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Yakobi, S.; Pooe, O. Evolution of Antimicrobial Resistance. Encyclopedia. Available online: https://encyclopedia.pub/entry/22746 (accessed on 04 July 2024).
Yakobi S, Pooe O. Evolution of Antimicrobial Resistance. Encyclopedia. Available at: https://encyclopedia.pub/entry/22746. Accessed July 04, 2024.
Yakobi, Sinethemba, Ofentse Pooe. "Evolution of Antimicrobial Resistance" Encyclopedia, https://encyclopedia.pub/entry/22746 (accessed July 04, 2024).
Yakobi, S., & Pooe, O. (2022, May 10). Evolution of Antimicrobial Resistance. In Encyclopedia. https://encyclopedia.pub/entry/22746
Yakobi, Sinethemba and Ofentse Pooe. "Evolution of Antimicrobial Resistance." Encyclopedia. Web. 10 May, 2022.
Evolution of Antimicrobial Resistance
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This entry is adapted from the peer-reviewed paper 10.3390/bacteria1020009

Neisseria gonorrhoeae has become a significant global public health problem due to growing infection rates and antibiotic resistance development. In 2012, N. gonorrhoeae positive samples isolated from Southeast Asia were reported to be the first strains showing resistance to all first-line antibiotics. To date, N. gonorrhoeae’s antimicrobial resistance has since been identified against a wide range of antimicrobial drugs globally. Hence, the World Health Organization (WHO) listed N. gonorrhoeae’s drug resistance as high-priority, necessitating novel therapy development. The persistence of N. gonorrhoeae infections globally underlines the need to better understand the molecular basis of N. gonorrhoeae infection, growing antibiotic resistance, and treatment difficulties in underdeveloped countries.

Neisseria gonorrhoeae antimicrobial-resistance gonococcal infection drug-resistance

1. Sulphonamides

Sulphonamides were first used to treat N. gonorrhoeae in the 1930s; however, by 1944, 75% of World War II soldiers in the Italian army had experienced treatment failure with these drugs. Sulphonamide antimicrobials compete with the dihydropteroate synthetase (DHPS) enzyme in the production of folic acid[1]. Resistance is established by increasing the production of the standard substrate, p-aminobenzoic acid, or by creating a mutant DHPS with a poor affinity for the antibiotic[2]. In the 1960s, combination therapy with trimethoprim was offered as an alternative to increasing the efficacy of sulphonamide in treating uncomplicated N. gonorrhoeae infections. Trimethoprim prevents susceptible N. gonorrhoeae from converting dihydrofolate to tetrahydrofolate in the metabolic pathway performed by the dihydrofolate reductase (DHFR) enzyme[3]N. gonorrhoeae DHRF, on the other hand, has a low affinity for trimethoprim and may be genetically changed, making the bacterium less susceptible to this antibiotic[4]. Until the 1970s, the synergic combination of sulphonamides and trimethoprim was utilised to treat gonorrhoeae in high and multi-dose treatment schemes. These drugs inhibit bacterial folic acid synthesis by targeting the bacterial dihydropteroate synthase (DHPS) enzymes[1]. Over synthesis of p-aminobenzoic acid, which dilutes the antimicrobial agent, or changes in the folP gene (point mutations or the presence of a mosaic gene containing DNA sequences from commensal Neisseria spp.), which encodes the drug target DHPS, can cause sulphonamide resistance[5]. The modifications to DHPS result in a significantly reduced affinity for sulphonamide agents as well as bacteriostatic activity[6].

2. Penicillin

Penicillin was introduced as an antibacterial therapy for N. gonorrhoeae in 1943, notably when sulphonamide treatment failed. Penicillin worked by inhibiting the bacterial cell wall production by binding to transpeptidase enzymes in the periplasm of penicillin-binding proteins (PBP). Therefore, penicillin resistance mechanisms in N. gonorrhoeae were linked to reduced sensitivity by cumulative chromosomal changes in various genes associated with cell wall production (penA and penA1) or structures influencing periplasmic drug concentration[1]. However, in the 1960s, penicillin had reduced susceptibility against Neisseria gonorrhoeae. In the 1970s, N. gonorrhoeae isolates had MICs of up to 128 g/mL, thus ending the penicillin era; however, in the 1960s, penicillin had reduced susceptibility against N. gonorrhoeae therapy[7]. The newly discovered resistance mechanism was a plasmid-mediated β-lactamase (bla) gene type TEM (blaTEM), and the isolates were dubbed penicillinase-producing N. gonorrhoeae (PPNG). The plasmids carried by N. gonorrhoeae blaTEM are genetically similar but have various sizes, insertion, or deletion sites and are termed according to their epidemiological origin. The African (5588 bp) is one of the most frequently reported bla-plasmids in N. gonorrhoeae isolates[8].

3. Tetracycline

In the 1950s, tetracycline was offered as a therapeutic alternative for N. gonorrhoeae in individuals allergic to penicillin. Overexpression of penB and mtr in N. gonorrhoeae isolates inhibited tetracycline action, thus establishing an emergence of tetracycline-resistant Neisseria gonorrhoeae [9]. In 1985, the first N. gonorrhoeae isolates with high-level tetracycline resistance (MIC 24–32 g/mL) were isolated; this was said to be a result of the expression of the TetM protein. The emergence of this resistance was the initiation of the quinolone era in N. gonorrhoeae therapy. Tetracyclines limit aminoacyl-tRNA binding to the mRNA-ribosome complex, mostly through binding to the 30S ribosomal subunit, and hence reduce protein synthesis, resulting in a bacteriostatic effect[1][10]. Chromosomally-mediated tetracycline resistance in gonococci is caused by mutations that change the structure of the ribosomal protein (target), which interacts with resistance determinants to enhance efflux and reduce the inflow of tetracycline[11].

4. Quinolone

Ciprofloxacin was developed in 1983 and released to the market in the late 1980s. Initially, ciprofloxacin was used to treat N. gonorrhoeae in a single dosage of 250 mg[1]. However, the Centers for Disease Control and Prevention (CDC) initially recommended 500 mg of ciprofloxacin in a single dose treatment. Although isolates with reduced susceptibility (MIC 0.25 g/mL) had been detected before 1989, and despite numerous therapeutic failures reported during the 1990s, ciprofloxacin therapy continued to be used at the exact dosage globally for an additional 10–25 years depending on the country[12]. Quinolones interfere with the activity of DNA gyrase and topoisomerase IV, two topoisomerases that are required for DNA replication, transcription, recombination, and repair[13]. Quinolone antibiotics create a drug–enzyme–DNA complex and then release double-stranded DNA breaks. Resistance to ciprofloxacin in N. gonorrhoeae is mediated by mutations in the quinolone resistance-determining region (QRDR), situated near the topoisomerase’s DNA binding site. Bacterial DNA gyrase and topoisomerase IV are type II topoisomerases that are required for DNA metabolism[12]. They work by breaking and reconnecting double-stranded DNA in an ATP-dependent process. Quinolones provide bactericidal effects via inhibiting DNA gyrase and topoisomerase IV[1].

5. Azithromycin

In the early 1980s, azithromycin was proposed as a potential treatment for Neisseria gonorrhoeae. This macrolide inhibits peptidyl transferase polypeptide chain elongation by interacting with the P site of the 50S ribosomal subunit. Various elements may influence azithromycin activity in Neisseria gonorrhoeae. One of these is the overexpression of the efflux pump mtrCDE, which is guided by the same molecular processes that have been found to reduce N. gonorrhoeae sensitivity to penicillin, raising the azithromycin MIC to 0.5 g/mL[7]. The development of mutations in the L4 ribosomal protein is another cause of azithromycin resistance development. Resistance to azithromycin develops when mutations occur directly in this 23S rRNA domain[14]. Mutations of A2143G or C2599T found in one to four rrl gene alleles encoding the 23S RNA result in azithromycin resistance[15]. In recent years, N. gonorrhoeae with a high level of azithromycin resistance has evolved. The first incidence occurred in 2001, and since then, high-level azithromycin resistance has been detected in many Sub-Saharan countries[3]. By attaching to the 50S ribosomal subunit, macrolides impair protein synthesis by impeding peptidyl-tRNA translocation, blocking the peptide exit channel in 50S subunits by interacting with 23S rRNA, and causing ribosomes to release incomplete polypeptides[1].

6. Ceftriaxone

Previously, ceftriaxone was the drug of choice for N. gonorrhoeae infections. Ceftriaxone aids by binding to PBP2 with great affinity; however, recently, it has been noted that N. gonorrhoeae sensitivity to this antibiotic declined rapidly, and resistance rates have reached 30%. Changes in the penBmtrR, and penC genes enhance ceftriaxone resistance, and mutations in the penA gene, which encodes PBP2, appear to be the primary ceftriaxone resistance determinant[16]. The changed PBP2 has a lower affinity for ceftriaxone, and resistance to ceftriaxone is characterised by MIC > 0.5 μg/mL by CDC, and most ceftriaxone resistance has been related to the presence of different patterns of PBP2[1]. The rise of ceftriaxone-resistance in N. gonorrhoeae and the lack of a new therapeutic option for N. gonorrhoeae prompted dual therapy regimens using ceftriaxone and azithromycin. Cephalosporins, like other -lactam antibiotics, block peptidoglycan cross-linking inside the bacterial cell wall by binding the -lactam ring to PBPs (transpeptidases), resulting in bactericidal action[17]. Cephalosporin resistance in gonococci is caused mostly by mutations that alter the target proteins (PBPs), but it can also be attributed to increased efflux and decreased inflow of cephalosporin[1].

References

  1. Ana Paula Ramalho Da Costa-Lourenço; Késia Thaís Barros Dos Santos; Beatriz Meurer Moreira; Sergio Eduardo Longo Fracalanzza; Raquel Regina Bonelli; Antimicrobial resistance in Neisseria gonorrhoeae : history, molecular mechanisms and epidemiological aspects of an emerging global threat. Brazilian Journal of Microbiology 2017, 48, 617-628, 10.1016/j.bjm.2017.06.001.
  2. Jose M. Munita; Cesar A. Arias; Mechanisms of Antibiotic Resistance. Virulence Mechanisms of Bacterial Pathogens 2016, 4, 481-511, 10.1128/9781555819286.ch17.
  3. Birkneh Tilahun Tadesse; Elizabeth A. Ashley; Stefano Ongarello; Joshua Havumaki; Miranga Wijegoonewardena; Iveth J. González; Sabine Dittrich; Antimicrobial resistance in Africa: a systematic review. BMC Infectious Diseases 2017, 17, 1-17, 10.1186/s12879-017-2713-1.
  4. J L Fourie; F M Claassen; J J Myburgh; Causative pathogens and antibiotic resistance in community-acquired urinary tract infections in central South Africa. South African Medical Journal 2021, 111, 124-128, 10.7196/samj.2021.v111i2.14905.
  5. Magnus Unemo; William M. Shafer; Antimicrobial Resistance in Neisseria gonorrhoeae in the 21st Century: Past, Evolution, and Future. Clinical Microbiology Reviews 2014, 27, 587-613, 10.1128/cmr.00010-14.
  6. Gonorrhea. Diagnostics to Pathog Sex Transm Infect . NICD. Retrieved 2022-5-10
  7. Beata Młynarczyk-Bonikowska; Anna Majewska; Magdalena Malejczyk; Grażyna Młynarczyk; Sławomir Majewski; Multiresistant Neisseria gonorrhoeae: a new threat in second decade of the XXI century. Medical Microbiology and Immunology 2019, 209, 95-108, 10.1007/s00430-019-00651-4.
  8. Santhuri Rambaran; Kavitha Naidoo; Navisha Dookie; Prashini Moodley; Adriaan Willem Sturm; Resistance Profile of Neisseria gonorrhoeae in KwaZulu-Natal, South Africa Questioning the Effect of the Currently Advocated Dual Therapy. Sexually Transmitted Diseases 2019, 46, 266-270, 10.1097/olq.0000000000000961.
  9. Mary Wandia Kivata; Margaret Mbuchi; Fredrick Eyase; Wallace Dimbuson Bulimo; Cecilia Katunge Kyanya; Valerie Oundo; Wilton Mwema Mbinda; Willy Sang; Ben Andagalu; Olusegun O. Soge; et al.Raymond Scott McClellandJohn Distelhorst Plasmid mediated penicillin and tetracycline resistance among Neisseria gonorrhoeae isolates from Kenya. BMC Infectious Diseases 2020, 20, 1-11, 10.1186/s12879-020-05398-5.
  10. Ahmed Elkashif; Mohamed Seleem; Investigation of auranofin and gold-containing analogues antibacterial activity against multidrug-resistant Neisseria gonorrhoeae.. Scientific Reports 2020, 10, 5602-9, 10.1038/s41598-020-62696-3.
  11. Jose M. Munita; Cesar A. Arias; Mechanisms of Antibiotic Resistance. Microbiology Spectrum 2016, 4, 72, 10.1128/microbiolspec.vmbf-0016-2015.
  12. Noemi D’Atanasio; Alessandra Capezzone de Joannon; Laura Di Sante; Giorgina Mangano; Rosella Ombrato; Marco Vitiello; Cristina Bartella; Gabriele Magarò; Federica Prati; Claudio Milanese; et al.Carla VignaroliFrancesco Paolo Di GiorgioSerena Tongiani Antibacterial activity of novel dual bacterial DNA type II topoisomerase inhibitors. PLoS ONE 2020, 15, e0228509, 10.1371/journal.pone.0228509.
  13. Michael D. Huband; Patricia A. Bradford; Linda G. Otterson; Gregory S. Basarab; Amy C. Kutschke; Robert A. Giacobbe; Sara A. Patey; Richard A. Alm; Michele R. Johnstone; Marie E. Potter; et al.Paul F. MillerJohn P. Mueller In Vitro Antibacterial Activity of AZD0914, a New Spiropyrimidinetrione DNA Gyrase/Topoisomerase Inhibitor with Potent Activity against Gram-Positive, Fastidious Gram-Negative, and Atypical Bacteria. Antimicrobial Agents and Chemotherapy 2015, 59, 467-474, 10.1128/aac.04124-14.
  14. Cau D. Pham; Samera Sharpe; Karen Schlanger; Sancta St. Cyr; Justin Holderman; Richard Steece; Olusegun O. Soge; Godfred Masinde; Janet Arno; Matthew Schmerer; et al.Ellen N. Kershthe SURRG Working Group Emergence of Neisseria gonorrhoeae Strains Harboring a Novel Combination of Azithromycin-Attenuating Mutations. Antimicrobial Agents and Chemotherapy 2019, 63, 1-8, 10.1128/aac.02313-18.
  15. Magnus Unemo; H Steven Seifert; Edward W. Hook; Sarah Hawkes; Francis Ndowa; Jo-Anne R. Dillon; Gonorrhoea. Nature Reviews Disease Primers 2019, 5, 1-23, 10.1038/s41572-019-0128-6.
  16. Magnus Unemo; Current and future antimicrobial treatment of gonorrhoea – the rapidly evolving Neisseria gonorrhoeae continues to challenge. BMC Infectious Diseases 2015, 15, 1-15, 10.1186/s12879-015-1029-2.
  17. Lilith K. Whittles; Peter J. White; John Paul; Xavier Didelot; Epidemiological Trends of Antibiotic Resistant Gonorrhoea in the United Kingdom. Antibiotics 2018, 7, 60, 10.3390/antibiotics7030060.
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Sinethemba Yakobi
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Ofentse Pooe
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Entry Collection: Biopharmaceuticals Technology
Revisions: 2 times (View History)
Update Date: 11 May 2022
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