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Ngeow, Y.F.; , . Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms. Encyclopedia. Available online: https://encyclopedia.pub/entry/22595 (accessed on 14 May 2024).
Ngeow YF,  . Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms. Encyclopedia. Available at: https://encyclopedia.pub/entry/22595. Accessed May 14, 2024.
Ngeow, Yun Fong, . "Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms" Encyclopedia, https://encyclopedia.pub/entry/22595 (accessed May 14, 2024).
Ngeow, Y.F., & , . (2022, May 05). Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms. In Encyclopedia. https://encyclopedia.pub/entry/22595
Ngeow, Yun Fong and . "Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms." Encyclopedia. Web. 05 May, 2022.
Mycobacteroides abscessus and Its Tigecycline Resistance Mechanisms
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This entry is adapted from the peer-reviewed paper 10.3390/antibiotics11050572

Mycobacteroides abscessus (formerly Mycobacterium abscessus) is a clinically important, rapid-growing non-tuberculous mycobacterium notoriously known for its multidrug-resistance phenotype. The intrinsic resistance of M. abscessus towards first- and second-generation tetracyclines is mainly due to the over-expression of a tetracycline-degrading enzyme known as MabTetX (MAB_1496c). Tigecycline, a third-generation tetracycline, is a poor substrate for the MabTetX and does not induce the expression of this enzyme. Recent work on tigecycline resistance or reduced susceptibility in M. abscessus revealed the involvement of the gene MAB_3508c which encodes the transcriptional activator WhiB7, as well as mutations in the sigH-rshA genes which control heat shock and oxidative-stress responses. The deletion of whiB7 has been observed to cause a 4-fold decrease in the minimum inhibitory concentration of tigecycline. In the absence of environmental stress, the SigH sigma factor (MAB_3543c) interacts with and is inhibited by the anti-sigma factor RshA (MAB_3542c). The disruption of the SigH-RshA interaction resulting from mutations and the subsequent up-regulation of SigH have been hypothesized to lead to tigecycline resistance in M. abscessus.

Mycobacteroides abscessus tigecycline resistance mechanisms

1. Introduction

1.1. Tigecycline

Tigecycline is the first and only clinically available glycylcycline (a new class of tetracycline). It is a minocycline derivative, with an N,N-dimethyglycylamido moiety attached to the 9′ carbon on the tetracycline four-ringed skeleton [1]. Like other tetracyclines, tigecycline is a bacteriostatic antibiotic which inhibits translation by binding to the A site of the 30S ribosomal subunit (made up of the 16S rRNA and ribosomal proteins) [2]. The protein-synthesis inhibitory activity of tigecycline is 3- and 20-fold more potent than that of minocycline and tetracycline, respectively [3]
Tigecycline is a broad-spectrum antibiotic. It is also active against important drug-resistant pathogens, such as methicillin-resistant Staphylococcus aureus, penicillin-resistant Streptococcus pneumoniae, vancomycin-resistant enterococci, and extended-spectrum beta-lactamase producers [2]. Furthermore, tigecycline is one of the rescue antibiotics, alongside colistin, to treat infections caused by pathogens expressing the New Delhi metallo-beta-lactamase-1 (a carbapenemase) that confers resistance to multiple antibiotics [4].

1.2. The M. abscessus Complex

M. abscessus complex is a species complex, consisting of M. abscessus subspecies abscessusM. abscessus subspecies massiliense and M. abscessus subspecies bolletii (hereafter referred to as M. abscessusM. massiliense and M. bolletii, respectively), that causes a wide spectrum of infections in humans, including but not limited to pulmonary and soft-tissue infections, and disseminated infections [5]. It is also one of the most important pathogens in cystic fibrosis patients [6]. More importantly, this species complex is notorious for its resistance to multiple antibiotics, mediated through its intrinsic features or through chromosomal mutations that arise under the selective pressure of antibiotic use [7]. Thus, the M. abscessus complex poses a major threat to clinical management and public health as treatment options for the infections caused by it are limited.

1.3. Genetic Determinants of Tigecycline Resistance or Reduced Susceptibility in Other Bacteria

Tigecycline resistance has emerged in the past 10 years and is most commonly observed among Gram-negative bacteria, mainly Acinetobacter baumannii and members of the Enterobacteriaceae [8]. The decreased susceptibility or resistance to tigecycline in these clinically important microorganisms has mostly been attributed to the over-expression of resistance-nodulation-cell division-type transporters, including the AcrAB efflux pumps [8]. Moreover, mutations in genes encoding the ribosomal protein S10 [9], a SAM-dependent methyltransferase [10], the acyl-sn-glycerol-3-phosphate acyltransferase [11], and proteins involved in the lipopolysaccharide core biosynthesis [12] have also been linked to tigecycline resistance in Gram-negative organisms. Another mechanism of tigecycline resistance is the TetX-mediated modification of the drug [13]. Tigecycline resistance has also been documented, albeit less frequently, in Gram-positive bacteria [8]. Through the characterization of laboratory-derived mutants, over-expression of MepA (a multidrug and toxic compound extrusion family efflux pump) and mutations in ribosomal genes (16S rRNA, ribosomal proteins and a 16S rRNA methyltransferase) were associated with resistance or decreased susceptibility to tigecycline in S. aureus and S. pneumoniae, respectively [14][15].

2. Genetic Determinants of Resistance or Reduced Susceptibility to Tigecycline in M. abscessus

Although tigecycline-resistant strains of M. abscessus complex have been documented in different parts of the world [16][17], their resistance determinants remain largely elusive. In this entry, the evidence for different genetic determinants reported to be linked to tigecycline resistance or reduced tigecycline susceptibility in the subspecies M. abscessus was examined and discussed. These reported genetic determinants were identified from mutants generated from M. abscessus ATCC 19977, the type strain of M. abscessus.

2.1. An Intrinsic Feature Associated with Reduced Tigecycline Susceptibility: WhiB7

In mycobacteria, WhiB7 is a transcriptional activator of intrinsic antibiotic resistance that can be induced by exposure to stresses, such as heat shock, iron deficiency and redox imbalance, and many antibiotics, including aminoglycosides, lincosamides, macrolides, pleuromutilins and tetracyclines [18][19][20][21]. In 2017, Pryjma et al. found whiB7 (MAB_3508c) to be associated with reduced tigecycline susceptibility in M. abscessus [22]. The deletion of the WhiB7-encoding gene caused a 4-fold decrease in the minimum inhibitory concentration (MIC—minimum inhibitory concentration) of tigecycline. Unfortunately, this group of authors did not identify the downstream effector gene(s) of WhiB7 that is linked to the reduced tigecycline susceptibility. To the best of our knowledge, this constitutes the earliest report on the genetic determinant associated with reduced tigecycline susceptibility in M. abscessus.

2.2. Acquired Tigecycline Resistance: RshA Mutations

In M. abscessus, the sigH gene (MAB_3543c) for the sigma factor SigH and rshA gene (MAB_3542c) for the anti-sigma factor RshA control heat shock and oxidative-stress responses. In the absence of environmental stress, RshA interacts with and inhibits SigH. In response to stress, however, the interaction between RshA and SigH is disrupted, leading to the release of SigH which would then form the RNA polymerase holoenzyme (with the core RNA polymerase) and initiate the transcription of sigH and other genes involved in stress response [23]. Other than heat and redox stress signals, the RshA-SigH interaction can also be disrupted by mutations in the HXXXCXXC motif of RshA [23].
Through the characterization of a tigecycline-resistant, spontaneous mutant of M. abscessus ATCC 19977 (MIC: 0.25 mg/L), designated as 7C (MIC: 2 mg/L), Ng et al. (2018) found the C51R mutation in the RshA to be associated with tigecycline resistance [24]. The non-species related breakpoints (sensitive ≤ 0.25 mg/L, resistant > 0.5 mg/L) proposed by the EUCAST (2018) [25] was used in this study. The C51R mutation changed the first cysteine residue in the HXXXCXXC motif to arginine. As a result, there was an up-regulation of sigH and other stress-response genes in 7C that was confirmed by transcriptome profiling [26]. The causal relationship between the mutation, identified by whole-genome sequencing, and the resistance phenotype was established using the complementation of 7C with the wild-type MAB_3542c gene. The whiB7 gene was not differentially expressed in 7C. In a follow-up study, Lee et al. (2021) showed that the over-expression of the sigH gene alone was capable of inducing tigecycline resistance in the wild-type M. abscessus ATCC 19977 [27]

2.3. SigH Mutation

SigH is known to play two functions, which are to interact with and be inhibited by the RshA anti-sigma factor under normal circumstances and to initiate transcription in response to stressful conditions [23]. Lee et al. (2021) isolated a tigecycline-resistant mutant, designated as CL7 (MIC: 2 mg/L), which carried a stop-gain mutation (E229×) in SigH (MAB_3543c) [27]. The stop-gain mutation led to a seven-amino-acid truncation in the SigH protein. Interestingly, by transforming an expression plasmid carrying the mutant sigH gene, the previously sensitive ATCC 19977 developed resistance towards tigecycline, suggesting that truncated SigH might retain its capability to cause tigecycline resistance. RT-qPCR analyses of CL7 showed an over-expression of sigH along with stress-response genes encoding the thioredoxin and heat-shock proteins, which are the known regulon of SigH [23]. As such, these findings suggested that the SigH mutation might not be a completely loss-of-function mutation, as it only disrupted the interaction of mutated SigH with RshA but retained the SigH ability to auto-up-regulate itself and key stress genes, ultimately leading to the development of tigecycline resistance.

References

  1. Townsend, M.L.; Pound, M.W.; Drew, R.H. Tigecycline: A new glycylcycline antimicrobial. Int. J. Clin. Pract. 2006, 60, 1662–1672.
  2. Noskin, G.A. Tigecycline: A new glycylcycline for treatment of serious infections. Clin. Infect. Dis. 2005, 41, S303–S314.
  3. Olson, M.W.; Ruzin, A.; Feyfant, E.; Rush, T.S.; O’Connell, J.; Bradford, P.A. Functional, biophysical, and structural bases for antibacterial activity of tigecycline. Antimicrob. Agents Chemother. 2006, 50, 2156–2166.
  4. Kumarasamy, K.K.; Toleman, M.A.; Walsh, T.R.; Bagaria, J.; Butt, F.; Balakrishnan, R.; Chaudhary, U.; Doumith, M.; Giske, C.G.; Irfan, S.; et al. Emergence of a new antibiotic resistance mechanism in India, Pakistan, and the UK: A molecular, biological, and epidemiological study. Lancet Infect. Dis. 2010, 10, 597–602.
  5. Griffith, D.E.; Aksamit, T.; Brown-Elliott, B.A.; Catanzaro, A.; Daley, C.; Gordin, F.; Holland, S.M.; Horsburgh, R.; Huitt, G.; Iademarco, M.F.; et al. An official ATS/IDSA statement: Diagnosis, treatment, and prevention of nontuberculous mycobacterial diseases. Am. J. Respir. Crit. Care Med. 2007, 175, 367–416.
  6. Skolnik, K.; Kirkpatrick, G.; Quon, B.S. Nontuberculous Mycobacteria in Cystic Fibrosis. Curr. Treat. Options Infect. Dis. 2016, 8, 259–274.
  7. Nessar, R.; Cambau, E.; Reyrat, J.M.; Murray, A.; Gicquel, B. Mycobacterium abscessus: A new antibiotic nightmare. J. Antimicrob. Chemother. 2012, 67, 810–818.
  8. Sun, Y.; Cai, Y.; Liu, X.; Bai, N.; Liang, B.; Wang, R. The emergence of clinical resistance to tigecycline. Int. J. Antimicrob. Agents 2013, 41, 110–116.
  9. Villa, L.; Feudi, C.; Fortini, D.; García-Fernández, A.; Carattoli, A. Genomics of KPC-producing Klebsiella pneumoniae sequence type 512 clone highlights the role of RamR and ribosomal S10 protein mutations in conferring tigecycline resistance. Antimicrob. Agents Chemother. 2014, 58, 1707–1712.
  10. Chen, Q.; Li, X.; Zhou, H.; Jiang, Y.; Chen, Y.; Hua, X.; Yu, Y. Decreased susceptibility to tigecycline in Acinetobacter baumannii mediated by a mutation in trm encoding SAM-dependent methyltransferase. J. Antimicrob. Chemother. 2014, 69, 72–76.
  11. Li, X.; Liu, L.; Ji, J.; Chen, Q.; Hua, X.; Jiang, Y.; Feng, Y.; Yu, Y. Tigecycline resistance in Acinetobacter baumannii mediated by frameshift mutation in plsC, encoding 1-acyl-sn-glycerol-3-phosphate acyltransferase. Eur. J. Clin. Microbiol. Infect. Dis. 2015, 34, 625–631.
  12. Linkevicius, M.; Sandegren, L.; Andersson, D.I. Mechanisms and fitness costs of tigecycline resistance in Escherichia coli. J. Antimicrob. Chemother. 2013, 68, 2809–2819.
  13. Moore, I.F.; Hughes, D.W.; Wright, G.D. Tigecycline is modified by the flavin-dependent monooxygenase TetX. Biochemistry 2005, 44, 11829–11835.
  14. McAleese, F.; Petersen, P.; Ruzin, A.; Dunman, P.M.; Murphy, E.; Projan, S.J.; Bradford, P.A. A novel MATE family efflux pump contributes to the reduced susceptibility of laboratory-derived Staphylococcus aureus mutants to tigecycline. Antimicrob. Agents Chemother. 2005, 49, 1865–1871.
  15. Lupien, A.; Gingras, H.; Leprohon, P.; Ouellette, M. Induced tigecycline resistance in Streptococcus pneumoniae mutants reveals mutations in ribosomal proteins and rRNA. J. Antimicrob. Chemother. 2015, 70, 2973–2980.
  16. Broda, A.; Jebbari, H.; Beaton, K.; Mitchell, S.; Drobniewski, F. Comparative drug resistance of Mycobacterium abscessus and M. chelonae isolates from patients with and without cystic fibrosis in the United Kingdom. J. Clin. Microbiol. 2013, 51, 217–223.
  17. Ananta, P.; Kham-ngam, I.; Chetchotisakd, P.; Chaimanee, P.; Reechaipichitkul, W.; Namwat, W.; Lulitanond, V.; Faksri, K. Analysis of drug-susceptibility patterns and gene sequences associated with clarithromycin and amikacin resistance in serial Mycobacterium abscessus isolates from clinical specimens from Northeast Thailand. PLoS ONE 2018, 13, e0208053.
  18. Burian, J.; Ramón-García, S.; Sweet, G.; Gómez-Velasco, A.; Av-Gay, Y.; Thompson, C.J. The mycobacterial transcriptional regulator whiB7 gene links redox homeostasis and intrinsic antibiotic resistance. J. Biol. Chem. 2012, 287, 299–310.
  19. Burian, J.; Yim, G.; Hsing, M.; Axerio-Cilies, P.; Cherkasov, A.; Spiegelman, G.B.; Thompson, C.J. The mycobacterial antibiotic resistance determinant WhiB7 acts as a transcriptional activator by binding the primary sigma factor SigA (RpoV). Nucleic Acids Res. 2013, 41, 10062–10076.
  20. Morris, R.P.; Nguyen, L.; Gatfield, J.; Visconti, K.; Nguyen, K.; Schnappinger, D.; Ehrt, S.; Liu, Y.; Heifets, L.; Pieters, J.; et al. Ancestral antibiotic resistance in Mycobacterium tuberculosis. Proc. Natl. Acad. Sci. USA 2005, 102, 12200–12205.
  21. Geiman, D.E.; Raghunand, T.R.; Agarwal, N.; Bishai, W.R. Differential gene expression in response to exposure to antimycobacterial agents and other stress conditions among seven Mycobacterium tuberculosis whiB-like genes. Antimicrob. Agents Chemother. 2006, 50, 2836–2841.
  22. Pryjma, M.; Burian, J.; Kuchinski, K.; Thompson, C.J. Antagonism between Front-Line Antibiotics Clarithromycin and Amikacin in the Treatment of Mycobacterium abscessus Infections Is Mediated by the whiB7 Gene. Antimicrob. Agents Chemother. 2017, 61, 61.
  23. Song, T.; Dove, S.L.; Lee, K.H.; Husson, R.N. RshA, an anti-sigma factor that regulates the activity of the mycobacterial stress response sigma factor SigH. Mol. Microbiol. 2003, 50, 949–959.
  24. Ng, H.F.; Tan, J.L.; Zin, T.; Yap, S.F.; Ngeow, Y.F. A mutation in anti-sigma factor MAB_3542c may be responsible for tigecycline resistance in Mycobacterium abscessus. J. Med. Microbiol. 2018, 67, 1676–1681.
  25. EUCAST. Breakpoint Tables for Interpretation of MICs and Zone Diameters. Version 8. 2018. Available online: http://www.eucast.org (accessed on 7 August 2018).
  26. Ng, H.F.; Ngeow, Y.F.; Yap, S.F.; Zin, T.; Tan, J.L. Tigecycline resistance may be associated with dysregulated response to stress in Mycobacterium abscessus. Int. J. Med. Microbiol. 2020, 310, 151380.
  27. Lee, C.L.; Ng, H.F.; Ngeow, Y.F.; Thaw, Z. A stop-gain mutation in sigma factor SigH (MAB_3543c) may be associated with tigecycline resistance in Mycobacteroides abscessus. J. Med. Microbiol. 2021, 70, 001378.
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