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Article

Snapshot of Phenotypic and Molecular Virulence and Resistance Profiles in Multidrug-Resistant Strains Isolated in a Tertiary Hospital in Romania

1
Fundeni Clinical Institute, 022328 Bucharest, Romania
2
Department of Microbiology and Immunology, Faculty of Biology, University of Bucharest, 060101 Bucharest, Romania
3
Research Institute of the University of Bucharest–ICUB, 91-95 Spl. Independentei, 050567 Bucharest, Romania
4
Fundeni Clinical Institute, University of Medicine and Pharmacy “Carol Davila” Bucharest, 020021 Bucharest, Romania
5
Romanian Academy, 050045 Bucharest, Romania
*
Author to whom correspondence should be addressed.
These author contributed equally to this work.
Pathogens 2023, 12(4), 609; https://doi.org/10.3390/pathogens12040609
Submission received: 29 March 2023 / Revised: 11 April 2023 / Accepted: 14 April 2023 / Published: 17 April 2023

Abstract

:
A current major healthcare problem is represented by antibiotic resistance, mainly due to multidrug resistant (MDR) Gram negative bacilli (GNB), because of their extended spread both in hospital facilities and in the community’s environment. The aim of this study was to investigate the virulence traits of Klebsiella pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa MDR, XDR, and PDR strains isolated from various hospitalized patients. These GNB strains were investigated for the presence of soluble virulence factors (VF), such as hemolysins, lecithinase, amylase, lipase, caseinase, gelatinase, and esculin hydrolysis, as well as for the presence of virulence genes encoding for VF involved in adherence (TC, fimH, and fimA), biofilm formation (algD, ecpRAB, mrkA, mrkD, ompA, and epsA), tissue destruction (plcH and plcN), and in toxin production (cnfI, hlyA, hlyD, and exo complex). All P. aeruginosa strains produced hemolysins; 90% produced lecithinase; and 80% harbored algD, plcH, and plcN genes. The esculin hydrolysis was detected in 96.1% of the K. pneumoniae strains, whereas 86% of them were positive for the mrkA gene. All of the A. baumannii strains produced lecithinase and 80% presented the ompA gene. A significant association was found between the number of VF and the XDR strains, regardless of the isolation sources. This study opens new research perspectives related to bacterial fitness and pathogenicity, and it provides new insights regarding the connection between biofilm formation, other virulence factors, and antibiotic resistance.

1. Introduction

The ability of a bacterial strain to both colonize the host organism and trigger a disease is related to its pathogenic potential, which is enhanced by the expression of one or more virulence factors [1,2]. The clinical presentation of an infectious disease depends on these major properties of a pathogen (pathogenicity and virulence), but also on several host-related factors (such as age, immune status, diet, and other environmental conditions). Different aggressins (enzymes, invasins, toxins, and secretion systems), adhesins (pili, fimbriae, and EPS components), siderophores, and the generation of biofilms are often included among the most studied virulence factors of the potentially pathogenic bacteria. Some virulence genes are chromosomally encoded, i.e., some adhesins, but others are located in plasmids or in other mobile genetic elements. Therefore, most of the AR (antibiotic resistance) and virulence genes are often co-located and could be transmitted horizontally [3]. Both have co-evolved, but with different rhythms and consequences overtime [4]. AR is an ancient evolutionary phenomenon that has been recently accelerated by various factors involved in the process of natural selection. Antibiotics are competitive factors with a naturally production rate in microbial metabolism. However, during the last eight decades, after the increased availability of different antibiotics, AR has become a global threat. Antibiotics certainly contributed to the worldwide reduction in morbidity and mortality rates due to infectious diseases, but their overuse or misuse effects, especially for the cheaper ones, led to a paradoxical effect and a continuously increasing AR [5]. On the other hand, the AR genes are not only a survival advantage for pathogens, but they also contribute to an enhancement of the virulence and the fitness of multidrug resistant (MDR) strains [6].
Some authors emphasize that, in order to improve the management of healthcare associated infections (HAIs), the detection of the virulence genes in MDR GNB is as equally important as the phenotypic and the genotypic description of AR [7]. The newly developed differences in the permeability of the outer membrane (OM) of Gram-negative bacteria has led to the initiation and extension of the AR phenomenon. The modified efflux pumps and the proteins of OM are major contributors to the intrinsic antibiotic resistance mechanisms in GNB [8]. However, the activity of the efflux pumps and OM proteins are associated with several virulence factors in GNB, according to many large protein databases (UniProt; VFDB) [9]. Resistance to β-lactam antibiotics is conferred by the production of antibiotic-modifying enzymes, efflux pumps, porins, protection of the antibiotic target, or biofilm production [10,11,12]. However, the primary mechanism of β-lactam resistance in GNB is represented by the production of β-lactamases (serine-β-lactamases: Ambler classes A, C, and D, and metallo-β-lactamases or MBL: Ambler class B) [13].
Pseudomonas aeruginosa (P. aeruginosa) is one of the most clinically relevant pathogens responsible for a high percentage of MDR infections in immunodeficient patients. The major concern regarding this microorganism is its great adaptability, which is correlated with many virulence factors and virulence-associated proteins. Their role over resistance mechanisms is currently being investigated, mostly because there is an increased need to develope new strategies for preventing and managing AR. The biofilm formation and quorum sensing processes are among the focus points, together with the functionality of the T3SS components and the secreted bacterial toxins [14]. Recent studies concerning biofilm forming bacteria have suggested the associative effect over the mechanisms of resistance for both the inflammatory endotoxins/lipopolysaccharides and the expression of the stress genes [15,16]. According to some authors, the quorum sensing mechanism and signal molecules are associated with biofilm formation and intrinsic resistance mechanisms in P. aeruginosa. The environment where the microorganism lives also plays a major role in the activation and functionality of the virulence factors [17].
Regarding Klebsiella pneumoniae (K. pneumoniae) strains, colonization is influenced by the presence of several virulence factors such as pili (especially coded by mrk and fim genes), efflux pumps, lipopolysaccharides, type VI secretion system, capsule, and siderophores. However, the ability of the MDR strains carrying virulence genes to produce infection after they colonize the human host remains an intensely debated subject [18]. Some authors underline the co-occurrence of a virulence plasmid and KPC genes in hypervirulent strains of K. pneumoniae isolated from patients with bacteriemia [19].
Among the non-fermentative GNB, Acinetobacter baumannii (A. baumannii) is also studied regarding its quorum sensing mechanisms, which are related to both the activation and the release of the virulence genes, as well as multidrug resistance. The goals are to identify the best drugs that target such mechanisms, and to reduce the excessive antibiotic burden, which eventually leads to AR [20]. This growing need to reduce multidrug resistance is a major target for microorganisms such as A. baumannii, which have various ways of avoiding the action of antibiotics. A series of studies have emphasized the presence of multiple resistance genes associated with this microorganism, which now encompasses almost all antibiotic classes [21]. This peculiarity represents a major epidemiological issue, especially in the era of the emergence of new viruses, such as COVID-19, which may infect the human host together with a bacterium. The attention of the researchers falls once again over a series of virulence associated factors, such as OmpA, which are often connected to β-lactam resistance [21].
An important epidemiological feature of these three opportunistic pathogens, which are members of the ESKAPE group, is their ability to colonize and then to cause an infection in hospitalized patients. This process is due to both the presence of resistance and to virulence factors synthesized in a manner dependent on the cellular density, as well as the mechanism of quorum sensing (QS), which protects bacterial cells (favoring their multiplication and host colonization) against antimicrobial substances that are part of the natural non-specific defense mechanisms of the host [22,23].
The aim of our study was to investigate the profiles of both the resistance and virulence of some selected MDR strains belonging to clinically significant opportunistic pathogens such as Klebsiella pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa, often involved in healthcare-associated infections.

2. Materials and Methods

2.1. Bacterial Strains

Bacterial strains from various biological samples (urine, blood, bile, wound, bronchial aspirate, rectal swab, drainage tube, ascitic fluid, and stool) of hospitalized patients were isolated from units with a high epidemiological risk from the Fundeni Clinical Institute during October 2019–October 2020. All of the strains were identified by an automatic method (BD Phoenix Vitek 2 Compact) and further investigated for antibiotic resistance [24]. The multidrug-resistance profile was established according to the international guidelines [25]. Furthermore, the expression of several virulence factors was investigated in a selected set of 72 MDR, XDR, and PDR strains of K. pneumoniae (n = 51), A. baumannii (n = 10), A. lwoffii (n = 1), and P. aeruginosa (n = 10) with phenotypic and molecular methods. Escherichia coli ATCC 25922 and P. aeruginosa ATCC 27853 were used as the reference strains.

2.2. Evaluation of Antibiotic Susceptibility

The antibiotic susceptibility testing was investigated according to CLSI 2021 (Clinical Laboratory Standard Institute), using disc diffusion and automatic methods (BD Phoenix/Vitek 2 Compact). Phenotypic confirmation for ESBL production was performed through a double-disc synergy test (DDST) (Ceftazidime–Amoxicillin/Clavulanic acid–Ceftriaxone) [26].

2.3. Detection of β-Lactamase Encoding Genes

DNA extraction was performed by an adapted alkaline extraction method. Briefly, 1–5 bacterial colonies from pure cultures were suspended in 1.5 mL tubes with 20 μL NaOH 0.05 M (sodium hydroxide) and SDS 0.25% (sodium dodecyl sulphate), heated at 95 °C for 15 min followed by the addition of 180 μL TE buffer (TRIS + EDTA) 1×, centrifugation at 13,000 rpm for 3 min, and lastly the supernatant was stored at 4 °C. Simplex and multiplex PCR (PCR thermal BioRad thermocycler) amplifications were performed for blaNDM, blaOXA-48, blaKPC, blaVIM, blaIMP, blaSHV, blaTEM, blaCTX-M, blaOXA-23, blaOXA-24, and blaOXA-51 genes, using specific primers (Table 1) in a final volume of 20 µL (PCR Master Mix 2×, Thermo Fisher Scientific, Bucharest, Romania), with a content of 1 µL of bacterial DNA, after using the following conditions: initial denaturation (95 °C, 10 min), followed by 30 cycles of denaturation (95 °C, 30 s), alignment of primers (52 °C, 40 s), extension (72 °C, 50 s), and final extension (72 °C, 10 min). DNA fragments were analyzed by electrophoresis in a 1% agarose gel, at 100 V for 1 h in TAE 1× (40 mmol/L Tris-HCl [pH 8.3], 2 mmol/L acetate, 1 mmol/L EDTA) containing 0.05 mg/L SYBR Safe DNA (Thermo Fisher Scientific, Bucharest, Romania). Positive strains for blaOXA23,-24,-51 genes (in A. baumannii); blaNDM, blaOXA-48, blaSHV, blaTEM, and blaCTX-M genes (in K. pneumoniae); and for blaVIM, and blaIMP genes (in P. aeruginosa), from the Microbiology Collection of the Research Institute of the University of Bucharest, were used as the positive controls.

2.4. Evaluation of the Soluble Enzymatic Factors

The virulence phenotypes were assessed by performing enzymatic tests for the expression of some soluble virulence factors, as described elsewhere [27]. Briefly, soluble virulence factors were detected using solid culture media supplemented with 5% sheep blood, 2.5% yolk, 1% Tween 80, 15% soluble casein, 3% gelatine, 1% starch and Fe3+ citrate for the bacterial toxins/enzymes.

2.5. Virulence Genes Detection

The genetic background of virulence was investigated by PCR for selected genes from UniProt and VFDB databases and is included in Table 1, along with the genes involved in the biofilm formation (algD, ecpRAB, mrkA, mrkD, ompA, and epsA), adherence (TC, fimH, fimA), tissue distruction (plcH and plcN), and toxin production (cnfI, hlyA, hlyD, and exo complex). Simplex and multiplex PCR reactions were conducted using a reaction mix of 20 μL (PCR Master Mix 2×, Thermo Scientific) with 1 μL of bacterial DNA obtained using the adapted alkaline extraction method, with the following conditions: 1 cycle at 95 °C, 2 min; followed by 30 cycles at 94 °C for 30 s; 42, 55, 57, 58, 59, 60, 61, 62, and 65 °C (cnf1/algD/ecpRAB/fimA/ompA, epsA, fimH/, exoT/exoU/TC/hlyA, mrkA, and mrkD/exoS) for 30 s, 72 °C for 1 min, and a final cycle at 72 °C for 7 min. The amplification products were visualized by electrophoresis on with same parameters described above. Positive strains for epsA and ompA genes (in A. baumannii); fimH, fimA, hlyD, hlyA, cnf1, ecpRAB, mrkA, and mrkD genes (in K. pneumoniae); and plcH, plcN, exoU, exoT, exoS, algD, and TC genes (in P. aeruginosa) from the Microbiology Collection of the Research Institute of the University of Bucharest were used as the positive controls.
The primers used during the PCR reaction are depicted in Table 1.

2.6. Statistical Analysis

The statistical analysis was performed with the programs Microsoft Excel 2021, Vassarstats [28], and PSPP 1.6.2 [29]. The obtained frequency values were compared using Fisher Exact Probability Test and chi-square test. The correlations depicted below were established using Pearson’ s correlation coefficient in bivariate correlation and a p value less than 0.05 was considered statistically significant.

3. Results

A total of 72 bacterial strains of K. pneumoniae (51), A. baumannii (10), A. lwoffii (1), and P. aeruginosa (10) were isolated from clinical samples during October 2019 and October 2020 (Table 2).
The tested strains of K. pneumoniae, P. aeruginosa, and Acinetobacter spp. showed high rates of resistance to all of the tested antibiotics (Supplementary Table S1). All of the K. pneumoniae strains were resistant to fluoroquinolones (ciprofloxacin and/or levofloxacin), piperacillin/tazobactam, carbapenems (ertapenem and/or imipenem and/or meropenem), and third-generation cephalosporins (ceftriaxone and cefotaxime); 74.5% were resistant to trimethoprim/sulfamethoxazole; 45.1% of strains were resistant to gentamycin; 29.4% showed resistance to amikacin; and only 17.6% were resistant to ceftazidime/avibactam. The P. aeruginosa strains were resistant to aminoglycosides, fluoroquinolones, ceftazidime, carbapenems (imipenem and meropenem), while 30% of them displayed resistance to piperacillin/tazobactam. All P. aeruginosa strains were susceptible to ceftazidime/avibactam. The A. baumannii strains were resistant to aminoglycosides, fluoroquinolones, ceftazidime, and carbapenems (imipenem and meropenem), 54.5% were resistant to trimethoprim/sulfamethoxazole, while a lower percent (18.2%) displayed a resistance pattern to ampicillin–sulbactam and minocycline.
The K. pneumoniae strains carried ESBLs and carbapenemase encoding genes of blaCTX-M (49%, 25/51), blaSHV (45.1%, 23/51), blaTEM (37.3%, 19/51), blaKPC (33.3%, 17/51), blaOXA-48 (31.4%, 16/51), and blaNDM (17.6%, 9/51) (Supplementary Figures S1 and S2). In A. baumannii, two class D carbapenemase encoding genes were present (blaOXA-23 in 54.5% of the strains and blaOXA-24 in 9.1%) (Supplementary Figure S3).
The phenotypic virulence analysis of P. aeruginosa revealed the production of haemolysins (100% of the strains), while 90% of the strains isolated from the blood cultures produced lecithinase.
The majority (96.1%) of K. pneumoniae strains hydrolysed esculin producing esculetol, which acted as a pseudo-siderophore, and 25.5% were amylase producers. Only 11.8% of the K. pneumoniae strains were lecithinase producers, while gelatinase was found in 9.8% of them. Here, 31.4% of the K. pneumoniae strains produced lipase. We included, in Table 3, an analysis regarding the probability of encountering some of these VF in several isolation sources. Only caseinase in K. pneumoniae strains was more likely to be source-dependent (p = 0.047).
In Supplementary Table S2, we show the virulence and resistance profiles of the identified strains of Acinetobacter spp., P. aeruginosa, and K. pneumoniae. No significant association was encountered between the virulence or resistance profiles and the isolation sources.
Next, we searched for an association between a certain virulence pattern and the isolation source. The association of fimA and mrkA genes was more likely to have a source-related distribution (p = 0.03) (see Table 4).
Because most of the analyzed strains were K. pneumoniae, we continued our correlation analysis on them. Thus, after indicating the source of isolation (urine, blood culture and other sources), we used a bivariate correlation tool to find any connection between the numbers of strains belonging to each resistance phenotype (XDR—extensive drug-resistant; MDR—multidrug resistant; PDR—pan drug resistant) and the numbers of strains with VF or with resistance genes. The categories of resistance were established according to international consensus guidelines [25]. Significant associations were found between the numbers of XDR strains and those with two virulence factors, or those with three virulence genes (Figure 1 and Figure 2). A significant correlation was found between the strains with one VF and those with one resistance gene (Figure 3).

4. Discussion

Currently, multidrug resistance in GNB is intensely studied because of the need for improved strategies for the treatment of infection caused by these opportunistic pathogens. In addition, the mechanisms related to the pathogenesis of MDR GNB are intensely being studied in order to gain a better understanding of their adaptability, fitness, and spreading rates [18,21].
Our research focused on the virulence traits of some selected strains belonging to three MDR, XDR, or PDR microorganisms, in relation to their phenotypic profile of AR. All of the investigated bacterial strains, and especially K. pneumoniae, showed high resistance levels, in accordance with other studies [30,31]. K. pneumoniae strains mostly carried the blaKPC carbapenemase encoding gene, followed by a smaller percentage of blaOXA-48 and blaNDM genes. Among the ESBLs, the most prevalent ones were blaCTX-M, followed by blaSHV and blaTEM. For A. baumannii, two acquired CHLDs encoding genes were revealed in the analyzed strains: blaOXA-23 and blaOXA-24. The same results were found by Gheorghe et al. (2019) in their study [32]. Most of the strains of P. aeruginosa were positive for blaIMP (Supplementary Figure S4) and blaVIM (Supplementary Figure S5).
P. aeruginosa is one of the pathogens that harbor numerous VF involved in cell invasion and toxicity. Most of its VF also are involved in biofilm formation. One of the most important VFs is an exopolysaccharide, alginate, with a role of adhesion to the cellular substrate and a protective role against certain environmental adverse conditions. Therefore, its presence is required for the survival of the microorganism and its multiplication within microbial biofilms [33,34,35]. Among VF, the presence of flagella and pili, exotoxin A, protease, alginate production, biofilm formation, and secretion systems III and IV determine the high pathogenicity of P. aeruginosa strains [36]. These factors seem not to act alone, but in the presence of other enzymes involved in pathogenicity [37]; these soluble components identified in our study were exoenzymes, such as hemolysins, caseinase, and lecithinase. Apart from gelatinase, we could also find lipase, esculinase, and amylase in strains of P. aeruginosa. These virulence factors were also identified in previous studies performed on such strains. Even if amylase, caseinase, and lipase are not literally real virulence factors, but metabolic enzymes (encoded by chromosomal genes), their presence in strains from the Enterobacterales and Pseudomonadaceae families facilitates adaptability inside the host and even the survival of these bacteria in the external environment, thus increasing the risk of transmission. This is a very important trait among the P. aeruginosa strains, which can pass and infect other hosts, thus creating a chain of events that lead to the spread of MDR, with a major impact on the health of the community [38].
LasA was described as the first virulence gene found in P. aeruginosa with an elastase and protease activity [39], while LasB was described as a metalloenzyme secreted by pathogenic strains of P. aeruginosa. A major role of LasB is currently designated in bacterial intercellular communication, and this metalloenzyme is also reported in 90% of the urine specimens [37,40,41,42]. A study conducted in Teheran, between June 2013 and June 2014, on pediatric patients with cystic fibrosis, revealed an increased prevalence rate in virulence genes in P. aeruginosa, of over 63.1% for toxA and 95.4% for lasB [43]. Most of the isolated strains in this study had a combination between many virulence genes, especially between plcH, plcN, exoS, exo U, and algD (Supplementary Figures S6–S8). The phenotypic expression of these genes consists of the destruction of tissues (plcH, plcN, exoS, and exoU) or in the cellular adhesion and formation of biofilms (algD) [44]. All these features promote the spreading process and the complex development of biofilms, which, in turn, are substantial factors in the development of multidrug resistance [45]. These intricate relations could be a subject for further study.
The virulence genes are different among the intestinal colonizing K. pneumoniae strains, compared with those from other sources [37]. This might be influenced by the fact that several environmental characteristics influence the adherence and survival of these strains, thus leading to the development of complex virulence systems [46]. Emphasizing that K. pneumoniae represents one of the most important opportunistic pathogens, this microorganism is frequently involved in urinary and respiratory tract infections, as well as sepsis [47]. The pathogenicity and virulence of K. pneumoniae strains are mainly due to the presence of the capsule, with the most common strains being those with the capsule type K1, K2, K5, K54, and K57, as well as K20 (which has two virulence factors, rmpA and wcaG) [48,49]. It was observed that the virulence gene wcaG is involved in the production of the capsular fucose, associated with K1 and K54 strains, while the rmpA gene was identified in strains of Klebsiella spp. type K2 [50,51,52]. However, the presence of a capsule was not the only contributor to virulence, with several studies underlining the association of various virulence factors in the persistence of this microorganism [53]. In our study, the majority of K. pneumoniae strains were positive for more than two virulence factors.
On the other hand, many VF contribute to a series of mechanisms that have a complex pathogenic response, such as biofilm formation. In this study, we emphasized that most of the encountered VF in all three mainly researched microorganisms were involved in biofilm formation (such as mrkA, ecpRAB, and algD) (Supplementary Figures S9 and S10) and adherence (fimA) (Supplementary Figures S11–S14). We also identified several correlations between the number of virulence genes and antibiotic resistance, depicted as a repetitive pattern in all of the isolation sites. However, the combination between two or more virulence genes was not newly discovered among MDR K. pneumoniae. The association between the ecp complex and the fim system was, for instance, observed in other strains of K. pneumoniae isolated from intra-hospital infections [54]. This probably brought a new mechanism of adaptability and biofilm formation for these bacterial strains, in order to increase their survival rate under any circumstances. However, the observed effect might be perilous for the health of the entire community because it might lead to the spread of MDR organisms. In our case, because of the increased number of genes involved in biofilm formation, all correlations need further study because of several interference factors that contribute to the achievement of multidrug-resistant genes/mechanisms. There are studies that emphasize the connection between biofilm formation and antibiotic resistance through various mechanisms [55]. Therefore, this subject needs further analysis.
In bacterial biofilms, tolerance to different classes of antibiotics is due to the different mechanisms involved, such as, the presence of the ndvB and brlR genes for the aminoglycosides, the efflux pumps for the polymyxin E, and porins (MexAB-oprM and MexCD-oprJ) for beta-lactams. Antibiotic tolerance is also given by the impermeability of the matrix secreted by the bacterial cells inside the biofilm. In fluoroquinolones, antibiotic tolerance appears because of the decrease in oxygen concentration, the low metabolic activity/dormancy state, or the activity of the efflux pumps [56]. A major part in biofilm formation is also played by the QS complex [39]. Three QS systems are known in P. aeruginosa: the most important is LuxI/LuxR, which controls the expression of virulence factors, but a major part is also played by the third non-LuxI/LuxR-type system called the Pseudomonas quinolone signal system (PQS). In the first phase, LuxI/LasI synthesizes the 3OC12HSL lactone detected by the cytoplasmic LuxR homologue LasR. The LasR–3OC12HSL complex activates the transcription of target genes, including those encoding VF, such as elastase, proteases, and exotoxin A. One of the targets of LasR–3OC12HSL is lasI; another target is a second luxI homolog called rhlI (synthesizes a second AI, butanoyl homoserine lactone—C4HSL). At high concentrations, this AI binds to RhlR, a second LuxR homolog, RhlR-C4HSL, which activates target genes, including those encoding elastase, proteases, pyocyanin, and siderophores. Among its targets is rhlI, which leads to autoinduction of the second QS system [56]. It is, therefore, already known that biofilms are a result of complex interactions both in Klebsiella pneumoniae and in P. aeruginosa.
Another pathogen that is also an important biofilm producer is A. baumannii [57], an opportunistic pathogen with major implications in HAIs, responsible for outbreaks and severe infections especially in patients with different immunodeficiencies. Although poor in the production of soluble VF (in our study, almost all of the strains produced only one VF-ompA) (see Supplementary Figure S15), it proved to be an important nosocomial pathogen due to the formation of biofilms (especially on medical devices) and due to its MDR, XDR, or PDR phenotypes [30,32,58,59]. Compared with the soluble VF reported for other Gram-negative bacteria, a small number of these factors have been identified for A. baumannii, in comparison with K. pneumoniae and P. aeruginosa. In a study performed by Zeighami et al. (2019) on a significant number of A. baumannii strains, it was observed that most of the strains that carried virulence genes were involved in bacterial biofilm development [60]. Among them, 98% simultaneously showed several virulence genes; the highest prevalence was represented by csuE (100%) and ompA (81%) genes. The severity of infections produced by pathogenic strains of A. baumannii and P. aeruginosa affecting both the respiratory system (pulmonary ventilated patients) and the teguments (patients with a compromised epidermal barrier) was due to the presence of QS mechanisms [59,60,61,62]. Gheorghe et al. also reported only strains positives for the ompA gene [32].
Numerous recent studies carried out in Romania concerning AR had a major impact, both clinically and especially epidemiologically, due to the high spreading capacity of the resistance genes among Enterobacterales [63]. One of the most recent studies (Tîrgu-Mureș, 2018) performed on 19 strains of carbapenemase producing Enterobacterales showed that the resistance genes detected by PCR were blaKPC, blaOXA-48, and blaNDM [64]. Gavriliu et al. (2016) mentioned, in a retrospective study conducted in “INBI Matei Balș”, a lower resistance level of K. pneumoniae strains isolated from blood cultures, especially to fluoroquinolones, aminoglycosides, and carbapenems, and to third generation cephalosporins, compared with our country’s results reported in EARS-Net [65].
In Romania, Gheorghe et al. (2014), reported for the first time the presence of the blaVIM-4 gene in P. aeruginosa clinical strains (involved in acquired resistance mediated by class I integrons) [66]. A year later, Lixandru et al. described for the first time the presence of the blaVIM-1 and blaKPC-2 genes in strains of K. pneumoniae, highlighting the urgent need for measures to combat and prevent intrahospital infections [67]. Two years later, Georgescu et al. (2016), mentioned for the first time the presence of the blaOXA-72 gene in A. baumannii strains, responsible for plasmid-mediated resistance through plasmid pAB120 [68].
Only a few papers have been published in Romania on the topic of antibiotic resistance and virulence; for instance, Delcaru et al. (2017) investigated these associated features in UTI strains; their study revealed a high ability of the UTI strains to adhere to HEp-2 cells. The Gram-negative UTI strains produced pore-forming toxins (hemolysins, lecithinase, and lipase), proteases, amylase, and siderophore-like molecules resulted from the process of esculin hydrolysis. In their opinion, searching for the correlation between resistance and virulence factors could provide information useful for anticipation of the clinical evolution and risk of UTI recurrence [22].
Our study depicted numerous carbapenem and ESBL-encoding genes, especially in K. pneumoniae, most of them being encoded by β-lactamases of class A (KPC, TEM, SHV), B (NDM) and D (OXA-48). This complex mixture was reflected in the resistance profile of the identified strains, most of them being classified as either PDR or XDR. These strains also had several VF, most of them being involved in biofilm formation or tissue destruction. However, despite very careful selection of the analyzed strains, the major limitation of our study was the reduced number of isolates (being selected strains with epidemiologically important resistance profiles), which might influence the statistical analyses.
Studies similar to this one can help gain a better understanding of the adaptability of a pathogen to the host environment. Finally, a good adaptation is as a result of a well-balanced distribution of energy resources necessary for growth, multiplication, and colonization; virulence factors expressed in a cell-density-dependent manner; and the pathogen’s survival in opposition with innate and adaptive immune system effectors, eventually with antibiotics too. This network of processes modulate the reproductive fitness of the pathogen and influence the community-acquired infections and HAIs evolution; therefore, gaining a better understanding of them will help with the development and implementation of appropriate prevention, diagnosis, and treatment actions [69].

5. Conclusions

Our study concerning the resistance and virulence profile of carefully selected MDR, XDR, and PDR strains of Gram-negative bacilli from the ESKAPE group (Klebsiella pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa) revealed a high repertoire of ARGs and VMs. The most frequently expressed virulence factors were those involved in host cell/tissue destruction and biofilm formation. Such phenotypes are of interest due to their fitness, adaptability, and capacity of dissemination, both in the environment and in the host. This study, which focused on the genotype−phenotype association of resistance and virulence (less approached in Romania), could contribute to a better understanding of bacterial pathogenesis in patients from intensive care units (where biofilm formers and antibiotic-resistant strains spread). The results of this study show that it is imperative to continue monitoring antibiotic resistance, which is often associated with virulence factors. The careful surveillance of both the environmental and host conditions in which the bacteria/microorganisms localize themselves, grow, and colonize is also of great importance because it helps in establishing the pathogenic characteristics for a better prevention and treatment policy regarding healthcare-associated infections.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/pathogens12040609/s1, Figure S1: Electrophoresis gel for blaTEM (1080 bp) and blaKPC (798 bp) genes detection in K. pneumoniae strains; Figure S2: Electrophoresis gel for blaOXA-48 (438 bp) and blaNDM (621 bp) genes detection in K. pneumoniae strains; Figure S3: Electrophoresis gel for blaOXA-51 (346 bp), blaOXA-23(501 bp) and blaOXA-24 (242 bp) genes detection in A. baumannii strains; Figure S4: Electrophoresis gel for blaIMP gene (232 bp) detection in P. aeruginosa strains; Figure S5: Electrophoresis gel for blaVIMlike (390 bp) gene detection; Figure S6: Electrophoresis gel for plcN (307 bp), plcH ( 466 bp), exoU ( 134 bp) and exoT ( 152 bp) genes detection in P. aeruginosa strains; Figure S7: Electrophoresis gel for exoS (1352 bp) and algD (1310 bp) genes detection in P. aeruginosa strains; Figure S8: Electrophoresis gel for TC gene ( 752 bp) detection in P. aeruginosa strains; Figure S9: Electrophoresis gel for mrkA (498 bp) and mrkD (756 bp) genes detection in K. pneumoniae strains; Figure S10: Electrophoresis gel for ecpRAB (1025 bp) gene detection in K. pneumoniae strains; Figure S11: Electrophoresis gel for fimA (500 bp) gene detection in K. pneumoniae strains; Figure S12: Electrophoresis gel for fimH (506 bp) gene detection in K. pneumoniae strains; Figure S13: Electrophoresis gel for cnf1 (544 bp) gene detection in K. pneumoniae strains; Figure S14: Electrophoresis gel for hlyA (1177 bp) and hlyD (904 bp) genes detection in K. pneumoniae strains; Figure S15: Electrophoresis gel for ompA (531 bp) gene detection in A. baumannii strains; Table S1: The resistance pattern of the isolated strains; Table S2: Virulence and β-lactamase encoding genes.

Author Contributions

Conceptualization, B.S.T., I.G.-B., L.-M.D., I.C.B. and V.L.; methodology, B.S.T., L.-M.D. and I.G.-B.; software, M.M.; validation, E.I., M.M., I.G.-B., L.G.M., L.-M.D. and V.L.; formal analysis, M.M. and L.-M.D.; resources, B.S.T., L.-M.D., I.G.-B. and L.G.M.; data curation, B.S.T.; writing—original draft preparation, B.S.T.; writing—review and editing, B.S.T., E.I., M.M., I.G.-B., M.-C.C. and V.L.; supervision, V.L. All authors have read and agreed to the published version of the manuscript.

Funding

The financial support of the Research Projects PN-III-P1.1-TE-2021-1515 (TE 112/2022); COFUND-AQUATIC POLLUTANTS-BIOCIDE (ERANET 243/2021); PN-III-P4-PCE2021-1797 awarded by The Executive Agency for Higher Education, Research, Development and Innovation Funding (UEFISCDI) and CNFIS-FDI-2022-0675; FDI 0609/2023 financed by the Ministry of Research, Innovation and Digitalization through Program 1—Development of the national R&D system, Subprogram 1.2—Institutional performance—Financing projects for excellence in RDI are acknowledged. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript or in the decision to publish the results.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Madigan, M.T.; Martinko, J.M.; Dunlap, P.V.; Clark, D.P. Brock Biology of Microorganisms, 12th ed.; Pearson Education Inc.: Upper Saddle River, NJ, USA, 2009. [Google Scholar]
  2. Otto, M. Staphylococcal Biofilms. Microbiol. Spectr. 2018, 6, 1–26. [Google Scholar] [CrossRef]
  3. Cepas, V.; Soto, S.M. Relationship between Virulence and Resistance among Gram-Negative Bacteria. Antibiotics 2020, 9, 719. [Google Scholar] [CrossRef]
  4. Beceiro, A.; Tomás, M.; Bou, G. Antimicrobial Resistance and Virulence: A Successful or Deleterious Association in the Bacterial World? Clin. Microbiol. Rev. 2013, 26, 185–230. [Google Scholar] [CrossRef] [PubMed]
  5. Levy, S.B. The Antibiotic Paradox. How Miracle Drugs Are Destroying the Miracle; Springer: New York, NY, USA, 1992; ISBN 978-1-4899-6042-9. Available online: https://link.springer.com/book/10.1007/978-1-4899-6042-9 (accessed on 15 February 2023).
  6. Wang, G.; Zhao, G.; Chao, X.; Xie, L.; Wang, H. The Characteristic of Virulence, Biofilm and Antibiotic Resistance of Klebsiella pneumoniae. Int. J. Environ. Res. Public Health 2020, 17, 6278. [Google Scholar] [CrossRef] [PubMed]
  7. Pereira, S.G.; Rosa, A.C.; Cardoso, O. Virulence factors as predictive tools for drug resistance in Pseudomonas aeruginosa. Virulence 2015, 6, 679–683. [Google Scholar] [CrossRef]
  8. Viveiros, M.; Dupont, M.; Rodrigues, L.; Couto, I.; Davin-Regli, A.; Martins, M.; Pagès, J.M.; Amaral, L. Antibiotic stress, genetic response and altered permeability of E. coli. PLoS ONE 2007, 2, e365. [Google Scholar] [CrossRef] [PubMed]
  9. Wang, Y.; Wang, Q.; Huang, H.; Huang, W.; Chen, Y.; McGarvey, P.B.; Wu, C.H.; Arighi, C.N. UniProt Consortium. A crowdsourcing open platform for literature curation in UniProt. PLoS Biol. 2021, 19, e3001464. [Google Scholar] [CrossRef] [PubMed]
  10. Zhu, Y.; Huang, W.E.; Yang, Q. Clinical Perspective of Antimicrobial Resistance in Bacteria. Infect. Drug Resist. 2022, 15, 735–746. [Google Scholar] [CrossRef]
  11. Halat, D.H.; Moubareck, C.A. The Current Burden of Carbapenemases: Review of Significant Properties and Dissemination among Gram-Negative Bacteria. Antibiotics 2020, 9, 186. [Google Scholar] [CrossRef]
  12. Santajit, S.; Indrawattana, N. Mechanisms of antimicrobial resistance in ESKAPE pathogens. Biomed Res. Int. 2016, 2016, 2475067. [Google Scholar] [CrossRef]
  13. Ambler, R.P. The structure of beta-lactamases. Philos. Trans. R. Soc. Lond. Ser. B Biol. Sci. 1980, 289, 321–331. [Google Scholar] [CrossRef]
  14. Liao, C.; Huang, X.; Wang, Q.; Yao, D.; Lu, W. Virulence Factors of Pseudomonas aeruginosa and Antivirulence Strategies to Combat Its Drug Resistance. Front. Cell. Infect. Microbiol. 2022, 12, 926758. [Google Scholar] [CrossRef] [PubMed]
  15. Baquero, M.R.; Galán, J.C.; Turrientes, M.C.; Cantón, R.; Coque, M.T.; Martínez, J.L.; Baquero, F. Increased Mutation Frequencies in Escherichia coli Isolates Harboring Extended-Spectrum β-Lactamases. Antimicrob. Agents Chemother. 2005, 49, 4754–4756. [Google Scholar] [CrossRef] [PubMed]
  16. Lazar, V.; Chifiriuc, M.C. Medical significance and new therapeutical strategies for biofilm associated infections. Roum. Arch. Microbiol. Immunol. 2010, 69, 125–138. [Google Scholar] [PubMed]
  17. Simanek, K.A.; Paczkowski, J.E. Resistance Is Not Futile: The Role of Quorum Sensing Plasticity in Pseudomonas aeruginosa Infections and Its Link to Intrinsic Mechanisms of Antibiotic Resistance. Microorganisms 2022, 10, 1247. [Google Scholar] [CrossRef] [PubMed]
  18. Martin, R.M.; Bachman, M.A. Colonization, Infection, and the Accessory Genome of Klebsiella pneumoniae. Front. Cell. Infect. Microbiol. 2018, 8, 4. [Google Scholar] [CrossRef]
  19. Du, F.-L.; Huang, Q.-S.; Wei, D.-D.; Mei, Y.-F.; Long, D.; Liao, W.-J.; Wan, L.-G.; Liu, Y.; Zhang, W. Prevalence of Carbapenem-Resistant Klebsiella pneumoniae Co-Harboring BlaKPC-Carrying Plasmid and PLVPK-Like Virulence Plasmid in Bloodstream Infections. Front. Cell. Infect. Microbiol. 2020, 10, 556654. [Google Scholar] [CrossRef]
  20. Zhong, S.; He, S. Quorum Sensing Inhibition or Quenching in Acinetobacter baumannii: The Novel Therapeutic Strategies for New Drug Development. Front. Microbiol. 2021, 12, 558003. [Google Scholar] [CrossRef]
  21. Kyriakidis, I.; Vasileiou, E.; Pana, Z.D.; Tragiannidis, A. Acinetobacter baumannii Antibiotic Resistance Mechanisms. Pathogens 2021, 10, 373. [Google Scholar] [CrossRef]
  22. Delcaru, C.; Alexandru, I.; Podgoreanu, P.; Grosu, M.; Stavropoulos, E.; Chifiriuc, M.C.; Lazar, V. Microbial Biofilms in Urinary Tract Infections and Prostatitis: Etiology, Pathogenicity, and Combating strategies. Pathogens 2017, 5, 65. [Google Scholar] [CrossRef]
  23. Lazar, V.; Holban, A.M.; Curutiu, C.; Chifiriuc, M.C. Modulation of Quorum Sensing and Biofilms in Less Investigated Gram-Negative ESKAPE Pathogens. Front. Microbiol. 2021, 12, 676510. [Google Scholar] [CrossRef] [PubMed]
  24. Trușcă, B.S.; Ianculescu, E.; Maruțescu, L.; Gheorghe-Barbu, I.; Chifiriuc, M.C.; Lazăr, V. Comparative performance of two immunochromatographic tests for the rapid detection of PCR confirmed, carbapenemase producing-Enterobacterales. Biointerface Res. Apll Chem. 2022, 13, 322. [Google Scholar] [CrossRef]
  25. Magiorakos, A.P.; Srinivasan, A.; Carey, R.B.; Carmeli, Y.; Falagas, M.E.; Giske, C.G.; Harbarth, S.; Hindler, J.F.; Kahlmeter, G.; Olsson-Liljequist, B.; et al. Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: An international expert proposal for interim standard definitions for acquired resistance. Clin. Microbiol. Infect. 2012, 18, 268–281. [Google Scholar] [CrossRef] [PubMed]
  26. Clinical and Laboratory Standards Institute. Performance Standards for Antimicrobial Susceptibility Testing, 31st ed.; CLSI supplement M100 ([Electronic]); Clinical and Laboratory Standards Institute: Wayne, PA, USA, 2021; ISBN 978-1-68440-105-5. [Google Scholar]
  27. Georgescu, M.; Gheorghe, I.; Curutiu, C.; Lazar, V.; Bleotu, C.; Chifiriuc, M.C. Virulence and resistance features of Pseudomonas aeruginosa strains isolated from chronic leg ulcers. BMC Infect. Dis. 2016, 16 (Suppl. 1), 92. [Google Scholar] [CrossRef] [PubMed]
  28. Available online: http://vassarstats.net/ (accessed on 5 September 2022).
  29. Available online: http://gnu.org/software/pspp/ (accessed on 2 March 2023).
  30. Borcan, E.; Ghiţă, C.; Chifiriuc, M.C.; Lazăr, V. Antibiotic resistance profiles of Acinetobacter sp. strains isolated from intensive-care unit patients. Roum. Arch. Microbiol. Immunol. 2012, 71, 75–80. [Google Scholar]
  31. Gheorghe, I.; Novais, A.; Grosso, F.; Rodrigues, C.; Chifiriuc, M.C.; Lazar, V.; Peixe, L. Snapshop of carbapenemase-producing Pseudomonas aeruginosa and Acinetobacter baumannii in Bucharest hospitals reveals unusual clones and novel genetic surroundings for blaOXA-23. J. Antimicrob. Chemother. 2015, 70, 1016–1020. [Google Scholar] [CrossRef] [PubMed]
  32. Gheorghe, I.; Cristea, V.C.; Marutescu, L.; Popa, M.; Murariu, C.; Trusca, B.S.; Borcan, E.; Ghita, M.C.; Lazar, V.; Chifiriuc, M.C. Resistance and Virulence Features in Carbapenem-resistant Acinetobacter baumannii Community Acquired and Nosocomial Isolates in Romania. Rev. Chim. 2019, 70, 3502–3507. [Google Scholar] [CrossRef]
  33. Boyd, A.; Chakrabarty, A.M. Pseudomonas aeruginosa biofilms: Role of the alginate exopolysaccharide. J. Ind. Microbiol. 1995, 15, 162–168. [Google Scholar] [CrossRef]
  34. Santos, D.A.; Nascimento, M.M.; Vitali, L.H.; Martinez, R. In vitro activity of antimicrobial combinations against multidrug-resistant Pseudomonas aeruginosa. Rev. Soc. Bras. Med. Trop. 2013, 46, 299–303. [Google Scholar] [CrossRef]
  35. Shahid, M.; Malik, A.; Sheeba. Multidrug-resistant Pseudomonas aeruginosa strains harbouring R-plasmids and AmpC β-lactamases isolated from hospitalised burn patients in a tertiary care hospital of North India. FEMS Microbiol. Lett. 2003, 228, 181–186. [Google Scholar] [CrossRef]
  36. Rocha, A.J.; Barsottini, M.R.O.; Rocha, R.R.; Laurindo, M.V.; Moraes, F.L.L.; Rocha, S.L. Pseudomonas aeruginosa: Virulence Factors and Antibiotic Resistance Genes. Braz. Arch. Biol. Technol. 2019, 62, e19180503. [Google Scholar] [CrossRef]
  37. Liao, W.; Huang, N.; Zhang, Y.; Sun, Y.; Chen, T.; Zeng, W.; Chen, L.; Wen, H.; Cao, J.; Zhou, T. Comparison of Carbapenem-Resistant Klebsiella Pneumoniae Strains Causing Intestinal Colonization and Extraintestinal Infections: Clinical, Virulence, and Molecular Epidemiological Characteristics. Front. Public Health 2021, 9, 783124. [Google Scholar] [CrossRef]
  38. Lazăr, V.; Măruțescu, L.G.; Chifiriuc, M.C. Microbiologie Generala și Aplicată; Editura Universității din București: Bucharest, Romania, 2017. [Google Scholar]
  39. Toder, D.S.; Ferrell, S.J.; Nezezon, J.L.; Rust, L.; Iglewski, B.H. lasA and lasB genes of Pseudomonas aeruginosa: Analysis of transcription and gene product activity. Infect. Immun. 1994, 62, 1320–1327. [Google Scholar] [CrossRef] [PubMed]
  40. Galdino, A.; Viganor, L.; de Castro, A.A.; da Cunha, E.; Mello, T.P.; Mattos, L.M.; Pereira, M.D.; Hunt, M.C.; O’Shaughnessy, M.; Howe, O.; et al. Disarming Pseudomonas aeruginosa Virulence by the Inhibitory Action of 1,10-Phenanthroline-5,6-Dione-Based Compounds: Elastase B (LasB) as a Chemotherapeutic Target. Front. Microbiol. 2019, 10, 1701. [Google Scholar] [CrossRef]
  41. Gupta, V. Metallo beta lactamases in Pseudomonas aeruginosa and Acinetobacter species. Expert Opin. Investig. Drugs 2008, 17, 131–143. [Google Scholar] [CrossRef]
  42. Walsh, T.R.; Toleman, M.A.; Poirel, L.; Nordmann, P. Metallo-beta-lactamases: The quiet before the storm? Clin. Microbiol. Rev. 2005, 18, 306–325. [Google Scholar] [CrossRef] [PubMed]
  43. Faraji, F.; Mahzounieh, M.; Ebrahimi, A.; Fallah, F.; Teymournejad, O.; Lajevardi, B. Molecular detection of virulence genes in Pseudomonas aeruginosa isolated from children with Cystic Fibrosis and burn wounds in Iran. Microb. Pathog. 2016, 99, 1–4. [Google Scholar] [CrossRef]
  44. Qin, S.; Xiao, W.; Zhou, C.; Pu, Q.; Deng, X.; Lan, L.; Liang, H.; Song, X.; Wu, M. Pseudomonas aeruginosa: Pathogenesis, virulence factors, antibiotic resistance, interaction with host, technology advances and emerging therapeutics. Signal Transduct. Target. Ther. 2022, 7, 199. [Google Scholar] [CrossRef] [PubMed]
  45. Jurado-Martín, I.; Sainz-Mejías, M.; McClean, S. Pseudomonas aeruginosa: An Audacious Pathogen with an Adaptable Arsenal of Virulence Factors. Int. J. Mol. Sci. 2021, 22, 3128. [Google Scholar] [CrossRef]
  46. Hsieh, P.-F.; Lu, Y.-R.; Lin, T.-L.; Lai, L.-Y.; Wang, J.-T. Klebsiella pneumoniae Type VI Secretion System Contributes to Bacterial Competition, Cell Invasion, Type-1 Fimbriae Expression, and In Vivo Colonization. J. Infect. Dis. 2019, 219, 637–647. [Google Scholar] [CrossRef]
  47. Tang, M.; Kong, X.; Hao, J.; Liu, J. Epidemiological Characteristics and Formation Mechanisms of Multidrug-Resistant Hypervirulent Klebsiella pneumoniae. Front. Microbiol. 2020, 11, 581543. [Google Scholar] [CrossRef] [PubMed]
  48. Huynh, D.T.N.; Kim, A.Y.; Kim, Y.R. Identification of Pathogenic Factors in Klebsiella pneumoniae Using Impedimetric Sensor Equipped with Biomimetic Surfaces. Sensors 2017, 17, 1406. [Google Scholar] [CrossRef] [PubMed]
  49. Zhu, J.; Wang, T.; Chen, L.; Du, H. Virulence Factors in Hypervirulent Klebsiella pneumoniae. Front. Microbiol. 2021, 12, 642484. [Google Scholar] [CrossRef] [PubMed]
  50. Turton, J.F.; Perry, C.; Elgohari, S.; Hampton, C.V. PCR characterization and typing of Klebsiella pneumoniae using capsular type-specific, variable number tandem repeat and virulence gene targets. J. Med. Microbiol. 2010, 59, 541–547. [Google Scholar] [CrossRef]
  51. Lee, C.R.; Lee, J.H.; Park, K.S.; Jeon, J.H.; Kim, Y.B.; Cha, C.J.; Jeong, B.C.; Lee, S.H. Antimicrobial Resistance of Hypervirulent Klebsiella pneumoniae: Epidemiology, Hypervirulence-Associated Determinants, and Resistance Mechanisms. Front. Cell. Infect. Microbiol. 2017, 7, 483. [Google Scholar] [CrossRef]
  52. Dong, N.; Yang, X.; Chan, E.W.; Zhang, R.; Chen, S. Klebsiella species: Taxonomy, hypervirulence and multidrug resistance. EBioMedicine 2022, 79, 103998. [Google Scholar] [CrossRef] [PubMed]
  53. Ballén, V.; Gabasa, Y.; Ratia, C.; Ortega, R.; Tejero, M.; Soto, S. Antibiotic Resistance and Virulence Profiles of Klebsiella pneumoniae Strains Isolated From Different Clinical Sources. Front. Cell. Infect. Microbiol. 2021, 11, 738223. [Google Scholar] [CrossRef]
  54. Alcántar-Curiel, M.D.; Blackburn, D.; Saldaña, Z.; Gayosso-Vázquez, C.; Iovine, N.; De la Cruz, M.A.; Girón, J.A. Multi-Functional Analysis of Klebsiella pneumoniae Fimbrial Types in Adherence and Biofilm Formation. Virulence 2013, 4, 129–138. [Google Scholar] [CrossRef]
  55. Dargahi, Z.; Hamad, A.A.; Sheikh, A.F.; Ahmad Khosravi, N.; Samei Fard, S.; Motahar, M.; Mehr, F.J.; Abbasi, F.; Meghdadi, H.; Bakhtiyariniya, P.; et al. The Biofilm Formation and Antibiotic Resistance of Bacterial Profile from Endotracheal Tube of Patients Admitted to Intensive Care Unit in Southwest of Iran. PLoS ONE 2022, 17, e0277329. [Google Scholar] [CrossRef]
  56. Ciofu, O.; Tolker-Nielsen, T. Tolerance and Resistance of Pseudomonas aeruginosa Biofilms to Antimicrobial Agents-How P. aeruginosa Can Escape Antibiotics. Front. Microbiol. 2019, 10, 913. [Google Scholar] [CrossRef]
  57. Hazhirkamal, M.; Zarei, O.; Movahedi, M.; Karami, P.; Shokoohizadeh, L.; Taheri, M. Molecular Typing, Biofilm Production, and Detection of Carbapenemase Genes in Multidrug-Resistant Acinetobacter baumannii Isolated from Different Infection Sites Using ERIC-PCR in Hamadan, West of Iran. BMC Pharm. Toxicol. 2021, 22, 32. [Google Scholar] [CrossRef] [PubMed]
  58. Rutherford, S.T.; Bassler, B.L. Bacterial quorum sensing: Its role in virulence and possibilities for its control. Cold Spring Harb. Perspect. Med. 2012, 2, a012427. [Google Scholar] [CrossRef] [PubMed]
  59. Ibrahim, S.; Al-Saryi, N.; Al-Kadmy, I.M.S.; Aziz, S.N. Multidrug-resistant Acinetobacter baumannii as an emerging concern in hospitals. Mol. Biol. Rep. 2021, 48, 6987–6998. [Google Scholar] [CrossRef]
  60. Zeighami, H.; Valadkhani, F.; Shapouri, R.; Samadi, E.; Haghi, F. Virulence characteristics of multidrug resistant biofilm forming Acinetobacter baumannii isolated from intensive care unit patients. BMC Infect. Dis. 2019, 19, 629. [Google Scholar] [CrossRef] [PubMed]
  61. Lazar, V. Quorum sensing in biofilms--how to destroy the bacterial citadels or their cohesion/power? Anaerobe 2011, 17, 280–285. [Google Scholar] [CrossRef]
  62. Saipriya, K.; Swathi, C.H.; Ratnakar, K.S.; Sritharan, V. Quorum-sensing system in Acinetobacter baumannii: A potential target for new drug development. J. Appl. Microbiol. 2020, 128, 15–27. [Google Scholar] [CrossRef]
  63. Holban, A.M.; Chifiriuc, M.C.; Cotar, A.I.; Bleotu, C.; Grumezescu, A.M.; Banu, O.; Lazar, V. Virulence markers in Pseudomonas aeruginosa isolates from hospital acquired infections occurred in patients with underlying cardiovascular disease. Rom. Biotechnol. Lett. 2013, 18, 8843–8854. [Google Scholar]
  64. Főldes, A.; Bilca, D.; Székely, E. Phenotypic and molecular identification of carbapenemase-producing Enterobacteriaceae-challenges in diagnosis and treatment. Rev. Romana Med. Lab. 2018, 26, 221–230. [Google Scholar] [CrossRef]
  65. Gavriliu, L.C.; Benea, O.E.; Benea, S. Antimicrobial resistance temporal trend of Klebsiella pneumoniae isolated from blood. J. Med. Life 2016, 9, 419–423. [Google Scholar] [CrossRef]
  66. Gheorghe, I.; Czobor, I.; Chifiriuc, M.C.; Borcan, E.; Ghita, C.; Banu, O.; Lazar, V.; Mihaescu, G.; Mihailescu, D.; Zhiyong, Z. Molecular screening of carbapenemase-producing Gram-negative strains in Romanian intensive care units during a one year survey. J. Med. Microbiol. 2014, 63, 1303–1310. [Google Scholar] [CrossRef]
  67. Lixandru, B.E.; Cotar, A.I.; Straut, M.; Usein, C.R.; Cristea, D.; Ciontea, S. Carbapenemase-Producing Klebsiella pneumoniae in Romania: A Six-Month Survey. PLoS ONE 2015, 10, e0143214. [Google Scholar] [CrossRef] [PubMed]
  68. Georgescu, M.; Gheorghe, I.; Dudu, A.; Czobor, I.; Costache, M.; Cristea, V.C.; Lazar, V.; Chifiriuc, M.C. First report of OXA-72 producing Acinetobacter baumannii in Romania. New Microbes New Infect. 2016, 13, 87–88. [Google Scholar] [CrossRef] [PubMed]
  69. Perlman, R.L. Life Histories of Pathogen Populations. Int. J. Infect. Dis. 2009, 13, 121–124. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Correlation XDR—strains with two VF (virulence factors).
Figure 1. Correlation XDR—strains with two VF (virulence factors).
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Figure 2. Correlation XDR—strains with three or more VG (virulence genes).
Figure 2. Correlation XDR—strains with three or more VG (virulence genes).
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Figure 3. Correlation strains with one RG (resistance gene)—strains with one VF (virulence factor).
Figure 3. Correlation strains with one RG (resistance gene)—strains with one VF (virulence factor).
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Table 1. The primers used for the detection of virulence and antibiotic resistance genes.
Table 1. The primers used for the detection of virulence and antibiotic resistance genes.
Target GenePrimer NamePrimer SequenceAmplicon Size (bp)
Primers used for antibiotic resistance genes detection
blaIMPIMP-F
IMP-R
5′-GGAATAGAGTGGCTTAAYTCTC-3′
5′-GGTTTAAYAAAACAACCACC-3′
232
blaVIMVIM-F
VIM-R
5′-GATGGTGTTTGGTCGCATA-3′
5′-CGAATGCGCAGCACCAG-3′
390
blaOXA-48OXA-48-F
OXA-48-R
5′-ATGCGTGTATTAGCCTTATC-3′
5′-CTAGGGAATAATTTTTTCCT-3′
438
blaNDMNDM-F
NDM-R
5′-GGGCAGTCGCTTCCAACGGT-3′
5′-GTAGTGCTCAGTGTCGGCAT-3′
621
blaKPCKPC-F
KPC-R
5′-GCTCAGGCGCAACTGTAA-3′
5′-AGCACAGCGGCAGCAAGAAAG-3′
798
blaCTX-MCTX-M-F
CTX-M-R
5′-CGCTGTTGTTAGGAAGTGTG-3′
5′-GGCTGGGTGAAGTAAGTGAC-3′
754
blaTEMTEM-F
TEM-R
5′-ATGAGTATTCAACATTTCCGT-3′
5′-TTACCAATGCTTAATCAGTGA-3′
1080
blaOXA-23OXA-23-F
OXA-23-R
5′-ATGAGTTATCTATTTTTGTC-3′
5′-TGTCAAGCTCTTAAATAATA-3′
501
blaOXA-24OXA24/40-F
OXA24/40-R
5′ GCAGAAAGAAGTAAARCGGGT3′
5′ CCAACCWGTCAACCAACCTA3′
270
blaOXA-51OXA-51-F
OXA-51-R
5′-TAATGCTTTGATCGGCCTTG-3′
5′-TGGATTGCACTTCATCTTGG-3′
353
Primers used for virulence markers detection
epsAepsA-F
epsA-R
5′-AGCAAGTGGTTATCCAATCG-3′
5′-T ACCAGACTCACCCATTACA-3′
451
ompAompA-F
ompA-R
5′-CGCTTCTGCTGGTGCTGAAT-3′
5′-CGTGCAGTAGCGTTAGGGTA-3′
531
plcHplcH-F
plcH-R
5′GAAGCCATGGGCTACTTCAA-3′
5′AGAGTGACGAGGGGTAG-3′
466
plcNplcN-F
plcN-R
5′-GTTATCGCAACCAGCCCTAC-3′
5′-AGGTCGAACACCTGGAACAC-3′
307
exoUexoU-F
exoU-R
5′-CCGTTGTGGTGCCGTTGAAG-3′
5′-CCAGATGTTCACCGACTCG-3′
134
exoTExoT-F
ExoT-R
5′-AATCGCCGTCCAACTGCATGCG-3′
5′-TGTTCGCCGAGGTACTGCTC-3′
152
exoSExoS-F
ExoS-R
5′-ATCGCTTCAGCAGAGTCCGTC-3′
5′-CAGGCCAGATCAAGGCCGCGC-3′
1352
algDalgD-F
algD-R
5′-ATGCGAATCAGCATCTTTGGT-3′
5′-CTACCAGCAGATGCCCTCGGC-3′
1310
TCTCF
TCR
5′-TATTTCGCCGACTCCCTGTA-3′
5′-GAATAGACGCCGCTGAAATC3′
752
fimHfimH-F
fimH-R
5′-TGCAGAACGGATAAGCCGTGG3′
5′-GCAGTCACCTGCCCTCCGGTA3′
506
fimAfimA-F
fimA-R
5′-CGGACGGTACGCTGTATTTT-3′
5′-GCTTCGGCGTTGTCTTTATC-3′
500
hlyDhlyD-F
hlyD-R
5′-CTCCGGTACGTGAAAAGGAC3′
5′-GCCCTGATTACTGAAGCCTG3′
904
hlyAhlyA-F
hlyA-R
5′-AACAAGGATAAGCACTGTTCTGGCT-3′
5′-ACCATATAAGCGGTCATTCCCGTCA-3′
1177
cnf1cnf1-F
cnf1-R
5′-GAACTTATTAAGGATAGT-3′
5′-CATTATTTATAACGCTG-3′
544
ecpRABecpRAB-F
ecpRAB-R
5′-CCTATGTAATTAATGGCAGGTTT-3′
5′-GCTGTTCATAAAGGATGAAATATC-3′
1025
mrkAmrkA-F
mrkA-R
5′-CGGTAAAGTTACCGACGTATCTTGTACTG-3′
5′-GCTGTTAACCACACCGGTGGTAAC-3′
498
mrkDmrkD-F
mrkD-R
5′-CTGACGCTTTTTATTGGCTTAATGGCGC-3′
5-′GCAGAATTTCCGGTCTTTTCGTTTAGTAG-3′
756
Table 2. The distribution of Gram-negative strains selected for this study.
Table 2. The distribution of Gram-negative strains selected for this study.
Isolation SourceNumber (n) of Isolated Species
K. pneumoniaeAcinetobacter spp.P. aeruginosa
Urinen = 28n = 3n = 4
Blood culturesn = 10 n = 3n = 4
Others *n = 13n = 5n = 2
* Biological fluids, wounds, endotracheal secretions, stool cultures, and rectal swabs.
Table 3. Bacterial strains producing soluble enzymatic factors.
Table 3. Bacterial strains producing soluble enzymatic factors.
MicroorganismVirulence FactorsUrine
N (%) *
Blood Culture
N (%) *
Bile
Culture
N (%) *
Wound
N (%) *
Bronchial Aspirate
N (%) *
Rectal Swab
N (%) *
Drainage Tube
N (%) *
Ascitic Fluid
N (%) *
Stool Culture
N (%) *
p-Value **
K. pneumoniaeamylase9 (34.6)1 (10)0001 (50)1 (50)1 (100)00.349
esculinase25 (96.2)10 (100)1 (100)1 (100)4 (100)2 (100)2 (100)1 (100)2 (66.7)0.556
lecithinase2 (7.7)2 (20)0000002 (66.7)0.251
caseinase02 (20)001 (25)01 (50)01 (33.3)0.047
lipase9 (34.6)3 (30)001 (25)01 (50)02 (66.7)0.833
gelatinase1 (3.8)3 (30)000001 (100)00.059
hemolysin2 (7.7)000000000.991
P.
aeruginosa
protease2 (50)2 (50)01 (50)00000NA
amylase0001 (50)000000.108
esculinase01 (25)00000000.435
lecithinase3 (75)4 (100)02 (100)000000.435
caseinase1 (25)2 (50)01 (50)000000.732
lipase02 (50)00000000.153
hemolysin4 (100)4 (100)02 (100)01 (100)000NA
Acinetobacter spp.amylase0000001 (100)000.088
lipase01 (33.3)001 (100)1 (100)0000.266
* N = number of isolates with a virulence factor. Percentages were calculated considering the total number of samples of a specific strain encountered in each isolation source. ** p-values reflected the significance between the differences in distribution of a virulence gene or resistance gene over the source types. Every p-value was obtained using a chi-test and only those values < 0.05 were considered significant. NA = not applicable.
Table 4. VF patterns encountered in the studied strains.
Table 4. VF patterns encountered in the studied strains.
MicroorganismVirulence Gene PatternUrine
N (%) *
Blood Culture N (%) *Other
N (%) *
p-Value **
K. pneumoniaemrkA01 (10)2 (13.3)0.11
fimA01 (10)00.19
fimA, mrkA02 (20)00.03
fimA, ecpRAB01 (10)00.19
ecpRAB, mrkA8 (30)2 (20)8 (53.3)0.22
fimA, ecpRAB, mrkA10 (38)2 (20)4 (26.6)0.56
fimH, ecpRAB, cnf11 (3.8)000.99
fimH, mrkA, cnf11 (3.8)000.99
fimH, fimA, ecpRAB, mrkA1 (3.8)000.99
fimA, hlyD. hlyA, ecpRAB1 (3.8)000.99
hlyD, hlyA, ecpRAB, mrkA01 (10)1 (6.66)0.23
fimH, hlyD, hlyA, ecpRAB, cnf11 (3.8)000.99
fimH, fimA, ecpRAB, mrkA, cnf11 (3.8)000.99
P. aeruginosaplcH, plcN, exoU, algD01 (33.3)00.9
plcH, plcN, exoU, exoS, algD2 (50)1 (33.3)00.9
plcH, plcN, exoT, exoS, algD1 (25)1 (33.3)1 (50)1
plcH, plcN, exoU, exoT, exoS, algD01 (33.3)00.9
Acinetobacter spp.ompA3 (100)3 (100)4 (80)1
* N = number of isolates with a virulence gene or an association of virulence genes. Percentages were calculated considering the total number of samples of a specific gene or association of genes encountered in each isolation source. Other includes biological fluids, wounds, endotracheal secretions, stool cultures, and rectal swabs. ** p-values reflected the significance between the differences in distribution of a virulence gene or resistance gene over the source types. Every p-value was obtained using a Fisher-test and only those values < 0.05 were considered significant.
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MDPI and ACS Style

Truşcă, B.S.; Gheorghe-Barbu, I.; Manea, M.; Ianculescu, E.; Barbu, I.C.; Măruțescu, L.G.; Dițu, L.-M.; Chifiriuc, M.-C.; Lazăr, V. Snapshot of Phenotypic and Molecular Virulence and Resistance Profiles in Multidrug-Resistant Strains Isolated in a Tertiary Hospital in Romania. Pathogens 2023, 12, 609. https://doi.org/10.3390/pathogens12040609

AMA Style

Truşcă BS, Gheorghe-Barbu I, Manea M, Ianculescu E, Barbu IC, Măruțescu LG, Dițu L-M, Chifiriuc M-C, Lazăr V. Snapshot of Phenotypic and Molecular Virulence and Resistance Profiles in Multidrug-Resistant Strains Isolated in a Tertiary Hospital in Romania. Pathogens. 2023; 12(4):609. https://doi.org/10.3390/pathogens12040609

Chicago/Turabian Style

Truşcă, Bianca Simona, Irina Gheorghe-Barbu, Marina Manea, Elvira Ianculescu, Ilda Czobor Barbu, Luminița Gabriela Măruțescu, Lia-Mara Dițu, Mariana-Carmen Chifiriuc, and Veronica Lazăr. 2023. "Snapshot of Phenotypic and Molecular Virulence and Resistance Profiles in Multidrug-Resistant Strains Isolated in a Tertiary Hospital in Romania" Pathogens 12, no. 4: 609. https://doi.org/10.3390/pathogens12040609

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