Enterococcus Virulence and Resistant Traits Associated with Its Permanence in the Hospital Environment

Enterococcus are opportunistic pathogens that have been gaining importance in the clinical setting, especially in terms of hospital-acquired infections. This problem has mainly been associated with the fact that these bacteria are able to present intrinsic and extrinsic resistance to different classes of antibiotics, with a great deal of importance being attributed to vancomycin-resistant enterococci. However, other aspects, such as the expression of different virulence factors including biofilm-forming ability, and its capacity of trading genetic information, makes this bacterial genus more capable of surviving harsh environmental conditions. All these characteristics, associated with some reports of decreased susceptibility to some biocides, all described in this literary review, allow enterococci to present a longer survival ability in the hospital environment, consequently giving them more opportunities to disseminate in these settings and be responsible for difficult-to-treat infections.


Introduction
Enterococcus spp. are ubiquitous Gram-positive and facultative anaerobic bacteria, commensal of the intestinal tract of humans, as well as other mammals [1][2][3]. These microorganisms are largely characterized by their ability to tolerate high concentrations of salt (6.5% NaCl), but also a wide range of temperature (from 10 • C to 40 • C) and pH (from 4.4 to 9.6) values [1,2]. They are also able to hydrolyze esculin in the presence of high quantities of bile salts (40%) [2].
Initially portrayed as organisms of little clinical importance, enterococci, particularly Enterococcus faecalis and Enterococcus faecium, have been progressively associated with an increasing number of hospital-acquired infections (HAIs) in both human and veterinary medicine [3]. In fact, enterococci account for 6.1-17.5% of all isolates retrieved between 2010 and 2020 from European patients with these types of infections in human medicine [4]. Apart from these two species, other enterococcal species can also be isolated, such as Enterococcus hirae, Enterococcus durans, Enterococcus gallinarium and Enterococcus casseliflavus, not only in veterinary medicine [3], but also in human medicine [5][6][7], although they are not as commonly associated with HAIs and thus are less commonly studied. Enterococci are associated with a wide range of infections including urinary tract infections, bacteremia, endocarditis, wound infections (burn wounds or surgical incisions), abdomen and biliary tract infections, and infection of catheters and medical implants [8].
This infection-inducing capacity becomes especially critical when its degree of antibiotic resistance is considered. The intrinsic and extrinsic resistance traits associated with this genus allow it to be resistant to several antibiotics, including β-lactams, aminoglycosides and glycopeptides, rendering it difficult to combat these infections [1,3,4,8,9]. In fact,

Cell Surface Virulence Factors
Cell surface components have been found to be important in a series of different bacterial defense mechanisms, including biofilm formation and protection against the host immune system [60,61].
In enterococci, these surface proteins are usually of the LPxTG-type (leucine, proline, X (any amino acid), threonine, and glycine), which include pili and microbial surface components recognizing adhesive matrix molecules (MSCRAMMs) [62].
The first ever described cell surface group of proteins included the aggregation substances (also known as AS or Agg), which depict a group of three adhesins: Asp1, Asc10 (sometimes also called PrgB) and Asa1. These proteins are encoded by three distinct conjugative plasmids, pPD1, pCF10 and pAD1, respectively, and are very similar in amino acid sequence [62]. These AS have been considered to be responsible for enterococcal adhesion to intestinal [63][64][65] and renal tubular cells [66]. As such, this is possibly associated with their ability to prompt systemic infections [62], since adhesion is usually the first step necessary for infection. This takes an even greater importance knowing that Asa1 adheres to extracellular matrix proteins, which also facilitates infection development [67]. Furthermore, AS have also been correlated to adhesion to immune system cells (especially Asa1 and Asc10) [68,69], and phagocytosis survival [69,70], as well as vanA (an operon associated to vancomycin resistance) co-transference in E. faecalis [71]. Asc10, which is encoded by the prgB gene, has also been associated to a higher virulence in infective endocarditis [72] and biofilm formation [73].
There are three main MSCRAMMs, which are a subfamily of bacterial adhesins that recognize and bind to extracellular matrix elements, described in enterococci: Ace (adhesion of collagen, from E. faecalis) [74], Acm (adhesion of collagen, from E. faecium) [75] and Scm (second collagen adhesion, from E. faecium) [76].
Ace was the first MSCRAMM identified in enterococci [74], followed by Acm [75], and lastly by Scm [76]. Although they all promote adhesion to collagen, Ace has also been characterized by its capacity to adhere to other components such as laminin [77] and dentin [78], while Scm also binds to fibrinogen [76]. Both Ace and Acm seem to play a role in the Antibiotics 2022, 11, 857 4 of 23 development of infectious endocarditis caused by enterococci [79][80][81]. Although all three are present in clinical and non-clinical isolates, Acm seems to be predominantly distributed among E. faecium clinical isolates, with a higher incidence among CC17, which could be one of the reasons this complex gained such importance as a nosocomial pathogen [82].
Pili are another relevant virulence factor that consist of multimeric fibres composed of pilin subunits that extend as long filaments from the cell surfaces. In enterococci, these fibres are encoded by an operon consisting of a collection of different genes, commonly called pili gene clusters (PGC).
On the other hand, E. faecium is considered to have four different gene clusters, which were identified as PGC1 to 4 [62,76,86]. PGC3, known as EMP (previously identified as EBP fm ) is composed by three different genes, empA, empB and empC [87,88], and has been associated with biofilm formation and adherence to EMCs [88], as well as colonization of both the kidneys and the bladder in an experimental urinary tract infection model [87].
Esp is another cell surface protein, present in both E. faecium and E. faecalis, which seems to be predominantly present in clinical isolates [89,90]. This protein has been proven to be important in biofilm formation [91][92][93], possibly through an amyloid-based mechanism [94], but has also been implicated in infectious endocarditis [95] and urinary tract infection development [96]. Furthermore, a study published in 2009 by Meredith et al. [97] also indicated a possible relation between the presence of this protein and E. faecium's susceptibility to β-lactams, which has also been corroborated by a more recent study [98].
Other cell surface proteins acting as potential virulence factors have also been described, such as PrpA [99], that binds to fibrinogen, fibronectin and platelets, and SgrA and EcbA, two adhesins that seem to be predominantly present in Enterococcus clinical isolates [100].
The most important virulence factors presented by the Enterococcus genus can be seen summarized in Figure 1.

Antibiotic Resistance
Enterococcus present a variable intrinsic resistance to the different classes of βlactams; they usually present only a reduced susceptibility to penicillins, which justifies the fact that amoxicillin and ampicillin are still considered the first line of antibiotic defence against this group of bacteria in both animal [101] and human medicine [1,8,9], respectively. Carbapenems are slightly less efficient towards enterococci, and they are considered resistant to cephalosporins [1,3,8,9].

β-Lactam Resistance
Enterococcus present a variable intrinsic resistance to the different classes of β-lactams; they usually present only a reduced susceptibility to penicillins, which justifies the fact that amoxicillin and ampicillin are still considered the first line of antibiotic defence against this group of bacteria in both animal [101] and human medicine [1,8,9], respectively. Carbapenems are slightly less efficient towards enterococci, and they are considered resistant to cephalosporins [1,3,8,9].
Bacterial D,D-transpeptidases, also known as penicillin binding proteins (PBPs), are responsible for the last step of cross-linkage in peptidoglycan formation, a complex structure responsible for the stability and rigidness of the bacterial cell wall. β-lactams have the capability of acting as substrates for these PBPs, effectively inhibiting them and, consequently, preventing cell wall formation [102].
In enterococci, intrinsic resistance is usually associated with the existence of lowaffinity PBPs that do not allow binding of the antibiotic molecules as easily. The presence of these proteins has been associated with low-level resistance to penicillins and moderate to high-level resistance to cephalosporins [3,8]. PBPs are usually divided into high-molecular and low-molecular weight PBPs. From both these groups, high-molecular PBPs are the ones associated with β-lactam resistance in bacteria [103]. These transpeptidases can also be divided into two classes: class A that presents both transpeptidase and transglycosylase activity, and class B that presents only transpeptidase activity [104].
It has been known for a long time that Enterococcus strains have at least five PBPs [105], associated with six putative genes: three of those genes belong to Class A (ponA, pbpF, pbpZ), and three to Class B (pbp5, pbpA, pbpB) [103,104]. The chromosomally encoded pbp5 gene, present in E. faecium strains, has been the gene most frequently associated to penicillin and cephalosporin resistance in Enterococcus [106]. Although this gene has also been identified in E. faecalis (pbp4), it has not been as associated to β-lactam resistance in this species as in E. faecium [104]. In fact, E. faecalis usually presents higher rates of susceptibility to β-lactams in comparative studies [107][108][109]. It has also been proven that the pbp5 gene is a transferable element between E. faecium and is sometimes associated with the transference of vacomycin-resistance determinants [110][111][112].
A higher resistance to these antibiotics is usually associated with a higher expression of PBP5 proteins [113,114] or to mutations in the amino acid gene sequence that lead to alterations of this protein's molecular structure [114][115][116]. When evaluating the relation between pbp5 sequences of E. faecium and penicillin's minimal inhibition concentration (MIC) presented by these isolates, a study by Galloway-Peña et al. [115], corroborated later by another study by Pietta et al. [116], concluded that isolates that presented a MIC ≤ 2 µg/mL and isolates that presented a MIC ≥ 16 µg/mL had a 5% difference in the pbp5 sequence, which remounted to the presence of two distinct allelic forms: a more susceptible (PBP5-S) and a more resistant (PBP5-R) form. These authors also proposed the existence of a hybrid PBP5 (PBP-S/R) for the isolates that present a MIC ≈ 4 µg/mL, whose genomic sequence fell between the other two genes. These differences were also associated to different enterococci clades previously mentioned, with PBP5-R being more associated to Clade A1 and PBP5-S to Clade B [113,115,116]. However, both studies concluded that the determination of which amino acid changes were responsible for this decrease in susceptibility to β-lactams was difficult. The divergence seen in results described in other studies also reinforces this conclusion, although some changes such as an additional serine after amino acid position 466 (Ser-466) or amino acid substitutions (for instance the substitution of a methionine, Met-485, for an alanine or threonine (Met-485 → Ala/Thr), the substitution of a glutamic acid, Glu-629, for a valine, and also the substitution of an aspartic acid, Asp-496, for a lysine) have been more frequently associated to a high-level of penicillin resistance than others [114,115,[117][118][119]. Although it has been proven that this PBP is responsible for some degree of resistance to penicillins, high-level resistance cannot be solely justified by Antibiotics 2022, 11, 857 6 of 23 the increased expression or mutations of the pbp5 gene, which means that other factors should also play some kind of role in this adaptation [106,114].
On rare occasions, decreased susceptibility to β-lactams has been also associated with the production of β-lactamases, with Murray reporting the first E. faecalis β-lactamase producer in 1983 [120] and Coudron et al. [121] reporting the first E. faecium β-lactamase producer in 1992. Since then, reports on β-lactamase producing enterococci have been scarce and more frequently associated with E. faecalis [1,122]. β-lactamases act through βlactam ring hydrolysis, originating a molecule incapable of binding to the PBP [102]. Even though Enterococcus and Staphylococcus present a very similar sequenced operon, which indicates the possibility that these genes were transferred from one genus to the other [122], the blaZ gene in enterococci has a low-level constitutive expression, which means that it occurs independently of the presence of β-lactams [104]. This means that an in vitro susceptibility may not be equivalent to an in vivo one, since infections by these bacteria equivalate to higher concentrations of β-lactamases than the ones seen in vitro [3,104]. However, considering that the isolation frequency of these bacteria is reportedly low and also that these β-lactamases seem to be susceptible to β-lactamases inhibitors, such as sulbactam [104,122], resistance to β-lactams through this mechanism is not as concerning as through PBPs.

Aminoglycosides
Aminoglycosides act through disruption of mRNA decoding by binding to the 16S rRNA of the 30S ribosomal subunit [9]. This means that in order to exert their action, they must first pass through the bacterial cell wall.
Enterococci are known to present an intrinsic resistance to aminoglycosides due to two distinct factors: poor uptake of this antibiotic group through the cell wall, and through modification of the antibiotic molecule, reducing its affinity to their target [3,8,9,104].
In aminoglycosides, modification of the antibiotic molecule occurs due to a group of enzymes that can be divided into three different categories: the acetyl-coenzyme Adependent amino-glycoside acetyltransferases (AACs), that act through acetylation of the amino groups; the ATP-dependent nucleotidyltransferases (ANTs), that act through adenylation of the hydroxyl group; and the ATP/GTP-dependent phosphotransferases (APHs), that act through phosphorylation of the hydroxyl group [9,123]. These molecules are also divided into sub-groups according to which position is altered (3 , 6 , 2",3", 4", etc.), and according to the resistance profile presented (I, II, III, etc.). Letters (a, b, c, d, e, etc.) were added at the end in order to distinguish each specific protein [1,123,124].
In enterococci, there have been three similar transferases described as being chromosomally encoded and that confer low-to moderate-level resistance to aminoglycosides: AAC(6 )-Ii in E. faecium [125][126][127]; AAC(6 )-Id in E. durans; and AAC(6 )-Ih in E. hirae [127], conferring resistance to kanamycin and tobramycin [126]. Some aminoglycoside-modifying enzymes have also been associated to acquired resistance, by the obtention of genes encoded in transposons and conjugative plasmids. All these enzymes are presented in Table 1, along with the type of resistance they confer. ANT(4")-Ia [134] Bifunctional Enzyme (AAC + APH) AAC-6 -Ie-APH-2 Extrinsic High-level resistance to gentamicin [135][136][137] From all the presented enzymes, AAC-6 -Ie-APH-2 seems to be the most frequently associated with high-level resistance to gentamicin, and ANT(6 )-Ia to high-level resistance to streptomycin [138][139][140][141][142][143][144]. It is important to note, however, that a discordance between phenotype and genotype can occur when it comes to these enzymes, which means that not all bacteria that present a resistance gene for aminoglycosides presents a resistant phenotype [145]. This means that phenotype determination is always important in order to determine resistance to these antibiotics.
Enterococci with the ability to produce these enzymes, conferring high-level resistance to both gentamicin and streptomycin which are the go-to aminoglycosides to control enterococcal infection, are also usually resistant to the synergism between these antibiotics and cell wall active agents such as β-lactams [1,8,9].
Another noteworthy reference is the fact that there is a possibility that, in polymicrobial infections, modifying enzyme-producing enterococci could possibly shield other bacteria from aminoglycoside action, increasing the MIC values necessary to inhibit bacterial multiplication [146].
Intrinsic resistance to tobramycin and kanamycin, in both E. faecium and E. faecalis, is associated to a rRNA methyltransferase, EfmM, that acts through alteration of the ribosomal target-site [147].
High-level resistance to streptomycin has also been associated to punctual ribosome mutations [3,8,148].
Additionally, EfrAB, an ABC-transporter efflux pump, also seems to be responsible for the reduction of gentamicin's MIC levels in enterococci [149].

Glycopeptides
It is known that glycopeptides, such as vancomycin and teicoplanin, act by binding to the peptidoglycan pentapeptide precursor, more specifically to the D-alanine-D-alanine (D-Ala-D-Ala) terminus, which blocks the last crosslinking step of peptidoglycan formation, consequently preventing cell wall formation [3,150]. In enterococci, the main mechanism of resistance to these antibiotics is the alteration of the terminus molecule, D-Ala-D-Ala, which corresponds to the glycopeptides target-site, thus reducing the affinity of these antibiotics to these targets [3,9,150].
E. faecium is the most common species associated to glycopeptide resistance and vanA is the most described operon, with vanB coming in second; both are present in transposons that are either chromosomally encoded or transferable through plasmids, namely Tn1546 for vanA, and Tn1547 or Tn1549 for vanB [1,3,8,104,150,151].
Ala-D-Ala, which corresponds to the glycopeptides target-site, thus reducing the affinity of these antibiotics to these targets [3,9,150].
E. faecium is the most common species associated to glycopeptide resistance and vanA is the most described operon, with vanB coming in second; both are present in transposons that are either chromosomally encoded or transferable through plasmids, namely Tn1546 for vanA, and Tn1547 or Tn1549 for vanB [1,3,8,104,150,151].
The vanA operon is composed by seven different genes: vanR, vanS, vanH, vanA, vanX, vanY and vanZ, all working in sequence in order to develop glycopeptide resistance ( Figure 2) [1,8,9,104,153]. Regulation of these genes is performed by the VanR-VanS system. In the absence of glycopeptides, the sensor kinase, VanS, acts as an inhibitor to the response regulator, VanR [8,157]. However, when glycopeptides are present in the environment, VanS activates the vanR gene through phosphorylation [1,9]. This gene subsequently activates a promoting region responsible for the transcription of three other genes: vanH, vanA and vanX. It also increases the regulation of the VanR-VanS system [8,159]. Moreover, vanH originates a dehydrogenase that reduces pyruvate to D-Lac that, along with the ligase Regulation of these genes is performed by the VanR-VanS system. In the absence of glycopeptides, the sensor kinase, VanS, acts as an inhibitor to the response regulator, VanR [8,157]. However, when glycopeptides are present in the environment, VanS activates the vanR gene through phosphorylation [1,9]. This gene subsequently activates a promoting region responsible for the transcription of three other genes: vanH, vanA and vanX. It also increases the regulation of the VanR-VanS system [8,159]. Moreover, vanH originates a dehydrogenase that reduces pyruvate to D-Lac that, along with the ligase produced by vanA, promotes the formation of the D-Ala-D-Lac terminus [9,104,153]. The vanX gene is responsible for the formation of a dipeptidase and vanY encodes a carboxypeptidase, both responsible for cleaving the remaining D-Ala-D-Ala forms. While VanX cleaves the free D-Ala-D-Ala terminus before its connection to the peptidoglycan precursors, VanY cleaves this same terminus after the pentapeptides' formation [9,104,153,160,161]. On another end, vanZ has a still unknown mechanism of action that is somehow related to teicoplanin resistance [6,162].
The vanB operon is very similar to the vanA (Figure 1), with only two major differences: first in the regulatory system, which is encoded by vanRB and vanSB; and second in the absence of the vanZ gene, which is exchanged for the vanW gene, and the reason why enterococci presenting resistance to glycopeptides due to this operon are susceptible to teicoplanin [3,153].

Fluoroquinolones
DNA replication is essential in order for cell division to occur. This replication is dependent of the activity of two enzymes: DNA gyrase, responsible for the negative supercoiling of DNA and essential for transcription occurrence; and topoisomerase IV, responsible for the disentanglement of the newly replicated DNA and segregation of the daughter chromosomes [104,166,167]. Both of these enzymes are heterotetramers with two different subunits-GyrA2GyrB2 for DNA gyrase and ParC2ParE2 for topoisomerase IV-and are formed due to the expression of two different groups of genes, gyrA/gyrB and parC/parE, respectively [166,167].
Quinolones act by binding and inhibiting both of these enzymes, which impedes DNA replication and consequently cell division [9,166]. Initial reports associated enterococci resistance to quinolones mainly to mutations in the gyrA gene [168][169][170]. In 1998, Kanematsu et al. [171] also corroborated the fact that these resistances arise from mutations in the gyrA gene, but additionally indicated that they were also associated to mutations in the parC gene. Since then, numerous studies have associated high-level quinolone resistance in E. faecium and E. faecalis to mutations in both of these genes [172][173][174][175][176]. These mutations alter the affinity of these enzymes to quinolones, leading to an impediment in the formation of the quinolone-enzyme-DNA complexes, responsible for the inhibition of cell division [104,166].
Additionally, Kanematsu et al. [171] also pointed out the fact that some isolates presenting low-level resistance to quinolones only present mutations in the parC gene, which could be an indication that points to topoisomerase IV being the primary target of quinolones in enterococci. This seems to be the general case in Gram-positive bacteria, contrary to what happens in Gram-negative bacteria, in which DNA gyrase is considered generally the primary target [8,166,167,171]. This is also corroborated by the fact that Gram-positive DNA gyrase appears to be less susceptible to quinolones when compared to the one of Gram-negative bacteria [166]. However, Oyamada et al. [177] also indicated that the primary target could change according to the quinolone used.
On the other hand, mutations in the gyrB and parE have been very infrequent in these bacteria [178].
Low-level resistance to quinolones in enterococci has also been associated to the activity of efflux pumps [178], mainly EmeA, a MDR efflux pump homolog to Staphylococcus aureus NorA [179].
Finally, in 2007, Arsène and Leclercq [167] also found, in E. faecalis, a protein homologue to QnrA, which they named Qnr E. faecalis . Similarly to QnrA, which is responsible for the protection of DNA gyrase and topoisomerase IV from fluoroquinolone inhibition, Qnr E. faecalis seems to be associated to resistance to ciprofloxacin through DNA gyrase protection [167,[180][181][182].

Tetracyclines
Tetracyclines act through inhibition of protein synthesis by binding to the ribosome and preventing tRNA linking, causing a bacteriostatic effect upon the cell [104].
Resistance to this group of antibiotics has been extensively described in a great number of bacteria and, in enterococci, it has mostly been related either to two genes associated to efflux pumps, tet(K) and tet(L), or to three genes associated to ribosomal protection, tet(M), tet(O) and tet(S) [3]. Of all five genes, tet(M) seems to be the most frequently isolated from enterococci strains from both human and animal origin, with tet(L) coming in close second [142,173,[183][184][185][186].
Transference of these genes through the Tn916/Tn1545 transposon family has also been associated to the co-transference of the gene erm(B), associated with macrolide, lincosamide and streptogramin B (MLSB) resistance [3,183,184,187].
Recently, resistance to tetracyclines in various Gram-positive bacteria including enterococci has also been associated to an ATP-binding cassette (ABC)-F ribosomal protection protein, encoded by the poxtA gene. This gene can either be present in the chromosome or be encoded in a transferable plasmid, and is also associated to co-resistance to phenicol and oxazolidinones [188][189][190][191][192].
Linezolid acts by binding to the 23s rRNA blocking tRNA docking, and thereby preventing protein translation [104,203].
The most common mechanism of resistance to this antibiotic, especially in E. faecium, consists of point mutations in the 23S rDNA, with the most frequent being the G2576T (E. coli numbering) [198,201,204]. While E. faecium has six genes encoding for this rRNA, E. faecalis has four, and the number of genes that suffer from this mutation has been associated to the degree of resistance presented by these bacteria [8,104,205].
Cfr proteins confer resistance through post-transcriptional methylations of the 23S rRNA, which alter susceptibility not only to oxazolidinones, but also to phenicols, lincosamides, pleuromutilins and streptogramin A (PhLOPSA phenotype) [207]. However, the presence of these genes in enterococci does not always equal a resistance phenotype to linezolid [209,211].
OptrA and PoxtA lead to decreased susceptibility to phenicols and oxazolidinones, with PoxtA also conferring resistance to tetracyclines [188,189,197]. While optrA and poxtA are both usually acquired through plasmids, the poxtrA gene can also be chromosome encoded [192].

Biocide Tolerance
Biocides have been used for a long time with the intent of reducing the quantity of microorganisms present in different surfaces, and are helpful in the prevention of the growing quantity of multi-resistant organisms, the spread of infections and, consequently, the amount of HAIs occurring in today's practice. Regulation (EU) n o 528/2012 of the European Parliament and the Council of 22 May 2012 defines "biocidal product" as a compound that contains in its composition (or that leads to the formation of) one or more active substances, utilized with the intent of "destroying, deterring or rendering harmless" microorganisms (by other means besides physical or mechanical ones), in order to attenuate or eliminate any detrimental action these agents may have towards host health. These compounds are usually divided into four categories: antiseptics, sterilants, disinfectants and preservatives; however, several compounds can fit into more than one category [214].
Although the term "resistance" is widely used in the "antibiotic world", the same cannot be said for biocides. In relation to this group of compounds, terms such as "reduced susceptibility" or "tolerance" are more frequently used since while they are associated with increases in the minimal inhibitory/bactericidal concentrations (MICs/MBCs) needed to either inhibit or kill a certain bacterium, they also imply that in-use concentrations are still effective against these microorganisms [215]. This definition, however, becomes a little more unclear when we contemplate the lack of standardized laboratory methods that can be used to determine biocide susceptibility, and MIC/MBC breakpoints that define the line between biocide tolerance and susceptibility [216].
There are a variety of factors that can affect a biocide's efficiency and lead to bacterial tolerance. These factors can be related to the biocide itself, such as its concentration, pH and formulation; to the treatment conditions in which these compounds are applied, such as the temperature, presence of organic matter and contact time; or to the targeted microorganisms, due to differences in the cell wall, the presence of efflux mechanisms or enzymatic degradation. The presence of organisms organized in the biofilm form are also associated to a higher biocide tolerance [217]. When considering biocide tolerance, concentration is usually considered the most important factor [215,217]; nevertheless, all other factors should be considered in order to achieve an optimal biocidal efficiency and reduce possible decreases in susceptibility.
In enterococci, such as in other bacteria, increases in tolerance to biocides could be associated to protective stress-associated mechanisms triggered when in the presence of sub-lethal concentrations of these compounds, either due to a wrongful application or to biocidal residues left in the environment after usage [16].
Small RNAs (sRNAs), typically composed of noncoding transcripts between 50 and 600 nucleotides, are usually produced under specific environmental conditions [218]. These sRNAs, still being studied in both E. faecalis [219,220] and E. faecium [218], have been thought to act as a regulatory system of a network of genes [219], activated when under antibiotic [218] or biocide [221] stress, possibly leading to an adaptation to both of these antimicrobials and consequent decreases in susceptibility.
Phosphotransferase systems (PTS), responsible for the transportation and phosphorylation of sugars used by bacteria to produce energy, have also been proven to be important in E. faecalis survival to a variety stress conditions [222]. This system has been indicated by Pidot et al. [14] as a possible explanation for an increase in alcohol tolerance in E. faecium.
On the other hand, the two-component system ChtRS, that also reacts to environmental alterations and is coded by the chts and chtr genes that putatively encode a histidine kinase and a response regulator, has been associated to chlorhexidine tolerance in E. faecium [12].
Efflux systems, such as QacA/B and EfrAB, have equally been associated to biocide tolerance in enterococci, especially to chlorhexidine [149,223].
Moreover, it seems valuable to indicate that different enterococci species seem to present different tolerance levels to different biocides, with the most tolerant species variating according to the biocide tested [224]. This means that when studying the efficacy of a biocide against Enterocccus or bacterial tolerance in this genus, different species should be tested.
There has also been a great debate on whether there is a possible association between biocides and antibiotics resistance, with some studies indicating this possibility [14,225], while other studies conclude that a link between the two does not exist [217,223]. What seems to be mostly accepted is that the existence of this association probably depends on the antibiotic and biocide tested and the resistance mechanisms associated. However, the application of sub-lethal concentrations of biocides could possibly co-select antimicrobialresistant enterococci [226].
This resilience and capability of adaptation to stressful conditions presented by the Enterococcus genus is very much a concern, and it goes beyond antibiotics and biocides, with reports indicating possible decreases of susceptibility even to venoms [227]. Table 2 presents a summary of the main mechanisms of resistance and decreased susceptible to antibiotics and biocides, presented by the Enterococcus genus.

COVID-19 and Enterococcus
One of the most menacing HAIs of the last few years has been the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. This infection, like most viral infections, is known to lead to patient immunosuppression, and consequently give-way to secondary bacterial infections caused by commensal opportunistic pathogens [228].
However, among all the opportunistic pathogens, enterococci seem to strive in the presence of SARS-CoV-2 infected patients, especially when it comes to bloodstream infections (BSI) [229,230]. This relation is still not completely clear [229], with some studies indicating that these enterococci could be of nosocomial origin [231], while others indicate that they could originate from the individual himself, due to disruption of the intestinal barrier caused by viral multiplication and a consequent increase of enterococcal concentration in the gut [232].
Considering all these factors, it is also important to note that during the COVID-19 pandemic there was an increase in antimicrobial usage in order to fight these secondary infections, which means that a corresponding increase in bacterial resistance to these compounds is also to be expected [229]. This has been reflected in the enterococcal population with reports of increments in highly resistant strains of Enterococcus [233], including VRE [234].
Although the SARS-CoV-2 infection's consequences and association with enterococcal infection have been, and are still being, thoroughly studied in human medicine, this has not been the case in veterinary medicine. It has been proven that both cats and dogs can become infected [235]; however, to the best of our knowledge, the consequences of these infections have not been studied in relation to the enterococcal population. Nevertheless, we hypothesize that these consequences could be similar to those seen in human medicine and should be carefully studied in order to understand what kind of impact they could possibly have in combating enterococcal infections.
This means that although enterococci have been gaining relevance as an infectioncausing pathogen, especially due to all the factors presented in this review, they become even more a point of concern when considering their increased relevance due to the COVID-19 pandemic.

Conclusions
Enterococci seem to have developed a variety of mechanisms that make them more apt at survival in the hospital environment. This capacity seems to be a result of the combination of diverse factors.
Although this genus is not known for its variability of virulence factors, all those described in this review seem to contribute to the development of infection and also to the increased resilience in the presence of adverse conditions, especially due to cell surface proteins, such as Esp, that aid in biofilm formation, structures known for their resistance not only to antibiotics but also to biocides.
On the other hand, the intrinsic resistance these bacteria present to a multitude of antibiotics, associated with their genome plasticity and consequent capability of acquiring new genetic elements connected to this same resistance, makes them a concern in terms of antibiotic therapy, especially in terms of vancomycin-resistant enterococci.
Finally, although representing a field that requires further studying, their multiplicity of stress survival-related mechanisms could make them less susceptible to biocides and consequently able to last in the environment.
All of the characteristics described in this article associated with a possible potentiation by COVID-19 of this genus, which make them a number one priority in terms of vigilance and infection control. Enterococcus faecium secreted antigen A generates muropeptides to enhance host immunity and limit bacterial pathogenesis.