Determination of nasal carriage and skin colonization, antimicrobial susceptibility and genetic relatedness of Staphylococcus aureus isolated from patients with atopic dermatitis in Szczecin, Poland

Atopic dermatitis – AD (also called atopic eczema AE) is a long - standing inflammatory dermatosis characterized by intense itching of affected skin and recurrence of chronic eczematous lesions [1]. In adult patients AD mainly manifests with lesions localized mostly on face and neck, and in up to 30% of these patients the hand atopic eczema is determined [2].

The multifactorial pathogenesis of AD includes altered immune response, several genetic predispositions and environmental factors which along with epidermal barrier dysfunctions significantly impair the functional integrity of the skin [3]. During flares of the disease the disturbances of skin microbial composition and also other skin barrier defects consequently contribute to exacerbation of AD symptoms [1].

Staphylococcus aureus (S. aureus) is the major pathogenic bacterium which activity is closely associated with severity and the course of the AD [4]. Although, S. aureus is present on skin and mucous membranes of healthy individuals and remains in balance with the host, its overgrowth is most probably linked to the reduced number of skin microbiota representatives on affected skin normally inhibiting activity of this bacterium. Nevertheless, some authors have suggested, that composition of the whole skin microbiome correlates with the course of AD and exacerbation of its symptoms [5‐7]. S. aureus isolated from individuals with AD demonstrates enhanced ability to adhere to corneocytes and produces toxins and enzymes contributing to the exacerbation of disease symptoms [8].

Higher rates of S. aureus nasal colonization, strongly linked with the duration and severity of AD have been observed in patients with AD. Moreover, patients persistently colonized by S. aureus in nose are more prone to skin and soft tissue infections (SSTIs), and therefore experience more often the AD symptoms worsening [9‐12].

In the current study the relatedness of 86 S. aureus isolated from nose and skin of patients with atopic dermatitis was determined with the special regard to genetic relatedness of strains from nose and skin in S. aureus nasal carriers. Obtained results indicate the autoinfection with S. aureus in nasal-carriers. The results of antimicrobial susceptibility test proved the good susceptibility in vast majority of strains to antimicrobial drugs recommended for treating AD complicated by S. aureus presence.

The course of atopic dermatitis (AD), an inflammatory skin condition, associated with type I allergic diseases is strongly influenced by a complex of variety of factors such as individual genetic and immunological predispositions, impaired skin barrier function and environment. All these taken together exacerbate AD symptoms from moderate to severe [18], nevertheless the detailed pathophysiology of AD still remains unclear. It is worth to note, that AD has an age-dependent distribution and affects around 20% of children worldwide. In 90% of patients AD begins from an early age, what is most probably associated with higher rates of skin colonization by S. aureus in children [19] and in 10% of AD patients it may persist for life [20].

Human skin microbiota is represented by a wide range of microorganisms which coexistence and integrity prevents skin from bacterial invasion. Most of the microorganisms reside on the skin in asymptomatic manner, among them also S. aureus which constitutes an integral part of skin microbiome in around 30% human population representatives [21]. It is worth emphasizing that less diverse skin microbiome, observed in patients with AD, may predispose to S. aureus overgrowth [22]. Lesional skin colonization by S. aureus is commonly observed in AD patients however, colonization may also indicate non-lesional skin [23‐25]. It has been demonstrated that the progression and severity of AD are closely related with the ability of S. aureus to penetrate through skin barrier what stimulates the immune response leading to the persistent skin inflammation [22]. Dehydrated and thinner skin of AD patients is much more vulnerable to injury and therefore to infection and irritation by allergens [26]. Celakovska and Bukac [27, 28] observed the significant relation between the severity of AD and sensitization mites, animal dander, dust of feather. According to authors observation patients with strong or moderate form of AD suffer more often from sensitization to aboved factors. In the present study 22 patients declared the contact dermatitis, 16 patients declared the allergic rhinitis (AR) and 2 patients declared the diagnosed bronchial asthma (BA). Among them 7 (with AR) and 1 (with BA) described the severity as strong. The obtained results seem to support the observation of the authors.

In comparison performed by Simpson et al. AD patients colonized with S. aureus more often experience severe course of AD than non-colonized individuals and demonstrate the elevated levels of IgE and eosinophils in serum. Furthermore, the skin barrier of S. aureus colonized patients is significantly impaired with enhanced expression of adhesive molecules and increased permability what made skin much more prone to be colonized [29]. In our study patients were asked to evaluate the grade the intensity of AD flares at the moment of specimen collection. What is interesting, the severity of AD exacerbations described as “strong” was declared by 7 patients from group I vs 11 who declared the severity of AD flares ass “moderate” (39%). “Strong severity of AD was declared by 19% and 25% of patients from group II and group III respectively. None of the patients declared the AD severity as “mild”. The above results seem to be consistent with Alsterholm et al. [30] and Ogonowska et al. who observed, that especially persistent nasal S. aureus carriers expierience more severe AD according to SCORAD system [31]. Its worth mentioning, that the present study evaluation of nasal carriage was performed ones for each patient, therefore in group III of patients (nasal non-carriers) intermittent nasal carriage cannot be certainly excluded. To support the management of AD it would be appropriate to consider nasal colonization screening performed periodically in these group of patients.

Patients examined in the present study were also asked to rate the frequency of flares in previous 6 months. None of the patients declared less than 4 episodes. Patients from group I with strong form of AD declared the frequency as 5–6 episodes. Ogonowska et al., [31] observed, that the concomitant nasal and skin colonization in AD patients is comparatively high and nasal vestibule is considered as the potential reservoir of S. aureus, contributing to the recolonization of skin.

The nasal vestibule constitutes the reservoir of S. aureus, from which it spreads to other body sites and may cause multiple autoinfections [32, 33]. It is estimated, that 20–30% of healthy population representatives are persistent carriers of this bacterium [34]. The percentage of S. aureus carriers is higher among people with AD (38–82%) compared to healthy individuals (10–45%). In the current study nasal carriers constituted more than a half (53,1%) of the of examined patients (34/64) and them in 18 (18/34) the simultaneous presence of S. aureus on skin was confirmed. Breuer et al. isolated S. aureus from 94% of people with AD: from 11% exclusively from the skin, from 6% only from the nose, and from 77% from affected skin and nasal vestibule [35].

Nose (nasal vestibule) of most people with SSTI’s is commonly colonized with indistinguishable, closely or potentially related S. aureus [35]. Phage typing and serotyping results performed by Namura et al. and Hoeger et al. revealed significant similarities between S. aureus strains isolated from cutaneous lesions and nasal vestibule in 64% (7 out of 11) adult patients with AD and in 73% (30 out of 41) children with AD respectively [36, 37]. Hoeger et al. demonstrated also the presence of indistinguishable S. aureus isolated from affected skin and from nasal vestibule of children with AD and isolated from their mothers (in 38% of cases – 22 out of 58) [37]. Pascolini et al. evaluated the risk of transmission of the S. aureus colonizing nasal vestibule to the other skin sites of the same patient with using the PFGE technique to determine the relatedness of analyzed strains. All 47 strains isolated from cutaneous lesions were genetically related to the strains isolated simultaneously from nose [38]. Detailed analysis of S. aureus isolated from colonized individuals sharing the same habitat and remaining in close contact with patients with AD proved, that S. aureus easily transmits between those individuals contributing a carrier state [35, 39, 40]. Similar PFGE findings were observed by Bonness et al. who confirmed the relatedness of S. aureus isolated from nose and skin in 73% (11 out of 15) of patients with AD and suggested, that significant similarities between PFGE patterns of S. aureus isolated from AD patients and their family members may prove the recolonization with S. aureus as intra - familial transmission of S. aureus. The S. aureus skin recolonization may be associated with the pathogen maintaining the carrier state in the vestibule of the nose [41]. PFGE results obtained in our study demonstrated that skin and nasal vestibule were colonized with indistinguishable strains in 16 (16/18) of examined patients and in 2 (2/18) with non- related S. aureus. The results showed also non-clonal structure of S. aureus isolated from affected skin of patients with AD and also the lack of predominating genetic type of S. aureus infecting patients with AD in West Pomeranian region. It’s worth mentioning, that all patients examined in current study were during the targeted antimicrobial therapy without the implemented nasal decolonization procedures. Therefore, the recurrent exacerbations of AD symptoms were most probably associated with autoinfection with S. aureus in these patients.

In the current study isolated S. aureus showed the low rates of antimicrobial resistance to examined agents. Although an increasing rates of methicillin resistant Staphylococcus aureus (MRSA) colonizing outpatients are reported worldwide [42, 43] reaching approximately 7% within the total population, the skin of outpatients with AD is most frequently affected with methicillin susceptible Staphylococcus aureus (MSSA). Data concerning the rates of AD patients colonized with MRSA vary. Kędzierska et al. among 76 S. aureus isolated from patients with AD determined the resistance to methicillin only in one strain isolated from 9-year old boy with history of hospitalization and prolonged antibiotic therapy [44]. Low rates of MRSA was also confirmed by Niehbuhr et al. who determined the presence of methicillin resistance only in 3% of analyzed S. aureus isolated from AD patients [45]. Pascolini et al. among 113 S. aureus isolated from carriers and from their infected skin found the presence of methicillin resistance in 9 strains (7,9%) of which 6 were isolated from skin lesions [38]. In studies conducted by Hoeger et al. and L.S. Chiu et al. the lack of MRSA was confirmed among all tested strains isolated from AD [37, 46]. Nevertheless, Ching - Shen Tang et al. demonstrated as many as 30,8% of MRSA colonizing skin of 78 healthy children with AD and 60% of MRSA infecting skin of 20 children with AD. High percentage of MRSA colonizing different body sites in patients with AD is most probably closely associated with the selection of MRSA following prior therapy with beta-lactams [47]. It is worth remembering, that skin colonization with MRSA also follows previous hospitalization increasing the likelihood of contact with hospital strains [48] or may be associated with the direct contact and transmission of MRSA within community. In the present study all examined patients denied hospitalization within 6 months before specimen collection, were also neither related nor shared the same habitat, therefore the low rates of MRSA within the patients examined in the present study seem to support the above observation.

In the study the susceptibility to erythromycin and clindamycin of investigated S. aureus was also determined. MLSB – the acquired resistance to macrolides, lincosamides and streptogramin B results from the decreased binding of these antibiotics to the methylated 50S ribosomal subunit, an overlapping binding site for all three groups of antimicrobial agents [49]. Constitutive MLSB (MLSBc) phenotype is associated with the rRNA methylase constantly produced by the bacterial strain, whereas in the bacteria with inducible MLSB (MLSBi) the production of methylase is observed in the presence of an inducing agent [50]. The D-test method is reccomended to determine the inducible MLSB, due to fact that this type of resistance cannot be determined with standard susceptibility tests. D-test reveals the inducible resistance to clindamycin (MLSBi) when disc with clindamycin is placed in close proximity to erythromycin disc and D-shaped inhibited growth zone is flattened between erythromycin and clindamycin. This method allows to avoid the clinical failures of treatment with clindamycin the infections caused by MLSBi strains and to distinguish the MLSBi from MS phenotype –strains resistant to erythromycin and streptogramin B but susceptible to clindamycin [51]. The importance of the proper determination MLSB phenotype is worth to underline, since clindamycin is recommended to treat uncomplicated skin and soft tissue infections, particularly an alternative for the treatment of infections caused by MRSA [52].

MLSB resistance phenotype was confirmed in 7 strains,among them 3 simultaneously showed methicillin resistance. Concomitant resistance to beta-lactams, macrolides and lincosamides significantly compromises therapy leaving not many treatment options for therapy in community [53‐55].

Although topical skin decolonization with antimicrobial agents may reduce the risk of subsequent SSTI’s [34, 35] and may be an important element of medical strategy in patients with AD. However Polish Society of Atopic Diseases does not recommend the prolonged topical use of antibiotics and oral antimicrobial therapy, short courses of oral antibiotics, such as cephalosporins, may be implemented in patients with clinical signs of bacterial infection. Other studies have shown that treatment with oral flucloxacillin or cefuroxime caused a significant reduction in S. aureus skin colonization in children. However no significant relief of AD symptoms was observed. Soon after the treatment, recolonization with S. aureus was observed [56] and exacerbation of AD symptoms were assumed [57]. Prolonged antimicrobial treatment entails also the risk of adverse effects such as skin microbiota disruption, contact dermatitis or selection of resistant bacteria, including MRSA.

Due to the fact that oral antimicrobial agents poorly penetrate the nasal mucosa, an oral treatment with topical application of mupirocin may be an improvement of carrier state eradication outcomes [12]. In the present study vast majority of examined strains isolated from nasal vestibule (79/86) showed susceptibility to mupirocin and the obtained result is close to ones obtained for S. aureus isolated from patients in Europe (6,6%) [58]. Mupirocin has been approved for eradication of MRSA and MSSA nasal carriage, however, the increasing prevalence of resistance to this antimicrobial agent among S. aureus is observed worldwide. In our study the lack of methicillin resistance in mupirocin resistant isolates was confirmed. Therefore overuse or uncontrolled use of mupirocin may lead to increased emergence of resistant strains and hence to reduction of the likelihood of S. aureus successful eradication.

It’s important to underline that antimicrobial therapy should be considered only in exacerbation of AD symptoms and complications following multiple and recurrent bacterial skin infections. The immunization with autovaccines composed of unique S. aureus antigens that aim the skin beneficial bacteria remain unharmed, is considered as an alternative in AD management [59‐61].

Consequently, management of AD complicated by S. aureus colonization should also consider the eradication of S. aureus from nose. With the restoration of skin structure and its function it may decrease the risk of autoinfection and the frequency of AD exacerbations significantly improving the severity of AD.