Short polymers of arginine rapidly translocate into vascular cells: effects on nitric oxide synthesis

Influencing uptake and localization of aminoglycoside-functionalized peptoids

The development of small-molecule therapeutics that target RNA remains a promising field but one hampered with considerable challenges that include programming high affinity, specificity, cell permeability, and favorable pharmacokinetic profiles. Previously, we employed the use of peptoids to modularly display RNA-binding modules to enhance binding affinity and specificity by altering valency and the distance between ligand modules. Herein, factors that affect uptake, localization, and toxicity of peptoids that display a kanamycin derivative into a variety of mammalian cells lines are reported. A series of peptoids that display various spacing modules was synthesized to determine if the spacing module affects permeability and localization. The spacing module does affect cellular permeability into C2C12, A549, HeLa, and MCF7 cell lines but not into Jurkat cells. Moreover, the modularly assembled peptoids carrying the kanamycin cargo localize in the cytoplasm and perinuclear region of C2C12 and A549 cells and throughout HeLa cells, including the nucleus. These studies could contribute to the development of general strategies to afford cell permeable, modularly assembled small molecules that specifically target RNAs present in a variety of cell types.

Influence of protein transduction domains on intracellular delivery of macromolecules

As the plasma membrane and blood-brain barrier selectively restrict the entry of most compounds into cells to < 500 Da, delivering macromolecules into cells was, until recently, little more than a goal. However, with significant effort to capitalise on therapeutic targets available in the post-genomic era, novel approaches for delivering therapeutic macromolecules are being rapidly developed. The discovery of small cationic peptides, termed peptide/protein transduction domains or cell-penetrating peptides, which cross biological membranes, has emerged as a venerable Trojan horse to transport large, biologically active molecules, such as peptides, proteins and oligonucleotides, into mammalian cells in vitro, as well as in preclinical models and clinical trials in vivo. This review discusses the implications of peptide/protein transduction domain-mediated delivery of macromolecules and their possible uses as important primary drug delivery agents.

Pharmacokinetics and biodistribution of novel aptamer compositions

PURPOSE

Aptamers are highly selective nucleic acid-based drugs that are currently being developed for numerous therapeutic indications. Here, we determine plasma pharmacokinetics and tissue distribution in rat of several novel aptamer compositions, including fully 2'-O-methylated oligonucleotides and conjugates bearing high-molecular weight polyethylene glycol (PEG) polymers, cell-permeating peptides, and cholesterol.

METHODS

Levels of aptamer conjugates in biological samples were quantified radiometrically and by a hybridization-based dual probe capture assay with enzyme-linked fluorescent readout. Intact aptamer in urine was detected by capillary gel electrophoresis and matrix-assisted laser desorption ionization time of flight mass spectrometry (MALDI-TOF).

RESULTS

Aptamer compositions examined exhibited a wide range of mean residence times in circulation (0.6-16 h) and significant variation in distribution levels among organs and tissues. Among the conjugates tested, in vivo properties of aptamers were altered most profoundly by conjugation with PEG groups. Complexation with a 20 kDa PEG polymer proved nearly as effective as a 40 kDa PEG polymer in preventing renal clearance of aptamers. Conjugation with 20 kDa PEG prolonged aptamer circulatory half-life, while reducing both the extent of aptamer distribution to the kidneys and the rate of urinary elimination. In contrast, the fully 2'-O-Me aptamer composition showed rapid clearance from circulation, and elimination with intact aptamer detectable in urine at 48 h post-administration.

CONCLUSIONS

We find that conjugation and chemical composition can alter fundamental aspects of aptamer residence in circulation and distribution to tissues. Though the primary effect of PEGylation was on aptamer clearance, the prolonged systemic exposure afforded by presence of the 20 kDa moiety appeared to facilitate distribution of aptamer to tissues, particularly those of highly perfused organs.

Cellular Uptake of Aminoglycosides, Guanidinoglycosides, and Poly-arginine

Aminoglycosides (including neomycin B and tobramycin) exhibit poor uptake by eukaryotic cell lines. When the amines of these natural products are converted into guanidine groups, their cellular uptake is dramatically enhanced. We have synthesized BODIPY-containing aminoglycosides and guanidinoglycosides to evaluate their cellular uptake properties. Fluorescence activated cell sorting (FACS) and fluorescence microscopy are used to compare the membrane translocation and the cellular localization of these compounds. Upon guanidinylation, the cellular uptake efficiencies of tobramycin and neomycin B are enhanced by 10-fold and 20-fold, respectively. Guanidino-neomycin B exhibits a highly efficient uptake, superior to a fluorescent poly-arginine peptide. Interestingly, the cellular uptake of this common transduction peptide is inhibited by guanidine-neomycin B, suggesting a similar uptake mechanism for both the arginine-rich peptides and the guanidinoglycosides.