Gabriela D. Ivanova

Cell penetrating peptide conjugates of steric block oligonucleotides

Abstract Charge neutral steric block oligonucleotide analogues, such as peptide nucleic acids (PNA) or phosphorodiamidate morpholino oligomers (PMO), have promising biological and pharmacological properties for antisense applications, such as for example in mRNA splicing redirection. However, cellular uptake of free oligomers is poor and the utility of conjugates of PNA or PMO to cell penetrating peptides (CPP), such as Tat or Penetratin, is limited by endosomal sequestration. Two new families of arginine-rich CPPs named (R-Ahx-R)4 AhxB and R6Pen allow efficient nuclear delivery of splice correcting PNA and PMO at micromolar concentrations in the absence of endosomolytic agents. The in vivo efficacy of (R-Ahx-R)4 AhxB PMO conjugates has been demonstrated in mouse models of Duchenne muscular dystrophy and in various viral infections.

Improved cell-penetrating peptide–PNA conjugates for splicing redirection in HeLa cells and exon skipping in mdx mouse muscle

Steric blocking peptide nucleic acid (PNA) oligonucleotides have been used increasingly for redirecting RNA splicing particularly in therapeutic applications such as Duchenne muscular dystrophy (DMD). Covalent attachment of a cell-penetrating peptide helps to improve cell delivery of PNA. We have used a HeLa pLuc705 cell splicing redirection assay to develop a series of PNA internalization peptides (Pip) conjugated to an 18-mer PNA705 model oligonucleotide with higher activity compared to a PNA705 conjugate with a leading cell-penetrating peptide being developed for therapeutic use, (R-Ahx-R)(4). We show that Pip-PNA705 conjugates are internalized in HeLa cells by an energy-dependent mechanism and that the predominant pathway of cell uptake of biologically active conjugate seems to be via clathrin-dependent endocytosis. In a mouse model of DMD, serum-stabilized Pip2a or Pip2b peptides conjugated to a 20-mer PNA (PNADMD) targeting the exon 23 mutation in the dystrophin gene showed strong exon-skipping activity in differentiated mdx mouse myotubes in culture in the absence of an added transfection agent at concentrations where naked PNADMD was inactive. Injection of Pip2a-PNADMD or Pip2b-PNADMD into the tibealis anterior muscles of mdx mice resulted in approximately 3-fold higher numbers of dystrophin-positive fibres compared to naked PNADMD or (R-Ahx-R)(4)-PNADMD.

Cell-penetrating-peptide-based delivery of oligonucleotides: an overview

Cationic CPPs (cell-penetrating peptides) have been used largely for intracellular delivery of low-molecular-mass drugs, biomolecules and particles. Most cationic CPPs bind to cell-associated glycosaminoglycans and are internalized by endocytosis, although the detailed mechanisms involved remain controversial. Sequestration and degradation in endocytic vesicles severely limits the efficiency of cytoplasmic and/or nuclear delivery of CPP-conjugated material. Re-routing the splicing machinery by using steric-block ON (oligonucleotide) analogues, such as PNAs (peptide nucleic acids) or PMOs (phosphorodiamidate morpholino oligomers), has consequently been inefficient when ONs are conjugated with standard CPPs such as Tat (transactivator of transcription), R(9) (nona-arginine), K(8) (octalysine) or penetratin in the absence of endosomolytic agents. New arginine-rich CPPs such as (R-Ahx-R)(4) (6-aminohexanoic acid-spaced oligo-arginine) or R(6) (hexa-arginine)-penetratin conjugated to PMO or PNA resulted in efficient splicing correction at non-cytotoxic doses in the absence of chloroquine. SAR (structure-activity relationship) analyses are underway to optimize these peptide delivery vectors and to understand their mechanisms of cellular internalization.

Arginine-rich cell penetrating peptides: Design, structure–activity, and applications to alter pre-mRNA splicing by steric-block oligonucleotides†

Rerouting the splicing machinery with steric‐block oligonucleotides (ON) might lead to new therapeutic strategies in the treatment of diseases such as β‐thalassemia, Duchenne muscular dystrophy, or cancers. Interfering with splicing requires the sequence‐specific and stable hybridization of RNase H‐incompetent ON as peptide nucleic acids (PNA) or phosphorodiamidate morpholino oligomers (PMO). Unfortunately, these uncharged DNA mimics are poorly taken up by most cell types and conventional delivery strategies that rely on electrostatic interaction do not apply. Likewise, conjugation to cell penetrating peptides (CPPs) as Tat, Arg9, Lys8, or Pen leads to poor splicing correction efficiency at low concentration essentially because PNA– and PMO–CPP conjugates remain entrapped within endocytotic vesicles. Recently, we have designed an arginine‐rich peptide (R‐Ahx‐R)4 (with Ahx for aminohexanoic acid) and an arginine‐tailed Penetratin derivative which allow sequence‐specific and efficient splicing correction at low concentration in the absence of endosomolytic agents. Both CPPs are undergoing structure–activity relationship studies for further optimization as steric‐block ON delivery vectors. Copyright

Optimization of Peptide Nucleic Acid Antisense Oligonucleotides for Local and Systemic Dystrophin Splice Correction in the mdx Mouse

Antisense oligonucleotides (AOs) have the capacity to alter the processing of pre-mRNA transcripts in order to correct the function of aberrant disease-related genes. Duchenne muscular dystrophy (DMD) is a fatal X-linked muscle degenerative disease that arises from mutations in the DMD gene leading to an absence of dystrophin protein. AOs have been shown to restore the expression of functional dystrophin via splice correction by intramuscular and systemic delivery in animal models of DMD and in DMD patients via intramuscular administration. Major challenges in developing this splice correction therapy are to optimize AO chemistry and to develop more effective systemic AO delivery. Peptide nucleic acid (PNA) AOs are an alternative AO chemistry with favorable in vivo biochemical properties and splice correcting abilities. Here, we show long-term splice correction of the DMD gene in mdx mice following intramuscular PNA delivery and effective splice correction in aged mdx mice. Further, we report detailed optimization of systemic PNA delivery dose regimens and PNA AO lengths to yield splice correction, with 25-mer PNA AOs providing the greatest splice correcting efficacy, restoring dystrophin protein in multiple peripheral muscle groups. PNA AOs therefore provide an attractive candidate AO chemistry for DMD exon skipping therapy.

Increased RNAi is related to intracellular release of siRNA via a covalently attached signal peptide

In the last decade short interfering RNA (siRNA) became an important means for functional genomics and the development of gene-specific drugs. However, major technical hurdles in the application of siRNA include its cellular delivery followed by its intracellular trafficking and its release in order to enter the RNA interference (RNAi) machinery. The novel phosphorothioate-stimulated cellular uptake of siRNA contrasts other known delivery systems because it involves a caveosomal pathway in which large amounts of siRNA are delivered to the perinuclear environment, leading to measurable though moderate target suppression. Limited efficacy seems to be related to intracellular trapping of siRNA. To study the role of intracellular trafficking of siRNA for biological effectiveness we studied whether a signal peptide for trans-membrane transport of bacterial protein toxins, which is covalently attached to siRNA, can promote its release from the perinuclear space into the cytoplasm and thereby enhance its biological effectiveness. We show that attachment of the peptide TQIENLKEKG to lamin A/C-directed siRNA improves target inhibition after its PS-stimulated delivery. This is related to increased efflux of the siRNA-peptide conjugate from the ER-specific perinuclear sites. In summary, this study strongly suggests that intracellular release of siRNA leads to increased biological effectiveness. Thus covalent peptide-siRNA conjugates are proposed as new tools to study the relationship between intracellular transport and efficacy of siRNA.

A Peptide-Based Dendrimer That Enhances the Splice-Redirecting Activity of PNA Conjugates in Cells

The full therapeutic potential of oligonucleotide (ON)-based agents has been hampered by cellular delivery challenges. Cell-penetrating peptides (CPP) represent promising delivery vectors for nucleic acids, and their potential has recently been evaluated using a functional splicing redirection assay, which capitalizes on the nuclear delivery of splice-correcting steric-block ON analogues such as peptide nucleic acids (PNA). Despite encouraging in vitro and in vivo data with arginine-rich CPP-steric block conjugates, mechanistic studies have shown that entrapment within the endosome/lysosome compartment after endocytosis remains a limiting factor. Previous work from our group has shown that CPP oligomerization greatly improves cellular delivery and increases transfection of plasmid DNA. We now report the chemical synthesis and the evaluation of multivalent CPP-PNA constructs incorporating monomeric (p53(mono)) and dendrimer-like tetrameric (p53(tet)) forms of the p53 tetramerization domain containing peptide, a 10 arginine CPP domain (R10), and a splice redirecting PNA (PNA705). These CPP-PNA conjugates were termed R10p53(tet)-PNA705 and R10p53(mono)-PNA705, referring to their oligomerization state. The present study demonstrates that the splicing redirection efficiency of PNA705 is much greater in the context of the tetrameric R10p53(tet)-PNA705 construct than for the monomeric and occurs at nanomolar concentrations, demonstrating that multivalency is an important factor in delivering PNA into cells.

Peptide-Based Delivery of Steric-Block PNA Oligonucleotides

Several strategies based on synthetic oligonucleotides (ON) have been proposed to control gene expression. As for most biomolecules, however, delivery has remained a major roadblock for in vivo applications. Conjugation of steric-block neutral DNA mimics such as peptide nucleic acids (PNA) or phosphorodiamidate morpholino oligonucleotides (PMO) to cell penetrating peptides (CPP) has recently been proposed as a new delivery strategy. It is particularly suitable to interfere sequence-specifically with pre-mRNA splicing thus offering various applications in fundamental research and in therapeutics. The chemical synthesis of these CPP conjugates as well as methodologies to monitor their cellular uptake and their efficiency in a reliable and easy to implement assay of splicing correction will be described.

PNA-peptide conjugates as intracellular gene control agents.

Serum-stabilized PNA-internalization peptides (Pip) conjugated to PNA complementary to the 705 aberrant beta-globin splice site are able to correct splicing and increase luciferase production in Hela pLuc705 cells with sub microM EC(50) in the absence of a transfection agent. Inhibition of microRNA-122 in liver cells is achieved by treatment with complementary PNA containing just a few attached Lys residues, again without need of a transfection agent.

Anti‐HIV Activity of Steric Block Oligonucleotides

Abstract:  The unabated increase in spread of HIV infection worldwide has redoubled efforts to discover novel antiviral and virucidal agents that might be starting points for clinical development. Oligonucleotides and their analogs targeted to form complementary duplexes with highly conserved regions of the HIV RNA have shown significant antiviral activity, but to date clinical studies have been dominated by RNase H‐inducing oligonucleotide analog phosphorothioates (GEM 91 and 92) that have specificity and efficacy limitations. However, they have proven the principle that oligonucleotides can be safe anti‐HIV drugs. Newer oligonucleotide analogs are now available, which act as strong steric block agents of HIV RNA function. We describe our ongoing studies targeting the HIV‐1 trans‐activation responsive region (TAR) and the viral packaging signal (psi) with steric block oligonucleotides of varying chemistry and demonstrate their great potential for steric blocking of viral protein interactions in vitro and in cells and describe the first antiviral studies. Peptide nucleic acids (PNA) disulfide linked to cell‐penetrating peptides (CPP) have been found to have particular promise for the lipid‐free direct delivery into cultured cells and are excellent candidates for their development as antiviral and virucidal agents.