To the Editor:
In both cystic fibrosis (CF) and non-CF bronchiectasis (NCFBr) chronic Pseudomonas aeruginosa infection is adversely prognostic [1, 2]. In CF, epidemic infections with specific clones of P. aeruginosa are associated with further adverse outcomes [3, 4]. This cross-infection risk has led to segregation of patients [5]. There are few data on P. aeruginosa cross-infection in NCFBr. As a result, segregation in NCFBr has not been addressed in guidelines [6].
Our aim was to undertake a cross-infection study in NCFBr. This was undertaken in an adult bronchiectasis service in the north-east of England (UK) that is separated from the regional CF unit (sited 2 miles (3 km) away). The service was initiated in 2007 with a weekly specialist clinic without a Pseudomonas-specific clinic. When NCFBr patients are hospitalised, there is a preference for cubicle-based (single-patient room) management, but when cubicles are unavailable, patients are managed in six-bed bays. All patients had computed tomographic confirmation and had predominantly idiopathic or post-infectious bronchiectasis with CF excluded following current guidelines [6]. The study had ethical permission and Caldicott approval (Newcastle and North Tyneside National Research Ethics Service Committee).
56 isolates were selected for analysis. Six were chosen from CF patients as laboratory controls. 50 were NCFBr isolates collected between 2008 and 2011 from 40 NCFBr patients. 36 patients (patients 1–36) attending the adult bronchiectasis service were randomly selected. Longitudinal isolates were included from 10 patients with a mean (range) 16 months (2–35 months) between isolates. Additionally, single isolates were chosen from four NCFBr patients (patients 37–40) as potential patient controls who had not attended the specialist clinic and had not been hospitalised. Isolates were cultured from spontaneous sputum and identified as P. aeruginosa by routine biochemical methods and matrix-assisted laser desorption/ionisation-time-of-flight (MALDI-TOF) mass spectrometry.
We used two genotyping methods; in each case, testing was blinded. First, we used the ArrayTube (AT genotyping; Alere, Jena, Germany) as per the manufacturer’s protocol. This system detects 13 single-nucleotide polymorphisms within conserved P. aeruginosa genes and the presence/absence of 38 variable genetic markers in the accessory genome. The data were converted into a four-digit hexadecimal code and then compared to a database [7, 8]. Secondly, we used variable number tandem repeat (VNTR) analysis based on variation in the number of DNA repeats at specified sites across the genome at nine variable loci [9] with comparison to a VNTR database [10].
The vast majority of the 36 NCFBr patients attending the service (patients 1–36) harboured their own strains (fig. 1). Patients 11 and 27 had distinct variants of clone C, which is a lineage that is widely found globally [10]; two patients in the nonhospitalised control group also had further variants of this clone (patients 39 and 40). Among the 34 remaining NCFBr patients attending the service, there were three pairs (patients 2 and 34; 12 and 19; and 16 and 17) whose isolates of P. aeruginosa shared very similar profiles by at least one method (fig. 1). For patients 12 and 19, this was confirmed by pulsed-field gel electrophoresis of SpeI-digested genomic DNA; this is an unusual profile and that these patients shared the same strain almost certainly does reflect cross-infection. Patients 2 and 34 both had a widely found type belonging to sequence type 27, while patients 16 and 17 had clearly distinct strains by VNTR, suggesting only one probable case of cross-infection.
Variable number tandem repeat dendrogram showing the diversity of types among the 50 non-cystic fibrosis bronchiectasis isolates analysed. The similarity coefficient was calculated using Euclidian distance, and strains were clustered using the unweighted pair group method with arithmatic mean using BioNumerics software (Applied Maths, Sint-Martens-Latem, Belgium). Pairs of longitudinal isolates are marked in boxes and with a dot. The hexadecimal code derived by ArrayTube analysis (Alere, Jena, Germany) is included for reference, as are the patient numbers (see text).
The location of the NCFBr isolates among the wider population structure of P. aeruginosa, based on AT genotype, was mapped (not shown) and demonstrated that NCFBr isolates were widely distributed. AT analysis found several pattern matches with the AT database: matches were with AT clones A2, K, E, I, A7, A, L, J, A5 and U. Both methods correctly identified the known control strains from CF patients.
Longitudinally paired isolates from 10 patients were examined (patients 3, 6–11, 14, 16 and 18). For nine patients, the first and second isolates were indistinguishable by both AT and VNTR genotyping, confirming persistence of the initial strain. In one patient (patient 11), VNTR analysis indicated that both isolates were identical, but AT genotyping did not.
Our key finding was the absence of dominant clones of P. aeruginosa with little evidence of cross-infection and many strains that were “unique”. While there is distinct clustering of AT clone types in ocular keratitis, the isolates from NCFBr were widely distributed in the Pseudomonas population structure. Collectively, this suggests that sporadic infection is the most common mode of infection in NCFBr. Clone C was found in only 6% of the NCFBr patients and is known to be widely distributed within the environment [8]. Cross-infection with clone C seems unlikely, as the VNTR profiles varied at two or three loci, suggesting that they were independently acquired. Other isolates matched those previously isolated from various clinical and environmental sources [8]. These data may suggest a risk of environmental acquisition in NCFBr [5, 8].
The absence of a dominant P. aeruginosa clone in NCFBr may reflect many factors, including the lower incidence of P. aeruginosa infection in NCFBr (<50%) as compared to CF (≤80%). The probable lower rate of hospitalisation in NCFBr compared to CF may also limit cross-infection exposures. The standard infection prevention and control measures used in our NCFBr centre are less stringent than those implemented in designated CF centres. The absence of significant cross-infection herein is therefore unlikely to be due to a higher standard of infection control practices.
Notably, our study is solely focused on P. aeruginosa cross-infection and we cannot exclude cross-infection in the NCFBr population with Staphylococcus aureus, Haemophilus influenzae or nontuberculous mycobacteria. Furthermore, limitations of our study include the single-centre design. Our observations may have been different if our NCFBr centre facilities were shared with our regional CF clinic. We therefore advocate further multicentre studies to delineate the cross-infection risks.
Footnotes
Support statement: A. De Soyza acknowledges a Higher Education Funding Council for England senior lectureship and funding from the National Institute for Health Research Newcastle Biomedical Resource Centre for Ageing and Chronic Disease.
Conflict of interest: Disclosures can be found alongside the online version of this article at www.erj.ersjournals.com
- Received September 25, 2013.
- Accepted October 16, 2013.
- ©ERS 2014