Niloofar Yavari scite author profile

Peptide Nucleic Acid (PNA)-peptide conjugates targeting essential bacterial genes are showing promise as antisense antimicrobials in drug discovery. Optimization has focused on selection of target genes and exact localization around the ribosome binding site, but surprisingly a length optimum around 10–12 nucleobases has been found. Addressing this observation, we have investigated the relationship between PNA-length, PNA–RNA duplex stability and antimicrobial activity in E. coli in more detail. For PNAs of identical length of ten nucleobases the expected reverse correlation between the thermal stability (Tm) of the PNA–RNA duplex and the MIC for single mismatched PNAs was found. Also the expected direct correlation between the length of the PNA and the PNA–RNA duplex stability was found. Nonetheless, 10-mer PNAs [in a 6–18 mer extension series of (KFF) 3 K- and (RXR) 4 conjugates] were the most active as antisense antimicrobials in both wild type E. coli MG1655 and AS19, suggesting that the size constraint is related to the bacterial uptake of PNA-peptide conjugates. This conclusion was supported by flow cytometry data showing higher bacterial uptake of shorter PNA fluorophore labeled conjugates. Interestingly, the size-limited uptake seems independent on outer membrane integrity (AS19), and thus the results suggest that the inner membrane limits the molecular size for peptide-PNA passage.

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Uptake, Stability, and Activity of Antisense Anti-acpP PNA-Peptide Conjugates in Escherichia coli and the Role of SbmA

Yavari

Goltermann

Nielsen

2021

ACS Chem. Biol.

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PNA oligomers conjugated to bacteria penetrating peptides (BPPs), such as (KFF) 3 K, targeting essential bacterial genes, such as acpP, can inhibit bacterial growth at one-digit micromolar concentrations. It has been found that the LPS of the outer membrane of Gram-negative bacteria is a barrier for cellular uptake of (KFF) 3 K-eg 1 -PNA and that the SbmA transporter protein is involved in the passage through the inner membrane. We now further elucidate the uptake mechanism of (KFF) 3 K-eg 1 -PNA by showing that the peptide part of (KFF) 3 K-eg 1 -PNA is unstable and is degraded by peptidases in the medium of a bacterial culture (t 1/2 < 5 min) and inside the bacteria. Analysis of peptide−PNA conjugates present in the periplasmic space and the cytoplasm showed the presence of mainly PNA with only the FFK tripeptide and without a peptide, at a concentration 10-fold that added to the medium. Furthermore, the two main degradation products showed no antibacterial effect when added directly to a bacterial culture and the antibacterial effect decreased with peptide length, thereby demonstrating that an intact peptide is indeed crucial for uptake but not for intracellular antisense activity. Most surprisingly, it was found that although the corresponding series of the proteolytically stable D-form (kff) 3 k-eg 1 -PNAs exhibited an analogous reduction of activity with peptide length, the activity was dependent on the presence of SbmA for the shorter peptides (which is not the case with the full length peptide). Therefore, our results suggest that the BPP is necessary for crossing both the LPS/outer membrane as well as the inner membrane and that full length (KFF) 3 K may spontaneously pass the inner membrane. Thus, SbmA dependence of (KFF) 3 K-eg 1 -PNA is ascribed to peptide degradation in the bacterial medium and in periplasmic space. Finally, the results show that stability and metabolism (by bacterial proteases/peptidases) should be taken into consideration upon design and activity/uptake analysis of BPPs (and antimicrobial peptides).

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Antibacterial Peptide Nucleic Acid–Antimicrobial Peptide (PNA–AMP) Conjugates: Antisense Targeting of Fatty Acid Biosynthesis

et al. 2016

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Antisense peptide nucleic acid (PNA) oligomers constitute a novel class of potential antibiotics that inhibit bacterial growth via specific knockdown of essential gene expression. However, discovery of efficient, nontoxic delivery vehicles for such PNA oligomers has remained a challenge. In the present study we show that antimicrobial peptides (AMPs) with an intracellular mode of action can be efficient vehicles for bacterial delivery of an antibacterial PNA targeting the essential acpP gene. The results demonstrate that buforin 2-A (BF2-A), drosocin, oncocin 10, Pep-1-K, KLW-9,13-a, (P59→W59)-Tat48-60, BF-2A-RXR, and drosocin-RXR are capable of transporting PNA effectively into E. coli (MICs of 1-4 μM). Importantly, presence of the inner-membrane peptide transporter SbmA was not required for antibacterial activity of PNA-AMP conjugates containing Pep-1-K, KLW-9,13-a, or drosocin-RXR (MICs of 2-4 μM).

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Antisense Peptide Nucleic Acid–Diaminobutanoic Acid Dendron Conjugates with SbmA-Independent Antimicrobial Activity against Gram-Negative Bacteria

et al. 2022

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Precision antisense antibacterial agents may be developed into novel antibiotics in the fight against multidrug-resistant Gram-negative bacteria. In this study, a series of diaminobutanoic acid (DAB) dendrons are presented as novel carriers for the delivery of antisense antibacterial peptide nucleic acids (PNAs). The dendron–PNA conjugates targeting the essential acpP gene exhibit specific antisense antimicrobial bactericidal activity against Escherichia coli and Klebsiella pneumoniae at one-digit micromolar concentrations, while showing low toxicity to human cells. One compound selected from a structure–activity relationship series showed high stability in mouse and human serum ( t 1/2 ≫ 24 h) as well as in vivo activity against a multidrug-resistant, extended spectrum beta-lactamase-producing E. coli in a murine peritonitis model. The compound was also well tolerated in mice upon i.v. administration up to a dose of 20 mg/kg, and in vivo fluorescence imaging indicated clearance via renal excretion with slight accumulation in the kidneys and liver. Thus, DAB-based dendrons constitute a promising new chemistry platform for development of effective delivery agents for antibacterial drugs with possible in vivo use.

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Antibiotic Potentiation in Multidrug-Resistant Gram-Negative Pathogenic Bacteria by a Synthetic Peptidomimetic

et al. 2021

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The peptidomimetic H-[NLys-t BuAla] 6 -NH 2 (CEP-136), which exhibits low inherent antimicrobial activity against Gramnegative bacteria (MIC = 16−64 μM), was shown to significantly potentiate the antibacterial activity of several clinically important antibiotics against the human pathogens Escherichia coli, Klebsiella pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa. Thus, the antibacterial spectrum of rifampicin, clarithromycin, and azithromycin could be extended to include also these Gram-negative bacteria. Additionally, the potentiation effect was demonstrated in a panel of clinically relevant multidrug-resistant isolates including extendedspectrum β-lactamase (ESBL)-and carbapenemase-producing as well as colistin-resistant strains. For some peptidomimetic−antibiotic combinations, the strong synergy corresponded to a more than 50fold reduction of the minimal inhibitory concentration of the antibiotic. Mechanistic studies indicate that the potentiation arises from a permeabilization effect exerted on the outer membrane lipopolysaccharide layer of the Gram-negative bacteria without significant disruption of the inner membrane. Furthermore, the peptidomimetic enhancer exhibited only a marginal effect on the viability of mammalian HepG2 cells even at concentrations 100fold higher than that enabling the antibiotic enhancement. Also, a low hemolytic activity combined with limited in vivo acute toxicity of CEP-136 in healthy mice allowed in vivo validation of the potentiation effect on both rifampicin and azithromycin treatment in a murine peritonitis model. Thus, CEP-136 is an interesting hit compound for further development of effective adjuvants for repurposing antibiotics for use against infections by multidrug-resistant Gram-negative bacteria.

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Niloofar Yavari

PNA Length Restriction of Antibacterial Activity of Peptide-PNA Conjugates in Escherichia coli Through Effects of the Inner Membrane

Uptake, Stability, and Activity of Antisense Anti-acpP PNA-Peptide Conjugates in Escherichia coli and the Role of SbmA

Antibacterial Peptide Nucleic Acid–Antimicrobial Peptide (PNA–AMP) Conjugates: Antisense Targeting of Fatty Acid Biosynthesis

Antisense Peptide Nucleic Acid–Diaminobutanoic Acid Dendron Conjugates with SbmA-Independent Antimicrobial Activity against Gram-Negative Bacteria

Antibiotic Potentiation in Multidrug-Resistant Gram-Negative Pathogenic Bacteria by a Synthetic Peptidomimetic

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