Design and Synthesis of Novel Antimicrobial Agents

5.1. Nanotechnology in Combating Bacterial Resistance

The drug resistance dilemma can potentially be resolved with the use of nanotechnology. Nanomaterials can be metallic, semiconducting, polymer, or carbon-based and have been widely employed in studies and have been shown to be effective against infections on the WHO priority list. Antibacterial activity of nanomaterials arises from interactions between nanoparticles and bacteria, which includes cellular uptake and nanoparticle aggregation, which leads to membrane damage and toxicity. In an effort to reduce resistance, nanoparticles can serve as both antibiotics and delivery systems [61,62,63]. Metal-based NPs (such as silver, copper and gold) have drawn attention due to their different properties such as being optically active, having a large surface area, being chemically reactive, as well as mechanically strong. Favorable physicochemical characteristics of metallic nanomaterials led them to be widely used in biomedical applications [64,65]. In order to circumvent vancomycin resistance, a short half-life, and the necessity for a greater dose, Yadav et al. [66] used a nanosized vehicle system for delayed and sustained release of the antibiotic. Vancomycin was captured using arginine-α,β-dehydrophenylalanine nanospheres in the procedure. When compared to vancomycin alone, which only moderately inhibited S. aureus growth in in vitro and in vivo tests, nanoparticles effectively inhibited S. aureus growth. The antibacterial therapy holds out a lot of promise thanks to the delivery mechanism. A sliver nanoparticle conjugated with chitosan was created by Mohammadinejat et al. [67] and tested for antibacterial and antibiofilm properties against carbapenem-resistant Acinetobacter baumannii (CRAB) and methicillin-resistant S. aureus (MRSA). The results showed that, compared to chitosan (64, 16 μg/mL) and Ag Np alone (32, 16 μg/mL), the nanoparticle conjugate had a MIC90 of 8 μg/mL against CRAB isolates and 4 μg/mL against MRSA. Ag Np–chitosan conjugation is a successful alternative with antibacterial and anti-biofilm effects against CRAB and MRSA isolates, as demonstrated by the conjugate’s ability to reduce biofilm formation of CRAB and MRSA isolates by ¼ MIC concentration (2 μg/mL) and ½ MIC concentration (2 μg/mL), respectively. Polydopamine (4-(2-aminoethyl)benzene-1,2-diol, PDA) has strong hydrophilicity and biocompatibility, and Na Xu et al. [68] designed ferrous sulfide-polydopamine nanoparticles (PDA@FeS NPs) in which ferrous and sulfur ions preserve normal body physiology. The photothermal antibacterial activities of PDA@FeS NPs were very effective against both E. coli and S. aureus. When hydrogen peroxide is present, the near-infrared (NIR) light-mediated release of ferrous ions under weakly acidic conditions (approximately 26.5%) caused the generation of harmful hydroxyl radicals (.OH), which caused bacterial cell membrane damage and content leakage. PDA@FeS NPs’ germicidal properties offer a fresh approach for creating new antibacterial platforms. Moreover, Li et al. [69] created a positively charged porphyrin iron-based porous organic polymer called FePPOP_Hydantoin that generates a significant quantity of hydroxyl radicals. FePPOP_Hydantoin provided strong near-infrared (NIR) absorption, superior stability, high density of surface catalytic centers, and reproducibility. In addition, it gave a multi-amplified antibacterial efficacy by combining photo-Fenton and peroxidase mimetic catalytic treatment. The efficiency of the nanozymes against bacterial infection was demonstrated in an in vivo study using infected mice with S. aureus. Furthermore, at the nanoscale range, diamagnetic silver nanoparticles (Ag) are renowned for their antiviral, anticancer, and antibacterial effects. El-Bassuony [70] investigated the results of combining ferromagnetic (cobalt) and paramagnetic (copper) components with silver-magnetite nanoparticles. The results demonstrated that, compared to copper nanoferrite (CuAF), cobalt nanoferrite/silver-magnetite (CoAF) nanocomposites produced a more dramatic effect in the magnetic experiments. This is due to the higher coercivity Hc and saturation magnetization Ms of CoAF. Both nanocomposites shown robust antimicrobial activities when tested against Gram-positive and Gram-negative bacteria, indicating the potential application of nanomaterials as antibacterial agents. Human alpha-defensin 5 (HD5) antimicrobial peptide (AMP) was coupled with myristic acid (tetradecanoic acid) to produce Myristoylated HD5 nanobiotics in a method utilized by Lei et al. [71] to induce self-assembly. Cationicity and hydrophobicity are both critical for killing Gram-positive and Gram-negative bacteria. Human alpha-defensins clustered in nanoassemblies combine these two characteristics for efficiently killing bacteria. Furthermore, the nanobiotic showed resistance to proteolytic degradation in vivo, and minimization of renal excretion due to increased molecular size which led to the improvement of the bioavailability of the HD5-myr nanobiotic. The self-assembled nanobiotic shown improved broad-spectrum bactericidal action specifically against E. coli and MRSA by disrupting the cell wall and possibly other membrane structures, according to in vitro data. Excellent tolerability was also demonstrated in in vivo testing, where it was discovered that the nanobiotic could protect mice from MRSA skin infections and save them from E. coli-induced sepsis [72].

5.2. Computational Methods in the Development of New Antibacterial Agents

5.3. Antibiotic Alternatives

6.2. Piperidinol

A piperidinol-containing molecule (PIPD1) (88, Scheme 3) has been discovered to be a powerful lead agent against M. tuberculosis using high-throughput whole-cell screening of a large compound library [197]. Non-tuberculous pathogen Mycobacterium abscessus is resistant to the majority of antibiotics and disinfectants. De Ruyck et al. study’s [198] concentrated on the creation and synthesis of piperidinol derivatives (PIPD1) that specifically target the flippase activity of the mycolic acid transporter MmpL3. By first treating 4-piperidinone monohydrate hydrochloride (84) with α-Bromo-O-xylene (85) to produce a bromine derivative (86), which was then treated with n-butyl lithium solution to produce PIPD1 analogues, the PIPD1 analogues were created (87). The results demonstrated that MmpL3 inhibition can result in the pathogen’s immediate death. Moreover, it can have synergistic effects by making it easier for other chemicals such as β-lactams to get through the mycobacterium’s wall. The two steps of N-benzylation and the bromine-lithium exchange reaction were used to make PIPD1 (Scheme 3). The two aromatic moieties A and B (Scheme 3) and the steric hindrance of the substituent on ring B are essential for the inhibitory activity against M. abscessus, according to structural-activity relationship (SAR) investigations of PIPD1 analogues.

6.3. Sugar-Based Bactericides

All organisms use chemicals with a carbohydrate foundation for energy, and some microbial organisms can be inhibited by these substances. Gram-negative and Gram-positive microorganisms have been shown to be resistant to the broad-spectrum antimicrobial action of monosaccharide analogs [199,200]. Methyl β-D-galactopyranoside (β-MGP) (89, Scheme 4) was reacted with 4-bromobenzoyl chloride to produce 6-O-(4/3-bromobenzoyl) (90, 91), as well as its 2,3,4-tri-O-acyl derivatives (92, 93), by Ahmmed et al. [201]. The antibacterial activity of the compounds was investigated in vitro and in silico. The results showed that the biological activities of the compounds were enhanced by the β-MGP structure with various aliphatic and aromatic substituents. This was supported by molecular docking, which revealed promising interactions and binding energies with bacterial and fungal proteins, making them potential antibacterial/antifungal candidates.

To evaluate their effectiveness against Gram-positive and Gram-negative bacteria in vitro, Dias et al. [202] synthesized a number of carbohydrate-based compounds derived from iso-quinoline-5,8-dione and naphthoquinone (94, 95 Figure 14), as well as their halogenated derivatives (96, 97 Figure 14). With MIC and MBC ranges of 4–64 µg/mL against Gram-negative bacteria, the compounds showed promising bactericidal activity. Only non-glycoconjugate naphthoquinones showed activity against particular Gram-positive bacteria. In a different study, Dias et al. [203] investigated deoxy glycosides as effective and selective bactericides that target PE and examined their efficacy against the indicated bacteria. Their study focused on Bacillus anthracis and B. cereus membranes that are rich in phosphatidyl-ethanolamine (PE). The results demonstrated that the deoxygenation pattern is a critical modulator for efficacy and selectivity and that the bactericidal activity was due to membrane disruption and highly permeable activity across the phosphatidylethanolamine membranes of B. anthracis and B. cereus.

6.4. Isoxazole Derivatives

The enteric bacterial infections, which are primarily brought on by S. aureus and E. coli, are one of the main causes of morbidity in poor nations. Amoxicillin, norfloxacin, and ciprofloxacin are the main antibiotics used to treat E. coli; however, they also have some adverse effects in addition to toxicity and drug resistance [204]. An important physicochemical factor that influences membrane permeability and medication absorption is lipophilicity. Isoxazoles and isoxazolines, which are heterocyclic compounds with nitrogen and oxygen, exhibit a variety of biological and pharmacological effects, including antitubulin, anti-inflammatory, antinociceptive, and anxiolytic activity. Sulfisoxazole and sulfamethoxazole, two β-lactam antibiotics, contain the five-membered heterocyclic ring known as isoxazole. Ahmad et al. [205] created isoxazole derivatives of fatty acids to prevent the growth of most pathogenic fungi, Gram-positive, and Gram-negative bacteria. Through 1,3-dipolar cycloaddition of nitrile oxide to lengthy chains of an alkene and an alkyne, the compounds were created (Scheme 5). Long-chain alkynoic acids (98) and long-chain alkenoates (100) were employed as the starting materials for the synthesis of 3,5-disubstituted isoxazole (99) and 3,4,5-trisubstituted-4,5-di-hydroisoxazole (101). Using PASS software, biological activity of these chemicals was predicted, supporting their historical use as antibacterial agents. Furthermore, physicochemical data demonstrated that the majority of the compounds had drug-like characteristics, with MIC decreasing with increasing lipophilicity, a finding that suggested the compounds had antibacterial capabilities. In addition to their antibacterial properties, the compounds were also tested against yeast, and the results revealed antifungal efficacy against the tested clinical species of Candida. Docking studies with the 30s ribosomal subunit revealed agreement with in vitro measurements of microbial activity as well as a near proximity to the ciprofloxacin binding site. All chemicals share a similar fundamental structure; however, variable levels of interaction and binding patterns were discovered. These results could aid in the development of new antifungal medications that target microbial protein production.

The polycyclic aromatic compound acridone, which has anticancer and antibacterial properties, was used by Aarjane et al. [206] to create isoxazole derivatives. By combining two possible pharmacophores, acridone and isoxazole; nitrile oxides and N-propargyl acridone underwent a 1,3-dipolar cycloaddition process (Scheme 6). Before being cyclized with polyphosphoric acid to create compounds (103), o-bromobenzoic acid was first reacted with p-toluidine or aniline to create 2-arylamino benzoic acids (102). Acridone derivatives were refluxed with propargyl bromide to produce 2-methyl-10-(prop-2-yn-1-yl)- acridone (104). Reacting with various nitrile oxides produced 3,5-disubstituted isoxazoles (105). Four harmful bacterial strains were used to test the compounds’ antibacterial efficacy (Pseudomonas putida, K. pneumoniae, E. coli, and S. aureus). These germs were resistant to the compounds’ moderate-to-good antibacterial activity. The isoxazole-acridone skeleton’s paranitrophenyl groups had the strongest antibacterial action against E. coli strains. To investigate the occupancy mode at the receptor pocket responsible for antibacterial activity, molecular docking of the drugs was carried out. The explanation for a compound’s antibacterial activity may be due to hydrogen bonds and hydrophobic interactions in the DNA topoisomerase E. coli receptor active site.

The parasitic infections known as leishmaniases are mostly spread by Leishmania donovani. For the creation of novel antileishmanial chemotherapeutics with enhanced efficacy and less toxicity, Tipparaju et al. [207] synthesized 2- [3-Hydroxy-2- [(3-hydroxypyridine-2-carbonyl)-amino]-phenyl]-benzoxazole-4-carboxylic acid (A–33853) antibiotic (113, Scheme 7) and a number of its derivatives and were tested for biological activity. Compound (113), a benzoxazole natural product with strong antibacterial action, was discovered a few decades ago in a culture broth of Streptomyces sp. NRRL 12068. Early testing revealed that the A-33853 (113) substance is three times as active as miltefosine, a medicine used to treat leishmaniasis, in inhibiting the growth of L. donoVani, T. b. rhodesiense, T. cruzi, and P. falciparum cultures. With substantially lower cytotoxicity, certain analogs selectively inhibited L. donoVani at nanomolar concentrations. The oxidative cyclization of the base (106) or through the cyclization-dehydration reaction of amide (107) were the two methods used to create the benzoxazole intermediate (108, Scheme 7). The amine (109) produced by the reduction in the nitro group in the intermediate (108) was linked with the 3-benzoyloxypicolinic acid (111) which was created from (110) to produce the intermediate (112). Antibiotic (113) was produced after BBr3 treatment in an excellent overall yield.

6.5. Carbazole

Other substances include carbazoles, which have generated a lot of attention for research into their potential as antibacterial agents. Carbazole is an aromatic heterocycle that contains nitrogen and occurs naturally and synthetically. Its ring is present in a number of drugs that have medical use, including carbazomycins and murrayafoline A [208,209,210]. Carbazoles may also be able to interact electrostatically or by intercalation to attach to DNA non-covalently [211]. 5-membered azoles can be introduced into the N-position of carbazole to suppress the growth of bacteria and fungi. Their effectiveness has been demonstrated to be superior to that of the reference medications Norfloxacin and Chloromycin. Making novel antibacterial agents has been a big topic for modification of the carbazole ring at the 3- and 6-positions [212]. The easiest way to create novel antimicrobial agents is to introduce 2-aminothiazole into the 3- and 6-positions of the carbazole backbone, as this other agent known as aminothiazole is found in many clinical antimicrobial medications, such as Cephalosporins, Aztreonam, Sulfathiazole, and others [210]. By reacting carbazole (114, Scheme 8) with various N-alkyl bromides to produce N-alkylcarbazole intermediates (115), Addla et al. [210] created novel carbazole aminothiazoles (Scheme 7). Halogenated carbazoles (116) were then produced by reacting chloroacetyl chloride with the intermediates, which were then fluxed with thiourea to create the aminothiazoles (117). The compounds’ antibacterial efficacy against Gram positive, Gram negative, and fungal organisms was assessed in vitro. Structure–activity relationships (SAR) revealed that the aminothiazole component was crucial for exerting biological activities, whereas the length of the alkyl chain affected the antibacterial efficacies. A carbazole aminothiazole molecule with a minimal inhibitory concentration (MIC) of 4 µg/mL, which outperformed the reference medications chloromycin and norfloxacin, showed negligible cytotoxicity to Hep-2 cells and good antibacterial activity against MRSA. Moreso, it was discovered that the substance interacts with DNA via hydrogen bonds and electrostatic interactions, which may prevent DNA replication and, as a result, have antimicrobial effects.

An innovative series of carbazole compounds was created by Xue et al. [213] (Scheme 8). The chemicals were first made by N-alkylating or arylating carbazole (114), which produced intermediates (118). Compounds (118) and (119) were then put through a formylation reaction (Vilsmeier–Haack) to produce 9-substituted carbazole-3-carbaldehyde analogues (120) that were then reacted with four other substances—metformin hydrochloride (121), aminoguanidine hydro-chloride/or thiosemicarbazide (123), and isonicotinic moiety (125)—to create carbazole (122, 124, and 126, Scheme 9). The substances had strong inhibitory effects against a variety of bacterial strains, including an isolate that was multidrug resistant. Dihydrotriazine group boosted antibacterial potency and decreased the toxicity of the carbazole compounds, according to SAR and docking tests. Moreover, in vitro enzyme activity studies demonstrated that the antibacterial effect of compounds binding to dihydrofolate reductase may be the cause of the effect

6.6. Pyrimidine Derivatives

Pyrimidine amine derivatives with two nitrogen atoms in the aromatic ring and a substituted amino outside have shown antibacterial and antiviral activities. Zhang et al. [214] synthesis and characterized pyrimidine amine derivatives containing bicyclic monoterpene moiety and evaluated their antimicrobial activity. Results showed that most of the compounds have antibacterial and antifungal activities against K. pneumoniae, Streptococcus pneumoniae, P. aeruginosa, S. aureus, E. coli, MRSA, Bacillus cereus, and C. albicans. Starting from aldehyde-ketone condensation reaction and in the presence of sodium methoxide or potassium tert-butoxide, a pinanyl ketene intermediates (127, Scheme 10) were synthesized. Cyclization of (127) with guanidine hydrochloride produced Pinanyl pyrimidines (128). Further substitution with haloalkanes generated Pinanyl pyrimidine amines (129). As for camphor, condensation with p-methoxybenzaldehyde generated the intermediate (130, Scheme 10), which was followed by cyclization with guanidine hydrochloride to afford the camphorylpyrimidine intermediate (131). Camphoryl pyrimidineamine compounds were finally obtained by substitution of (132) with alkyl.

Irrational use of pesticides leads to the emergence of drug resistance. The need for the development of a new broad-spectrum pesticide to control plant pests and disease infestations led Li et al. [215] to combine pyrimidine with sulfonate ester for the development of interesting bioactive compounds. A novel series of pyrimidine derivatives containing sulfonate esters were designed. Result showed that the synthesized compounds exhibited good antibacterial activity with certain insecticidal activity against Xanthomonas axonopodis pv. Citri (Xac), Xanthomonas oryzae pv. Oryzae (Xoo), Ralstonia solanacearum (Rs), and Pseudomonas syringae pv. actinidiae (Psa), which provided insight for the designing of new broad-spectrum pesticides. Synthesis of the compounds started from cyclization reaction using ethyl glycolate which produced the intermediate (6-methyl-2-thioxo-2,3-dihydropyrimidin4(1H)-one) methanol (133, Scheme 11) that was converted into thioether derivatives (134, 135, and 136) by thioetherification with CH₃I, C₂H₅I, and Benzyl chloride. The final compounds (137, 138, and 139) were obtained by esterification with RSOOCl.

7.1. Siderophores

Using the bacteria’s nutrition absorption pathway to carry medications into the cells is one method for enhancing the effectiveness of antibiotics. A very promising tactic is to inject antibiotics into the bacteria through the iron absorption pathway. By using siderophores, which are low-molecular weight organic chelators (150 to 2000 Da) that are rich in the heteroatoms oxygen and nitrogen, microorganisms have evolved a highly effective mechanism for the uptake of iron. Bacteria produce siderophores, which are then released into the environment to chelate iron with an extremely high affinity [227]. In order to treat Enterobacteriaceae that are multidrug resistant (MDR) and carbapenem resistant (CR), including K. pneumoniae, cefiderocol (CFDC) (149, Figure 15) binds to penicillin-binding proteins, inhibiting the formation of peptidoglycan and ultimately killing the bacteria [228,229]. Using the Gram-negative bacteria’s outer membrane-located iron transport mechanism or passive diffusion, CFDC binds to ferric iron (Fe³⁺) and passes into the periplasmic region, where it detaches iron and enables the presentation of CFDC in large concentrations [230,231]. In their study of the susceptibility of Klebsiella pneumoniae to CFDC under iron-depleted and iron-enriched environments, Daoud et al. [229] discovered that CFDC had a susceptibility of 96.1%, which was higher than that of any other antibiotic. The findings also demonstrated that CFDC MICs increased in iron-enriched media where iron uptake receptors (fecA and/or kfu) are expressed, resulting in a loss of drug activity. In contrast, the presence of enterobactin receptors (fepA) is essential for capturing the drug and allowing its entry into the periplasm. As a result, with different iron acquisition mechanisms, bacteria may not be as dependent on the development of siderophores, which would reduce the uptake of catechol-CFDC. A siderophore-antibiotic compound (150, Figure 15) was created by Zheng and Nolan [232] by joining antibiotics with enterobactin, a tricatecholatesiderophore. Amoxicillin and amoxicillin, two β-lactam medicines, were joined to enterobactin via a polyethylene glycol linker. The combination increased β-lactam activity against E. coli, allowing enterobactin to carry antibiotics through Gram-negative membranes more effectively. An Enterobactin-ciprofloxacin compound (151, Figure 15) with an alkyl linker was created by Neumann et al. [233]. The cytoplasmic esteraseIroD enzyme, which is exclusively expressed in E. coli, activates the prodrug intracellularly. By employing a Gram-positive medication with three components—oxazolidinone antibiotic, cephalosporin, and bis-catechol-based siderophore conjugates—Liu et al. [234] created an elegant method to kill Gram-negative bacteria (152, Figure 15). The conjugates take advantage of the periplasmic β-lactamases that cleave the β-lactam ring of the cephalosporin to release the oxazolidinone, which then crosses the bacterial inner membrane and reaches its intracellular ribosomal target and kills the Gram-negative bacteria. The conjugates also take advantage of the bacterial ferri-siderophore uptake transporters for efficient passage through the outer membrane. To tackle P. aeruginosa species, Loupias et al. [235] created two piperazine-based siderophore mimics with catechol or hydroxypyridone chelating groups (153, 154, Figure 15). Unfortunately, the complexes exhibited no antibacterial action, although they could be employed as antibiotic transporters against Pseudomonas species. The two compounds demonstrated a strong affinity for Fe(III) and were used to internalize gallium as a hazardous metal. A Siderophore-linked ruthenium catalyst (155, Figure 15) for the activation of an antibacterial prodrug inside cells was created and examined by Southwell et al. [236]. Due to its tiny size and hydrophilic nature, the fluoroquinolone antibiotic moxifloxacin (156, Figure 15) is mostly absorbed by bacteria through porins. The drug was derivatized at the N or C termini to provide allyl carbamate (N-moxi) (157, Figure 15) or allyl ester prodrugs (C-moxi) (158, Figure 15) to boost bacterial uptake through passive membrane diffusion in response to an increase in porin deficiency-associated resistance. Only C-moxi was used in bacterial experiments to explore its activation in the presence of a variety of siderophore-linked ruthenium catalysts against E. coli K12 (BW25113) due to N-poor moxi’s solubility. The results demonstrated that the combination of catalysts and prodrugs had an antibacterial impact, with the azotochelin- and dihydroxybenzoic acid-linked catalysts demonstrating the most promising cellular uptake and intracellular prodrug activation. An anticancer cisplatin prodrug (cis, cis, trans– [Pt(NH₃)₂Cl₂(OOCCH₃)(OH)] and l/d enterobactin enantiomer) was produced in a recent work by Guo and Nolan [237] (159, Figure 15). The enterobactin-mediated delivery of the platinum(IV) prodrug into the cytoplasm increased its accumulation more than ten times compared to cisplatin treatment, and the conjugate demonstrated antibacterial activity against specific strains of E. coli where it causes bacterial growth inhibition and filamentation. This paper reveals a siderophore attachment method for medication repurposing.

7.2. Carbapenem-Oxazolidinones

By combining numerous pharmacophores in one molecule, it is possible to find novel medications without having to look for new targets and may even be possible to overcome resistance. In this study, oxazolidinones, a synthetic antibacterial drug that inhibits protein synthesis by binding to the 23S RNA region, were conjugated to carbapenem, a powerful β-lactam antibiotic, via a thioether link to create a series of carbapenem-oxazolidinone hybrids (163, Scheme 14). The intermediate (162) was first produced by coupling prepared oxazolidinonemethyl-thiols (160, Scheme 10) with carbapenem diphenylphosphate (161) in the presence of diisopropylethylamine, and the hybrids were then produced by deprotecting intermediate (162) through catalytic hydrogenation [238].

7.3. Oral GyrB/ParE Dual Binding Inhibitor

Finding novel target sites is necessary due to the growing antibiotic resistance brought on by binding site mutations. For the development of dual-targeting antibacterial drugs, the ATP-binding subunits of DNA gyrase (GyrB) and topoisomerase IV (ParE) are ideal candidates [239,240]. A. baumannii, P. aeruginosa, and K. pneumoniae resistant strains are just a few examples of the Gram-positive and Gram-negative bacterial pathogens that can be effectively treated with a dual-targeting tricyclic class pyrimidoindole inhibitor (TriBE inhibitor) against GyrB and ParE enzymes [241]. The tricyclic pyrimidoindole small molecule compound JSF-2414 (8-(6-fluoro-8-(methylamino)-2-((2-methylpyrimidin-5-yl)oxy) -9H-pyrimido [4,5-b]indol-4-yl)-2-oxa-8-azaspiro [4.5]decan-3-yl)methanol and JSF-2659, the phosphate prodrug’s in vitro and in vivo properties, were described by Park et al. [242] (164, 165, Figure 16). The prodrug JSF-2659 swiftly and completely converts to its active form JSF-2414 by host phosphatases to demonstrate significant efficacy against N. gonorrhoeae and its resistant strains. JSF-2659 prodrug exhibited high efficacy in decreasing microbial burdens and resistance.