, valaciclovir, was shown to stabilize GDA to the same degree as the natural substrate, guanine, with a ΔT(agg) around 7°C. Aciclovir, penciclovir, ganciclovir, thioguanine and mercaptopurine were also identified as ligands for GDA. The crystal structure of GDA with valaciclovir bound in the active site was determined, revealing the binding of the long unbranched chain of valaciclovir in the active site of the enzyme. Several ligands were identified for UPP1: vidarabine, an antiviral nucleoside analog, as well as trifluridine, idoxuridine, floxuridine, zidovudine, telbivudine, fluorouracil and thioguanine caused concentration-dependent stabilization of UPP1. A kinetic study of UPP1 with vidarabine revealed that vidarabine was a mixed-type competitive inhibitor with the natural substrate uridine. The unexpected ligands identified for UPP1 and GDA imply further metabolic consequences for these nucleoside analogs, which could also serve as a starting point for future drug design.     

胸腺素β4与药物开发

胸腺素β4是广泛分布于脊椎动物体内的一种蛋白质,能够调节肌动蛋白聚合、解聚,具有多项生物学功能。胸腺素β4尤其具有促进组织再生、修复的重要功能,在创伤修复、角膜修复和心肌修复方面极具药物开发潜力。近年来,研究者们对胸腺素β4进行了大量生理机制研究,本文对其目前的研究状况和药物开发情况进行了综述。