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The cell-impermeable Ru(II) polypyridyl complex as a potent intracellular photosensitizer under visible light irradiation via ion-pairing with suitable lipophilic counter-anions.
TYPE Original Research
PUBLISHED 21 August 2024
DOI 10.3389/fimmu.2024.1421036
OPEN ACCESS
EDITED BY
Paulo Rodrigues-Santos,
University of Coimbra, Portugal
REVIEWED BY
Mauro Di Ianni,
University of Studies G. d’Annunzio Chieti and
Pescara, Italy
Olga Janouskova,
Jan Evangelista Purkyně University in Ústı´ nad
Labem, Czechia
Exploring cell-derived
extracellular vesicles in
peripheral blood and bone
marrow of B-cell acute
lymphoblastic leukemia pediatric
patients: proof-of-concept study
*CORRESPONDENCE
Allyson Guimarães Costa
allyson.gui.costa@gmail.com
†
These authors share senior authorship
RECEIVED 21 April 2024
ACCEPTED 25 July 2024
PUBLISHED 21 August 2024
CITATION
Magalhães-Gama F,
Malheiros Araújo Silvestrini M, Neves JCF,
Araújo ND, Alves-Hanna FS, Kerr MWA,
Carvalho MPSS, Tarragô AM, Soares Pontes G,
Martins-Filho OA, Malheiro A,
Teixeira-Carvalho A and Costa AG (2024)
Exploring cell-derived extracellular vesicles in
peripheral blood and bone marrow of B-cell
acute lymphoblastic leukemia pediatric
patients: proof-of-concept study.
Front. Immunol. 15:1421036.
doi: 10.3389/fimmu.2024.1421036
COPYRIGHT
© 2024 Magalhães-Gama,
Malheiros Araújo Silvestrini, Neves, Araújo,
Alves-Hanna, Kerr, Carvalho, Tarragô,
Soares Pontes, Martins-Filho, Malheiro,
Teixeira-Carvalho and Costa. This is an openaccess article distributed under the terms of
the Creative Commons Attribution License
(CC BY). The use, distribution or reproduction
in other forums is permitted, provided the
original author(s) and the copyright owner(s)
are credited and that the original publication
in this journal is cited, in accordance with
accepted academic practice. No use,
distribution or reproduction is permitted
which does not comply with these terms.
Fábio Magalhães-Gama 1,2,3,4,
Marina Malheiros Araújo Silvestrini 3,4,
Juliana Costa Ferreira Neves 2,5, Nilberto Dias Araújo 1,2,6,
Fabı́ola Silva Alves-Hanna 1,2, Marlon Wendell Athaydes Kerr 2,6,
Maria Perpétuo Socorro Sampaio Carvalho 2,6,
Andréa Monteiro Tarragô 2,6, Gemilson Soares Pontes 1,6,7,
Olindo Assis Martins-Filho 3,4,6, Adriana Malheiro 1,2,6,
Andréa Teixeira-Carvalho 3,4,6†
and Allyson Guimarães Costa 1,2,6*†
1
Programa de Pós-graduação em Imunologia Básica e Aplicada, Instituto de Ciências Biológicas,
Universidade Federal do Amazonas (UFAM), Manaus, Brazil, 2 Diretoria de Ensino e Pesquisa, Fundação
Hospitalar de Hematologia e Hemoterapia do Amazonas (HEMOAM), Manaus, Brazil, 3 Programa de
Pós-graduação em Ciências da Saúde, Instituto René Rachou - Fundação Oswaldo Cruz (FIOCRUZ)
Minas, Belo Horizonte, Brazil, 4 Grupo Integrado de Pesquisas em Biomarcadores, Belo
Horizonte, Brazil, 5 Programa de Pós-graduação em Medicina Tropical, Universidade do Estado do
Amazonas (UEA), Manaus, Brazil, 6 Programa de Pós-graduação em Ciências Aplicadas à Hematologia,
UEA, Manaus, Brazil, 7 Laboratório de Virologia e Imunologia, Instituto Nacional de Pesquisas da
Amazônia (INPA), Manaus, Brazil
Extracellular vesicles (EVs) are heterogeneous, phospholipid membrane
enclosed particles that are secreted by healthy and cancerous cells. EVs are
present in diverse biological fluids and have been associated with the severity of
diseases, which indicates their potential as biomarkers for diagnosis, prognosis
and as therapeutic targets. This study investigated the phenotypic characteristics
of EVs derived from peripheral blood (PB) and bone marrow (BM) in pediatric
patients with B-cell acute lymphoblastic leukemia (B-ALL) during different
treatment stages. PB and BM plasma were collected from 20 B-ALL patients at
three time points during induction therapy, referred to as: diagnosis baseline
(D0), day 15 of induction therapy (D15) and the end of the induction therapy
(D35). In addition, PB samples were collected from 10 healthy children at a single
Abbreviations: ADAM17, A Disintegrin and Metalloproteinase 17; AUC, area under the curve; ATG3,
Autophagy Related Protein 3; B-ALL, B cell acute lymphoblastic leukemia; BM, bone marrow; CD, cluster of
differentiation; D0, diagnosis baseline; D15, day 15 of the induction therapy; D35, end of the induction
therapy; EVs, extracellular vesicles; IQR, interquartile range; ISEV, International Society for Extracellular
Vesicles; LR, likelihood ratio; mAB, monoclonal antibody; NTA, nanoparticle tracking analysis; PB,
peripheral blood; ROC, receiver operating characteristic; RT, room temperature; SEM, scanning electron
microscopy; Se, sensitivity; Sp, specificity; TEM, transmission electron microscopy.
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�Magalhães-Gama et al.
10.3389/fimmu.2024.1421036
time point. The EVs were measured using CytoFLEX S flow cytometer. Calibration
beads were employed to ensure accurate size analysis. The following,
fluorescent-labeled specific cellular markers were used to label the EVs:
Annexin V (phosphatidylserine), CD235a (erythrocyte), CD41a (platelet), CD51
(endothelial cell), CD45 (leukocyte), CD66b (neutrophil), CD14 (monocyte), CD3
(T lymphocyte), CD19, CD34 and CD10 (B lymphoblast/leukemic blast). Our
results demonstrate that B-ALL patients had a marked production of EV-CD51/
61+, EV-CD10+, EV-CD19+ and EV-CD10+CD19+ (double-positive) with a
decrease in EV-CD41a + on D0. However, the kinetics and signature of
production during induction therapy revealed a clear decline in EV-CD10+ and
EV-CD19+, with an increase of EV-CD41a+ on D35. Furthermore, B-ALL patients
showed a complex biological network, exhibiting distinct profiles on D0 and D35.
Interestingly, fold change and ROC curve analysis demonstrated that EVCD10+CD19+ were associated with B-ALL patients, exhibited excellent clinical
performance and standing out as a potential diagnostic biomarker. In conclusion,
our data indicate that EVs represent a promising field of investigation in B-ALL,
offering the possibility of identifying potential biomarkers and therapeutic targets.
KEYWORDS
childhood leukemia, leukemic microenvironment, extracellular vesicles, nano-flow
cytometry, biomarkers
Introduction
cell-derived EVs are capable of transporting oncogenic factors.
These factors can then be transported and internalized by
surrounding cells, leading to alterations in the gene expression
of recipient cells. This process can significantly impact the
progression of the disease (12–14).
Although studies in ALL are scarce compared to solid tumors,
EVs have been shown to play an important role in bidirectional
communication between leukemic cells and bone marrow stromal
cells. Leukemic EVs targeting hematopoietic stem cells and
progenitors have been shown to affect the quiescence and
maintenance of the hematopoietic compartment (15). On the other
hand, EVs derived from endothelial cells and mesenchymal cells
sustain the activities and offer a role in protecting leukemic blasts (16,
17). In the context of tumor immunity, it was also demonstrated that
EVs derived from leukemic blasts inhibit the biological function of
natural killer cells and effector T cells by increasing the expression of
Foxp3 and the signaling of regulatory cytokines, including TGF-b
and IL-10 (18, 19). Collectively, these features highlight the potential
of EVs as promising biomarkers in B-ALL, since EV levels can not
only predict therapeutic responses but are also easily detectable in
blood via minimally invasive methods (20).
Therefore, the aim of the present investigation was to analyze
the immunophenotypic profile of cell-derived EVs in the PB and
BM aspirates of newly diagnosed B-ALL patients undergoing
remission induction therapy. By investigating these EVs, we hope
to provide insight into the use of EVs as potential biomarkers in
childhood leukemia.
B-cell acute lymphoblastic leukemia (B-ALL) is characterized
by an abnormal proliferation of B lymphoblasts/leukemic cells in
the bone marrow (BM), which are released into the bloodstream
and extramedullary tissues, and is the most common childhood
cancer in the world (1, 2). The immunological mechanisms
involved in triggering or maintaining B-ALL in patients are still
being investigated. Similar to other cancers, B-ALL is characterized
by a complex interplay between the immune system and leukemic
cells throughout progression of the disease (3). In this context, it is
important to highlight that the leukemic microenvironment
comprises a diverse cellular landscape. This includes leukemic
cells, hematopoietic stem cells, immune cells and bone marrow
stromal cells. Together, they form a singular network of intrinsic
interactions that can be explored by leukemic cells to contribute to
the progression of cancer (4–6).
Historically, these interactions have been shown to be
modulated by several immunological mediators, including
cytokines, chemokines and growth factors (7–9). In a similar
way to what occurs in these molecules, recent advances in
cancer biology have revealed that heterogeneous cell membranederived vesicles, termed extracellular vesicles (EVs), which include
exosomes and microvesicles, are released in large quantities by
cancer cells, acting as key mediators of cellular communication,
through bioactive charges transfer, as proteins, lipids and nucleic
acids (10, 11). In addition, some studies have shown that cancer
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TABLE 1 Demographic and clinical characteristics of the
study population.
Materials and methods
Ethics statement
This study was submitted to and approved by the Ethics
Committee at Fundaç ão Hospitalar de Hematologia e
Hemoterapia do Amazonas (HEMOAM), under protocol
registration number #739.563. Prior to the inclusion of all the
patients and controls in the study, all the respective parents or
legal guardians read and signed the informed assent form. The
study was carried out in accordance with the principles of the
Helsinki Declaration and Resolution 466/2012 of the Brazilian
National Health Council, which relates to research involving
human participants.
Variables
CG PB
(n=10)
B-ALL
PB (n=10)
B-ALL
BM (n=10)
Age, median (IQR)
9 (6-13)
3 (2-9)
5 (3-6)
Sex, Male/Female
5M/5F
7M/3F
8M/2F
1 to <5
1 (10%)
7 (70%)
4 (40%)
5 to <10
4 (40%)
1 (10%)
5 (50%)
10 to <15
5 (50%)
2 (20%)
1 (10%)
–
10 (100%)
10 (100%)
Absent
–
10 (100%)
10 (100%)
Present
–
0 (0%)
0 (0%)
Good prognosis
–
10 (100%)
10 (100%)
Poor prognosis
–
0 (0%)
0 (0%)
Low Risk
–
7 (24%)
6 (27%)
High Risk
–
3 (24%)
4 (55%)
True low risk
–
0 (0%)
1 (10%)
Low intermediate risk
–
6 (60%)
5 (50%)
High risk rapid responder
–
3 (30%)
4 (40%)
High risk slow responder
–
1 (10%)
0 (0%)
Negative
–
1 (10%)
1 (10%)
Positive
–
9 (90%)
9 (90%)
M1
–
100 (100%)
100 (100%)
M2
–
0 (0%)
0 (0%)
M3
–
0 (0%)
0 (0%)
Age group, n (%)
Immunophenotyping
Common B-ALL (CD10+)
CNS infiltration
Patients and control subjects
The study population consisted of 20 patients under the age of
15 who had been recently diagnosed with B-ALL at Fundaç ão
HEMOAM, the reference center for diagnosis and treatment of
hematological diseases in the state of Amazonas, Brazil. The
diagnosis was performed according to the classification criteria
and guidelines of the World Health Organization (21). The B-ALL
patients were subdivided into two subgroups (B-ALL peripheral
blood [PB] and B-ALL bone marrow [BM]), according to the
biological material used to measure the EVs. The B-ALL PB group
consisted of 10 patients (7 males and 3 females), with a median age
of 3 years; IQR = 2-9. The BM group consisted of 10 patients (8
males and 2 females), with a median age of 5 years; IQR = 3-6.
Additionally, 10 children without leukemia (5 males and 5
females) with a median age of 9 years, IQR = 6-13, were
included as a control group. For this, only PB samples were
collected to provide a reference value in the analyses, since BM
aspiration is a very invasive procedure. The children recruited in
this study had not experienced any infections for at least four
weeks prior to the collection of samples and did not present
immunological alterations in the leukocyte series. The
demographic and clinical data, together with the hematological
patterns of the studied population are summarized in Tables 1,
2, respectively.
Cytogenetics
Risk stratification at D0
Risk re-stratification at D15
MRD at D15
Myelogram at D35 [n (%)]
Treatment regimen
CG, control group; B-ALL, B-cell acute lymphoblastic leukemia; PB, peripheral blood; BM,
bone marrow; IQR, interquartile range; CNS, central nervous system; MRD, measurable
residual disease; D0, diagnosis baseline; D15, day 15 of induction therapy; D35, end of the
induction therapy; M1, <5% lymphoblasts; M2, 5-25% lymphoblasts; M3, >25% lymphoblasts.
All the B-ALL patients underwent remission induction
therapy (according to the protocol and guidelines found in the
Brazilian Group for Treatment of Childhood Leukemia, version
2009), which is an intensive stage of chemotherapy of
fundamental importance for the prognosis of patients, and
whose objective is to achieve disease remission, with less than
5% lymphoblasts in five weeks. The treatment regimen includes
the drugs prednisone, dexamethasone, vincristine, daunorubicin,
L-asparaginase and MADIT (intrathecal methotrexate,
cytarabine and dexamethasone) (22).
Frontiers in Immunology
Biological sample collection
The PB and BM samples of the B-ALL patients were obtained by
venipuncture and iliac crest aspiration, respectively, at three
consecutive time points, referred to as: D0 (diagnosis baseline),
D15 (day 15 of induction therapy) and D35 (end of the induction
therapy). In addition, PB samples from controls were obtained (single
time point) via venipuncture. After collection, the biological samples
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TABLE 2 Hematological characteristics of the study population.
Characteristics
CG PB
(n = 10)
B-ALL PB
(n = 10)
B-ALL BM
(n = 10)
p-value
Total leukocytes (x103/uL), median (IQR)
7,540
(6,788-8,178)
9,135
(4,593-12,195)
56,735
(41,865-76,825)
0.0014b
Lymphoblasts ABS [%], median (IQR)
–
7,239 [62%]
(995- 8,278)
47,964 [82%]
(28,483-64,920)
0.0048b
Neutrophils (x103/uL), median (IQR)
3.24
(2.89-3.55)
0.43
(0.18-0.98)
0.30
(0.21-0.64)
<0.0001a
Lymphocytes (x103/uL), median (IQR)
3.18
(2.50-3.73)
3.10
(2.25- 4.29)
3.19
(3.13-4.61)
0.7031
Monocytes (x103/uL), median (IQR)
0.40
(0.29-0.54)
0.11
(0.00-0.21)
0.13
(0.05-0.27)
0.0005a
Hemoglobin (g/dL), median (IQR)
13.4
(12.3-13.7)
8.3
(3.7-9.7)
7.1
(4.6-8.1)
0.0010a
Platelets (x103/uL), median (IQR)
325
(302-434)
54
(28-101)
53
(24-89)
<0.0001a
CG, control group; BM, bone marrow; PB, peripheral blood; IQR, interquartile range. Reference values: Leukocytes: 5.2 - 12.4 x10³/μL; Neutrophils: 1.9 - 8 x10³/μL; Lymphocytes: 0.9 - 5.2 x10³/
μL; Monocytes: 0.16 - 1 x10³/μL; Hemoglobin: 12 - 18 g/dL; Platelets: 130 - 140 x10³/μL. Significant differences of p<0.05 are represented in bold with the following superscript letters: “a” and “b”,
which refer to comparisons of the B-ALL PB group with the CG and B-ALL BM group, respectively.
were transferred to EDTA vacuum tubes (BD Vacutainer® EDTA
K2) and submitted to centrifugation at 600 xg, for 10 minutes at room
temperature (RT). Subsequently, the supernatants or platelet-poor
plasma were collected and immediately stored at -80°C until
processing for EV measurement.
suspension was incubated in the absence of mAB and Annexin VFITC (all purchased from BD Bioscience, San Diego, CA, USA).
Additionally, aliquots of mAB and Annexin V-FITC, incubated in
the absence of EVs, were also used as internal controls. After
incubation for 30 minutes in the dark at RT, 300 mL of Annexin
V buffer was added to the wells of each plate and then transferred to
FACS tubes. The samples were acquired in a flow cytometer
(CytoFLEX S, Beckman Coulter, Brea, CA, USA) with volume
control aspirated per minute. The CytoFLEX S has a volumetric
sample injection system that allows counting of absolute particles.
The sample flow rate was 30 mL/min, and the sample acquisition
occurred during 2 minutes per sample. Calibration beads
(Megamix-Plus FSC and SSC, Biocytex, Marseille, France) with
standard sizes of 100, 160, 200, 240, 300, 500, 900 nm were used to
identify different EV size ranges, defined as: small EVs (sEVs): 100200 nm; medium EVs (mEVs): 201-500 nm; and large EVs (lEVs):
501-900 nm. The steps of the protocol are summarized in Figure 1.
Different gating strategies were used to analyze the phenotypic
characteristics and size of the EVs, according Megamix beads, as
illustrated in Supplementary Figures 1, 2.
Sample preparation and extracellular
vesicle measurement via flow cytometry
Initially, the samples were thawed at 37 °C and then centrifuged
at 1,500 xg for 5 minutes to obtain platelet-free plasma. The latter
was diluted in a citrate buffer solution containing heparin (1 mg/mL)
and centrifuged at 1,500 xg for 90 minutes at RT. The EV-rich
sediment was resuspended in commercially available Annexin V
buffer (25 mM CaCl2 solution in 140 mM NaCl and 10 mM HEPES,
pH 7.4; BD Bioscience, San Diego, CA, USA) to obtain the EV
suspension. Aliquots of 100 mL of EV suspension were transferred
to a plate containing 2 mL of distinct monoclonal antibodies (mAB)
to evaluate the immunophenotypes of the study panel. Of
importance, prior to staining, mABs were centrifuged at 1,500 x g
for 30 minutes to remove fluorescent particles. The panel was
composed of specific markers of B cell lineage and maturation
stage, which are used for the diagnosis and monitoring of B-ALL.
Markers of cellular populations/elements (erythrocytes, platelets
and leukocytes) were also used, which are frequently used as
parameters for classifying therapeutic response. Thus, the study
panel was composed of CD235a (erythrocyte), CD41a (platelets),
CD51 (endothelial cell), CD45 (leukocytes), CD66b (neutrophils),
CD14 (monocytes), CD3 (T lymphocytes), CD19 (B lymphocyte/B
lymphoblast) and CD34 and CD10 (B lymphoblast/leukemic blast);
and 2.5 mL of Annexin V-FITC, which binds to phosphatidylserine
residues expressed on the surface of EVs. Internal autofluorescence
control was included in each trial run, in which an aliquot of EV
Frontiers in Immunology
Conventional statistical analysis
The comparative analysis between the B-ALL patients and
controls was carried out using Student’s t test or the MannWhitney test. Comparisons among the timepoints of induction
therapy (D0, D15 and D35) and EV size ranges (sEVs, mEVs and
lEVs) were performed using one-way ANOVA followed by the Tukey
or Friedman tests followed by Dunn’s test; along with the paired t test
or Wilcoxon matched-pairs signed-ranks test. In all cases, the
Shapiro-Wilk test was used to verify the normality of the data and
significance was considered when p was <0.05. The GraphPad Prism
software v8.0.2 (San Diego, CA, USA) was used for statistical analysis.
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FIGURE 1
Compendium of study. The study population (A), sampling (B), and methods (C), including the steps of the protocol are summarized in this figure.
(r >0.68), which were represented by connecting edges, as proposed
by Taylor (1990) (24). Cytoscape software and Microsoft PowerPoint
program were used for the graphics.
Overall signatures of extracellular vesicles
The signature analysis was carried out according to Kerr et al.
(2021) (23), by converting the original results of each variable expressed
as a continuous variable in categorical data. For this purpose, the global
median values obtained for the whole data universe from all
participants (B-ALL patients on different days of induction therapy
and the controls) as the cut-off to classify the patients with low (below
the cut-off) or high (above the cut-off) production of EVs. The
following cut-offs were used: (EV-CD235a+ = 27,917; EV-CD41a+ =
658; EV-CD51/61+ = 4,839; EV-CD45+ = 296; CD66b+ = 797; EVCD14+ = 200; EV-CD3+ = 445; EV-CD34+ = 299; EV-CD10+ = 3,289;
and EV-CD19+ = 7,617) expressed as an absolute number of EVs/mm3
of plasma. The overall signatures were assembled in radar charts using
the 50th percentile as a threshold to identify the proportion of subjects
with EV populations above the global median cut-off.
Fold change and performance analysis of
extracellular vesicles
The magnitude of change in the EV levels in the B-ALL patients was
calculated as the proportion ratio between the serum levels observed for
each B-ALL patient at the diagnosis baseline (D0) divided by the median
values reported for the control group. The magnitude of changes in the
EV levels in the PB were determined considering decreased (≤ 1x) and
increased (≥ 1x) levels in relation to the median values observed in the
control group. Bubble charts were generated using Microsoft Excel®.
Receiver operating characteristic (ROC) curve analysis (25) was carried
out to assess the performance of EVs as biomarkers for B-ALL in the
study population. ROC curve data were used to define cut-off points for
the EVs evaluated. Performance indices of sensitivity (Se), specificity (Sp)
and likelihood ratio (LR) were calculated at a specific cut-off and the area
under the curve (AUC) and p-value were considered as indicators of
global accuracy. The MedCalc v7.3.0 (Ostend, West Flemish, BE) and
GraphPad Prism software v8.0.2 (San Diego, CA, USA) were used for
statistical analysis and construction of the ROC curves.
Biological networks of
extracellular vesicles
Analysis of correlation networks was performed to evaluate the
multiple associations among the EV populations in the B-ALL patients
and the controls. The association between the EV levels was determined
by using the Spearman correlation coefficient in GraphPad Prism, v8.0.2
(GraphPad Software, San Diego, CA, USA), and statistical significance
was considered only if p was <0.05. After performing the correlation
analysis between EV populations, a database was created using
Microsoft Excel® program. Then, the significant correlations were
compiled using the open source Cytoscape software, v3.9.1 (National
Institute of General Medical Sciences, Bethesda, MD, USA). The
biological networks were constructed using circular layouts in which
each EV population is represented by a globular node, in which the
larger the nodule size, the greater the number of correlations established.
The correlation indices (r) were used to categorize the correlation
strength as negative (r <0), moderate (0.36≥ r ≤0.68), or strong
Frontiers in Immunology
Results
Characterization of the profiles of the
extracellular vesicles at diagnosis baseline
The characterization of the EV profile at diagnosis (D0)
demonstrated that the B-ALL PB group had a decrease in plateletderived EVs (EV-CD41a+) and an increase in endothelial cell-derived
EVs (EV-CD51/61+) and B lymphoblasts/lymphocytes with CD10 and
CD19 phenotype (EV-CD10+ and EV-CD19+) when compared to
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control group. Additionally, an increase in the levels of EV-CD51/61+
and EV-CD19+ was observed when compared to the B-ALL BM group.
Nevertheless, a thorough analysis revealed a trend towards increased
levels of leukocyte-derived EVs (EV-CD45+), neutrophils (EVCD66b+), monocytes (EV-CD14+) and B lymphoblast with the CD34
phenotype (EV-CD34+) in the B-ALL BM group (Figure 2).
diagnosis, at the beginning and at the end of induction therapy
(Figure 3). The results demonstrated a decrease in EV-CD235a+,
EV-CD51/61+, EV-CD45+ and EV-CD66b+ in the PB group on
D15. Moreover, there was a noticeable decline in EV-CD10+ and
EV-CD19+ on D15 and D35. This trend was similarly observed in
the B-ALL BM group, wherein EV-CD10+ decreased at D15 and
D35. However, EV-CD19 + exhibited a distinct pattern,
decreasing on D15 and increasing on D35. Furthermore, both
the B-ALL PB and B-ALL BM groups showed an increase in EVCD41a+ on D35. In addition, a specific an increase in EV-CD14+
and EV-CD45+ was observed in the B-ALL PB and B-ALL BM
groups, respectively.
Kinetics of extracellular vesicles during
induction therapy
The analysis of EV kinetics of in PB and BM was performed
on the samples from D0, D15 and D35 to assess the EV levels on
FIGURE 2
Characterization of the profile of the extracellular vesicles at diagnosis baseline. The EV populations were measured at the time of diagnosis in the
) and B-ALL BM (
) groups and in the control group (CG) (
). The count and immunophenotypic characterization of EVs was
B-ALL PB (
performed using flow cytometry, as described in the Materials and Methods section. The results are presented using bar and symbol charts, reported
in log10 scale, showing the mean with standard error of the absolute number of EVs/mm3 of plasma. Statistical analyses were performed using
Student’s t test or the Mann-Whitney test and significant differences are highlighted by asterisks for p<0.01 (**) or p<0.05 (*).
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FIGURE 3
Kinetics of extracellular vesicles during induction therapy. The EV populations were measured on D0, D15, and D35 in the B-ALL PB (
) and B-ALL
) groups to assess the behavior of these EVs during remission induction therapy. The count and immunophenotypic characterization of the
BM (
EVs was performed using flow cytometry, as described in the Materials and Methods section. The results are presented using bar and symbol charts,
reported in log10 scale, showing the mean with standard error of the absolute number of EVs/mm3 of plasma. Statistical analyses were performed
using a paired t test or Wilcoxon matched-pairs signed-rank test for comparisons between D0, D15 and D35 and significant differences are
highlighted by asterisks for p<0.01 (**) or p<0.05 (*).
exhibited a predominance of lEV. On D0, the EV-CD10+ and
CD19+ populations showed an increase in sEV compared to
lEV (Figure 4B).
Kinetics of extracellular vesicles according
to size range
To better understand the size distribution of the EV
populations evaluated, we used calibration beads with specific
sizes (100, 160, 200, 240, 300, 500, 900 nm). Based on this
calibration, we classified the EVs into three size ranges: small
EVs (sEV: 100-200 nm), medium EVs (mEV: 201-500 nm) and
large EVs (lEV: 501-900 nm) (Figure 4). On diagnosis baseline and
throughout induction therapy (D0, D15 and D35) in the B-ALL
PB group, there was a consistent predominance of EV-CD235a+
and EV-CD51/61+ in the sEV and mEV size ranges. In contrast,
the EV-CD45+, EV-CD14+, EV-CD34+ populations showed a
predominance of lEV during the treatment. The EV-CD41a+
population showed an increase in sEV on D0 compared to
control group, followed by an increase in mEV on both D15
and D35, compared to lEV. In addition, EV-CD10+ and EVCD19+ exhibited a predominance of sEV, followed by mEV on D0
(Figure 4A). In the B-ALL BM group, EV-CD235a+ predominated
in both sEV and mEV ranges, while EV-CD14+ and EV-CD34+
Frontiers in Immunology
Signature of extracellular vesicles during
induction therapy
To further refine the characterization of the EV profile in the BALL patients (Figure 5), we calculated the median for each EV
population across all the patients. This median value was then used as
a cut-off to categorize patients as low or high producers of specific
EVs. Our findings demonstrated that on D0, compared to the control
group, the B-ALL PB group displayed a greater production of most
EV populations, except for EV-CD41a+ and EV-CD34+. On D15,
there was a significant decrease in the production of all EV
populations. By D35, only EV-CD3+ was observed and EV-CD14+
remained elevated. In contrast, the B-ALL BM group exhibited a
different pattern. On D0, high production was observed for EVCD235a+, EV-CD66b+, EV-CD10+ and EV-CD19+. By D15, only
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FIGURE 4
Kinetics of extracellular vesicles according to size range. The EV populations were analyzed in (A) B-ALL PB ( ) and (B) B-ALL BM ( ) groups
according to their size, based on Megamix beads size range, being divided into small EVs = 100-200 nm (sEVs), medium EVs = 201-500 nm (mEVs)
and large EVs = 501-900 nm (lEVs), represented by the symbols: “ ”, “ ” and “ ”, respectively. For the control group, sEVs, mEVs, and lEVs were
represented by gray background lines: “ ”, “ ” and “ ”, respectively. The count, size and immunophenotypic characterization of the EVs was
performed using flow cytometry, as described in the Materials and Methods section. The results are presented using symbol charts, reported in log10
scale, showing the median of the absolute number of EVs/mm3 of plasma. Statistical analyses were performed using a paired t test or Wilcoxon
matched-pairs signed-rank test for comparisons between sEVs, mEVs, and lEVs and significant differences are represented by the letters: “a” and “b”,
which refer to the comparisons with sEVs and mEVs, respectively.
EV-CD45+ and EV-CD14+ showed an increase. Nonetheless, on D35,
there was an increase in the production of most EV populations,
except EV-CD3+, EV-CD10+ and EV-CD19+.
the number of interactions between EV populations, resulting in a
network with a profile that was more similar to the control group.
Similarly, the B-ALL BM group’s network displayed a restricted
number of interactions on D0 when compared to the control group.
This number increased slightly on D15, followed by a significant
increase in interactions between EV populations on D35.
Biological network of extracellular vesicles
during induction therapy
Fold change and performance of
extracellular vesicles CD10+and CD19+ as
diagnostic biomarkers of B-ALL
The construction of integrative biological networks was
performed to assess the complex interactions between EV
populations during induction therapy (Figure 6). The results
demonstrated that the B-ALL PB group exhibited a network with
a restricted number of interactions on D0. On D15, a minor
decrease in the number of neighborhood connections was
observed. Despite this, on D35, there was a substantial increase in
Frontiers in Immunology
To identify potential diagnostic biomarkers, we performed a
translational analysis that focused on EV-CD10+ and EV-CD19+
levels measured in the PB of the B-ALL patients at D0. Our findings
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FIGURE 5
Signature of extracellular vesicles during induction therapy. The overall signature of EV populations in the B-ALL patients was assembled on D0, D15
and D35. Data, originally expressed as absolute number of EVs/mm3 of plasma, were converted into categorical data using the global median values,
which were used as a cut-off point to classify the study population as being a low or high producer of the EVs evaluated. The overall signatures were
assembled in radar charts using the 50th percentile as the threshold (central circle/gray zone) to identify EV populations with increased levels in a
higher proportion of patients. Cellular markers: CD235a (erythrocyte), CD41a (platelet), CD51 (endothelial cell), CD45 (leukocyte), CD66b
(neutrophil), CD14 (monocyte), CD3 (T lymphocyte), CD34 and CD10 (B lymphoblast/Leukemic blast) and CD19 (B lymphocyte/B lymphoblast).
revealed significant changes in EV levels in the B-ALL patients
when compared to the control group at D0. EV-CD10+ levels
showed the most dramatic increase (over 5-fold), followed by EVCD19+ (over 3.5-fold) and EV-CD51/61 (over 2-fold). In addition,
EV-CD41a exhibited a significant decrease (below 1.5-fold)
(Figures 7A, B). To assess the diagnostic potential of these EV
levels in the B-ALL patients, we performed ROC curve analysis.
This analysis calculates the area under the curve (AUC), a measure
of overall accuracy, along with sensitivity (Se), specificity (Sp) and
likelihood ratio (LR) to evaluate how well an EV level discriminates
B-ALL from the control group. Data analysis demonstrated that
EV-CD10+ showed high performance (Se = 100.0% and Sp = 70.0%)
and good global accuracy (AUC = 0.860 and p = 0.0065) to
discriminate the B-ALL PB group from the control group.
However, EV-CD19+ levels exhibit a moderate performance
(Se=75.0% and Sp=87.5%) and global accuracy (AUC = 0.844 and
p = 0.0209) (Figure 7C). Additionally, EV-CD41a and EV-CD51/61
also presented moderate/high performance (Se = 66.7% and Sp =
100.0%/Se = 100.0% and Sp = 75.0%, respectively) and global
accuracy (AUC = 0.852 and p = 0.0118/AUC = 0.812 and
p = 0.0357, respectively) (Supplementary Figure 3).
Frontiers in Immunology
Profile, Kinetic, fold change and
performance of extracellular vesicles
CD10+CD19+ as diagnostic biomarkers of
B-ALL
Aiming of investigating whether CD10+ and CD19+ markers
were present simultaneously in EVs, we carried out a strategy to
evaluate EV-CD10 + CD19 + (double-positive) in our study
population. Compilation of data relating to the EVs profile;
kinetics during induction therapy; fold change analysis; and
performance of EV-CD10+CD19+ as biomarkers, are represented
in Figure 8. The results demonstrated that B-ALL patients showed a
significant increase in serum levels of EV-CD10+CD19+ compared
to GC (Figure 8A). During induction therapy, a decline in D15 was
observed in both the B-ALL PB and the B-ALL BM groups
(Figure 8B). Regarding the fold change analysis, it was observed
that B-ALL PB showed a pronounced increase in EV-CD10+CD10+
levels (more than 5 times) (Figures 8C, D). In parallel, the ROC
curve analysis on D0 revealed excellent performance (Se = 100.0%
and Sp = 87.5%) and global accuracy (AUC = 0.984 and p = 0.0011)
to discriminate the B-ALL PB patients from the CG (Figure 8E).
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FIGURE 6
Biological network of extracellular vesicles during induction therapy. Integrative networks were assembled to identify the complex interactions
among EV populations during induction therapy. Colored nodes are used to identify the EVs in the B-ALL PB ( ) and B-ALL BM ( ) groups and in
the control group (CG) ( ), where the larger the node, the greater the number of interactions established. Correlation analysis was employed to
construct integrative networks according to significant “r” scores at p<0.05 using the Spearman correlation test. Connecting edges illustrate the
positive correlations between pairs of attributes, according to the strength of correlation as described in the Materials and Methods section. Different
colored and thickness are used to represent moderate correlations (black fine edges) and strong correlations (dark blue solid edges). Cellular
markers: CD235a (erythrocyte), CD41a (platelet), CD51 (endothelial cell), CD45 (leukocyte), CD66b (neutrophil), CD14 (monocyte), CD3 (T
lymphocyte), CD34 and CD10 (B lymphoblast/Leukemic blast) and CD19 (B lymphocyte/B lymphoblast).
(EV-CD66b+), monocytes (EV-CD14+), T lymphocytes (EV-CD3+)
and B lymphocytes (EV-CD19+).
EVs contained in blood mainly originate from platelets and
erythrocytes and account for about 50% of the total vesicles in
healthy subjects (26). In our data, we detected a decrease in EVCD41a+ levels in the B-ALL PB group compared to the control
group (Figure 2), which reflects the intense thrombocytopenia
observed in the blood count on D0 (Table 2). However, on D35,
there was an increase in EV-CD41a+, indicating recovery of
thrombopoiesis with increased platelet production (Figure 3). In
the context of solid tumors, platelets are reported to play a role in
the mechanisms by which cancer cells can accelerate their growth
rate and evade the immune system (27–29). However, studies
investigating the role of platelets in hematological malignancies
are scarce (30–32). From a therapeutic point of view, it is considered
that platelet count can be used as a parameter for prognostic
assessment of ALL patients during and after induction therapy
(33, 34). These questions highlight the need for in-depth
investigations into the interactions of EV-CD41a+ with leukemic
blasts, as well as its use as a biomarker related to thrombopoiesis or
recovery of normal hematopoiesis.
Discussion
Growing evidence shows that the bone marrow (BM)
microenvironment plays a crucial role in the survival of leukemic
blasts and that communication between these cancer cells and
surrounding cells can be mediated by various soluble immune
molecules such as cytokines, chemokines and growth factors (5, 8,
9). Much like what occurs in other signaling molecules, recent
advances in cancer biology have revealed that EVs are released in
large quantities by cancer cells. These EVs act as key mediators in
cell communication, carrying bioactive loads capable of
reprogramming stromal and immune cells, thereby creating a
favorable microenvironment for leukemic survival and
progression (11). In this study, we analyzed the profile of
leukemic blast-derived EVs (EV-CD34+/CD10+/CD19+) in the
peripheral blood (PB) and BM plasma of pediatric patients with
B-ALL (B-ALL PB and B-ALL BM, respectively), at diagnosis
baseline (D0) and during induction therapy (D15 and D35). Of
interest, we also analyzed the levels of erythrocyte-derived EVs (EVCD235a+), platelets (EV-CD41a+) and endothelial cells (EV-CD51/
61+), as well as leukocyte-derived EVs (EV-CD45+), neutrophils
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FIGURE 7
Fold change and performance of the extracellular vesicles CD10+ and CD19+ as diagnostic biomarkers of B-ALL. The fold changes (A) and
significance of fold changes (B) were performed in the peripheral blood of the B-ALL patients at the diagnosis baseline as described in the Materials
and Methods section. Receiver operating characteristic (ROC) curve analysis was carried out to assess the performance of EV-CD10+ and EV-CD19+
levels as diagnostic biomarkers for B-ALL (C). ROC curves were assembled to define the cut-off points and calculate the following performance
indices: sensitivity (Se), specificity (Sp), likelihood ratio (LR), the best cut-off point, as well as the area under the curve (AUC) and p-value as indicators
of global accuracy, as described in the Materials and Methods section.
active tissue factor, which is the main initiator of the coagulation
cascade reactions (44, 45).
Not less important, pro-angiogenic effects of EV-ECs were also
reported and considered to be a potential mechanism that leads to
neovascularization (46, 47). One recent study demonstrated that the
secretion of EC-derived EVs containing angiopoietin like 2
(ANGPTL2) played important roles in the development of
murine B-ALL, sustaining leukemogenic activities of leukemic
blasts (16). Collectively, these data indicate that EV-ECs actively
participate in inflammation, coagulation and angiogenesis. This
functional repertoire introduces the possibility of using EV-ECs as
biomarkers and therapeutic targets in cancer; however, the field
remains very obscure and requires further investigations, especially
in the context of acute leukemias.
Regarding markers associated with leukemic blasts, our B-ALL
patients showed an increase in EV-CD10 + and EV-CD19 +
(Figure 2). CD19 is a signal amplifying coreceptor expressed
throughout B-cell development, though not in the mature plasma
cell stage; it is, however, the single best clinical marker for B-cell
identity (48). Instead, CD10, also known as common acute
lymphoblastic leukemia antigen (CALLA), is a type II cell surface
integral membrane protein of the M13 family, which is specifically
The fraction of EVs derived from endothelial cells (EV-ECs)
is relatively low in physiological conditions but is highly
increased in pathologies characterized by endothelial
dysfunction, such as thrombotic thrombocytopenic purpura,
diabetes or hypertension (35). When the release of EVs derives
from activated ECs, their action has been frequently associated
with inflammatory processes and procoagulant states (36, 37).
Our results identified high levels of EV-CD51/61+ on D0 in the
B-ALL PB group when compared to the control group
(Figure 2). These findings are important as they indicate
greater activation of the endothelium in leukemia, which may
be associated with an increased risk of thrombosis. Importantly,
venous thromboembolism is described as a serious and relatively
common condition in pediatric ALL patients (38, 39), and
reported incidences vary from 1.1% to 36.7% (40, 41).
Mechanisms underlying the increased risk are not completely
understood, but studies have shown that besides treatment
components, the malignancy itself can contribute to a
prothrombotic state (42, 43). In this scenario, EV-ECs emerge
as a potential contributor to these events since they are one of
the EV populations with the most pronounced coagulation
activity. This is a feature that is due to the high expression of
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FIGURE 8
Profile, kinetic, fold change and performance of extracellular vesicles CD10+CD19+ as diagnostic biomarkers of B-ALL. The EV-CD10+CD19+ (double) and B-ALL BM (
) groups and
positive) populations were analyzed at the diagnosis baseline (A) and during induction therapy (B) in the B-ALL PB (
). The count and immunophenotypic characterization of EV-CD10+CD19+ was performed using flow cytometry. The
in the control group (CG) (
results are presented using bar and symbol charts, reported in log10 scale, showing the mean with standard error of the absolute number of EVs/mm3 of
plasma. Statistical analyses were performed using the Mann-Whitney test or Wilcoxon matched-pairs signed-rank test and significant differences are
highlighted by asterisks for p<0.001 (***) or p<0.05 (*). The fold changes (C) and significance of fold changes (D) were performed in the peripheral blood
of the B-ALL patients at the diagnosis baseline. Receiver operating characteristic (ROC) curve analysis (E) was carried out to assess the performance of
EV-CD10+CD19+ plasma levels as diagnostic biomarkers for B-ALL. ROC curves were assembled to define the cut-off points and calculate the following
performance indices: sensitivity (Se), specificity (Sp), likelihood ratio (LR), the best cut-off point, as well as the area under the curve (AUC) and p-value as
indicators of global accuracy.
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among the mediators of the different response profiles, suggesting
the recovery of pro-inflammatory response (61).
The most critical issue to be highlighted and evaluated in our
data is whether the EVs originate specifically from leukemic blasts
or from another cellular source, albeit on a smaller scale. This is of
great importance because, if the former is true, then EV-CD10+ and
EV-CD19+ can be qualified as very promising biomarkers of
diagnosis and therapeutic response in ALL. Aiming to answer this
question, the double-positivity of EVs for the CD10+ and CD19+
markers was evaluated. Incredibly, our results demonstrate that, just
like EV-CD10+ and EV-CD19+, the double positive EVs (EVCD10+CD19+) were elevated in B-ALL PB patients at diagnosis,
with a 5-fold magnitude of change in relation to the CG
(Figures 8A–D). However, the ROC curve analysis revealed an
even better clinical performance (AUC = 0.984) in discriminating
B-ALL patients from CG (Figure 8E), compared to isolated EVCD10+ (AUC = 0.860) and EV-CD19+ (AUC = 0,844) (Figure 7),
highlighting the potential of these vesicles as biomarkers.
Although these results appear promising, they still require
further investigation. Such investigations involve a richer analysis
of the protein cargo of EVs, as well as their impact on the leukemic
microenvironment. Although scarce, studies in B-ALL have
demonstrated that EVs derived from leukemic blasts are enriched
in tetraspanins (CD9, CD61 and CD81), adhesion molecules (CD29
and CD1446), in addition to lineage-specific markers (CD10, CD19
and CD22) (17, 62). Furthermore, proteomic analyze revealed that
A Disintegrin and Metalloproteinase 17 (ADAM17) and Autophagy
Related Protein 3 (ATG3) molecules were highly expressed in EVs
derived from plasma of B-ALL patients, being found enriched in the
Notch and autophagy pathways, respectively. In addition, ROC
curve analyzes revealed that ADAM17 and ATG3 showed high
clinical performance (AUC = 0.989 and AUC = 0.956, respectively),
reinforcing that EVs enriched by the proteins may represent
valuable biomarkers in B-ALL (63).
Noteworthy, this study has limitations: i) Since it is a segment
study, in many cases, the sample volume was insufficient to perform
EV assays. This ended up leading to a reduction in the study
population, which compromised the analysis of association with the
clinical prognosis; ii) Another limitation was the non-application of
other methods for evaluation of EVs, as nanoparticle tracking
analysis (NTA), and transmission electron microscopy (TEM) or
scanning electron Microscopy (SEM), which would provide more
accurate data on the size range and diversity of EVs; iii) Finally,
given the absence of an ultracentrifuge, the isolation protocol
applied was not that recommended by the International Society
for Extracellular Vesicles (ISEV) guidelines (64), which could result
in a lower yield in the purification of EVs and imply the co-isolation
of potential contaminants.
However, it is important to highlight that this is a proof-ofconcept study. Additional studies will be carried out to fill the gaps
and correct the limitations left by this study. In this sense, from a
larger study population, we will seek to carry out a richer
characterization, from a phenotypic and protein cargo point of
view, aiming to explore the impact of EVs on the clinical prognosis
of patients with B-ALL undergoing chemotherapy and remission.
expressed in the early stages of the lymphoid progenitor, thus aiding
in the identification of stages in B lymphocyte development (49).
CD10 is widely used to distinguish most cases of ALL from other
hematologic malignancies, and is commonly used in diagnosis via
flow cytometry and monitoring of hematologic malignancies of B
cell origin, in the categorization of the mature and blastic stage, and
also for detection of measurable residual disease (50, 51). Originally
identified in leukemic blasts, CD10 was later detected in cells from
the prostate, kidney, intestine and endometrium (52, 53). The
presence of CD10 in other cells suggests a varied role that is not
specifically restricted to hematologic malignancies. Biologically, its
main function is to metabolize polypeptides through peptide
cleavage between hydrophobic residues, leading to the
inactivation of a variety of physiologically active neuropeptides (54).
In the context of cancer, CD10 activity and its high expression
has been correlated with a poor prognosis and decreased survival in
a variety of malignancies, through mechanisms that include
therapeutic drug and radiation resistance, increased tumor grade
and a more aggressive phenotype (invasion and metastasis) (54–
60). In the ontogeny of B lymphocytes, CD10, present in pre-B
lymphocytes, is transiently expressed during different stages of
maturation and disappears in mature B lymphocytes. In this
sense, by evaluating the kinetics during induction therapy, it was
possible to observe a clear decline in the EV-CD10+ levels in B-ALL
PB and B-ALL BM on D35. In parallel, a decline in EV-CD19+ was
observed in B-ALL PB; while, in B-ALL BM, a distinct behavior was
observed, with a decrease on D15 followed by an increase on D35
(Figure 3). In a similar way, the EV signature during induction
therapy demonstrated that, on D0, a greater proportion of B-ALL
patients exhibited high production of EV-CD10+ and EV-CD19+, in
contrast to on D35 (Figure 5). Collectively, these findings may be
indicative of the elimination or meaningful decrease of leukemic
blasts on D35, with subsequent production of mature B
lymphocytes and EV-CD19+ (mature B lymphocyte-derived EVs)
in the medullary compartment.
The signature analysis also demonstrated important changes in
the other EV populations during induction therapy. Where on D0,
B-ALL PB presented a higher proportion of high-producers of EVs,
followed by a decline on D15 and D35, on the other hand, B-ALL
BM presented a lower proportion of high-producers of EVs on D0,
followed by an increase on D15 and D35 (Figure 5). Interestingly,
the analysis of the integrative network of EVs also exhibited notable
changes during treatment, but with a distinct behavior. On D0, BALL PB patients exhibited a network of EVs that was characterized
by a limited number of interactions. However, on D35, a network
more like that of the control group was observed. This network was
characterized by an increase of connections among EV populations,
with emphasis on EVs derived from leukocytes (CD45+, CD66+,
CD14+ and CD3+). In parallel, B-ALL BM presented a profile
similar to that of B-ALL PB, but with a greater number of
interactions, which can be explained by the greater complexity of
the medullary microenvironment (Figure 6). Similar behavior was
observed in a previous study, where on D35, the B-ALL patients
exhibited a network of cytokines characterized by an increase of
multiple connections. This was composed of greater interactions
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Conclusion
Investigation, Methodology, Writing – original draft, Validation.
MC: Investigation, Methodology, Supervision, Writing – original
draft. AT: Investigation, Methodology, Project administration,
Writing – original draft. GS: Conceptualization, Formal analysis,
Funding acquisition, Writing – review & editing, Data curation.
OM-F: Conceptualization, Data curation, Formal analysis, Writing
– review & editing, Funding acquisition, Writing – original draft.
AM: Formal analysis, Funding acquisition, Methodology,
Supervision, Writing – original draft. AT-C: Conceptualization,
Data curation, Formal analysis, Funding acquisition, Writing –
original draft, Writing – review & editing. AC: Conceptualization,
Formal analysis, Funding acquisition, Supervision, Writing –
original draft, Writing – review & editing.
Our data demonstrated that: (i) The B-ALL patients exhibited a
decrease in EV-CD41a+ on D0 that is followed by a progressive
increase on D15 and D35, indicating recovery of thrombopoiesis;
(ii) The B-ALL patients showed a marked production of EV-CD51/
61+, indicating greater activation of ECs; (iii) In our cohort, CD10
and CD19 were the most expressed markers in the leukemic blasts;
(iv) EV-CD10+ and EV-CD19+ showed predominance in the
Megamix beads size range of 100-200 nm, configuring them as
“small vesicles”; (v) The B-ALL patients exhibited dynamic EV
kinetics and signatures during induction therapy, exhibiting distinct
profiles on D0 and D35; (vi) The B-ALL patients showed a marked
increase in the number of connections on D35, displaying a
biological network that was more similar to that of the control
group; (vii) EV-CD10 + CD19 + (double-positives) were also
increased and exhibited excellent clinical performance and
general accuracy for discriminating the B-ALL patients from the
CG, and are possibly associated with unfavorable outcomes.
Finally, our data indicate that EVs represent a potential field of
investigation in ALL. Future studies should explore the cargos
carried by EVs-CD10 + CD19 + , how it affects the leukemic
microenvironment and, ultimately, its potential as a combined
diagnostic and prognostic biomarker for B-ALL. If successful,
leukemic EVs could become a valuable liquid biopsy tool,
allowing the real-time monitoring of malignancy progression.
Funding
The author(s) declare financial support was received for the
research, authorship, and/or publication of this article. Financial
support was provided in the form of grants from Fundação de
Amparo à Pesquisa do Estado do Amazonas (FAPEAM) (Pró Estado Program - #002/2008, #007/2018, #005/2019 and POSGRAD
Program #002/2023 and #002/2024), Conselho Nacional de
Desenvolvimento Cientı́ fi co e Tecnoló gico (CNPq) and
Coordenação de Aperfeiçoamento de Pessoal de Nı́vel Superior
(CAPES) (PROCAD-Amazô nia 2018 Program - #88881.200581/
2018-01 and PDPG-CONSOLIDACAO-3-4 Program
#88887.707248/2022-00). FM-G, MM, JN, NA, MK, and FA-H have
fellowships from FAPEAM, CAPES and CNPq (Masters and PhD
student fellowships). OM-F is a level 1 research fellow from CNPq and
a research fellow from the program supported by the Universidade do
Estado do Amazonas (PROVISIT No. 005/2023-PROPESP/UEA).
AT-C and AC are a level 2 research fellow from CNPq. The
funders made no contribution to the study’s design, data collection
and analysis, decision to publish or preparation of the manuscript.
Data availability statement
The original contributions presented in the study are included
in the article/Supplementary Material. Further inquiries can be
directed to the corresponding author.
Ethics statement
Acknowledgments
This study was submitted to and approved by the Ethics
Committee at Fundaç ão Hospitalar de Hematologia e
Hemoterapia do Amazonas (HEMOAM), under protocol
registration number #739.563. The studies were conducted in
accordance with the local legislation and institutional
requirements. Written informed consent for participation in this
study was provided by the participants’ legal guardians/next of kin.
The authors thank the Diretoria de Ensino e Pesquisa at
Fundaç ã o HEMOAM and Programa de Desenvolvimento
Tecnoló gico em Insumos para Saú de da FIOCRUZ (PDTISFIOCRUZ) for the use of their facilities. We are also grateful to the
patients and controls who participated in the study, as well as their
parents or legal guardians for allowing participation. Finally, we
thank the Grupo Integrado de Pesquisas em Biomarcadores of the
Instituto René Rachou, Fundação Oswaldo Cruz (FIOCRUZ-Minas),
for the excellent technical assistance and support with the trials.
Author contributions
FM-G: Conceptualization, Formal analysis, Investigation,
Methodology, Writing – original draft, Writing – review &
editing. MM: Investigation, Methodology, Writing – original
draft. JN: Formal analysis, Writing – original draft, Investigation,
Methodology. NA: Formal analysis, Investigation, Methodology,
Writing – original draft. FA-H: Formal analysis, Investigation,
Methodology, Writing – original draft, Supervision. MK:
Frontiers in Immunology
Conflict of interest
The authors declare that the research was conducted in the
absence of any commercial or financial relationships that could be
construed as a potential conflict of interest.
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SUPPLEMENTARY FIGURE 1
Publisher’s note
Analysis of strategies for the phenotypic characterization of EVs using
flow cytometry.
All claims expressed in this article are solely those of the
authors and do not necessarily represent those of their affiliated
organizations, or those of the publisher, the editors and the
reviewers. Any product that may be evaluated in this article, or
claim that may be made by its manufacturer, is not guaranteed or
endorsed by the publisher.
SUPPLEMENTARY FIGURE 2
Analysis of strategies for the phenotypic characterization of EVs using flow
cytometry according to size range.
SUPPLEMENTARY FIGURE 3
Fold change and performance of the extracellular vesicles CD41a+ and CD51/
61+ as diagnostic biomarkers of B-ALL. The fold changes (A) and significance
of fold changes (B) were performed in the peripheral blood of the B-ALL
patients at the diagnosis baseline as described in the Materials and Methods
section. Receiver operating characteristic (ROC) curve analysis was carried
out to assess the performance of EV-CD41a+ and EV-CD51/61+ levels as
diagnostic biomarkers for B-ALL (C). ROC curves were assembled to define
the cut-off points and calculate the following performance indices: sensitivity
(Se), specificity (Sp), likelihood ratio (LR), the best cut-off point, as well as the
area under the curve (AUC) and p-value as indicators of global accuracy, as
described in the Materials and Methods section.
Supplementary material
The Supplementary Material for this article can be found online
at: https://www.frontiersin.org/articles/10.3389/fimmu.2024.1421036/
full#supplementary-material
References
1. Carroll WL, Bhojwani D, Min DJ, Raetz E, Relling M, Davies S, et al. Pediatric
acute lymphoblastic leukemia. Hematol Am Soc Hematol Educ Progr. (2003) 2003:102–
31. doi: 10.1182/asheducation-2003.1.102
leukemia as a growth factor on bone marrow mesenchymal stromal cells. Mol Biol Rep.
(2024) 51:749. doi: 10.1007/s11033-024-09674-4
2. Terwilliger T, Abdul-Hay M. Acute lymphoblastic leukemia: a comprehensive
review and 2017 update. Blood Cancer J. (2017) 7:e577. doi: 10.1038/bcj.2017.53
18. Yu H, Huang T, Wang D, Chen L, Lan X, Liu X, et al. Acute lymphoblastic
leukemia-derived exosome inhibits cytotoxicity of natural killer cells by TGF-b
signaling pathway. 3 Biotech. (2021) 11:313. doi: 10.1007/s13205-021-02817-5
3. Vinay DS, Ryan EP, Pawelec G, Talib WH, Stagg J, Elkord E, et al. Immune
evasion in cancer: Mechanistic basis and therapeutic strategies. Semin Cancer Biol.
(2015) 35:S185–98. doi: 10.1016/j.semcancer.2015.03.004
19. Gholipour E, Kahroba H, Soltani N, Samadi P, Sarvarian P, Vakili-Samiani S, et al.
Paediatric pre-B acute lymphoblastic leukaemia-derived exosomes regulate immune function
in human T cells. J Cell Mol Med. (2022) 26:4566–76. doi: 10.1111/jcmm.17482
4. Emon B, Bauer J, Jain Y, Jung B, Saif T. Biophysics of tumor microenvironment
and cancer metastasis - A mini review. Comput Struct Biotechnol J. (2018) 16:279–87.
doi: 10.1016/j.csbj.2018.07.003
20. Srivastava A, Rathore S, Munshi A, Ramesh R. Extracellular vesicles in oncology:
from immune suppression to immunotherapy. AAPS J. (2021) 23:30. doi: 10.1208/
s12248-021-00554-4
5. Chiarini F, Lonetti A, Evangelisti C, Buontempo F, Orsini E, Evangelisti C, et al.
Advances in understanding the acute lymphoblastic leukemia bone marrow
microenvironment: From biology to therapeutic targeting. Biochim Biophys Acta Mol Cell Res. (2016) 1863:449–63. doi: 10.1016/j.bbamcr.2015.08.015
21. World Health Organization (WHO). World health organization classification of
tumours of haematopoietic and lymphoid tissues. (2016).
6. Tabe Y, Konopleva M. Advances in understanding the leukaemia
microenvironment. Br J Haematol. (2014) 164:767–78. doi: 10.1111/bjh.12725
23. Kerr MWA, Magalhães-Gama F, Ibiapina HNS, Hanna FSA, Xabregas LA, Alves
EB, et al. Bone marrow soluble immunological mediators as clinical prognosis
biomarkers in B-cell acute lymphoblastic leukemia patients undergoing induction
therapy. Front Oncol. (2021) 11:3631. doi: 10.3389/fonc.2021.696032
22. Sociedade Brasileira de Oncologia Pediá trica. Protocolo brasileiro de tratamento
da leucemia linfó ide aguda na infâ ncia GBTLI LLA-2009. (2011).
7. Burkholder B, Huang RY, Burgess R, Luo S, Jones VS, Zhang W, et al. Tumorinduced perturbations of cytokines and immune cell networks. Biochim Biophys Acta Rev Cancer. (2014) 1845:182–201. doi: 10.1016/j.bbcan.2014.01.004
24. Taylor R. Interpretation of the correlation coefficient: A basic review. J Diagn
Med Sonogr. (1990) 6:35–9. doi: 10.1177/875647939000600106
8. Sheu BC. Cytokine regulation networks in the cancer microenvironment. Front
Biosci. (2008) 13):6255. doi: 10.2741/3152
25. Swets JA. Measuring the accuracy of diagnostic systems. Sci (80- ). (1988)
240:1285–93. doi: 10.1126/science.3287615
9. Nagarsheth N, Wicha MS, Zou W. Chemokines in the cancer microenvironment
and their relevance in cancer immunotherapy. Nat Rev Immunol. (2017) 17:559–72.
doi: 10.1038/nri.2017.49
10. Meldolesi J. Exosomes and ectosomes in intercellular communication. Curr Biol.
(2018) 28:R435–44. doi: 10.1016/j.cub.2018.01.059
26. Arraud N, Linares R, Tan S, Gounou C, Pasquet J-M, Mornet S, et al.
Extracellular vesicles from blood plasma: determination of their morphology, size,
phenotype and concentration. J Thromb Haemost. (2014) 12:614–27. doi: 10.1111/
jth.12554
11. Pando A, Reagan JL, Quesenberry P, Fast LD. Extracellular vesicles in leukemia.
Leuk Res. (2018) 64:52–60. doi: 10.1016/j.leukres.2017.11.011
27. Goubran HA, Stakiw J, Radosevic M, Burnouf T. Platelets effects on tumor
growth. Semin Oncol. (2014) 41:359–69. doi: 10.1053/j.seminoncol.2014.04.006
28. Catani MV, Savini I, Tullio V, Gasperi V. The “Janus face” of platelets in cancer.
Int J Mol Sci. (2020) 21:788. doi: 10.3390/ijms21030788
12. Martins VR, Dias MS, Hainaut P. Tumor-cell-derived microvesicles as carriers of
molecular information in cancer. Curr Opin Oncol. (2013) 25:66–75. doi: 10.1097/
CCO.0b013e32835b7c81
29. Schmied L, Höglund P, Meinke S. Platelet-mediated protection of cancer cells
from immune surveillance – possible implications for cancer immunotherapy. Front
Immunol. (2021) 12:640578/full. doi: 10.3389/fimmu.2021.640578/full
13. Skog J, Würdinger T, van Rijn S, Meijer DH, Gainche L, Curry WT, et al.
Glioblastoma microvesicles transport RNA and proteins that promote tumour growth
and provide diagnostic biomarkers. Nat Cell Biol. (2008) 10:1470–6. doi: 10.1038/
ncb1800
30. Zhang L, Liu J, Qin X, Liu W. Platelet–acute leukemia interactions. Clin Chim
Acta. (2022) 536:29–38. doi: 10.1016/j.cca.2022.09.015
14. Lee Y, Andaloussi S EL, Wood MJA. Exosomes and microvesicles: extracellular
vesicles for genetic information transfer and gene therapy. Hum Mol Genet. (2012) 21:
R125–34. doi: 10.1093/hmg/dds317
31. Yan M, Jurasz P. The role of platelets in the tumor microenvironment: From
solid tumors to leukemia. Biochim Biophys Acta - Mol Cell Res. (2016) 1863:392–400.
doi: 10.1016/j.bbamcr.2015.07.008
15. Georgievski A, Michel A, Thomas C, Mlamla Z, Pais de Barros JP, Lemaire-Ewing S,
et al. Acute lymphoblastic leukemia-derived extracellular vesicles affect quiescence of
hematopoietic stem and progenitor cells. Cell Death Dis. (2022) 13:337. doi: 10.1038/
s41419-022-04761-5
32. Li Y, Wang S, Xiao H, Lu F, Zhang B, Zhou T. Evaluation and validation of the
prognostic value of platelet indices in patients with leukemia. Clin Exp Med. (2023)
23:1835–44. doi: 10.1007/s10238-022-00985-z
33. Lee JW, Cho B. Prognostic factors and treatment of pediatric acute lymphoblastic
leukemia. Korean J Pediatr. (2017) 60:129. doi: 10.3345/kjp.2017.60.5.129
16. Huang D, Yuan Y, Cao L, Zhang D, Jiang Y, Zhang Y, et al. Endothelial-derived
small extracellular vesicles support B-cell acute lymphoblastic leukemia development.
Cell Oncol. (2023) 47:129–40. doi: 10.1007/s13402-023-00855-0
34. Dai Q, Shi R, Zhang G, Yang H, Wang Y, Ye L, et al. Combined use of peripheral
blood blast count and platelet count during and after induction therapy to predict
prognosis in children with acute lymphoblastic leukemia. Med (Baltimore). (2021) 100:
e25548. doi: 10.1097/MD.0000000000025548
17. Amirpour M, Kuhestani-Dehaghi B, Kheyrandish S, Hajipirloo LK, Khaffafpour
Z, Keshavarz F, et al. The impact of exosomes derived from B-cell acute lymphoblastic
Frontiers in Immunology
15
frontiersin.org
�Magalhães-Gama et al.
10.3389/fimmu.2024.1421036
50. Borowitz MJ, Devidas M, Hunger SP, Bowman WP, Carroll AJ, Carroll WL, et al.
Clinical significance of minimal residual disease in childhood acute lymphoblastic
leukemia and its relationship to other prognostic factors: a Children’s Oncology Group
study. Blood. (2008) 111:5477–85. doi: 10.1182/blood-2008-01-132837
35. Desideri E, Ciccarone F, Ciriolo MR, Fratantonio D. Extracellular vesicles in
endothelial cells: from mediators of cell-to-cell communication to cargo delivery tools.
Free Radic Biol Med. (2021) 172:508–20. doi: 10.1016/j.freeradbiomed.2021.06.030
36. Brodsky SV, Malinowski K, Golightly M, Jesty J, Goligorsky MS. Plasminogen
activator inhibitor-1 promotes formation of endothelial microparticles with procoagulant
potential. Circulation. (2002) 106:2372–8. doi: 10.1161/01.CIR.0000033972.90653.AF
37. Abid Hussein MN, Böing AN, Biró É , Hoek FJ, Vogel GMT, Meuleman DG, et al.
Phospholipid composition of in vitro endothelial microparticles and their in vivo
thrombogenic properties. Thromb Res. (2008) 121:865–71. doi: 10.1016/j.thromres.2007.08.005
51. Cherian S, Hedley BD, Keeney M. Common flow cytometry pitfalls in diagnostic
hematopathology. Cytom Part B Clin Cytom. (2019) 96:449–63. doi: 10.1002/
cyto.b.21854
52. Greaves MF, Brown G, Rapson NT, Lister TA. Antisera to acute lymphoblastic
leukemia cells. Clin Immunol Immunopathol. (1975) 4:67–84. doi: 10.1016/0090-1229
(75)90041-0
38. Schmiegelow K, Attarbaschi A, Barzilai S, Escherich G, Frandsen TL, Halsey C,
et al. Consensus definitions of 14 severe acute toxic effects for childhood lymphoblastic
leukaemia treatment: a Delphi consensus. Lancet Oncol. (2016) 17:e231–9.
doi: 10.1016/S1470-2045(16)30035-3
53. Ritz J, Pesando JM, Notis-McConarty J, Lazarus H, Schlossman SF. A
monoclonal antibody to human acute lymphoblastic leukaemia antigen. Nature.
(1980) 283:583–5. doi: 10.1038/283583a0
39. Klaassen ILM, Lauw MN, Fiocco M, van der Sluis IM, Pieters R, Middeldorp S,
et al. Venous thromboembolism in a large cohort of children with acute lymphoblastic
leukemia: Risk factors and effect on prognosis. Res Pract Thromb Haemost. (2019)
3:234–41. doi: 10.1002/rth2.12182
54. Shipp MA, Tarr GE, Chen CY, Switzer SN, Hersh LB, Stein H, et al. CD10/
neutral endopeptidase 24.11 hydrolyzes bombesin-like peptides and regulates the
growth of small cell carcinomas of the lung. Proc Natl Acad Sci. (1991) 88:10662–6.
doi: 10.1073/pnas.88.23.10662
40. Caruso V, Iacoviello L, Di Castelnuovo A, Storti S, Mariani G, de Gaetano G,
et al. Thrombotic complications in childhood acute lymphoblastic leukemia: a metaanalysis of 17 prospective studies comprising 1752 pediatric patients. Blood. (2006)
108:2216–22. doi: 10.1182/blood-2006-04-015511
55. Fukusumi T, Ishii H, Konno M, Yasui T, Nakahara S, Takenaka Y, et al. CD10
as a novel marker of therapeutic resistance and cancer stem cells in head and
neck squamous cell carcinoma. Br J Cancer. (2014) 111:506–14. doi: 10.1038/
bjc.2014.289
41. Athale UH, Chan AK. Thrombosis in children with acute lymphoblastic
leukemia. Thromb Res. (2003) 111:125–31. doi: 10.1016/j.thromres.2003.10.013
56. Jang TJ, Park JB, Lee JI. The expression of CD10 and CD15 is progressively
increased during colorectal cancer development. Korean J Pathol. (2013) 47:340.
doi: 10.4132/KoreanJPathol.2013.47.4.340
42. Appel IM, Hop WCJ, van Kessel-Bakvis C, Stigter R, Pieters R. L-Asparaginase
and the effect of age on coagulation and fibrinolysis in childhood acute lymphoblastic
leukemia. Thromb Haemost. (2008) 100:330–7.
57. Jana S, Jha B, Patel C, Jana D, Agarwal A. CD10-A new prognostic stromal
marker in breast carcinoma, its utility, limitations and role in breast cancer
pathogenesis. Indian J Pathol Microbiol. (2014) 57:530. doi: 10.4103/0377-4929.142639
43. Nowak-Göttl U, Kenet G, Mitchell LG. Thrombosis in childhood acute lymphoblastic
leukaemia: epidemiology, aetiology, diagnosis, prevention and treatment. Best Pract Res Clin
Haematol. (2009) 22:103–14. doi: 10.1016/j.beha.2009.01.003
58. Sasaki T, Kuniyasu H, Luo Y, Fujiwara R, Kitayoshi M, Tanabe E, et al. Serum
CD10 is associated with liver metastasis in colorectal cancer. J Surg Res. (2014)
192:390–4. doi: 10.1016/j.jss.2014.05.071
44. Antonova OA, Yakushkin VV, Mazurov AV. Coagulation activity of membrane
microparticles. Biochem (Moscow) Suppl Ser A Membr Cell Biol. (2019) 13:169–86.
doi: 10.1134/S1990747819030036
59. Dall’Era MA, True LD, Siegel AF, Porter MP, Sherertz TM, Liu AY. Differential
expression of CD10 in prostate cancer and its clinical implication. BMC Urol. (2007)
7:3. doi: 10.1186/1471-2490-7-3
45. Tripisciano C, Weiss R, Eichhorn T, Spittler A, Heuser T, Fischer MB, et al.
Different potential of extracellular vesicles to support thrombin generation:
contributions of phosphatidylserine, tissue factor, and cellular origin. Sci Rep. (2017)
7:6522. doi: 10.1038/s41598-017-03262-2
60. Tse GMK. Stromal CD10 expression in mammary fibroadenomas and phyllodes
tumours. J Clin Pathol. (2005) 58:185–9. doi: 10.1136/jcp.2004.020917
61. Magalhães-Gama F, Kerr MWA, de Araú jo ND, Ibiapina HNS, Neves JCF,
Hanna FSA, et al. Imbalance of chemokines and cytokines in the bone marrow
microenvironment of children with B-cell acute lymphoblastic leukemia. J Oncol.
(2021) 2021:1–9. doi: 10.1155/2021/5530650
46. Deregibus MC, Cantaluppi V, Calogero R, Lo Iacono M, Tetta C, Biancone L,
et al. Endothelial progenitor cell–derived microvesicles activate an angiogenic program
in endothelial cells by a horizontal transfer of mRNA. Blood. (2007) 110:2440–8.
doi: 10.1182/blood-2007-03-078709
62. Miljkovic-Licina M, Arraud N, Zahra AD, Ropraz P, Matthes T. Quantification
and phenotypic characterization of extracellular vesicles from patients with acute
myeloid and B-cell lymphoblastic leukemia. Cancers (Basel). (2021) 14:56. doi: 10.3390/
cancers14010056
47. Lacroix R, Sabatier F, Mialhe A, Basire A, Pannell R, Borghi H, et al. Activation
of plasminogen into plasmin at the surface of endothelial microparticles: a mechanism
that modulates angiogenic properties of endothelial progenitor cells in vitro. Blood.
(2007) 110:2432–9. doi: 10.1182/blood-2007-02-069997
63. Zhu S, Xing C, Li R, Cheng Z, Deng M, Luo Y, et al. Proteomic profiling of
plasma exosomes from patients with B-cell acute lymphoblastic leukemia. Sci Rep.
(2022) 12:11975. doi: 10.1038/s41598-022-16282-4
48. Mei HE, Wirries I, Frölich D, Brisslert M, Giesecke C, Grün JR, et al. A unique
population of IgG-expressing plasma cells lacking CD19 is enriched in human bone
marrow. Blood. (2015) 125:1739–48. doi: 10.1182/blood-2014-02-555169
64. Welsh JA, Goberdhan DCI, O’Driscoll L, Buzas EI, Blenkiron C, Bussolati B,
et al. Minimal information for studies of extracellular vesicles (MISEV2023): From
basic to advanced approaches. J Extracell Vesicles. (2024) 13. doi: 10.1002/jev2.12404
49. Vale AM, Schroeder HW. Clinical consequences of defects in B-cell development.
J Allergy Clin Immunol. (2010) 125:778–87. doi: 10.1016/j.jaci.2010.02.018
Frontiers in Immunology
16
frontiersin.org
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