ARTICLE

Journal of Circulating Biomarkers

Identification of Immunoreactive Tumour
Antigens Using Free and Exosome-
Associated Humoral Responses
Original Research Article

Carolyn D. Roberson1, Cicek Gercel-Taylor2, Ying Qi3, Kevin L. Schey3 and Douglas D. Taylor2*

1 Department of Microbiology and Immunology, University of Louisville School of Medicine, Louisville, KY , USA
2 Exosome Sciences, Monmouth Junction, NJ, USA
3 Department of Biochemistry, Mass Spectrometry Research Center, Vanderbilt University, Nashville, TN, USA
*Corresponding author(s) E-mail: douglastaylor@exosomes.org

Received ; Accepted 21 November 2013

 

© 2013 The Author(s). Licensee InTech. This is an open access article distributed under the terms of the Creative Commons Attribution License
(http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the
original work is properly cited.

Abstract

Altered tumour antigens can initiate cellular and humoral
immune responses; however, they often fail to eliminate
tumours. In humans, the presence of cancer is generally
associated with the suppression of T cell activation and
effector responses, characterized as a Th1 to Th2 biased
response. This Th2 response leads to the production of
tumour-reactive antibodies. Further, neoplastic lesions and
biological fluids of cancer patients contain an abundance of
tumour-derived exosomes (TDE) expressing tumour
antigens. Expression of tumour antigens on TDE may
represent an antibody target and serve to block antibody
binding to the tumour, implicating a role for these nano‐
vesicles in tumour survival. In this study, ovarian tumour
cell proteins were separated by two-dimensional electro‐
phoresis (2-DE) and patient-derived antibodies were used
to analyse immunoreactivity. Common immunoreactive
proteins among ovarian cancer patients were identified by
mass spectrometry and six proteins were selected based on
recognition and correlation with cancer pathogenesis. The
identity of these proteins were confirmed by immunoreac‐
tivity of patient-derived antibodies with recombinant
proteins and their presence on in vivo and in vitro-derived

ovarian tumour exosomes was defined. Analysis of the
TDE demonstrated bound tumour-reactive immunoglobu‐
lins, exhibiting immunoreactivity with specific antigens,
suggesting that patient-derived antibodies recognize
tumour antigens on circulating exosomes.

Keywords Autoantibodies, Ovarian , Cancer, Exosomes

1. Introduction

In the tumour microenvironment, antigens are functional‐
ly  and/or  structurally  altered  by  overexpression,  muta‐
tion,  aberrant  degradation  or  post-translational
modification  that  makes  them  immunogenic  [1].  In  an
effective immune response, these immunogenic proteins are
detected  and  an  antitumour  response  is  promoted  to
eliminate the transformed precursors before they establish
malignancy. Effective elimination is characterized by the
simultaneous  collaboration  of  innate  and  adaptive  cell-
mediated and humoral responses. In the adaptive antitu‐
mour  response,  T  cells  (with  cognate  TCR)  recognize
tumour-associated  antigens  processed/presented  on  the
MHC  of  antigen-presenting  cells  (APC),  along  with
subsequent  costimulation  and  cytokine  expression  for
facilitation and maintenance of the response [2]. Elimina‐

1 



tion of the tumour is accomplished through the activation
of cytotoxic T (CTL) cells to induce tumour cell apoptosis,
activation  of  CD4+T  cells  to  promote  both  cellular  and
humoral responses through stimulation of APC presenta‐
tion of antigens to CTL and activation of B cells to produce
antigen-specific antibodies that enhance tumour cell uptake
by APCs [3,4]. The primary antitumour response is facilitat‐
ed  by  the  cellular  arm  of  the  adaptive  immune  system;
however, humoral responses to tumour antigens are clearly
demonstrated  through  the  production  of  antitumour
antibodies [5,6]. This production of antibodies is present‐
ed as elevated IgG in the blood [7]. In ovarian cancer sera,
levels of tumour reactive-IgG are elevated [8], suggesting
intact humoral immunity in ovarian cancer patients and an
effective humoral antitumour response. However, in the
midst  of  this  IgG-laden  environment,  ovarian  tumours
continue to thrive.

A  key  factor  in  the  progression  of  transformed  cells  to
malignancy is the tumour microenvironment. The tumour
microenvironment consists of a number of cellular partici‐
pants, including immune cells, which are critical for the
suppression of tumour growth [9]. However, the function‐
al  activities  of  these  immune  cells  are  often  counter-
regulated by tumour cell expression and the release of a
number of biologic components, which act to promote the
growth and metastatic progression of the tumour [10]. One
essential biologic component in growth and progression is
the tumour-derived exosome (TDE). Studies indicate that
increased  release  of  exosomes  facilitate  communication
between the tumour's microenvironment and the tumour
cell [11]. TDE express tumour-derived antigens; however,
they  are  not  molecular  duplicates  of  the  plasma  mem‐
brane of their parental tumour cells; rather, they represent
a ‘micromap’ that displays increased expression of anti‐
gens associated with the tumour [12,13]. TDE are abundant‐
ly found in plasma and malignant effusions derived from
cancer patients [14] and their presence and expression of
tumour-related antigens has been documented to contrib‐
ute to tumour progression. Progressive effects mediated by
TDE have been found to range from regulation of tumour
growth  to  invasion,  angiogenesis  and  metastasis  [14,15]
through expression of molecules such as matrix metallopro‐
teinases (MMP-2, MMP-9) and horizontal transfer of growth
factor receptors (EGFRvIII)[16,17]. Additionally, TDE have
been shown to directly and indirectly modulate the evasion
of anti-tumour responses provided by effector T cells for
assisting in progression. Melanoma-derived exosomes have
been shown to promote monocyte production of myeloid-
derived suppressor cells [14], which can act to suppress T-
cell  responses.  Ovarian  TDE  demonstrate  induced
apoptosis of T cells by enhanced expression of Fas L on the
exosomes and CD3zeta suppression on the T cell [18], while
nasopharyngeal  TDE  have  been  shown  to  express  in‐
creased galectin-9 to induce T cell apoptosis via Tim-3 [19].

Since TDE can mediate the progression of the tumour and
its evasion of cellular antitumour responses, they may also
intervene  in  the  humoral  antitumour  response,  thereby
permitting further development of the tumour. Utilizing

these circulating antitumour antibodies to identify immu‐
noreactive antigens may define proteins that are essential to
carcinogenesis [20]. Likewise, analyses of antigens associat‐
ed with TDE may unlock the mysteries of the essential, but
inadequate, humoral response needed for efficient eradica‐
tion  of  the  tumour  and  the  role  of  the  TDE  in  tumour
progression and the humoral response. We hypothesize that
the circulating free and TDE-associated humoral immune
response can be used to identify specific tumour-associat‐
ed antigens, which in the context of TDE may be a mecha‐
nism for diverting the immune response from the tumour.
Using  human  ovarian  cancer  as  our  model  system,  we
investigated  immunoreactivity  of  tumour-associated
antigen of ovarian patient cancer cells, patient in vivo and in
vitro-derived  tumour  exosome  antigens  and  patient-
derived  free  and  exosome-associated  antibodies.  We
established  that  ovarian  tumour-derived  exosomes
expressed  tumour-associated  antigens,  which  are  recog‐
nized by tumour-reactive antibodies, thereby indicating a
role for TDE in the ovarian tumour humoral response.

2. Materials and Methods

2.1 Patient sera, ascites and cell lines

Biofluids (sera or ascites) used in this study were derived
from patients diagnosed with Stage III (T3c) serous
adenocarcinoma (designated UL-124, UL-167, UL-190,
UL-207, UL-351, UL-398), mucinous adenocarcinoma
(UL-324), carcinosarcoma (designated UL-224), teratoma
(designated UL-184) and serous/endometrioid mixed
carcinoma (designated UL-472). Samples were obtained
from the Gynecologic Oncology Repository at the Univer‐
sity of Louisville, under an approved IRB protocol. Addi‐
tional information about ascites sample UL-309 was
unavailable. Control sera were derived from age-matched
women with no evidence of ovarian disease. Primary
ovarian tumour cell cultures were established from UL-124
ascites. Primary cultures were grown in 75 cm2 tissue
culture flasks, initially in Hyclone RPMI 1640 medium
(ThermoScientific, Pittsburgh, PA) supplemented with
2mM L-glutamine, 10% foetal bovine serum (FBS, Biowest),
1mM sodium pyruvate (CellGro, Mediatech, Manassas,
VA), 0.1 mM nonessential amino acids (CellGro, Medi‐
atech) and 100 units/mL penicillin-streptomycin (Gibco,
Life Technologies, Carlsbad, CA) in a humidified incubator
at 37ºC with 5% CO2. Cells were transferred into Ultracul‐
ture General Purpose Serum-Free Media without L-
glutamine, but supplemented with the same amount of
sodium pyruvate, non-essential amino acids and penicillin-
streptomycin. Cell viability was evaluated by trypan blue
exclusion and all cultures utilized were >95% viable.

2.2 Preparation of tumour cell lysates

Prior to the harvesting of cells, culture media was removed
and saved for subsequent culture exosome isolation. Cells
were rinsed twice with cold Hyclone DPBS/Modified

2  



(ThermoScientific) and were solubilized with RIPA Buffer
(1x, Pierce Chemical Co., Rockford IL) supplemented with
protease inhibitor cocktail III (100x, RPI) and phosphatase
inhibitor II (100x, Sigma Chemical Co., St. Louis, MO).
RIPA-solubilized cells were kept on ice for 5-10 minutes
and then cells were collected using a cell scraper. Solubi‐
lized cell lysate was collected into 1.5 mL microcentrifuge
tubes (Eppendorf) and centrifuged at 14,000 x g for 15
minutes at 4ºC to pellet the cell debris. The resulting
supernatant was collected and assayed for total protein by
the Bradford assay (Bio-Rad Laboratories, Herceles, CA)
using bovine serum albumin (BSA) as a standard.

2.3 Isolation of cellular protein by Rotofor fractionation

Cellular lysate was desalted by column chromatography
using P6 Desalting Gel (BioRad Laboratories) and the
resulting protein was assayed by the Bradford method.
Desalted protein concentration was used to determine the
amount of ampholyte to combine with the protein sample.
Desalted protein was combined with 0.5% Bio-Lyte 3/10
Ampholyte (Bio-Rad Laboratories) and ddH2O and loaded
onto the Rotofor Cell (BioRad). Protein was focused for 4 h
using the PowerPacHV under recirculated refrigeration.
Focused proteins were collected into 20 fractions. The pH
and protein concentrations were determined for each
fraction. Each fraction (50µg) was loaded onto a Criterion
Tris HCl 4-15% gel, electrophoretically separated and silver
stained or analysed by western immunoblotting. Mem‐
branes were probed overnight at 4ºC with patient sera
(1:250) followed by peroxidase-conjugated anti-human
IgGAM (1:4000, Sigma Chemical Co). Bound immune
complexes were visualized by ImmunoStar HRP chemilu‐
minescence (BioRad) and the resulting film was analysed
for similarity in reactivity between different sera. Thirteen
bands corresponding to shared immunoreactivity were cut
from of the Rotofor fractionated-silver stained gel and
analysed by mass spectrometry (Vanderbilt University,
Nashville, TN).

2.4 Protein identification by mass spectrometry

Silver-stained  protein  gel  bands were  thoroughly  rinsed
with water to remove residual acetic acid. Fresh reducing
reagents  (30  mM  of  potassium  ferricyanide,  100  mM  of
sodium thiosulfate) in a 1:1 ratio were mixed and immedi‐
ately added in sufficient volume to cover the gel piece. The
gel slice was washed with HPLC-grade H2O and 100 mM of
NH4HCO3, alternatively, until the gel piece was clear. Each
gel slice was diced into small pieces (1 mm2) and placed into
a clean tube, then washed twice with 100 µl (or enough to
cover the gel pieces) of 25 mM NH4HCO3/50% ACN with
vortexing for 10 minutes. The gel pieces were completely
dried by Speedvac. Dried gel pieces were partially rehydrat‐
ed with 5 µl of 100 mM NH4HCO3  and the proteins re‐
duced in 25 µl of 10 mM DTT in 25 mM NH4HCO3 for 1 hr
at  56ºC.  Supernatant  was  removed  and  discarded  and
proteins were alkylated with 25 µl of 55 mM iodoaceta‐

mide in 25 mM NH4HCO3 in the dark for 45 minutes at room
temperature. Gel pieces were washed twice in 100 µl of 100
mM NH4HCO3 (with vortexing for 10 minutes), dehydrat‐
ed  with  100  µl  of  25mM  NH4HCO3  in  50%  ACN  (with
vortexing for 5 minutes, repeated once) and were complete‐
ly dried by Speedvac for 20 minutes. Dried gel pieces were
rehydrated with 5 µl of trypsin solution (0.1 µg/µl trypsin
in 100 mM NH4HCO3) and 50-70 µl of 100 mM NH4HCO3
was added until the gel pieces returned to their original size.
Digestion  was  carried  out  overnight  at  37ºC  and  then
stopped by the addition of 1.5 µl of trifluoroacetic acid. The
resulting  peptides  were  recovered  by  two-25  minute
extractions using 30 µl of 50% ACN/5% formic acid at room
temperature  with  20  minute  vortex/5  minute  sonication
cycles. The extracts were combined and dried in a Speed‐
vac. The tryptic peptides were reconstituted in 25 µl of HPLC
water with 0.1% formic acid.

Digested peptides were separated and mass analysed using
an Eksigent Nano-LC system connected to a LTQ Velos
(Thermo Fisher Scientific) ion trap mass spectrometer.
Briefly, tryptic peptides were loaded onto a 150 µm ID
microcapillary fused silica pre-column, which was in-
house packed with 4 cm ξ 5 µm C18 resin (Jupiter C18, 5µm
particle size, 300Å pore size). The C18 trap column was
coupled to a nanoflow analytical column packed with 10
cm of 3 µm C18 reverse-phase resin (Jupiter C18, 3µm
particle size, 300 Å pore size) constructed with an integrat‐
ed electrospray emitter tip. Peptides were eluted with a 90
minute gradient (from 2%ACN with 0.1% FA to 35% ACN
with 0.1% FA) over 35 minutes, followed by 35% ACN to
90% ACN over 15 minutes at a flow rate of 0.5 µl per minute.
The LTQ Velos mass spectrometer was operated in data-
dependent mode in which an initial MS scan recorded the
mass-to-charge range as 300-2000u and the five most
abundant ions were selected for subsequent collision-
induced dissociation. Dynamic exclusion (repeat count 1,
exclusion list size 150 and exclusion duration 60s) was
enabled to allow for the detection of less abundant ions.

LC-MS/MS raw files were converted into.dta files by a
custom ScanSifter algorithm. Spectra that contained fewer
than 25 peaks or that had less than 2e1 measured total ion
current were removed. DTA files for singly charged
precursor ions were created if 90% of the total ion current
occurred below the precursor ion m/z ratio and all other
spectra were processed for doubly and triply charged ions.
DTA files were searched against the human protein
database Uniprot-human 155_200907_rev with 20,914 total
protein entries using the SEQUEST algorithm. The search
parameters used allowed for the following differential
modifications:+57 on cysteine and+16 on methionine.
SEQUEST-searched files (pepXML) were imported into ID
Picker software for protein assembly. Results were filtered
using the following criteria: a minimum peptide length of
five amino acids, a minimum of one unique peptide per
protein (modifications to cysteines or methionines were not
considered distinct from the unmodified peptides), overall
maximum false positive rate (FDR) of 5%, a minimum of

3Carolyn D. Roberson, Cicek Gercel-Taylor, Ying Qi, Kevin L. Schey and Douglas D. Taylor:
Identification of Immunoreactive Tumour Antigens Using Free and Exosome-Associated Humoral Responses



two additional peptides to establish a unique protein
group, one protein reported per protein group and single
protein groups indicated by proteins that shared the same
set of peptides (indiscernible from each other based on
available data).

2.5 Verification of mass spectrometry-identified ovarian cancer
antigen by immunoprecipitation and immunoblot

To verify the presence of the ovarian cancer antigen
identified by mass spectrometry, immunoprecipitation
was performed using Protein G HP SpinTrap columns (GE
Healthcare, Piscataway, NJ) and True Blot anti-rabbit or
anti-mouse Ig IP Beads (eBioscience, San Diego, CA).
UL-124 cell lysates were preclarified by combining 500µg
lysate proteins with anti-rabbit/anti-mouse Ig IP beads.
Lysate and beads were incubated at 4ºC for 1 hour, centri‐
fuged to obtain the precleared lysate and protein concen‐
trations of clarified lysate determined by the Bradford
method (Bio-Rad Laboratories). For SpinTrap column-
based immunoprecipitation, commercial antibodies
corresponding to the MS-identified antigens were conju‐
gated to the Protein G SpinTrap matrix (20µg protein/
column) for 3-4 hours at room temperature and the
manufacturer’s cross-link protocol was followed. The
antibodies used included GRP-78 (rabbit polyclonal),
annexin 2 (mouse monoclonal), Cathepsin D (mouse
monoclonal), alpha-enolase (mouse monoclonal), HSC 70
(mouse monoclonal) and PDI (mouse monoclonal). All
precipitating antibodies were obtained from Santa Cruz
Biotechnology (SCBT, Santa Cruz, CA). The unbound
antibody was removed and precleared lysate in Tris-
buffered saline (TBS) was added to the immunoaffinity
beads and incubated overnight at 4ºC. Bound antigens were
eluted using 0.1M glycine/urea as an elution buffer and the
fractions were neutralized by addition of 1M Tris base. To
determine the quantity of eluted protein, the Bradford
protein assay was performed. For dot blot analysis, 5µl
(0.5µg) of each antigen sample (in duplicate) were spotted
onto individual nitrocellulose membranes (Bio-Rad
Laboratories) with BSA (1 mg/mL) and HeLa or A431
(epidermoid carcinoma cell line) lysates added as negative
and positive controls, respectively. Membranes were
blocked in 5% nonfat milk/TBST, washed with 1xTBST (TBS
+0.1% Tween-20) and incubated at 4ºC overnight with
corresponding commercial antibodies (diluted 1:1000) and
control or ovarian patient sera (diluted 1:250). Secondary
HRP goat anti-mouse/anti-rabbit (1:5000, Bio-Rad Labora‐
tories) or peroxidase-conjugated anti-human IgGAM
(1:4000, Sigma Chemical Co) was added and immunoreac‐
tivity analysed by Immune Star HRP chemiluminescence
(Bio-Rad Laboratories).

For immunoprecipitation with the TrueBlot immunopreci‐
pitation system (Pierce Chemical Co.), 5 µg of each of the
antibodies listed above were added to the precleared lysate
and incubated for three hours at 4ºC. The incubated
GRP-78/lysate sample was added to the True Blot anti-

rabbit beads, with the remaining Ab/lysate samples added
to the True Blot anti-mouse beads for overnight incubation
at 4ºC. Following this incubation, supernatants were
collected by centrifugation at 10,000xg; beads were washed
3x in a cold NP-40 Lysis Buffer (50 mM Tris HCl, pH 8, 150
mM NaCl, 1% NP-40) and supernatant aspirated, and
beads were combined with 50 µL of 1x Laemmli. The bead
complexes were boiled and centrifuged to collect superna‐
tant containing the immunoprecipitated antigen.

The immunoprecipitated antigen samples were loaded
onto Mini-Protean TGX Precast Gels (4-15%, Bio-Rad
Laboratories), electrophoretically separated and analysed
by western immunoblotting. Membranes were blocked and
probed overnight at 4ºC with corresponding commercial
antibodies, as previously mentioned. Secondary rabbit and
mouse TrueBlot anti-rabbit/anti-mouse IgG HRP (eBio‐
science) were added, followed by analysis of immunoreac‐
tivity using Immune Star HRP chemiluminescence (Bio-
Rad Laboratories).

2.6 Recognition of recombinant proteins by ovarian cancer sera
antibodies

To verify recognition of the mass spectrometry-identified
proteins by ovarian cancer sera, 0.2 µg human recombinant
protein for GRP-78 (ProSpec Bio, East Brunswick, NJ),
annexin 2 (ProSpec Bio), cathepsin D (ProSpec Bio), PDI
(ProSpec Bio), alpha-enolase (American Research Prod‐
ucts, Waltham, MA) and HSC70 (Enzo Life Sciences,
Farmingdale, NY) were combined with 4x LDS nonreduc‐
ing buffer (ThermoScientific), loaded onto a 10% SDS-
PAGE gel and analysed by western immunoblotting using
serum from a non-cancer control (Ctrl, 1:250) and ovarian
cancer patients (samples UL167, UL190, UL207, UL324,
UL351, UL398). All ovarian sera were used at 1:250, with
the exception of the mucinous sample (1:100), based on a
lack of detection at the greater dilution. In addition, as a
positive control, the recombinant proteins were probed
with a mixture of commercial antibodies against the
identified proteins (1:1000) to further ensure detection of
the recombinant antigen.

2.7 Isolation of ovarian tumour exosomes and analysis of tumour-
exosome protein immunoreactivity

Exosomes were isolated from ovarian tumour-patient
(UL-124) ascites and conditioned ovarian tumour culture
media by a two-step chromatographic procedure devel‐
oped in our laboratory [18]. Ascites and media, either
serum-containing or serum-free, (100 mL), were concen‐
trated by ultrafiltration and applied to a 2% agarose
(Agarose Bead Technologies, Tampa, FL) chromatography
column (1.5 x 20 cm) and equilibrated with ddH2O.
Fractions (1 mL) were collected and the elution was
monitored by absorbance at 280 nm. Fractions containing
material greater than 50 million Daltons were obtained and
ultrafiltrated to a concentrate, and the quantity of protein

4  



was assayed using the Bradford method. The biofluid-
derived vesicular proteins (15µg) were mixed with a 1x
Laemmli sample buffer, loaded on a 10% SDS-PAGE gel
and analysed using western immunoblotting. Immunor‐
eactivity of tumour-exosome-derived protein was assayed
by commercial antibodies corresponding to mass spec‐
trometry-identified proteins.

2.8 Isolation of IgG from TDE and analysisof immunoreactivity

1 mL of the UL-124 ascites bound exosome fraction was
combined with 50µL increments of the IgG elution buffer
until a pH of ~3.0 was obtained. The sample was allowed
to incubate with end-over-end rotation for 30 minutes at
room temperature. Post incubation, the sample was added
to a pre-rinsed (1x PBS) Vivaspin 2 centrifugal concentrator
with a membrane MWCO of 1 x 106 (Sartorius Stedim
Biotech, Bohemia, NY). IgG was eluted from the exosomes
by centrifugation (4000 x g, 10-20 min.) and collected from
the filtrate tube. IgG was neutralized using 1M Tris-HCl,
pH 9.0 and protein quantitated using the Bradford method.
0.5µg Human recombinant protein corresponding to the
antigens of interest was loaded onto a Mini PROTEAN TGX
4-15% gel and western immunoblot performed using the
isolated IgG at 1:50 to detect immunoreactivity.

3. Results

3.1 Recognition of ovarian tumour antigens by patient serum
antibodies

Previously, traditional isoelectric focusing of ovarian
tumour antigenic proteins evaluated by silver staining of
IPG SDS-PAGE gels containing focused protein followed
by immunoblotting with serum-derived antibodies from
ovarian carcinosarcoma patient (UL-224) and an ovarian
teratoma patient (UL-184) revealed distinct patterns of
immunoreactivity associated with cancer patients. Subse‐
quently, Rotofor fractionation has been used to fractionate
cellular proteins based on isoelectric focusing. Ovarian
tumour antigenic proteins were initially Rotofor fractio‐
nated, this material was then separated by SDS-PAGE gels
and subsequently immunoblotted with sera from patient
UL-224 (Figure 1a) and UL-184 (Figure 1b) as primary
antibodies. Bands corresponding to shared recognition
(n=13) between sera were subjected to mass spectrometry.
Similar reactivity between patient-derived antibodies to
antigenic proteins was noted with some variation in
intensity (for example, stronger recognition with UL-224:
fraction 12; stronger recognition with UL-184: fraction 9,
lower band).

Figure 1. Shared immunoreactivity of Rotofor-fractionated UL-124 serum-
free lysate with serum of ovarian tumour-patient a) UL-224 (1:250) and b)
UL-184 (1:250). Boxes indicate randomly chosen bands' shared reactivity.
Molecular marker (MM) and Rotofor fraction numbers (1-20) are indicated
above each image. Increasing isoelectric point (pI) is indicated by the arrow
beneath images.

3.2 Identification of ovarian tumour antigens by patient
antibodies

From the 13 selected bands, mass spectrometry analysis
identified six proteins with high confidence: GRP 78
(glucose-related protein 78), annexin 2, cathepsin D, alpha-
enolase, HSC70 and PDI (protein disulfide isomerase).
These were selected for focus due to their protein scores,
their association with tumour survival and their status as a
potential biomarker. In order to verify the presence of these
antigenic proteins in the ovarian cancer lysate sample,
these proteins were isolated from tumour cell lysates by
immunoprecipitation. The proteins of interest were
subjected to western and dot immunoblotting and probing
with commercial antibodies corresponding to the antigens
of interest. For the dot blot assays, captured antigens were
applied to the membrane in duplicate. Immunoreactivity
of precipitated antigen for all antigens of interest was
detected by dot blot (Figure 2A). In some cases, the
presence of specific proteins was verified by western
immunoblotting (Figure 2B); however, some proteins
failed to demonstrate reactivity in western immunoblot‐
ting. This was potentially due to the loss of specific epitopes
through protein reduction and heating.

5Carolyn D. Roberson, Cicek Gercel-Taylor, Ying Qi, Kevin L. Schey and Douglas D. Taylor:
Identification of Immunoreactive Tumour Antigens Using Free and Exosome-Associated Humoral Responses



Figure 2. Representative immunoblots validate the presence of mass
spectrometry antigens of interest using commercial antibodies. UL-124
cellular antigen was immunoprecipitated by a) Protein G HP SpinTrap
columns, applied in duplicate and subjected to dot blot; and b) True Blot IP
beads subjected to western blot (representative immunoreactivity shown).

3.3 Validation of serum antibody detection of mass spectrometry
antigens of interest using corresponding recombinant proteins

Humoral responses detecting GRP 78, annexin 2, cathepsin
D, alpha-enolase, HSC70 and PDI were evaluated by
western immunoblot using recombinant proteins and sera
from patients with serous adenocarcinoma/carcinoma and
mucinous adenocarcinoma. Using patient-derived anti‐
bodies (Figure 3a-e), western immunoblotting identified
the presence of annexin 2, alpha-enolase and HSC70 with
variations in intensities and isoforms between samples.
Preliminary assays for antigen detection by serum revealed
minimal detection of Cathepsin D by the serous samples
tested, with the exception of patient UL-351. Out of the
serous carcinoma samples assayed, patient 351 displayed
lone recognition of the intermediate Cathepsin D isoform
(~46 kDa). Additionally, reactivity to isoforms of HSC70
(~30 kDa) and annexin 2 (~75-90 kDa) were detected to
varying degrees by the serous samples. Mucinous adeno‐
carcinoma patient antibodies (Figure 3f) detected GRP78
and alpha-enolase, and faintly detected the intermediate
form of Cathepsin D (~46 kDa). Additionally, the higher
molecular weight isoform was detected with annexin 2, as
seen in some of the serous samples. A mixture of commer‐
cial antibodies (Figure 3g) corresponding to recombinant
proteins of interest was utilized to detect viability of the
antibodies and their ability to recognize the antigens at
their standard molecular weights. Of the six recombinant
proteins assayed, the commercial antibodies recognized
GRP78, annexin 2 (both isoforms), alpha-enolase and PDI.
Identification of recombinant antigens using serum
antibodies from normal, non-cancer presenting controls

(Figure 3h) similarly recognized alpha-enolase and HSC70
at its standard molecular weight and the lower molecular
weight form.

Figure 3. Representative immunoblot validating ovarian cancer patient
antibody recognition of antigens of interest. Immunoreactivity of human
recombinant protein with human ovarian serum from patients with: a-b)
serous adenocarcinoma; c-d) serous carcinoma; d) mucinous adenocarcino‐
ma; f) commercial Ab mix; g) non-cancer control (Ctrl). Recombinant
proteins indicated as: G78 (GRP78), A2 (annexin 2), A-eno (alpha-enolase),
H70 (HSC70), PDI (protein disulfide isomerase) and CD (Cathepsin D), were
shown with serous sample 351, mucinous sample and control. Ovals
indicate recognition of CD. Boxes indicate recognition of other antigens.
Molecular marker indicated by MM. Initial assays showed no reactivity of
CD with other sera samples.

3.4 Enrichment of ovarian tumour mass spectrometry antigens
of interest in in vivo and in vitro-derived ovarian tumour
exosomes

Previous work conducted by our group demonstrated the
presence of bound immunoglobulins on circulating
exosomes. These exosome-bound antibodies appear to
recognize specific proteins. To determine whether ovarian
tumour-derived exosomes are enriched with the same
antigens identified by mass spectrometry of ovarian
tumour cells, exosomes from UL-124 ascites or cell culture
were probed in western blots with commercial antibodies
against the antigens of interest from the mass spectrometry
analysis. Western immunoblot analysis of ascites-derived
and culture-derived exosomes demonstrated the presence
of GRP 78, alpha-enolase, PDI and varying isoforms of
Cathepsin D (Figure 4).

6  



Figure 4. Analysis of the association of mass spectrometry antigens of
interest with in vivo and in vitro-derived exosomes. Western immunoblots
of UL-124 ascites-derived (ASC), serum-containing (SC) and serum-free (SF)
culture-derived exosomes demonstrating immunoreactivity to commercial
antibodies corresponding to the antigens of interest. Cathepsin D isoforms:
immature (IMM), intermediate (INTM), mature (MAT).

The presence of the Cathepsin D active intermediate
enzyme (~46 kDa) was detected in all samples, while the
immature proenzyme (52-60 kDa) was detected in ascites
and culture media. The active mature form (~33 kDa) was
detected in ascites only. Variation in recognition was seen
between the culture-derived samples, particularly in the
identification of annexin 2 and HSC70 in FBS-containing
vesicles and whose expression was shared in the ascites
sample (Figure 4). Since cells grown in serum-free media
are more sensitive to factors such as pH, temperature,
mechanical stresses, etc., the molecular expression of
specific proteins may have been altered.

3.5 Exosome-bound immunoglobulin reactivity to mass
spectrometry antigens of interest

To examine the ability of exosome-associated IgG to
recognize the antigens of interest, bound-immunoglobu‐
lins were eluted from exosomes isolated from the ascites
fluid of patient UL-124. Recombinant proteins correspond‐
ing to the antigens of interest were subjected to electropho‐

resis and their immunoreactivity was examined with the
isolated exosome-associated antibodies (Figure 5). Exo‐
some-associated immunoglobulins exhibited recognition
of both isoforms of annexin 2, alpha-enolase and HSC70,
with minor recognition of GRP 78.

Figure 5. Recognition of antigens of interest by patient ascites exosome-
associated IgG. Western immunoblot of recombinant proteins’ immunor‐
eactivity to UL-124s ascites exosome-associated IgG. Molecular marker
indicated by MM. Recombinant proteins indicated as in previous figures.

4. Discussion

Cellular proteins present in the tumour microenvironment
can be functionally and/or structurally altered, resulting in
them becoming immunogenic and provoking autoanti‐
body responses. These autoantibodies reflect responses to
tumour-associated (differentially expressed on normal and
cancer cells) antigens and can be detected in the circulation
regardless of the magnitude of tumour-associated antigen
expression or tumour size [21]. As a result of the long-lived
humoral response, the antigen presence is “amplified,”
which facilitates ease of detection. Since autoantibodies act
as sentinels of aberrant cellular activity and their presence
reflects the execution of a humoral immune response to the
tumour, detailed analysis of their immunoreactivity can
provide a clearer understanding of the tumour-associated
antigens that they recognize [22].

Progress in the characterization of human cancers has been
attained through proteomic analyses of cancer-associated
serum proteins. Proteomic analysis involves extensive
characterization of proteins, including identification of any
modifications and interactions, and structural determina‐
tion of isoforms and related functional components.
Traditional approaches to quantitative analysis of pro‐
teomes involve high resolution separation of the proteins
(by size and charge) using 2DE, accompanied by identifi‐

7Carolyn D. Roberson, Cicek Gercel-Taylor, Ying Qi, Kevin L. Schey and Douglas D. Taylor:
Identification of Immunoreactive Tumour Antigens Using Free and Exosome-Associated Humoral Responses



cation of the resolved proteins using mass spectrometry
(MS) [23]. Protein profiles from such analyses can reveal
differential protein expression between samples, which
may denote key molecules that are critical to protein
function.

In this investigation of ovarian cancer patients' humoral
antitumour responses, we used patient serum autoanti‐
bodies for the detection of ovarian-cancer-specific-antigen‐
ic proteins. Proteomic analysis allowed for the
identification of numerous proteins with shared recogni‐
tion: six of particular interest (GRP78, annexin 2, Cathepsin
D, alpha-enolase, HSC70 and PDI), due to their roles in
tumour survival and as potential biomarkers for different
cancers. In this instance, the identities of these antigenic
proteins were confirmed by western immunoblotting and
dot immunoblotting of immunoprecipitated ovarian
tumour cell-derived proteins, using commercial antibodies
against these proteins. One concern in this study was the
effects of denaturation on the ability of the antigenic protein
to be recognized by our commercial antibodies. Hence, we
utilized both western and dot immunoblot analysis to
reduce the likelihood of “overlooking” the detection of the
antigens. As expected, there was variability in detection of
annexin 2, HSC70, and PDI between western and dot blot
analysis. Dot blot analysis revealed detection of all anti‐
gens, while western blot resulted in definitive detection of
GRP 78, Cathepsin D and alpha-enolase.

GRP78, a member of the heat shock protein 70 family, is a
chaperone protein commonly housed in the lumen of the
endoplasmic reticulum, but is also expressed on the cell
surface in various cancers [24]. Cell-surface expression of
GRP78 in cancer cells has been shown to activate pathways
that induce cellular survival and proliferation [24], and to
correlate with the expression of circulating autoantibodies
in prostate [25] and ovarian [26] cancers. Previous studies
of circulating ovarian cancer sera autoantibodies by this lab
demonstrated recognition of GRP78 and Cathepsin D
(immature proenzyme form and mature form) in ovarian
cancer patients. In this study, immunoprecipitated antigen
probed with commercial antibodies revealed bands ~75
kDa (corresponding to GRP78), ~48 kDa (corresponding to
the intermediate form of Cathepsin D) and ~47 kDa
(corresponding to alpha-enolase). Cathepsin D is an
aspartic lysosomal peptidase present in normal cells, but its
overexpression has been reported in a number of cancers
[27]. Functionally, it is believed to act on tumour growth
and metastasis by assisting with stromal remodelling.
Processing of the single polypeptide immature (pro) form
(52 kDa) of Cathepsin D involves removal of the pro-
peptide to form the active intermediate isoform (48 kDa)
and eventual formation of the double-chained mature
isoform (34 kDa heavy chain, 14 kDa light chain). Alpha-
enolase is a glycolytic enzyme important in the catalysis of
2-phospho-D-glycerate (PGA) to phosphoenolpyruvate
[28], and is upregulated under stressful conditions, like
hypoxia, in order to mediate enhanced anaerobic metabo‐

lism. Increased autoantibodies against alpha-enolase have
been recorded in some cases of organ-specific autoimmun‐
ity [29] and in a number of metastatic cell lines. This study
indicates strong recognition of immunoprecipitated
ovarian cancer antigens by commercial anti-Cathepsin D
and alpha-enolase antibodies. Consistent recognition of
human recombinant alpha-enolase by serous adenocarci‐
noma/carcinoma and mucinous adenocarcinoma serum
antibodies was seen, with variation in Cathepsin D and
GRP78 recognition between sera types. Additionally,
recombinant alpha-enolase also appeared to be weakly
recognized by non-cancer controls. GRP78 and alpha-
enolase were also detected in all 3 exosome samples, with
detection of all 3 isotypes of Cathepsin D among the
exosome samples. Exosome-associated antibodies also
recognized alpha-enolase with faint detection of GRP78.
Our data suggests that GRP78, Cathepsin D and alpha-
enolase are tumour-associated antigens that are transport‐
ed to the released exosome and elicit a humoral response,
indicated by the presence of antibodies to these molecules.

Annexins are calcium-binding proteins with functions
ranging from trafficking of vesicles, to apoptosis and
regulation of cellular growth [29]. Annexin 2, a key
mediator in the plasminogen activator system, has been
shown to be important in clot dissolution and wound
healing, and integral to cancer progression. Located on the
surface of endothelial cells and various tumour cells,
annexin 2 can exist as a monomer (~36 kDa) or a heterote‐
tramer (~90 kDa), which acts a binding protein for proca‐
thepsin B on the surface of tumour cells to facilitate
invasion and metastasis. Expression of annexin 2 is varied
in different types of cancers with increased expression in
pancreatic [30] and breast [31] cancers, but variable
expression in prostate cancer [32]. In our studies, the
presence of annexin 2 was validated by dot blot and ovarian
cancer patient serum antibodies primarily recognized the
heterotetramer form of the antigen, while both isoforms
were detected in the ascites TDE. Furthermore, IgG isolated
from TDE detected both isoforms.

Chaperone proteins HSC70 and PDI were detected by dot
blot assay and were also found to be associated with TDE.
HSC70 is a constitutively expressed cytoplasmic protein
that binds to new peptides exiting the ribosomes to protect
the hydrophobic residues from inefficient interactions.
Additionally, it can catalyse the disassembly of clathrin
cages and has been implicated in the regulation of tumouri‐
genesis and apoptosis. With the assistance of co-chaper‐
ones, it can be recruited to the intracellular membrane, but
can be released from cells as a result of active secretion [33].
Studies of a cell line transfected with Cathepsin D showed
that overexpression of Cathepsin D resulted in an increase
in the malignant phenotype of the transformed cells [34].
Subsequent studies of these cells have revealed that this
overexpression prevented the release of HSC70, which led
to the malignant phenotype. In our study, the expression
of Cathepsin D was seen in the ovarian cancer cells and all

8  



isoforms on the exosomes. However, the ovarian patient
serum antibodies failed to detect Cathepsin D in all cases.
The antigen expression of Cathepsin D, the lack of anti‐
bodies to cathepsin D, and the reduced HSC70 expression
on the cells may indicate a “protective” mechanism used
by the tumour in order to maintain high Cathepsin D
expression, so that HSC70 release can be minimized and
the tumour growth can be maintained. Furthermore, the
exosome expression of all three isoforms may act to “block”
recognition of antigens on the tumour cell, thereby protect‐
ing the tumour from immunosurveillance. PDI is a key
endoplasmic reticulum chaperone that catalyses the
breakage of disulfide bonds within a protein and rearrang‐
es them to form the native protein. Because accumulation
of misfolded proteins in the cell can lead to enhanced
cellular stress and death [35], upregulation of PDI can act
to reduce stress-associated apoptosis. Human PDI-family
member ERp5 has been shown to promote shedding of
MICA from epithelial tumours [36]. MICA is the ligand for
the NKG2D (NK group member 2D) receptor on NK,
CD8+T, NKT and T cells, and upon ligation, activates
cytolysis of the target cell. Tumour-derived exosomes have
been shown to express MICA/B, which downregulates
NKG2D expression to reduce NKG2D-mediated killing
[37]. In our studies, PDI was strongly expressed in TDE.
Expression of PDI in TDE may participate in the facilitation
of MICA expression, resulting in interference of innate and
adaptive immune effector cell function against the tumour.

5. Conclusions

Studies of TDE have demonstrated their critical role in
cancer pathogenesis; however, much remains to be discov‐
ered about their roles in the humoral antitumour response.
The vast amount of autoantibodies present in the circula‐
tion clearly indicates that a humoral response is mounted
against the tumour, but that its efficacy in mediating
tumour elimination is compromised [38]. TDE cannot only
express tumour antigens, but are also able to elicit a
humoral response against the antigen, as indicated in this
study. We propose that the tumour cell expresses certain
antigens in their exosomes in order to divert the humoral
immune response away from the tumour, thereby prevent‐
ing its effective detection and elimination.

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11Carolyn D. Roberson, Cicek Gercel-Taylor, Ying Qi, Kevin L. Schey and Douglas D. Taylor:
Identification of Immunoreactive Tumour Antigens Using Free and Exosome-Associated Humoral Responses