Citation: Retana Moreira, L.;

Steller Espinoza, M.F.;

Chacón, Camacho, N.;

Cornet-Gomez, A.; Sáenz-Arce, G.;

Osuna, A.; Lomonte, B.;

Abrahams Sandí, E. Characterization

of Extracellular Vesicles Secreted by a

Clinical Isolate of Naegleria fowleri

and Identification of Immunogenic

Components within Their Protein

Cargo. Biology 2022, 11, 983. https://

doi.org/10.3390/biology11070983

Academic Editor: Meena Kumari

Received: 12 May 2022

Accepted: 20 June 2022

Published: 29 June 2022

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biology

Article

Characterization of Extracellular Vesicles Secreted by a Clinical
Isolate of Naegleria fowleri and Identification of Immunogenic
Components within Their Protein Cargo
Lissette Retana Moreira 1,2,*, María Fernanda Steller Espinoza 1, Natalia Chacón Camacho 1,
Alberto Cornet-Gomez 3 , Giovanni Sáenz-Arce 4 , Antonio Osuna 3 , Bruno Lomonte 5

and Elizabeth Abrahams Sandí 1,2

1 Departamento de Parasitología, Facultad de Microbiología, Universidad de Costa Rica,
San José 11501, Costa Rica; maria.steller@ucr.ac.cr (M.F.S.E.); natalia.chaconcamacho@ucr.ac.cr (N.C.C.);
elizabeth.abrahams@ucr.ac.cr (E.A.S.)

2 Centro de Investigación en Enfermedades Tropicales (CIET), Universidad de Costa Rica,
San José 11501, Costa Rica

3 Grupo de Bioquímica y Parasitología Molecular (CTS 183), Departamento de Parasitología,
Campus de Fuentenueva, Instituto de Biotecnología, Universidad de Granada, 18071 Granada, Spain;
acornetgomez@ugr.es (A.C.-G.); aosuna@ugr.es (A.O.)

4 Departamento de Física, Universidad Nacional, Heredia 40101, Costa Rica; gsaenz@una.ac.cr
5 Instituto Clodomiro Picado, Facultad de Microbiología, Universidad de Costa Rica, San José 11501, Costa Rica;

bruno.lomonte@ucr.ac.cr
* Correspondence: lissette.retanamoreira@ucr.ac.cr

Simple Summary: Extracellular vesicles are vesicles produced by cells and organisms, capable of
developing different functions. In this sense, these vesicles have been involved in communication,
in the production of damage during an infection and in the modulation of different cell pathways.
These vesicles have also been proposed as key players for the diagnosis and treatment of several
diseases. In this study, we report for the first time the production of extracellular vesicles by Naegleria
fowleri, the free-living amoeba that causes primary amoebic meningoencephalitis, a severe infection
of the central nervous system that is fatal in more than 95% of cases. The vesicles were isolated and
size, surface charge and protein content were analyzed. The report of the production of extracellular
vesicles by this amoeba is relevant for different reasons: i. these vesicles could be implicated during
the processes of invasion and damage to the brain; ii. they could influence the environment to trigger
specific responses by cells and, iii. specific vesicles secreted by the amoeba could be employed for
diagnostic purposes. Several studies to reveal the role of extracellular vesicles of this pathogen are
being performed in our laboratory.

Abstract: Extracellular vesicles (EVs) are small lipid vesicles released by both prokaryotic and
eukaryotic cells, involved in intercellular communication, immunomodulation and pathogenesis.
In this study, we performed a characterization of the EVs produced by trophozoites of a clinical
isolate of the free-living amoeba Naegleria fowleri (N. fowleri). Size distribution, zeta potential, protein
profile and protease activity were analyzed. Under our incubation conditions, EVs of different sizes
were observed, with a predominant population ranging from 206 to 227 nm. SDS-PAGE revealed
protein bands of 25 to 260 KDa. The presence of antigenic proteins was confirmed by Western blot,
which evidenced strongest recognition by rat polyclonal antibodies raised against N. fowleri in the
region close to 80 KDa and included peptidases, as revealed by zymography. Proteins in selected
immunorecognized bands were further identified using nano-ESI-MS/MS. A preliminary proteomic
profile of the EVs identified at least 184 proteins as part of the vesicles’ cargo. Protease activity assays,
in combination with the use of inhibitors, revealed the predominance of serine proteases. The present
characterization uncovers the complexity of EVs produced by N. fowleri, suggesting their potential
relevance in the release of virulence factors involved in pathogenicity. Owing to their cargo’s diversity,
further research on EVs could reveal new therapeutic targets or biomarkers for developing rapid and
accurate diagnostic tools for lethal infections such as the one caused by this amoeba.

Biology 2022, 11, 983. https://doi.org/10.3390/biology11070983 https://www.mdpi.com/journal/biology

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Biology 2022, 11, 983 2 of 20

Keywords: extracellular vesicles; Naegleria fowleri; characterization; immunogenic; proteases; proteome

1. Introduction

Extracellular vesicles (EVs) are a heterogeneous group of nano to micro-sized vesicles,
naturally released by both prokaryotic and eukaryotic cells. These vesicles are commonly
surrounded by a phospholipid bilayer [1] and contain a bioactive cargo of proteins, metabo-
lites, nucleic acids (DNA and RNA) and lipids. The three main subtypes of EVs include
apoptotic bodies, microvesicles and exosomes, which are differentiated based upon their
biogenesis, release pathways, size, content and function [2]. First considered as cell waste
products or “platelet dust” [3], it has been confirmed the role of EVs in the regulation of
physiological processes, emerging as key players in intercellular communication mainly
through their ability to transfer biological content [4]. Furthermore, these vesicles have
also been involved in pathogenesis, modulation and evasion of the immune response in
pathophysiological processes. Diverse research groups have also evaluated the potential
role of EVs for diagnostic (liquid biopsy) and therapeutic purposes [5–7].

Regarding parasites, results from different studies suggest that these organisms release
different types of vesicles capable of inducing an efficient immune response or modulate the
immune response by either triggering [8] or inhibiting the production of pro-inflammatory
cytokines [9]. Besides this immunomodulatory activity, EVs could serve as carriers for
virulence factors [10]. The study of EVs from parasites includes helminths such as Fasciola
hepatica, [11], Heligmosomoides polygyrus [12], Schistosoma mansoni [13] and Echinostoma
caproni [14], as well as protozoa such as Toxoplasma gondii [15], Trypanosoma cruzi [16–20],
Leishmania [21], different Plasmodium species [22,23] and anaerobic protozoan parasites
such as Entamoeba histolytica, Trichomonas vaginalis and Giardia intestinalis [24], among
others. More recently, and in the case of free-living amoebae with pathogenic potential, the
secretion of EVs has been described in Acanthamoeba, a genus related to the production of
fatal granulomatous amoebic encephalitis, keratitis and skin lesions. In this specific case,
biological and nanomechanical properties of extracellular vesicles produced by clinical and
environmental isolates of Acanthamoeba have been recently reported [25–28].

To our knowledge, the secretion of EVs by trophozoites of Naegleria fowleri (N. fowleri)
has not been described. In this work, we confirm the secretion of EVs by a clinical isolate of
N. fowleri, a thermophilic free-living amoeba that produces primary amoebic meningoen-
cephalitis (PAM), an infection of rapid progression of the central nervous system that is
fatal in more than 95% of cases [29]. Since the description of the first clinical case and until
2019, more than 440 cases have been reported worldwide [29]. However, for example, an
underestimation of the disease of up to 50% has been proposed for the United States, which
makes it difficult to know the true incidence of the infection [30].

During the pathogenic process of primary amoebic encephalitis, certain events may
be relevant, such as the trophozoites’ ability to attach to the nasal mucosa, the chemo-
tactic response to components of the nerves and the increased locomotion rate of the
amoebae [31,32]. Moreover, a significant immune response through activation of the innate
immune system [31], the phagocytic activity by structures known as food cups, and the
release of cytolytic molecules (phospholipases, acid hydrolases, neuraminidases, pore-
forming polypeptides such as naegleriapores and phospholipolytic enzymes) play a role
in host cell and nerve destruction. This combination of both, pathogenic mechanisms of
N. fowleri and the intense immune response resulting from its presence, produce significant
nerve damage and subsequent central nervous system tissue damage [33]. However, some
specific factors involved in the pathogenesis of PAM are still unknown and need extensive
research. As an important step towards gaining a deeper knowledge on the production of
EVs by N. fowleri, here we address the characterization of several physical and biochemical
parameters, including the proteomic profiling of their cargo and the immunogenicity of
some of their proteins.



Biology 2022, 11, 983 3 of 20

2. Materials and Methods
2.1. Axenic Culture of Naegleria fowleri Trophozoites

Trophozoites of a clinical isolate of Naegleria fowleri from Costa Rica (accession number:
MT090627) [34] were cultured in 75 cm2 and 125 cm2 flasks (Nunc EasYFlask®, Thermo
Fisher Scientific, Waltham, MA, USA) with 2% casein hydrolysate (Sigma Aldrich, St. Louis,
MO, USA) culture medium, supplemented with 10% inactivated fetal bovine serum (Gibco,
Grand Island, NY, USA) and antibiotics (penicillin/streptomycin). The flasks were incu-
bated at 37 ◦C, with daily observation under an inverted microscope. The culture medium
was replaced, at least, every two days.

The manipulation of N. fowleri and products derived from this organism was per-
formed in biosafety level 2 facilities.

2.2. Isolation of Extracellular Vesicles (EVs)

EVs of trophozoites of N. fowleri were obtained as previously described by Retana
Moreira et al. with some modifications [19,20], following the Minimal Information for the
Study of Extracellular Vesicles (MISEV) guidelines [35]. Briefly, amoebae were washed
3 times using sterile PBS and then, 5 × 107 trophozoites were incubated for 5 h at 37 ◦C
in 10 mL of 2% casein hydrolysate (Sigma Aldrich, St. Louis, MO, USA) culture medium
without serum and antibiotics. After this incubation, the supernatants were collected and
centrifuged at 2500× g for 15 min at 4 ◦C to discard possible remaining trophozoites. The
resulting supernatants were collected for EV purification.

In order to eliminate larger vesicles and obtain exosome-enriched pellets, supernatants
were centrifuged at 17,000× g for 30 min at 4 ◦C and then filtered through 0.22 µm-
pore membranes (Sartorius, Göttingen, Germany), for subsequent ultracentrifugation at
120,000× g for 150 min in a Sorvall™ WX80 Ultracentrifuge (Thermo Fisher Scientific,
Waltham, MA, USA). The resulting pellets were washed twice in sterile-filtered (0.22 µm
pore) PBS at 120,000× g for 150 min and finally resuspended in 150 µL PBS. The samples
were analyzed immediately or stored at 4 ◦C for a maximum period of 4 days.

The viability of trophozoites after the 5 h secretion period was evaluated using the
trypan blue exclusion test, and the protein concentration of each sample was quantified
using the Micro-BCA protein assay kit (Thermo Fisher Scientific, Waltham, MA, USA).

EV characterization techniques included transmission electron microscopy, atomic
force microscopy, nanoparticle tracking analysis and dynamic light scattering, as previously
reported [19,20] and briefly described below.

2.3. Transmission Electron Microscopy

To confirm the production of EVs by trophozoites of N. fowleri, pellets of the samples
obtained ultracentrifugation were fixed in 500 µL of Karnovsky’s fixative (2.5% glutaralde-
hyde and 2% formaldehyde in 0.1 M cacodylate buffer; 50 mg of CaCl2 in 100 mL) for 2 h at
37 ◦C. After this step, 25 µL of the samples was placed onto a parafilm piece and a zinc grid
with a carbon film was disposed over the samples for 5 min. After this time, two washing
steps were performed using ultrapure water and the samples were negative-stained and
contrasted with 1% (v/v) uranyl acetate for 1 min. The grids were dried with filter paper
and the final examination was achieved under a Carl Zeiss LIBRA 120 PLUS SMT electron
microscope (Carl Zeiss, Oberkochen, Germany). Three samples from different days of
isolation were analyzed.

2.4. Atomic Force Microscopy

Topographic imaging of EVs obtained after the ultracentrifugation step was performed
using the non-contact AFM mode in an NX-10 instrument (Park Systems, Suwon, Korea)
with TAP300 cantilevers (K = 40 N m−1 and f = 300 kHz). Briefly, each sample was diluted
1:10 in sterile-filtered PBS and 8 µL of the dilution were deposited onto freshly cleaved
muscovite mica. After 10 min, the substrate with the sample was carefully rinsed three
times with ultrapure water (MilliQ®, Millipore, Burlington, MA, USA) to remove salts



Biology 2022, 11, 983 4 of 20

and finally air-dried. Images were typically acquired as 256 × 256 pixels at a scan rate of
0.3–0.5 Hz and further processed and analyzed using XEI software (Park Systems, Suwon,
Korea). Representative images of each sample were obtained by scanning at least 3 different
locations on at least 3 different samples.

To confirm the secretion of EVs by N. fowleri, trophozoites were washed 3 times by
centrifugation at 800× g or 10 min using sterile PBS. Then, 5 × 104 trophozoites were
resuspended in 2% casein hydrolysate culture medium without serum and antibiotics and
placed onto 18 mm round coverslips (Fisher Scientific, Portsmouth, NH, USA) that were
previously rinsed and sterilized in an autoclave for 15 min at 121 ◦C. After 1 h of incubation
at 37 ◦C, the coverslips with trophozoites were carefully washed in sterile filtered PBS and
fixed in 4% paraformaldehyde for 30 min at room temperature. The coverslips were then
washed three times in sterile filtered PBS (5 min each washing step) and air-dried, prior to
atomic force microscopy analysis in a NX-10 instrument. For this purpose, the non-contact
mode was also employed and images were acquired and analyzed as described.

2.5. Nanoparticle Tracking Analysis

Size, distribution and concentration of the EVs secreted by N. fowleri were determined
by measuring the rate of Brownian motion according to the particle size in a Nanosight
NS300 system (Malvern Panalytical, Worcestershire, UK). For the analysis, samples were
diluted (1/100) in low-binding tubes (Eppendorf, Gamburg, Germany) using sterile-filtered
PBS and measurements were performed at 25 ◦C. As previously reported, for data acquisi-
tion and information processing, the NTA software 3.2 Dev Build 3.2.16 was employed. The
particle movement was analyzed by NTA software with the camera level at 16, slider shut-
ter at 1200 and slider gain at 146, as previously reported [19]. The mean size distribution
was calculated as a mean of three independent size distributions.

2.6. Dynamic Light Scattering

Dynamic light scattering analyses of isolated EVs were performed using a Zetasizer
nano ZS90 Size Analyzer (Malvern Panalytical, Worcestershire, UK), following sample
preparation and measurement conditions as described for nanoparticle tracking analysis.
The Zetasizer Ver. 7.11 software was employed for data acquisition and information
processing and the mean size distribution was calculated as a mean of five independent
size distributions (10 runs per measurement).

2.7. Measurement of Zeta Potential

Zeta potential of EVs was measured in a Zetasizer NanoZeta ZS90 system (Malvern
Panalytical, Worcestershire, UK), at 25 ◦C. Briefly, EV samples were resuspended in 1 mL PBS,
pH 7.4, and the electrophoretic mobility (µe) was determined by Laser Doppler electrophoresis.
Zeta potential was calculated by using the Smoluchowski equation and results were obtained
from at least four independent measurements (20 runs each).

2.8. Protein Pattern and Recognition of Extracellular Vesicles by Rat Polyclonal Anti-Naegleria
fowleri Antibodies
2.8.1. Preparation of Whole Protein Extracts of Naegleria fowleri Trophozoites

Whole protein extracts were obtained as follows: 5 × 107 trophozoites of N. fowleri
were washed three times in sterile PBS, resuspended in 500 µL PBS and submitted to
sonication in a 4710 series ultrasonic homogenizer (Cole-Parmer Instrument, Vernon Hills,
IL, USA) by applying 3 cycles of 30 s, with pause of 60 s between cycles. The resulting
extracts were used immediately or stored in aliquots at −80 ◦C until use.

Protein quantification of the whole protein extracts was performed using the Micro-
BCA protein assay kit (Thermo Fischer Scientific, Waltham, MA, USA).



Biology 2022, 11, 983 5 of 20

2.8.2. Electrophoretic Separation of Proteins Using SDS-PAGE

To obtain protein profiles, samples of EVs and whole protein extracts of N. fowleri were
diluted 1:1 in reducing sample buffer [36], heated for 10 min at 98 ◦C and subsequently
loaded onto 12% SDS-polyacrylamide gels (SDS-PAGE). Electrophoretic runs were performed
for 90 min (120 V) and proteins were finally visualized by Coomassie blue R-250 (BioRad,
Hercules, CA, USA) and silver stains, following previously described protocols [37].

2.8.3. Polyclonal Antibody Production

Two four-week old female Wistar rats were immunized with 40 µg of a whole protein
extract of N. fowleri trophozoites (ATCC N. fowleri Carter 30808). The antigen was prepared
by emulsification of the amoebae lysate (in sterile PSB) in complete Freund’s adjuvant
(Sigma, Ronkonkoma, NY, USA), in a 1:1 ratio (final volume: 500 µL). This emulsion was
administered intraperitoneally to the rats. For subsequent immunizations, the adjuvant
was switched to incomplete Freund’s adjuvant (Sigma Aldrich, St. Louis, MO, USA). A
total of 8 immunizations (1 per week) were performed. Finally, the animals were bled two
weeks after the final immunization. The antibody response was evaluated using ELISA
and Western blot, as described elsewhere [38].

2.8.4. Western Blot

The recognition of proteins in EVs and trophozoites by rat polyclonal anti-N. fowleri
antibodies was analyzed by Western blot. Briefly, SDS-PAGE was performed as described
and proteins were transferred to nitrocellulose membranes (60 min, 90 V) in an Enduro
VE10 Vertical Gel System (Labnet International, Edison, NJ, USA). Then, the membranes
were blocked overnight with 5% non-fat milk in PBS-0.1% Tween 20, washed four times
in a solution of PBS-0.1% Tween 20 and incubated for 1 h at room temperature with the
polyclonal anti-N. fowleri serum (1:10,000). After the incubation, the membranes were
washed and incubated for 1 h at room temperature with peroxidase-conjugated goat anti-
rat IgGs (1:10,000) (Thermo Fisher Scientific, Waltham, MA, USA). After four washing steps
with PBS-0.1% Tween 20, the fluorogenic substrate reaction was visualized using the Clarity
ECL Western substrate (BioRad, California, United States) in a ChemiDoc imaging system
(BioRad, California, United States).

2.9. Evaluation of Protease Activity of Extracellular Vesicles

In order to evaluate protease activity of EVs, zymographic assays were performed as
described by Herron et al. [39]. Briefly, protein extracts of EVs and whole protein extracts
of N. fowleri trophozoites were subjected to electrophoresis on SDS-polyacrylamide gels
containing gelatin (1 mg/mL) [40]. Then, SDS was removed by washing the gels twice
in 1% Triton X-100 (w/v) for 30 min, for subsequent incubation overnight at 37 ◦C in a
developing buffer (50 mM Tris-HCl, 10 mM CaCl2, pH 8.0). After the incubation, gels
were rinsed and finally stained with Coomassie brilliant blue R-250 (BioRad, California,
United States). Areas of gelatin digestion, which indicate protease activity, were seen as
non-stained regions.

To characterize the general types of proteases present in EVs, the methodology de-
scribed by Castro Artavia et al. [40] was employed. In this case, 1 mM phenylmethylsulfonyl
fluoride (Sigma Aldrich, St. Louis, MO, USA) was employed as the serine proteases in-
hibitor, 1 mM 2-iodoacetamide (Merck, Hohebrunn, Germany) was selected as the cysteine
proteases inhibitor and 10 mM EDTA (Sigma Aldrich, St. Louis, MO, USA) was employed
as the metalloproteases inhibitor. To this end, EV samples were incubated for 30 min at
37 ◦C with each protease inhibitor and then submitted to SDS-PAGE in gels containing
gelatin. Since EDTA is a reversible inhibitor, it was also included in the developing buffer.



Biology 2022, 11, 983 6 of 20

2.10. Proteomic Analyses
2.10.1. Protein Identification from SDS-PAGE/Western Blot Immunogenic Bands

Immunogenic protein bands recognized by anti-N. fowleri antibodies in Western blots
were matched to the corresponding bands on Coomassie blue stained gels. On the basis of
immunoblotting results, 3 strongly recognized bands were manually excised from gels and
submitted to tryptic digestion followed by nano-LC-MS/MS for protein identification, as
described [41]. Proteins in gel plugs were reduced with 10 mM dithiothreitol, alkylated
with 50 mM iodoacetamide and digested overnight in an automated workstation (Intavis,
Tübingen, Germany) using sequencing-grade trypsin (Sigma Aldrich, St. Louis, MO, USA).
The resulting peptides were dried, redissolved in water containing 0.1% formic acid and
transferred to polypropylene nano-LC vials. Ten µL of each digest was loaded on a C18
trap column (75 µm × 2 cm, 3 µm particle; PepMap®, Thermo Fisher Scientific, Waltham,
MA, USA), washed with 0.1% formic acid (solution A), and then separated at 200 nL/min
with a 3 µm particle, 15 cm × 75 µm C18 Easy-spray® analytical column using a nano-
Easy® 1200 chromatograph (Thermo Fisher Scientific, Waltham, MA, USA). A gradient
from 0.1% formic acid (solution A) to 80% acetonitrile with 0.1% formic acid (solution B)
was developed: 1–5% B in 1 min, 5–26% B in 25 min, 26–79% B in 4 min, 79–99% B in
1 min, and 99% B in 4 min, for a total time of 35 min. MS spectra were acquired in positive
mode at 1.9 kV, with a capillary temperature of 200 ◦C, using 1 µscan at 400–1600 m/z,
maximum injection time of 100 msec, AGC target of 3 × 106, and orbitrap resolution of
70,000. The top 10 ions with 2–5 positive charges were fragmented with AGC target of
1 × 105, maximum injection time of 110 msec, resolution 17,500, loop count 10, isolation
window of 1.4 m/z, and a dynamic exclusion time of 5 s. The obtained MS/MS spectra
were processed for peptide matching against protein sequences contained in the UniProt
database for Naegleria, using Peaks X® (Bioinformatics Solutions, Waterloo, ON, Canada).
Cysteine carbamidomethylation was set as a fixed modification, while deamidation of
asparagine or glutamine, and methionine oxidation were set as variable modifications,
allowing up to 2 missed cleavages by trypsin. Parameters for match acceptance were set to
FDR < 1%, −10 lgP protein score ≥ 20, and ≥1 unique peptides.

2.10.2. Proteome Profiling of Whole EVs by Bottom-Up Shotgun Analysis

A preliminary proteome profiling of whole EV cargo was performed by a bottom-up
shotgun strategy. To this end, EV proteins were concentrated by adding 4 volumes of
cold acetone and incubating overnight at −20 ◦C [20]. The samples were submitted to
centrifugation at 13,000× g for 10 min at 4 ◦C and two washing steps in 1 mL of cold
acetone were performed. The acetone was then removed with a mixture of nitrogen and
air stream and proteins were redissolved in one volume up to 12 µL of sterile PBS, mixed
with electrophoresis sample buffer and loaded into wells of a 12% SDS-PAGE gel. The
electrophoretic run was stopped as soon as the migration front entered 3 mm into the
resolving gel, in order to concentrate the whole protein cargo as a single band in the
stacking/resolving gel interface. This band was visualized by Coomassie stain, excised,
destained in 50% acetonitrile, and finally submitted to tryptic digestion and nano-LC-
MS/MS analysis as described above.

3. Results
3.1. Characterization of Extracellular Vesicles
3.1.1. Transmission Electron Microscopy and Atomic Force Microscopy

A standardized protocol that includes differential centrifugation, coupled to a filtra-
tion process through 0.22 µm pore membranes and ultracentrifugation was employed to
evaluate the production of EVs by trophozoites of a clinical isolate of N. fowleri. After
the isolation procedure, transmission electron microscopy and atomic force microscopy
analyses were employed to identify the EVs secreted by this species.

In this work, 5 × 107 trophozoites were placed in cell culture flasks of 125 cm2 with
10 mL 2% casein hydrolysate culture medium and incubated for 5 h at 37 ◦C to further



Biology 2022, 11, 983 7 of 20

isolate the EVs. Under our incubation conditions, amoebae produced approximately
0.675 µg/µL protein in EVs. After the 5 h incubation, viability of trophozoites remained
above 97.5% (mean percentage of viability of amoebae remaining in the supernatant after
the first centrifugation step at 2500× g and amoebae in the surface of the culture flask).

Figure 1 shows a representative transmission electron microscopy image of the pellets
collected after applying the EV isolation protocol. In this Figure, diameters of the vesicles
ranged from 43.88 nm to 207.95 nm.

Biology 2022, 11, x FOR PEER REVIEW 7 of 21 
 

 

interface. This band was visualized by Coomassie stain, excised, destained in 50% acetoni-
trile, and finally submitted to tryptic digestion and nano-LC-MS/MS analysis as described 
above. 

3. Results 
3.1. Characterization of Extracellular Vesicles  
3.1.1. Transmission Electron Microscopy and Atomic Force Microscopy 

A standardized protocol that includes differential centrifugation, coupled to a filtra-
tion process through 0.22 µm pore membranes and ultracentrifugation was employed to 
evaluate the production of EVs by trophozoites of a clinical isolate of N. fowleri. After the 
isolation procedure, transmission electron microscopy and atomic force microscopy anal-
yses were employed to identify the EVs secreted by this species. 

In this work, 5 × 107 trophozoites were placed in cell culture flasks of 125 cm2 with 10 
mL 2% casein hydrolysate culture medium and incubated for 5 h at 37 °C to further isolate 
the EVs. Under our incubation conditions, amoebae produced approximately 0.675 µg/µL 
protein in EVs. After the 5 h incubation, viability of trophozoites remained above 97.5% 
(mean percentage of viability of amoebae remaining in the supernatant after the first cen-
trifugation step at 2500× g and amoebae in the surface of the culture flask).  

Figure 1 shows a representative transmission electron microscopy image of the pel-
lets collected after applying the EV isolation protocol. In this Figure, diameters of the ves-
icles ranged from 43.88 nm to 207.95 nm.  

 
Figure 1. Transmission electron microscopy image of extracellular vesicles secreted by trophozoites 
of Naegleria fowleri. A pellet of extracellular vesicles obtained after the isolation procedure employed 
is shown in (A). The content of these pellets was analyzed using transmission electron microscopy 
and vesicles of different diameters were obtained (B) (43.88 nm; 50.26 nm; 51.10 nm, 54.25 nm; 121.12 
nm; 139.45 nm and 207.95 nm in this image). Magnified images of (C,D) are also shown. Representa-
tive image of three different samples analyzed. 

The secretion of EVs by trophozoites of N. fowleri was also analyzed using atomic 
force microscopy (Figures 2, S1 and S2). In this case, pellets of EVs obtained after ultra-

Figure 1. Transmission electron microscopy image of extracellular vesicles secreted by trophozoites of
Naegleria fowleri. A pellet of extracellular vesicles obtained after the isolation procedure employed is
shown in (A). The content of these pellets was analyzed using transmission electron microscopy and
vesicles of different diameters were obtained (B) (43.88 nm; 50.26 nm; 51.10 nm, 54.25 nm; 121.12 nm;
139.45 nm and 207.95 nm in this image). Magnified images of (C,D) are also shown. Representative
image of three different samples analyzed.

The secretion of EVs by trophozoites of N. fowleri was also analyzed using atomic
force microscopy (Figure 2, Figures S1 and S2). In this case, pellets of EVs obtained after
ultracentrifugation and trophozoites incubated for 1 h following the conditions for EV
production were analyzed. Figure 2 shows topography (A) and amplitude (B) images of a
trophozoite of N. fowleri surrounded by EVs of different sizes. A topography image of the
extracellular vesicles obtained after the isolation procedure is shown in C.

3.1.2. Nanoparticle Tracking Analysis and Dynamic Light Scattering

Results of nanoparticle tracking analysis (NTA) and dynamic light scattering are
summarized in Figure 3. For EVs secreted by trophozoites of N. fowleri, NTA revealed a
mean size of 216 ± 83 nm and a mode of 206 nm (A-C). Using the same technique, it was
also possible to determine that 5 × 107 trophozoites of N. fowleri secreted approximately
4.96 × 1010 particles.



Biology 2022, 11, 983 8 of 20

Biology 2022, 11, x FOR PEER REVIEW 8 of 21 
 

 

centrifugation and trophozoites incubated for 1 h following the conditions for EV produc-
tion were analyzed. Figure 2 shows topography (A) and amplitude (B) images of a 
trophozoite of N. fowleri surrounded by EVs of different sizes. A topography image of 
the extracellular vesicles obtained after the isolation procedure is shown in C.  

 
Figure 2. Atomic force microscopy analysis of extracellular vesicles of Naegleria fowleri. (A) Tropho-
zoite surrounded by secreted extracellular vesicles (1 h incubation): (A) Z-height image and (B) am-
plitude image. (C) Analysis of isolated pellets of EVs revealed the production of vesicles ranging 
from 30 nm to 400 nm in length and 4.5 nm to 40 nm in height. Representative images are shown. 

3.1.2. Nanoparticle Tracking Analysis and Dynamic Light Scattering 
Results of nanoparticle tracking analysis (NTA) and dynamic light scattering are 

summarized in Figure 3. For EVs secreted by trophozoites of N. fowleri, NTA revealed a 
mean size of 216 ± 83 nm and a mode of 206 nm (A-C). Using the same technique, it was 
also possible to determine that 5 × 107 trophozoites of N. fowleri secreted approximately 
4.96 × 1010 particles.  

Figure 2. Atomic force microscopy analysis of extracellular vesicles of Naegleria fowleri. (A) Tropho-
zoite surrounded by secreted extracellular vesicles (1 h incubation): (A) Z-height image and
(B) amplitude image. (C) Analysis of isolated pellets of EVs revealed the production of vesicles
ranging from 30 nm to 400 nm in length and 4.5 nm to 40 nm in height. Representative images
are shown.

For dynamic light scattering (DLS), measurements of the pellets of EVs and 1 mL of
the remaining supernatant at the bottom of the tube (collected after the washing step by
ultracentrifugation) were performed (Figure 3D,E). For the pellets, the mean size obtained
for EVs was 227.13 ± 37.98 nm, while the remaining supernatant contained vesicles of
206.29 ± 37.08 nm. A second population of EVs of 24.24 ± 9.18 nm was obtained in one of
the replicates of the supernatant.

Finally, to characterize the surface electrical charge of EVs of N. fowleri, zeta poten-
tial measurements were performed in different samples, resulting in a mean value of
−12.228 ± 4.843 mV.



Biology 2022, 11, 983 9 of 20
Biology 2022, 11, x FOR PEER REVIEW 9 of 21 
 

 

 
Figure 3. Nanoparticle tracking analysis and dynamic light scattering results of extracellular vesicles 
secreted by trophozoites of Naegleria fowleri: (A) Graph showing sizes and relative concentration of 
the vesicles using NTA; (B) 3D plot of particle size/relative intensity using NTA and (C) table of 
concentration of particles of different sizes obtained during the NTA analysis. (D) Graph showing 
the size of EVs from the pellets using DLS and (E) graph showing size of EVs from the remaining 
supernatant (after the washing steps) using DLS. 

For dynamic light scattering (DLS), measurements of the pellets of EVs and 1 mL of 
the remaining supernatant at the bottom of the tube (collected after the washing step by 
ultracentrifugation) were performed (Figure 3D,E). For the pellets, the mean size obtained 
for EVs was 227.13 ± 37.98 nm, while the remaining supernatant contained vesicles of 
206.29 ± 37.08 nm. A second population of EVs of 24.24 ± 9.18 nm was obtained in one of 
the replicates of the supernatant. 

Finally, to characterize the surface electrical charge of EVs of N. fowleri, zeta potential 
measurements were performed in different samples, resulting in a mean value of −12.228 
± 4.843 mV. 

  

Figure 3. Nanoparticle tracking analysis and dynamic light scattering results of extracellular vesicles
secreted by trophozoites of Naegleria fowleri: (A) Graph showing sizes and relative concentration of
the vesicles using NTA; (B) 3D plot of particle size/relative intensity using NTA and (C) table of
concentration of particles of different sizes obtained during the NTA analysis. (D) Graph showing
the size of EVs from the pellets using DLS and (E) graph showing size of EVs from the remaining
supernatant (after the washing steps) using DLS.



Biology 2022, 11, 983 10 of 20

Table 1. Proteins identified by nano-LC-MS/MS in trypsin-digested immunorecognized bands (a–c)
of extracellular vesicles of Naegleria fowleri after SDS-PAGE/Western blot analysis using rat anti-N.
fowleri antibodies *.

Band a (~140 KDa) Band b (~100 KDa) Band c (~80 KDa)

Accession Description Accession Description Accession Description

1 B5M6J9 Actin (fragment) A0A6A5C9S6 Uncharacterized protein A0A6A5BE22
Methylmalonate-

semialdehyde
dehydrogenase

2 A0A6A5BG15
Peptidase_S9

domain-containing
protein

B5M6J9 Actin (fragment) B5M6J9 Actin (fragment)

3 A0A6A5BDZ7 Uncharacterized protein A0A6A5BQ42 Glucose-6-phosphate
isomerase A0A6A5BJW8 Uncharacterized protein

4 A0A6A5BS42 Uncharacterized protein A0A6A5C1E4 Uncharacterized protein A0A6A5C7K8 Cytosol_AP
domain-containing protein

5 A0A6A5CCP5 Uncharacterized protein A0A6A5C7K8 Cytosol AP
domain-containing protein A0A6A5BFY9 Peptidase_M28

domain-containing protein

6 A0A6A5CD16 VWFA domain-containing
protein A0A6A5C8E9

Guanine
nucleotide-binding protein

subunit β-like protein
A0A6A5BNQ4 Glutamate dehydrogenase

7 A0A6A5BUK4 Uncharacterized protein A0A6A5BXF2 Histidine ammonia-lyase A0A6A5BBK6 Uncharacterized protein

8 A0A6A5C3B7 Uncharacterized protein A0A6A5CD16 VWFA domain-containing
protein A0A6A5CD16 VWFA domain-containing

protein

9 A0A6A5BAB4 Uncharacterized protein A0A6A5BR20 Uncharacterized protein A0A6A5C9S6 Uncharacterized protein

10 A0A6A5BQ87 Uncharacterized protein A0A6A5BHL2 CCT-alpha A0A6A5BJJ6 Coronin

11 A0A6A5C150 C2 domain-containing
protein A0A6A5CCP5 Uncharacterized protein A0A6A5C761 Uncharacterized protein

12 A0A6A5CG58 Uncharacterized protein A0A6A5BT30 Uncharacterized protein A0A6A5B5S1 ADP/ATP translocase

13 A0A6A5CHB1 Uncharacterized protein A0A6A5C7Z0 Beta-hexosaminidase A0A6A5CCP5 Uncharacterized protein

14 A0A6A5BVL0 Cytokinin dehydrogenase A0A1L1XWF9 Fowlerpain-2 A0A1L1XWF9 Fowlerpain-2

15 A0A6A5BDH1 Prolyl endopeptidase A0A6A5BP20 Pept_C1
domain-containing protein A0A6A5BUU2

Bifunctional dihydrofolate
reductase-thymidylate

synthase

16 A0A6A5BXC9
Peptidase_S9

domain-containing
protein

A0A6A5CCE5 SHOCT
domain-containing protein A0A6A5BUH9 Dihydrolipoyl

dehydrogenase

17 A0A6A5BF81 Fructose-bisphosphate
aldolase A0A6A5C1F7 PRK domain-containing

protein A0A6A5BYK8 Adenosylhomocysteinase

18 D2W4E3 Leucine aminopeptidase ** D2V4W4 Mitochondrial chaperonin
cpn60 ** A0A6A5BWP7 Catalase

19 A0A6A5BKE4 Alpha-mannosidase A0A6A5C3B7 Uncharacterized protein A0A6A5BF81 Fructose-bisphosphate
aldolase

20 A0A6A5BP34 Uncharacterized protein A0A6A5B5S1 ADP/ATP translocase A0A6A5C539 WH2 domain-containing
protein

21 A0A6A5C4U4 Peptidase_M3 domain-
containing protein A0A6A5C052 Uncharacterized protein D2V5W7 Vacuolar proton pump

subunit B

22 A0A6A5C7J0 Pyruvate carboxylase A0A6A5C6S5 M20_dimer
domain-containing protein A0A6A5BFD6 UDP-glucose

6-dehydrogenase

23 A0A6A5C9S6 Uncharacterized protein A0A6A5BBK6 Uncharacterized protein A0A6A5BXJ0 AMP_N
domain-containing protein

24 A0A1L1XWF9 Fowlerpain-2 A0A6A5BSJ3 Peptidase S53
domain-containing protein A0A6A5BA58 Uncharacterized protein

25 D2VDR3 Methylcrotonyl-CoA
carboxylase ** A0A6A5BFH5 Uncharacterized protein A0A6A5CIW0

Non-specific
serine/threonine protein

kinase

26 A0A6A5C8W6 Uncharacterized protein A0A6A5BUK4 Uncharacterized protein A0A6A5BWG6 Uncharacterized protein

27 A0A4V8H039 Glyceraldehyde-3-
phosphate dehydrogenase Q6B3P1 Hsp70 A0A6A5BYB7 Uncharacterized protein

28 A0A6A5CIU9 Peptidase_S8 domain-
containing protein A0A6A5CFU9 Peptidase A1

domain-containing protein D2V4W4 Mitochondrial
chaperonin cpn60

29 A0A6A5CBE6 Uncharacterized protein Q94626 Cpn-60 (fragment)

30 A0A6A5CHD7 Uncharacterized protein A0A4V8H039 Glyceraldehyde-3-
phosphate dehydrogenase



Biology 2022, 11, 983 11 of 20

Table 1. Cont.

Band a (~140 KDa) Band b (~100 KDa) Band c (~80 KDa)

Accession Description Accession Description Accession Description

31 A0A6A5BGJ7 Imidazolonepropionate
hydrolase A0A6A5CAR5 Elongation factor 1-alpha

32 A0A6A5C721 RGS domain-containing
protein A0A6A5C052 Uncharacterized protein

33 Q25548 Penicillin amidase
homolog (fragment) A0A6A5BQM0 Isocitrate dehydrogenase

34 A0A6A5BBK6 Uncharacterized protein A0A6A5C3B7 Uncharacterized protein

35 A0A6A5B2H1 Lysine–tRNA ligase A0A6A5BUK8 Uncharacterized protein

36 A0A6A5BY41 Uncharacterized protein

* Gel bands (a,b,c) of Figure 4 were excised, proteins were in-gel digested with trypsin and analyzed by nano-LC-
MS/MS as described in Materials and Methods. ** Match with Naegleria gruberi entry in the Uniprot database for
Naegleria. All other matches correspond to N. fowleri.

3.2. Protein Profile and Recognition of Extracellular Vesicles by Anti-Naegleria fowleri
Polyclonal Antibodies

Figure 4 shows the electrophoretic protein profile of EVs produced by trophozoites of
N. fowleri after Coomassie and silver stains (A-B). Protein bands ranging from approximately
25 KDa to 260 KDa were evidenced. However, low molecular weight proteins seem to be
less abundant in both stains.

Western blot analysis using polyclonal anti-N. fowleri antibodies confirmed the im-
munorecognition of several EV proteins. Recognition was observed in bands from over
10 KDa to 175 KDa. The major recognition of proteins in EVs was observed close to 80 KDa,
where 3 intense bands were identified. In addition, 3 less intense bands of <23 KDa were
also observed (C).

Preliminary whole proteome analysis of EVs revealed a total of 184 proteins
(Supplemental Table S1), of which 85 are still uncharacterized in the current Uniprot
database. The list of proteins includes Rho GTPases, actin and actin related proteins,
ubiquitin, dehydrogenases and fowlerpain, among others.

3.3. Protease Activity of Extracellular Vesicles

Results from protease activity of EVs of N. fowleri are presented in Figure 5. EVs and
whole trophozoite extracts were submitted to zymography using gels with gelatin. From
the Figure, protease activity in both type of samples is observed (A). EVs and trophozoite
extracts showed similar protease activity, which resulted more evident in whole trophozoite
extracts. In both types of samples, proteases appeared in the region of high molecular
weight (from approximately 100 KDa to 260 KDa).

When the samples were treated with protease inhibitors, areas of gelatin digestion
were not observed when incubating samples of EVs with phenylmethylsulfonyl fluoride,
which could indicate the majority of proteases found in EVs of N. fowleri consist of serine
proteases (B-B′). On the other hand, protease activity was partially inhibited when the
samples were incubated with EDTA (metalloproteases inhibitor) and, apparently, less
inhibition was found when incubating with 2-iodoacetamide (cysteine proteases inhibitor).



Biology 2022, 11, 983 12 of 20

Biology 2022, 11, x FOR PEER REVIEW 10 of 21 
 

 

3.2. Protein Profile and Recognition of Extracellular Vesicles by Anti-Naegleria fowleri 
Polyclonal Antibodies 

Figure 4 shows the electrophoretic protein profile of EVs produced by trophozoites 
of N. fowleri after Coomassie and silver stains (A-B). Protein bands ranging from approxi-
mately 25 KDa to 260 KDa were evidenced. However, low molecular weight proteins seem 
to be less abundant in both stains.  

Western blot analysis using polyclonal anti-N. fowleri antibodies confirmed the im-
munorecognition of several EV proteins. Recognition was observed in bands from over 10 
KDa to 175 KDa. The major recognition of proteins in EVs was observed close to 80 KDa, 
where 3 intense bands were identified. In addition, 3 less intense bands of <23 KDa were 
also observed (C).  

 
Figure 4. Electrophoretic (SDS-PAGE) protein profile of extracellular vesicles and protein recogni-
tion by polyclonal anti-Naegleria fowleri antibodies using Western blot. (A) Coomassie and (B) silver 
stains showing similar band patterns in extracellular vesicles, which range from >25 KDa to 260 

Figure 4. Electrophoretic (SDS-PAGE) protein profile of extracellular vesicles and protein recognition
by polyclonal anti-Naegleria fowleri antibodies using Western blot. (A) Coomassie and (B) silver stains
showing similar band patterns in extracellular vesicles, which range from >25 KDa to 260 KDa; EVs:
extracellular vesicles; WPE: whole protein extracts of trophozoites of N. fowleri. For Coomassie stain,
approximately 30 µg of protein/sample were loaded onto the gel and for silver stain, approximately
9 µg of protein/sample were loaded onto the gel. (C) Western blot showing the recognition of
3 intense bands over 70–80 KDa ((C), a–c) and 3 less intense bands under 23 KDa, using the polyclonal
anti-N. fowleri antibody (1:10,000) produced in rat. Bands over 70–80 KDa ((A), a–c) were excised
from Coomassie stained gels and submitted to nano-LC-MS/MS. Protein identifications are listed
in Table 1.



Biology 2022, 11, 983 13 of 20

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The list of proteins includes Rho GTPases, actin and actin related proteins, ubiquitin, de-
hydrogenases and fowlerpain, among others. 

3.3. Protease Activity of Extracellular Vesicles 
Results from protease activity of EVs of N. fowleri are presented in Figure 5. EVs and 

whole trophozoite extracts were submitted to zymography using gels with gelatin. From 
the Figure, protease activity in both type of samples is observed (A). EVs and trophozoite 
extracts showed similar protease activity, which resulted more evident in whole tropho-
zoite extracts. In both types of samples, proteases appeared in the region of high molecular 
weight (from approximately 100 KDa to 260 KDa).  

When the samples were treated with protease inhibitors, areas of gelatin digestion 
were not observed when incubating samples of EVs with phenylmethylsulfonyl fluoride, 
which could indicate the majority of proteases found in EVs of N. fowleri consist of serine 
proteases (B-B’). On the other hand, protease activity was partially inhibited when the 
samples were incubated with EDTA (metalloproteases inhibitor) and, apparently, less in-
hibition was found when incubating with 2-iodoacetamide (cysteine proteases inhibitor). 

 
Figure 5. Protease activity of extracellular vesicles and whole protein extracts of trophozoites of 
Naegleria fowleri showing clear areas of gelatin digestion. For this experiments, 2.5 µg of protein/sam-
ple were loaded onto the gel. (A) Protease activity of extracellular vesicles (EVs) and whole protein 
extracts (WPE) of trophozoites of N. fowleri. (B) Specific protease activity of EVs previously incu-
bated with EDTA 10 mM (metalloproteases inhibitor), 2-iodoacetamide 1 mM (cysteine proteases 
inhibitor) and phenylmethylsulfonyl fluoride (PMSF) 1 mM (serine proteases inhibitor). Protease 
activity was fully inhibited by PMSF, which could indicate a predominance of serine proteases in 
the samples analyzed. Densitometry analysis of the gel was preformed using Image J software and 
band intensities are represented in (B’). 

4. Discussion 
EVs are small lipid vesicles released by prokaryotic and eukaryotic cells that contain 

nucleic acids, proteins, and small metabolites essential for cellular communication. De-
pending on the targeted cell, these vesicles can act either locally or in distant tissues in a 
paracrine, endocrine or juxtacrine cell signaling manner [42,43]. In EVs released by para-
sites, the analysis of the cargo and related functions suggest that these vesicles could be 

Figure 5. Protease activity of extracellular vesicles and whole protein extracts of trophozoites of Naeg-
leria fowleri showing clear areas of gelatin digestion. For this experiments, 2.5 µg of protein/sample
were loaded onto the gel. (A) Protease activity of extracellular vesicles (EVs) and whole protein
extracts (WPE) of trophozoites of N. fowleri. (B) Specific protease activity of EVs previously incubated
with EDTA 10 mM (metalloproteases inhibitor), 2-iodoacetamide 1 mM (cysteine proteases inhibitor)
and phenylmethylsulfonyl fluoride (PMSF) 1 mM (serine proteases inhibitor). Protease activity was
fully inhibited by PMSF, which could indicate a predominance of serine proteases in the samples ana-
lyzed. Densitometry analysis of the gel was preformed using Image J software and band intensities
are represented in (B’).

4. Discussion

EVs are small lipid vesicles released by prokaryotic and eukaryotic cells that con-
tain nucleic acids, proteins, and small metabolites essential for cellular communication.
Depending on the targeted cell, these vesicles can act either locally or in distant tissues
in a paracrine, endocrine or juxtacrine cell signaling manner [42,43]. In EVs released by
parasites, the analysis of the cargo and related functions suggest that these vesicles could
be considered a mechanism of transferring biomolecules to host cells and tissues [44].
Recent reviews indicate that EVs released by protozoan parasites are capable of inducing
an effective immune response, modulating the immune response and affecting the invasion
process [45,46]. To our knowledge, this is the first study that evidences the production of
EVs by N. fowleri; more specifically, a clinical isolate of this free-living amoeba that produces
primary amoebic meningoencefalitis was employed.

In this study, trophozoites of N. fowleri incubated at 37 ◦C for 5 h in serum-free casein
hydrolysate culture medium released EVs of different sizes. Transmission electron mi-
croscopy images showed vesicles ranging from ~44 nm to ~208 nm in diameter (Figure 1).
Nanoparticle tracking analysis also revealed that ~76% of the vesicles were within <250 nm
and only 2.3% of the population showed sizes of >390 nm (Figure 3), which could corre-
spond to aggregates of vesicles, as ultracentrifugation could cause aggregation due to the
high speed of centrifugation employed. The mean sizes of 206 nm or 227 nm, obtained by
nanoparticle tracking analysis and dynamic light scattering, are slightly higher than those
reported for EVs of Acanthamoeba, which range from 111.3 nm to 184.6 nm using DLS [27]
and 166.7 nm using NTA [26]. For the latter genus, different size populations in the same
sample of EVs were reported, especially when incubating trophozoites at 28 ◦C [27,46]. It
is known that factors such as cell type, cell confluency or density, stimulation of cells with
exogenous compounds, or abrupt change in culture conditions during the production of



Biology 2022, 11, 983 14 of 20

conditioned media might all potentially affect the yield outcome and the functional charac-
teristics of the EVs secreted [47]. More studies are necessary to compare the EVs released
under different culture conditions or by different isolates and/or species of Naegleria.

Atomic force microscopy also confirmed the secretion of EVs by N. fowleri
(Figures 2, S1 and S2). In this case, samples of trophozoites and EVs collected after the
isolation procedure employed were analyzed. For EVs, heights of 4.5 nm to 40 nm and
diameters of 30 nm to 400 nm were obtained; diameters >220 nm could consist of EV
aggregates. EVs of more heterogeneous sizes were observed when analyzing samples of
trophozoites incubated at 37 ◦C for 1 h in serum-free casein hydrolysate culture medium.

Besides imaging, particle number and size, determination of zeta potential was also in-
cluded in the EV characterization analyses, which resulted in a value of−12.228 ± 4.843 mV.
The zeta potential in a dispersed system is a measure of charge stability and affects particle-
particle interaction [48]. This is considered a popular method to determine the surface
potential of EVs, while used as an indicator of surface charge and colloidal stability, in-
fluenced by surface chemistry, bioconjugation and the theoretical model applied [49]. As
the electrical charge of the surface of EVs is reflected in the zeta potential, it could be also
considered as a characteristic of the vesicle´s population [19]. Determination of zeta poten-
tial is also considered one of the most useful tools to investigate the collective behavior of
nanoparticles, such as EVs in dispersed systems, and thus, holds promise as a method for
studying the activity of EVs in biological processes [49]. In this sense, the surface charge is
known to influence different biological processes related to vesicles, such as cellular uptake
and cytotoxicity. For example, charge-dependent differences in the mode of cytotoxic action
have been reported using synthetic nanoparticles (NPs); it appears that positively charged
NPs cause membrane damage, whereas anionic particles cause intracellular damage [50].
Studies on the effect of charge density and the kind of charge (positive, negative) in non-
phagocytic cells have also shown that charged NPs (polystyrene and iron oxide) are taken
up better than their uncharged counterparts [50]; moreover, anionic NPs seem to be better
ingested in phagocytic cells [50]. These observations could suggest that, due to the mean
zeta potential obtained in this study, EVs of N. fowleri could easily be captured by host cells
and release their contents within the cells, including virulence factors, as will be discussed
below. Uptake experiments to evaluate the entrance of EVs of N. fowleri in different cell
lines are being currently performed by our research group.

Literature reports that include zeta potential values of EVs of parasitic origin are very
scarce. Mean values of zeta potential of −16 ± 4 mV and −18 ± 8 mV have been reported
for trypomastigotes and epimastigotes of Trypanosoma cruzi [19]. In this study, the mean
zeta potential value obtained in EVs secreted by trophozoites of N. fowleri is considered
within the range previously reported by different EV research groups. It is important to
mention that, according to several authors, there are still limitations when interpreting the
results of zeta potential of EVs [51] and the isolation methodology should be taken into
account when performing the interpretations.

To evaluate the presence of immunogenic cargo in EVs released by our clinical isolate
of N. fowleri, Western blots were performed using polyclonal antibodies raised in rats
against a whole protein extract of trophozoites of N. fowleri (ATCC N. fowleri Carter 30,808).
Results showed a similar recognition pattern in EVs and protein extracts of trophozoites;
however, in EVs, the stronger recognition was observed in a group of 3 bands above
70–80 KDa and 3 bands below 23 KDa (Figure 4). Similarities found in the recognition
patterns of whole protein extracts and EVs suggest that antigenic components—either
cytosolic or from the plasma membrane of trophozoites—could be packed within the EVs
secreted by the amoeba, components that may possibly stimulate the immune response
during the invasion process of the amoeba to the host. In recent years, the ability of EVs to
elicit an effective immune response has been the subject of extensive research related to
diagnosis and immunotherapy in parasitic diseases produced by helminths and protozoan
microorganisms [8]. For example, in the case of malaria, evidence suggests that EVs are a
source of circulating virulence factors that appear to influence disease severity [52]. More-



Biology 2022, 11, 983 15 of 20

over, the release of EVs by Plasmodium berghei elicits a strong proinflammatory reaction
thtrough macrophage activation [53], while the immunization with EVs of P. yoelii seems to
induce a protective response in a murine model, triggering the production of IgG and stim-
ulating reticulocitosys [22]. These findings suggest that EVs could be employed as antigen
carriers for novel vaccination strategies. In this sense, it has been shown that EVs secreted
by tachyzoites of Toxoplasma gondii are highly immunogenic, capable of inducing both
protective humoral and cellular immune responses [54,55] and triggering the production
of IL-10, TNFα and iNOS in an in vitro model using murine macrophages [56]. However,
in another protozoan parasite, Leishmania, exosomes have shown an immunosuppresive
role, inhibiting the production of IFN-γ and IL-10 by monocyte-derived dendritic cells [57].
Besides this immunomodulatory activity, EVs could act as vehicles for virulence factors
like the major surface protease (MSP), also known as GP63 [58,59]. Regarding free-living
amoebae, Costa et al. have demonstrated that EVs of clinical and environmental isolates of
Acanthamoeba are capable of inducing the production of nitric oxide via TLR4 in an in vitro
model using murine macrophages [28]. These authors concluded that EVs carry different
types of PAMPs that could trigger the innate immune response during the infection process.

In order to identify the predominant proteins in EVs recognized by the polyclonal
anti-N. fowleri antibodies, the 3 more intense bands over 70–80 KDa were submitted to
proteomic analysis. In this case, 36, 28 and 35 proteins were identified in bands a, b, and c,
respectively. From these proteins, actin (B5M6J9), Hsp70 (Q6B3P1) and glyceraldehyde-
3-phosphate dehydrogenase (D2W142) are proteins that had been previously reported by
Gutiérrez Sanchez et al. in 2020, showing differential expression between N. fowleri and N.
lovaniensis [60]. Another protein of interest is adenosyl homocysteinase (A0A6A5BYK8)
(Table 1), a protein that has been considered as potential target in the design of new drugs
for the treatment of primary amoebic meningoencephalitis. This protein participates in
methylation reactions required for growth and gene regulation; for this reason, it has been
considered an ideal target for antimicrobial drugs, especially for eukaryotic parasites [61].
Regarding peptidases, fowlerpain (a cysteine protease) and leucine aminopeptidase were
also identified in EVs of N. fowleri (Table 1 and S1). In general terms, peptidases are consid-
ered virulence factors in different parasitic infections, being implicated in immune evasion
and in host invasion. In N. fowleri infections, cysteine proteases present in trophozoites
and conditioned media have been considered essential during the invasion process of the
amoeba to the central nervous system and its survival in brain tissue [62,63]. It is important
to highlight the presence of the elongation factor 1-alpha (eeEF1 α), identified in one of
the bands (Table 1 and S1). This protein has been found in exosomes of Leishmania in
early infections and has been identified as an important factor for immunosuppression and
priming of host cells for Leishmania invasion [64,65].

Besides the identification of immunogenic proteins, a preliminary whole proteome
analysis of N. fowleri EVs was also obtained by a shotgun approach, revealing the presence
of 184 proteins in vesicles obtained under our experimental conditions (Table S1). The
presence of Rho GTPases, actin and actin related proteins, ubiquitin, dehydrogenases and
fowlerpain was confirmed in EVs (Table S1). However, 85 of the detected proteins are still
uncharacterized in databases. Previous studies have identified the presence of 110, 148 and
130 proteins in EVs of another free-living amoeba, Acanthamoeba, grown under different
experimental conditions [25,46]. Results obtained after quantitative analysis showed that
the largest protein families in EVs of Acanthamoeba were categorized into the classes of
hydrolases and oxidoreductases.

Protease activity of EVs of N. fowleri was analyzed using zymography (Figure 5). In
this case, protease activity between 140 KDa and 260 KDa, at 37 ◦C and pH 8, was identified.
A complete and partial inhibition of protease activity was achieved when incubating EVs
with phenylmethylsulfonyl fluoride and EDTA, respectively. These results suggest that
the predominant enzymatic activity in EVs is related to serine proteases, followed by a
less intense metalloprotease activity (Figure 4), similar to that described for clinical and
environmental isolates of Acanthamoeba [25,26,28,46]. In contrast, published reports of pro-



Biology 2022, 11, 983 16 of 20

tease activity of whole protein extracts of N. fowleri trophozoites suggest a predominance
of cysteine proteases [63,66]. The release of serine proteases via EVs could contribute to
the degradation of the extracellular matrix during the initial stages of the infection with
this amoeba, thus facilitating tissue invasion as reported in in vitro infections with Acan-
thamaoeba genotype T4 [67–69]. Moreover, proteases could exert an effect over the immune
response of the host, as reported for several parasites. For example, it has been demon-
strated that serine proteases secreted by Leishmania donovani downregulate macrophages
microbicidal activity [70], while in infections with Acanthamoeba, these enzymes are capable
of inducing the production of IL-12 and mostly IL-6 by these cells [71].

In general terms, protease activity in protozoan related infections, including those
produced by free-living amoebae, has been demonstrated and extensively discussed as a
virulence factor. Proteases participate in the invasion and egress process of intracellular
parasites like Plasmodium falciparum [72–75] and Toxoplasma gondii [76]; in the modulation
of the immune response of macrophages during an infection with Leishmania Mexicana
and L. donovani [77,78]; in the pathogenesis of the intestinal infection with Entamoeba
histolytica [79,80], among others. Regarding free-living amoebae, the secretion and release
of proteases has been related to the increase in cell permeability and in permeability of
mitochondrial membranes, in extracellular matrix degradation, and in apoptosis induction
and cell death [81,82]. More recently, the release in Leishmania infantum of the major surface
protease, a metalloprotease responsible of the suppression of the immune response, was
confirmed in EVs [59]. Ongoing studies to evaluate the significance of this secretion
pathway of proteases in infections by free-living amoeba such as N. fowleri are being carried
out in our laboratory.

5. Conclusions

Since 2012, scientific literature regarding EVs has increased at an exponential rate [83].
In parasitology, evidence suggests that EVs could be considered as key players in a pathway
for the release of virulence factors. Research on EVs secreted by emerging pathogens,
including free-living amoebae, could help to better understand pathogenic-related aspects
in infections. The present study provides an extensive characterization of general properties
and protein cargo for the EVs of a clinical isolate of N. fowleri, representing a valuable
platform of information to pursue further investigations on this protozoon. Research in this
field focusing on EVs could open new possibilities for the discovery of therapeutic targets
and possible diagnostic biomarkers for infections such as the highly lethal primary acute
meningoencephalitis caused by N. fowleri.

Supplementary Materials: The following supporting information can be downloaded at: https://
www.mdpi.com/article/10.3390/biology11070983/s1. Figure S1: Atomic force microscopy images of
a trophozoite of Naegleria fowleri surrounded by secreted extracellular vesicles: (A) Z-height image
and (B) amplitude image; Figure S2: Atomic force microscopy images of extracellular vesicles secreted
by trophozoites of Naegleria fowleri: A. and B. Z-height images, C. and D. amplitude images; Figure
S3: Electrophoretic protein profile of extracellular vesicles and trophozoites of Naegleria fowleri after
Coomassie stain; Figure S4: Electrophoretic protein profile of extracellular vesicles and trophozoites
of Naegleria fowleri after silver stain; Figure S5: Molecular recognition of proteins of extracellular
vesicles of Naegleria fowleri by polyclonal anti-Naegleria fowleri antibodies, using Western blot: A.
molecular weight marker; B. samples of extracellular vesicles and trophozoites of Naegleria fowleri;
Figure S6: Protease activity of extracellular vesicles (A) and trophozoites (B) of Naegleria fowleri;
Figure S7: Determination of the protease types in extracellular vesicles of Naegleria fowleri using
zymography. Table S1: Proteins identified in extracellular vesicles of Naegleria fowleri (total proteome).

Author Contributions: Conceptualization, L.R.M. and E.A.S.; methodology, L.R.M., E.A.S., G.S.-A.
and B.L.; validation, E.A.S., L.R.M., B.L., G.S.-A. and A.O.; formal analysis, L.R.M., E.A.S., G.S.-A.
and B.L.; investigation, L.R.M., E.A.S., M.F.S.E., A.C.-G., N.C.C., G.S.-A. and B.L.; resources, E.A.S.,
L.R.M., G.S.-A., B.L. and A.O.; data curation, L.R.M., B.L., G.S.-A. and E.A.S.; writing—original draft
preparation, L.R.M., E.A.S., B.L. and G.S.-A.; writing—review and editing, E.A.S., L.R.M., B.L., G.S.-A.

https://www.mdpi.com/article/10.3390/biology11070983/s1
https://www.mdpi.com/article/10.3390/biology11070983/s1


Biology 2022, 11, 983 17 of 20

and A.O.; funding acquisition, E.A.S. and L.R.M. All authors have read and agreed to the published
version of the manuscript.

Funding: This research was funded by “Vicerrectoría de Investigación” of the “Universidad de
Costa Rica”, by supporting the research projects C-1061: “Caracterización de antígenos de ex-
creción/secreción y antígenos somáticos en amebas de vida libre mediante empleo de anticuerpos
policlonales producidos en roedores” and C-2600: “Secreción de vesículas extracelulares por Naegleria
fowleri y evaluación de su potencial rol inmunomodulador en un modelo in vitro”.

Institutional Review Board Statement: The use of animals was performed following the institutional
guidelines (Spanish government regulations (Real Decreto RD1201/05)) and the guidelines of the
European Union (European Directive 2010/63/EU). These experiments were approved by the Ethical
Committee of the University of Granada (235-CEEA-OH-2018) and by the authorities of the Regional
Government of Andalucía (JJAA) (number 12/11/2017/162).

Informed Consent Statement: Not applicable.

Data Availability Statement: Mass spectrometry raw files of the data presented in this work are
available from the authors upon reasonable request.

Acknowledgments: Transmission electron microscopy was performed at the “Centro de Instru-
mentación Científica” of the “Universidad de Granada”. Dynamic light scattering was performed
at the “Laboratorio de Polímeros” of the School of Chemistry, “Universidad Nacional” and atomic
force microscopy imaging was performed at the Physics Department of the same university. Pro-
teomic analyses were performed at the “Instituto Clodomiro Picado”, of the “Universidad de Costa
Rica”. Special thanks to Oscar Rojas Carrillo for allowing the access to the equipment and for his
methodological support during the dynamic light scattering analyses and Desire Arrieta Murillo and
Jocelyn Cortés Espínola for the technical support during the atomic force microscopy analyses. G.S.-A.
wants to thank “Plan de Mejoramiento Institucional UNA BM-04”, Consejo Nacional de Rectores
(FEES-CONARE) and the “Vicerrectoría de Investigación” of Universidad Nacional de Costa Rica for
funding for equipment.

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Materials and Methods 
	Axenic Culture of Naegleria fowleri Trophozoites 
	Isolation of Extracellular Vesicles (EVs) 
	Transmission Electron Microscopy 
	Atomic Force Microscopy 
	Nanoparticle Tracking Analysis 
	Dynamic Light Scattering 
	Measurement of Zeta Potential 
	Protein Pattern and Recognition of Extracellular Vesicles by Rat Polyclonal Anti-Naegleria fowleri Antibodies 
	Preparation of Whole Protein Extracts of Naegleria fowleri Trophozoites 
	Electrophoretic Separation of Proteins Using SDS-PAGE 
	Polyclonal Antibody Production 
	Western Blot 

	Evaluation of Protease Activity of Extracellular Vesicles 
	Proteomic Analyses 
	Protein Identification from SDS-PAGE/Western Blot Immunogenic Bands 
	Proteome Profiling of Whole EVs by Bottom-Up Shotgun Analysis 


	Results 
	Characterization of Extracellular Vesicles 
	Transmission Electron Microscopy and Atomic Force Microscopy 
	Nanoparticle Tracking Analysis and Dynamic Light Scattering 

	Protein Profile and Recognition of Extracellular Vesicles by Anti-Naegleria fowleri Polyclonal Antibodies 
	Protease Activity of Extracellular Vesicles 

	Discussion 
	Conclusions 
	References