Design, Synthesis, Applications of Polymers and Dendrimers

Nimmagadda, Alekhya

16 November 2017

WHO has reported that antibiotic resistance is the third major cause of human death all over the globe. Recent study, has focused on the development of new antibacterial resistance drugs. Herein, we tried to synthesis a series of polymers that can mimic the HDPs. HDPs can target the bacterial cell membrane and they have less chances to develop bacterial resistance. We synthesized the amphiphilic polycarbonates that are highly selective to Gram-positive bacteria, including multidrug resistant pathogens. The membrane disruption activity of these polymers was proved by fluorescence and TEM studies and the drug resistance study showed that the polymers don’t develop bacterial resistance. In order to further design the molecules that can target a broad spectrum of bacteria, we have designed a series of lipidated dendrimers that can target the Gram-positive and Gram-negative bacteria. These dendrimers mimic the HDPs and target the bacterial cell membrane. Dendrimers are reported to inhibit the formation of bacterial biofilm which makes them promising for their future development of antibiotic agents. Apart from the synthesis of polymers and dendrimers as antibacterial agents, we have designed a series of small molecular antibacterial agents that are based on the acylated reduced amide scaffold and small dimeric cyclic guanidine derivatives. These molecules display good potency against a panel of multidrug-resistant Gram-positive and Gram-negative bacterial strains. Meanwhile, they also effectively inhibit the biofilm formation. Mechanistic studies suggest that these compounds kill bacteria by compromising bacterial membranes, a mechanism analogous to that of host-defense peptides (HDPs). Lastly, we also demonstrate that these molecules have excellent in vivo activity against MRSA in a rat model. This class of compounds could lead to an appealing class of antibiotic agents combating drug-resistant bacterial strains.

Antimicrobial polymers

Dendrimers

amphiphilic

γ-AApeptide

Host defense peptide

Chemistry

Structure-based Design, Synthesis and Applications of a New Class of Peptidomimetics: <em>'Y</em>-AA Peptides and Their Derivatives

Su, Ma

09 November 2018

Peptidomimetics can mimic hierarchical structures of peptides and proteins. Thus, they are extensively studied for therapeutic applications. To break the limitation of backbones and frameworks and expand the peptidomimetics family, a new class of peptidomimetics - “γ-AApeptides” was developed. Design of γ-AApeptides is based on the chiral peptide nucleic acids (PNAs) backbone. The World Health Organization estimates that one -third of all deaths in the world are on account of infectious diseases. AMPs are important because of their high activity against broad spectrum microbes, less susceptible to grow resistance and selectivity in binding to bacterial cells over human cells. γ-AApeptides as a new class of peptidomimetics have increased stability and enhanced chemical diversity. We have developed polymyxin mimic cyclic peptides, small linear molecules and hydantoin derivatives as potent antibiotic agents with γ-AApeptides. They have good bioactivity and selectivity. Combinatorial library is key technology for accelerating the discovery of novel therapeutic agents. One-bead-two-compound γ-AApeptides-based library was developed and screened against SMYD2 protein which is essential for tumor growing.

γ-AApeptide

antimicrobial agents

OBTC library

drug resistance

Chemistry

Interrogation of Protein Function with Peptidomimetics

Bolarinwa, Olapeju

03 July 2018

Proteins can be described as the “machineries” responsible for almost all tasks in the levels of organizational complexity in multi-cellular organisms namely: the cells, tissues, organs and systems. Any disorder in the function of a protein at any of these levels could result in disease, and a study of protein function is critical to understanding the pathological features of the disease at the molecular level. A quick glance at these abundantly present proteins reveals two striking features: large diversity of biological function, and the variations in structural complexity, which varies from simple random coils, to turns and helices, and on to structured assemblies of turns, helices and sheets. Over the past few years, more research efforts have been channeled to the application of synthetic research to protein dynamics, most especially in disease conditions. This provides insight into the design and development of chemical tools capable of modulating protein functions .Some of such tools include small molecules, peptides and peptidomimetics. In this work, we have described the application of these tools to three (3) different disease systems topping the list of incurable diseases: HIV, Diabetes, and Cancer. We have designed and developed chemical probes to facilitate a better understanding of major “culprit” proteins underlying the pathological conditions associated with these diseases. Our designed chemical probes were capable of modulating protein functions by producing the desired effects: inhibition of protein-protein interactions.

amylin

MPP8

diabetes

hIAPP

peptidomimetics

protein-protein interaction

γ-AApeptide

Biochemistry

Chemistry

Organic Chemistry

Development of Bioactive Peptidomimetics

She, Fengyu

01 October 2018

Peptidomimetics are synthetic foldamers that expected more resistant to proteolytic degradation and enormous chemodiversity when compared with peptides. To date, the functional peptidomimetics such as β-peptides, peptoids, oligoureas, etc have been developed in many science fields. In order to explore the unnatural foldameric architectures, it’s necessary to discover the novel frameworks and molecular scaffolds. γ-AApeptides were reported to be a new class of peptidomimetics that showed its potential applications in drug discovery and chemical biology. However, a wide function and property of γ-AApeptides need to be further explored. To expand the potential application of γ-AApeptides in biochemistry, I have been focusing on the development of bioactive peptidomimetics, such as exploring the antibacterial activity of helical 1:1 α-sulfono-γ-AA heterogeneous peptides, developing the helical peptidomimetic as the inhibitor of the protein Ras_Raf interaction, identifying the protein/peptide ligands by the novel one-bead-two compound macrocyclic γ-AApeptide screening library, and elucidating the de novo dragon-boat-shaped synthetic foldamers.

γ-AApeptide

antimicrobial agents

protein interaction

OBTC library

left-handed peptidomimetic foldamers

Chemistry

Gamma AApeptides as Host Defense Peptide Mimics

Li, Yaqiong

16 May 2016

There has been increasing concern regarding the emergence of multi-drug resistant pathogens. The resistance develops when pathogens, especially bacteria, are frequently exposed to conventional antibiotics, as they are heavily used in both human and livestock. This is due to the high target specificity of conventional antibiotics, which places pathogens in high selective pressures and eventually results in drug resistant by mutations. To address this issue, global actions and cooperation are needed. At the same time, new technologies and strategies need to be developed. Host defense peptides (HDPs) are widely found in the innate immune system. They show both direct antimicrobial properties and immunomodulatory activities. The multifaceted functions of HPDs make them less likely to promote antimicrobial resistance. Thus, they are promising as new therapeutics to treat multi-drug resistant infections. In fact, several drug candidates derived from HDPs have entered the clinical trial, but none of them got into the clinic. This is due to several challenges associated with HDPs, such as low in vivo stability, high cost of manufacturing, and toxicity to mammalian cells. In this dissertation, we explored the ability of a new type of unnatural scaffolds (γ-AApeptides) to mimic the functions of HDPs, including both broad spectrum antimicrobial properties and immunomodulatory activities. Furthermore, the efforts to identify simpler and more drug like γ-AApeptide based antimicrobial agents were also discussed. The findings in this dissertation may lead to the development of potential drug candidates to treat multi-drug resistant infections.

γ-AApeptide

host defense peptide

toll-like receptor 4

lipopeptide

helical mimetic

Chemistry