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Inicio Enfermedades Infecciosas y Microbiología Clínica (English Edition) Epidemiology and in vitro antimicrobial susceptibility of aerobic Actinomycetale...
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Vol. 40. Núm. 10.
Páginas 562-567 (diciembre 2022)
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Vol. 40. Núm. 10.
Páginas 562-567 (diciembre 2022)
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Epidemiology and in vitro antimicrobial susceptibility of aerobic Actinomycetales in a clinical setting
Epidemiología y sensibilidad in vitro de especies de Actinomycetales aerobios en la rutina asistencial
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Llanos Salar-Vidal, Marta Martín-García, Alicia Macías-Valcayo, Ana Ponz, Jaime Esteban
Autor para correspondencia
jestebanmoreno@gmail.com

Corresponding author.
Department of Clinical Microbiology, IIS-Fundación Jiménez Díaz, UAM Madrid, Spain
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Abstract
Introduction

The incidence of infections caused by aerobic actinomycetes is increasing. Recent changes in taxonomy and the variability in susceptibility patterns among species make necessary a proper identification and antibiotic susceptibility testing.

Material and methods

Fifty-three strains of aerobic actinomycetes were identified by MALDI-TOF MS using the VITEK MS Mycobacterium/Nocardia kit (bioMérieux, France) in a tertiary hospital in Spain during a six-year period. Antimicrobial susceptibility testing of the isolates was performed using the Sensititre Rapmycoi microdilution panel (Thermo Fisher Scientific, Massachusetts, USA).

Results

Forty strains of Nocardia spp. were identified in the study, being N. farcinica and N. cyriacigeorgica the most prevalent ones. All isolates were susceptible to linezolid and the resistance to amikacin was only observed in one isolate of Gordonia sputi. Resistance to cotrimoxazole was only found in five isolates.

Conclusions

Routine identification and antimicrobial susceptibility testing of aerobic actinomycetes is advisable for an efficient identification of species and effective treatment.

Keywords:
Actinomycetes
Nocardia
Tsukamurella
Gordonia
MALDI-TOF
Antimicrobial susceptibility
Resumen
Introducción

La incidencia de infecciones por actinomicetos aerobios está aumentando. Los recientes cambios en la taxonomía y la variabilidad en la sensibilidad entre especies hacen necesaria una identificación y estudio de sensibilidad adecuados.

Material y métodos

Se identificaron 53 cepas de actinomicetos aerobios mediante MALDI-TOF utilizando el kit VITEK-MS Mycobacterium/Nocardia (bioMérieux, Francia) en un hospital terciario español durante seis años. Los estudios de sensibilidad de los aislados se realizaron utilizando el panel de microdilución Sensititre Rapmycoi (Thermo Fisher Scientific, Massachusetts, EE. UU.).

Resultados

Se identificaron 40 cepas de Nocardia spp., siendo Nocardia farcinica y Nocardia cyriacigeorgica las más prevalentes. Todos los aislados fueron sensibles a linezolid, y solo se detectó resistencia a amikacina en un aislado de Gordonia sputi. Solo se encontró resistencia al cotrimoxazol en cinco aislados.

Conclusiones

Es aconsejable realizar la identificación de rutina y las pruebas de sensibilidad antimicrobiana de los actinomicetos aerobios para conseguir una identificación eficiente de las especies y un tratamiento eficaz.

Palabras clave:
Actinomycetales
Nocardia
Tsukamurella
Gordonia
MALDI-TOF
Sensibilidad antimicrobiana
Texto completo
Introduction

The incidence of infections caused by aerobic actinomycetes (especially Nocardia spp.) has increased in the last years, in association with the improvement in detection and diagnostic techniques, and the higher prevalence of immunosuppressed patients.1 Usually, nocardiosis appears as pulmonary disease, although the infection could disseminate from the lungs, and local abscesses may result from direct inoculation.1,2 The most typical sites for dissemination are the central nervous system, skin and subcutaneous tissue, and other organs.1–4 Optimal treatment regimens for nocardiosis have not been established, but recommended ones use antibiotics with a proven efficacy in clinical studies.5–7 However, it is recommended that antimicrobial in vitro testing should be performed to assist treatment management.1,2,4

Other species of actinomycetes that may cause infections in humans belong to the genus Rhodococcus, Gordonia and Tsukamurella.1 It is important to individualize the treatment of those infections according to in vitro susceptibility results because of the lack of clinical data. The difficulties with the conventional identification methods using biochemical tests and the current molecular taxonomy as gold standard for the identification, by using PCR and sequencing, have led us to use matrix assisted laser desorption/ionization time of flight (MALDI-TOF) mass spectrometry as a routine method for the identification of these species.

Given the wide spectrum of clinical manifestations, the increasing number of species of aerobic actinomycetes, the different prevalence and their variation in susceptibility to antibiotics, it is necessary an accurate identification and susceptibility testing for an efficient and effective treatment.2,8,9

Materials and methods

All isolates of aerobic actinomycetes that were recovered in our hospital from different clinical samples between 2014 and July 2020 were included.

Identification

Strains were grown on tryptic-soy agar plates supplemented with 5% of sheep blood (bioMérieux, Marcy l’Étoile, France) and incubated for 48–72h at 37°C. Species identification was performed by MALDI-TOF mass spectrometry, using the VITEK MS® Mycobacterium/Nocardia kit (bioMérieux, Marcy l’Étoile, France). This kit provides some reagents and consumables needed to process samples by inactivation and protein extraction. Briefly, samples were collected from the plate and re-suspended in 500μL of 70% ethanol in glass beads vials. They were vortexed for 15min and incubated at room temperature for 10min. The supernatant was transferred into new tubes and centrifuged at 13,000×g for 2min. The pellet was resuspended in 10μL of 70% formic acid and subsequently in 10μL of acetonitrile. Samples were vortexed and centrifuged at 13,000×g for 2min. One μL of the supernatant was used for MALDI-TOF testing. Two different data bases (bioMérieux, Marcy l’Étoile, France) were used for the identification at species level, IVD® v3.2 (close database for clinical practice) and Saramis® v.15/RUO (open database for research use). Some of the isolates randomly selected were submitted to the National Center of Microbiology (Majadahonda, Spain) for 16S rRNA gene sequencing to verify the correct identification at species level given by MALDI-TOF.

Antimicrobial susceptibility testing

Antimicrobial susceptibility was tested by the broth microdilution method using Sensititre® RAPMYCOI microtiter plates (ThermoFisher Scientific, Massachusetts, USA), according to the reference methodology for aerobic actinomycetes.10 Tested antibiotics were amikacin, amoxicilin-clavulanate, cefoxitin, ceftriaxone, ciprofloxacin, clarithromycin, doxycycline, imipenem, linezolid, minocycline, moxifloxacin, tigecycline, tobramycin, and cotrimoxazole. Minimum inhibitory concentration (MIC) was determined after 72h of incubation at 37°C and interpreted according to the Clinical and Laboratory Standards Institute (CLSI) guidelines.10 Tigecycline breakpoints for Enterobacteriaceae were used for interpretation. Staphylococcus aureus ATCC 29213 was used as quality control.

Results

During the study period a total of 53 non-duplicated actinomycetes isolates were studied, including Nocardia spp. (40/53), Gordonia spp. (10/53), and Tsukamurella spp. (3/53) from 54 patients. One patient had two different isolates of Nocardia spp.

Among Nocardia spp. isolates, N. farcinica (12) and N. cyriacigeorgica (11) were the most prevalent species, followed by N. nova/africanum (9), N. paucivorans (2), N. abscessus (1), N. carnea (1), N. neocaledonensis (1), N. otidiscaviarum (1), N. veterana (1) and N. wallacei (1). Within the other aerobic actinomycetes the isolated species were G. sputi (6), G. bronchialis (4), T. pulmonis (2) and T. tyrosinosolvens (1). No discrepancies were found between the results obtained by MALDI-TOF and 16S rRNA on the studied isolates.

Most of the isolates were recovered from the respiratory tract (80%) including 32 isolates of Nocardia spp., seven of Gordonia spp., and one of Tsukamurella spp.; followed by subcutaneous abscesses and wounds (10.9%) including six Nocardia spp. isolates and one Gordonia spp. isolate; and blood (9.1%) including two Gordonia spp., one Nocardia spp., and one Tsukamurella spp. N. cyriacigeorgica was the most frequent species isolated from the respiratory tract (27.5%; 11/40), followed by N. nova/africanum (22.5%, 9/40). N. farcinica was the predominant species from skin and soft tissues samples (42.9%; 3/7), and G. sputi from blood samples (50%; 2/4).

Antimicrobial susceptibility of Nocardia spp. to the 14 antibiotics tested is summarized in Table 1. All the isolates were susceptible to amikacin and linezolid, and most of them were also susceptible to cotrimoxazole (97.5%), followed by imipenem (67.5%), tigecycline (52.5%) and tobramycin (52.5%).

Table 1.

MIC50, MIC90, and range (mg/L), and percentage of susceptible isolates of Nocardia spp.

Antimicrobial agent  Breakpoints  Species (no. of strains tested)
    All Nocardia spp. (n=40)  N. farcinica (n=12)  N. cyriacigeorgica (n=11)  N. nova/africanum (n=9)  Other Nocardia spp. (n=8) 
Amikacin  S         
Susceptible [n (%)]    40 (100)  12 (100)  11 (100)  9 (100)  8 (100) 
MIC range    <1 to 4  <1 to 2  <1  <1  <1 to 4 
MIC50    <1  <1  <1  <1  <1 
MIC90    <1  <1 
Amoxicillin-clavulanate  S         
Susceptible [n (%)]    12 (30)  5 (41.7)  2 (18.2)  2 (22.2)  3 (37.5) 
MIC range    <2 to >64  <2 to >64  <2 to >64  8 to >64  <1 to >64 
MIC50    32  32  16  32  32 
MIC90    >64  >64  >64  >64  >64 
Cefoxitin  S16           
Susceptible [n (%)]    9 (22.5)  1 (8.3)  3 (27.3)  1 (11.1)  4 (50) 
MIC range    <4 to >128  8– 128  <4 to 128  16 to >64  8 to >128 
MIC50    64  64  32  64  16 
MIC90    >128  >128  128  >128  >128 
Ceftriaxone  S         
Susceptible [n (%)]    24 (60)  3 (25)  10 (90.1)  4 (44.4)  7 (87.5) 
MIC range    <4 to >64  <4 to >64  <4 to 16  <4 to >64  <4 to >64 
MIC50    <4  <4 
MIC90    >64  >64  >64  >64 
Ciprofloxacin  S         
Susceptible [n (%)]    12 (30)  8 (66.7)  5 (62.5) 
MIC range    <0.12 to >4  <0.12 to >4  2 to >4  >4  0.25 to >4 
MIC50    >4  >4  0.5 
MIC90    >4  >4  >4  >4  >4 
Clarithromycin  S         
Susceptible [n (%)]    21 (52.5)  3 (25)  6 (54.5)  8 (88.9)  4 (0.5) 
MIC range    0.25 to >16  0.5 to >16  0.5 to >16  0.25 to >16  0.5 to >16 
MIC50   
MIC90    16  >16  >16  >16 
Cotrimoxazole  S         
Susceptible [n (%)]    39 (97.5)  12 (100)  11 (100)  9 (100)  7 (87.5) 
MIC range    <0.25 to >8  <0.25 to 2  <0.25 to 2  <0.25 to 2  <0.25 to >8 
MIC50    0.5  <0.25 
MIC90    >8 
Doxycycline  S         
Susceptible [n (%)]    15 (37.5)  3 (25)  7 (58.3)  5 (62.5) 
MIC range    <0.12 to >16  <0.12 to >16  <0.12 to 4  2 to >16  <0.12 to 8 
MIC50   
MIC90    >16 
Imipenem  S         
Susceptible [n (%)]    27 (67.5)  6 (50)  8 (72.7)  9 (100)  4 (50) 
MIC range    <1 to >64  <2 to 64  <2 to 32  <2 to 4  <1 to >64 
MIC50    <2  <2  <2 
MIC90    64  >64  32  >64 
Linezolid  S         
Susceptible [n (%)]    40 (100)  12 (100)  11 (100)  9 (100)  8 (100) 
MIC range    <1 to 8  <1 to 8  <1 to 4  <1 to 4  <1 to 4 
MIC50    <1  <1  <1  <1  <1 
MIC90   
Minocycline  S         
Susceptible [n (%)]    18 (45)  4 (33.3)  7 (63.6)  1 (11.1)  6 (75) 
MIC range    <1 to >8  <1 to >8  <1 to 4  1–4  <1 to 2 
MIC50    <1  <1 
MIC90   
Moxifloxacin  S         
Susceptible [n (%)]    16 (40)  8 (66.7)  1 (9.1)  1 (11.1)  6 (75) 
MIC range    <0.25 to >8  <0.25 to >8  <0.25 to 4  1 to >8  <0.25 to 8 
MIC50    0.5  0.5 
MIC90    >8 
Tigecycline  S0.5           
Susceptible [n (%)]    21 (52.5)  5 (45.5)  7 (70)  5 (55.5)  4 (50) 
MIC range    0.12–4  0.12–4  0.25–1  0.5–2  0.25–2 
MIC50    0.5  0.5  0.5  0.5 
MIC90   
Tobramycin  S         
Susceptible [n (%)]    21 (52.5)  1 (8.3)  11 (100)  2 (22.2)  7 (87.5) 
MIC range    <1 to >16  <1 to >16  <1 to 2  <1 to >16  <1 to >16 
MIC50    <1  >16  <1 
MIC90    16  >16  >16  >16 

Results of antimicrobial susceptibility testing for Gordonia spp. and Tsukamurella spp. isolates are shown in Table 2. All the strains were susceptible to linezolid, and most of them were susceptible to amikacin, ciprofloxacin, and moxifloxacin.

Table 2.

MIC50, MIC50, and range (mg/L) and percentage of susceptible isolates of Gordonia spp. and Tsukamurella spp.

Antimicrobial agent  Breakpoints  Species (no. of strains tested)
    G. sputii (n=8)  G. bronchialis (n=4)  Tsukamurella spp. (n=3) 
Amikacin  S     
Susceptible [n (%)]    5 (83.3)  4 (100)  3 (100) 
MIC range    <1 to 32  <1  <1 to 2 
MIC50    <1  <1  <1 
MIC90    32  <1 
Amoxicillin-clavulanate  S     
Susceptible [n (%)]    6 (100)  3 (75) 
MIC range    <2 to 8  <2 to >64  64 to >64 
MIC90    <2  <2  >64 
MIC50    >64  >64 
Cefoxitin  S16       
Susceptible [n (%)]    3 (50)  1 (25) 
MIC range    8– 128  <4 to 128  128 
MIC50    32  32  128 
MIC90    128  128  128 
Ceftriaxone  S     
Susceptible [n (%)]    6 (100)  3 (75)  1 (33.3) 
MIC range    <4 to 16  <4 to >64  8 to >64 
MIC50    <4  <4  16 
MIC90    16  >64  >64 
Ciprofloxacin  S     
Susceptible [n (%)]    5 (83.3)  4 (100)  3 (100) 
MIC range    <0.12 to 2  <0.12 to 0.25  <0.12 to 1 
MIC50    <0.12  <0.12 
MIC90    0.25 
Clarithromycin  S     
Susceptible [n (%)]    6 (100)  2 (50)  2 (66.6) 
MIC range    0.12–1  0.5 to >16  0.25–4 
MIC50    0.25  0.5  0.25 
MIC90    >16 
Cotrimoxazole  S     
Susceptible [n (%)]    5 (83.3)  4 (100)  2 (66.6) 
MIC range    <0.25 to >8  <0.25 to 1  <0.25 to >8 
MIC50    0.5  <0.25  <0.25 
MIC90    >8  >8 
Doxycycline  S     
Susceptible [n (%)]    6 (100)  2 (50)  1 (33.3) 
MIC range    0.25 to 1  <0.12 to 2  <0.12 to 4 
MIC50    0.5 
MIC90   
Imipenem  S     
Susceptible [n (%)]    5 (83.3)  2 (50)  1 (33.3) 
MIC range    <2 to 32  <2 to 32  <2 to 32 
MIC50    <2  <2  16 
MIC90    32  32  32 
Linezolid  S     
Susceptible [n (%)]    6 (100)  4 (100)  3 (100) 
MIC range    <1 to4  <1 to 2  <1 to 4 
MIC50    <1  <1 
MIC90   
Minocycline  S     
Susceptible [n (%)]    5 (83.3)  1 (25)  2 (66.6) 
MIC range    <1 to 4  <1 to 4  <1 to 2 
MIC50    <1  <1 
MIC90   
Moxifloxacin  S     
Susceptible [n (%)]    5 (83.3)  4 (100)  3 (100) 
MIC range    <0.25 to 8  <0.25 to 1  <0.25 
MIC50    <0.25  <0.25  <0.25 
MIC90    <0.25 
Tigecycline  S0.5       
Susceptible [n (%)]    3 (50)  2 (50)  3 (100) 
MIC range    0.06–2  0.25–2  0.25–3 
MIC50    0.5  0.5  0.5 
MIC90    0.5 
Tobramycin  S     
Susceptible [n (%)]    6 (100)  4 (100)  1 (33.3) 
MIC range    <1 to 2  <1 to 2  <1 to 16 
MIC50    <1  <1 
MIC90    16 
Discussion

Because of the recent Nocardia species discovered during the past years,2 and the diversity of susceptibility patterns, it is necessary to have available techniques that could give a rapid and accurate identification at the species level.11,12 In this scenario, MALDI-TOF may represent a quick and reliable option, as it is seen in previous studies.12,13 It has been demonstrated that this tool is also potentially useful for identifying species of the genera Gordonia14 and Tsukamurella.15 A proper and rapid identification could be useful to guide antibiotic therapy, until invitro susceptibility results are available. However, MALTI-TOF shows some limitations, as uncommon species may be still difficult to identify depending on the database coverage.11,13 In fact, in several laboratories, modified protocols or in-house created libraries are used.8,16 For instance, our Vitek MS IVD database cannot distinguish between N. nova and N. africanum, as they are closely related species from the N. nova complex.

During the study period, the most predominant Nocardia species were N. farcinica (30%), N. ciryacigeorgica (27.5%) and N. nova/africanum (22.5%). The predominance of these species has also been reported in previous Spanish studies,9,17 even though there could be local differences in the epidemiology of the different species. Interestingly, in those studies, N. abscessus accounts for around 10–15% of nocardiosis cases, and we only had one case in our series.

Overall, amikacin and linezolid were the most active drugs, which is in accordance with previous reports.9,18 Cotrimoxazole is usually the treatment of choice for Nocardia infections, although increasing resistance has been reported.19 In the present study, the resistance rate still remains low (2.5%) in agreement with data reported for our country.9

Even though imipenem is considered as a first-line alternative for the treatment of nocardiosis, we observed that 32.5% of the isolates were resistant in vitro, including 50% of N. farcinica strains and 27.3% of N.cyriacigeogica strains, the most frequentlty isolated species in this study. Regarding other β-lactams, the susceptibility of ceftriaxone was variable, susceptibility to amoxicillin was low (30%), and almost all isolates (77.5%) were resistant to cefoxitin. Resistance to tetracyclines remains moderate in comparison with other data previously reported, being tigecycline the most active drug. We found a high percentage of quinolone-resistant isolates, being susceptibility rates slightly raised for moxifloxacin. Although all isolates were susceptible to amikacin, approximately only half of them (52.5%) were tobramycin susceptible.

Information in the literature regarding the identification by MALDI-TOF and antimicrobial susceptibility of aerobic actinomycetes other than Nocardia spp. is scarce. Optimal treatment of infections caused by Gordonia spp. and Tsukamurella spp. remains unclear, mainly because of the lack of experience due to the low number of cases of human disease caused by these genera. In our series we obtained nine isolates from sputum (Gordonia spp. n=7, Tsukamurella spp. n=2), three from blood (Gordonia spp. n=2, Tsukamurella spp. n=1), and one from a wound exudate (Gordonia spp.). Among our isolates, we found that aminoglycosides, fluoroquinolones, and linezolid showed good activity against Gordonia spp. The MIC values of the antibiotics tested were generally low except for cefoxitin. For Tsukamurella spp., in this study, the MIC values were variable between the three isolates, being amikacin, ciprofloxacin, moxifloxacin, and linezolid the most active drugs.

A major limitation of our study is the small number of isolates, especially those that are less-common species. This study was performed only in one center of the area and may not represent the epidemiology of the whole region, although these data will aid in future studies and it will be helpful for the understanding of infections caused by these microorganisms.

In conclusion, in our study, most of the Nocardia spp. isolates are susceptible to the recommended antibiotics for treatment (cotrimoxazole, amikacin, imipenem, linezolid). The accuracy in the identification of these species can be easily obtained with the MALDI-TOF technology. The identification together with the determination of its in vitro susceptibility could be critical to ensure a successful treatment and outcome. Moreover, these results will improve our knowledge of different aspects regarding these uncommon isolates in our area.

Ethical approval, consent to participate and consent to publish

The present study included only strains, and according to the current laws, it needs no approval from the ERC. No specific consents for participation and publication are also needed according the laws.

Funding

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Authors’ contribution

LS-V, MM-G, AM-V performed the susceptibility study and some of the MALDI-ToF identifications, AP performed all other MALDI-ToF identifications, LS-V supervised the MALDI-ToF identification and wrote the draft of the manuscript, JE has the idea, supervised all the project and reviewed the manuscript until its final version. All authors agreed with the content of the manuscript and to participate in its publication.

Competing interests

JE received travel grants from bioMérieux. No other competing interests related with the present manuscript need to be declared.

Acknowledgements

The technical assistance of A. Bodas and E. Ruiz is gratefully acknowledged. We want to acknowledge the Centro Nacional de Microbiología (Majadahonda, Spain), for its help with the identification of some isolates.

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