Recently it has been reported that serous tubal intraepithelial carcinoma (STIC), the likely precursor of ovarian/extra-uterine high-grade serous carcinoma, are frequently located in the vicinity of tubal-peritoneal junctions, consistent with the cancer-prone features of many epithelial transitional regions. To test if p53 (aka TP53)-signatures and secretory cell outgrowths (SCOUTs) also localize to tubal-peritoneal junctions, we examined these lesions in the fallopian tubes of patients undergoing salpingo-oophorectomy for sporadic high-grade serous carcinomas or as a prophylactic procedure for carriers of familial BRCA1 or 2 mutations. STICs were located closest to the tubal-peritoneal junctions with an average distance of 1.31 mm, while SCOUTs were not detected in the fimbriated end of the fallopian tube. As many epithelial transitional regions contain stem cells, we also determined the expression of stem cell markers in the normal fallopian tube, tubal intraepithelial lesions and high-grade serous carcinomas. Of those, LEF1 was consistently expressed in the tubal-peritoneal junctions and all lesions, independent of p53 status. All SCOUTs demonstrated strong nuclear expression of β-catenin consistent with the LEF1 participation in the canonical WNT pathway. However, β-catenin was preferentially located in the cytoplasm of cells comprising STICs and p53 signatures, suggesting WNT-independent function of LEF1 in those lesions. Both frequency of LEF1 expression and β-catenin nuclear expression correlated with the worst 5-year patient survival, supporting important role of both proteins in high-grade serous carcinoma. Taken together, our findings suggest the existence of stem cell niche within the tubal-peritoneal junctions. Furthermore, they support the notion that the pathogenesis of SCOUTs is distinct from that of STICs and p53 signatures. The location and discrete patterns of LEF1 and β-catenin expression may serve as highly sensitive and reliable ancillary markers for the detection and differential diagnosis of tubal intraepithelial lesions.
Recently it has been reported that serous tubal intraepithelial carcinoma (STIC), the likely precursor of ovarian/extra-uterine high-grade serous carcinoma, are frequently located in the vicinity of tubal-peritoneal junctions, consistent with the cancer-prone features of many epithelial transitional regions. To test if p53 (aka TP53)-signatures and secretory cell outgrowths (SCOUTs) also localize to tubal-peritoneal junctions, we examined these lesions in the fallopian tubes of patients undergoing salpingo-oophorectomy for sporadic high-grade serous carcinomas or as a prophylactic procedure for carriers of familial BRCA1 or 2 mutations. STICs were located closest to the tubal-peritoneal junctions with an average distance of 1.31 mm, while SCOUTs were not detected in the fimbriated end of the fallopian tube. As many epithelial transitional regions contain stem cells, we also determined the expression of stem cell markers in the normal fallopian tube, tubal intraepithelial lesions and high-grade serous carcinomas. Of those, LEF1 was consistently expressed in the tubal-peritoneal junctions and all lesions, independent of p53 status. All SCOUTs demonstrated strong nuclear expression of β-catenin consistent with the LEF1 participation in the canonical WNT pathway. However, β-catenin was preferentially located in the cytoplasm of cells comprising STICs and p53 signatures, suggesting WNT-independent function of LEF1 in those lesions. Both frequency of LEF1 expression and β-catenin nuclear expression correlated with the worst 5-year patient survival, supporting important role of both proteins in high-grade serous carcinoma. Taken together, our findings suggest the existence of stem cell niche within the tubal-peritoneal junctions. Furthermore, they support the notion that the pathogenesis of SCOUTs is distinct from that of STICs and p53 signatures. The location and discrete patterns of LEF1 and β-catenin expression may serve as highly sensitive and reliable ancillary markers for the detection and differential diagnosis of tubal intraepithelial lesions.
Ovarian carcinoma is the most lethal gynecological malignancy and is
5th among all cancer related deaths of women in the US (1). During the past decade a number of studies
have shown that about half of the most malignant ovarian/extra uterine cancers,
high-grade serous carcinomas, may arise from the fallopian tube epithelium (2). In this situation, neoplastic tubal lesions
lead to metastatic disease with the main manifestation in the ovary. This
possibility is supported by the finding of dysplastic lesions in prophylactically
removed fallopian tubes from high-risk carriers of BRCA1/2 germ-line mutations
(3), detection of identical
p53 mutations in early tubal lesions and high-grade serous
carcinomas of the same patients (4, 5), and experimental demonstration of high-grade
serous carcinoma induction by conditional mutations in the secretory (PAX8 positive)
cells of mouse tubal epithelium (6).
Considering that ovarian cancer can be successfully treated if diagnosed at an early
stage, with 90% of such patients having over a 5-year survival, its early
detection is of particular importance.Early dysplastic lesions associated with high-grade serous carcinoma include
p53 (aka TP53) signatures, serous tubal intraepithelial carcinomas (STICs) and
potentially secretory cell outgrowth (SCOUTs). p53 signatures are characterized by
areas of a single layer of consecutive PAX8 positive secretory cells that contain
aberrant p53 expression, commonly associated with p53 mutations,
but lack cellular atypia and show a low proliferative index (4). STICs also show aberrant p53 expression and express
PAX8, but are characterized by dysplastic epithelial cells with the loss of cell
polarity and high proliferative index (7–10). A large fraction
of STICs (30–50%) completely lack p53 expression, largely due to p53
null mutation in the p53 gene, and their detection by
immunohistochemistry may be more challenging (4, 5, 9). SCOUTs consist of a row of at least 30 almost
exclusively PAX8 positive secretory epithelial cells with a pseudostratified benign
appearance and low proliferative-index (11–13).p53 signatures and STICs are preferentially located in the distal, fimbriated
region of the fallopian tube (4), whereas
SCOUTs are reported to be evenly distributed between fimbriated and more proximal
areas of the fallopian tube (13). However, it
remains elusive if SCOUTs, p53 signatures and STICs represent independent or
continuous stages of neoplastic progression (11, 13, 14).A recent study demonstrated that the majority STICs are located in the
vicinity of the tubal-peritoneal junction (15). The tubal-peritoneal junctions connects the columnar epithelium of the
fimbriated end of the fallopian tube to the flat mesothelial layer of the
peritoneum. The finding of STICs near the tubal-peritoneal junctions is consistent
with previous observations that transitional epithelial zones, such as the corneal
limbus and squamo-columnar junctions in the uterine cervix, gastro-esophageal and
ano-rectal areas are frequently cancer-prone (16–18). Furthermore, it
may offer an equivalent to the recently discovered cancer-prone stem cell niche in
the mouse hilum area, which connects the ovarian surface epithelium, tubal
epithelium and mesothelium (19). The location
of p53 signatures and distal SCOUTs with respect to tubal-peritoneal junctions
remains unknown. Such information could provide an important clue to their role as
precursor lesions to STICs.One consistent marker of hilum stem cells is Lymphoid Enhancer-binding
Factor-1 (LEF1). LEF1 is a transcription factor that interacts with
β-catenin in the nucleus as a component of canonical WNT-signaling (20). LEF1-expression has been reported in human
STICs and SCOUTs (21). However, the frequency
and extent of this expression were not described. Furthermore expression of LEF1 in
normal tubal-peritoneal junctions and p53 signatures remains unknown.In this study we compared the distance from the tubal-peritoneal junctions to
STICs, p53 signatures and SCOUTs in the fallopian tubes of patients undergoing
salpingo-oophorectomy for sporadic high-grade serous carcinomas or as prophylactic
procedures for carriers of familial BRCA1 or 2
mutations. Furthermore, we have determined expression of LEF1 and other stem cell
markers in the tubal-peritoneal junctions, tubal intraepithelial lesions and
high-grade serous carcinomas. We have also compared survival of patients with tumors
containing high and low number of LEF1 expressing cells.
Materials and Methods
Study groups and clinical data
Material in these studies was submitted to the Institute of Pathology,
Ludwig Maximilians University, Munich, Germany between 2009 and 2014. Cases
included fallopian tubes from 42 patients with sporadic high-grade serous
carcinoma without BRCA1/2 germ-line mutation (further denoted
as “high-grade serous carcinoma-group”), from 44 patients tested
positive for BRCA1 or 2 germ-line mutations
(further denoted as “BRCA-group”), and 31 control cases.In the high-grade serous carcinoma -group the status of somatic
BRCA-mutation of tumor was unknown. In order to avoid that
a bulky tumor obscured the potential tubal intraepithelial lesions only cases
with complete right and left tube and presentable fimbria were included. Cases
with advanced tumor mass in the tube and invasion of one or both tubes were
excluded. Patient’s age ranged from 42 to 85 years, with an average of
65 years. 37 patients were of advanced tumor-stage (FIGO ≥ IIIA). Two
patients presented with a FIGO-stage I (one of IA and one of IC). 3 patients
were of FIGO stage II. A representative paraffin-block of the invasive cancer
was obtained for immunohistochemical stainings.In the BRCA group 1 patient presented with an early invasive serous
high-grade serous carcinoma of the fallopian tube (FIGO IC). All other cases
were from prophylactic salpingo-oophorectomy and encompassed 28 cases of BRCA1-
and 16 cases of BRCA2-mutation. Patients’ age ranged from 33 to 79
years, with an average of 52 years.Control cases of fallopian tubes were from 31 patients who underwent
hysterectomy for leiomyoma of the uteri or carcinoma of the cervix.
Patients’ age ranged from 40 to 74 years, with an average of 56
years.Location and size of STICs and their distance to tubal-peritoneal
junctions were additionally evaluated in 10 cases (5 high-grade serous
carcinoma, 2 BRCA and 3 without either high-grade serous carcinoma or BRCA) from
Weill Cornell Medicine, New York, New York.
Histotechnology and Immunohistochemistry
The fallopian tubes were fixed in buffered formalin and prepared for
paraffin embedding according to the SEE-FIM-protocol (8). Serial 4 μm sections were prepared from
each paraffin block and mounted on SuperFrost Plus microscope slides (Menzel
Gläser, Braunschweig, Germany). After deparaffinization and rehydration
step-wise slides were stained with hematoxylin and eosin, while parallel slides
were subjected immunohistochemical stainings for p53, Ki67, PAX2, PAX8, CD44,
CD49f, CD133, LEF1, and β-catenin (Supplementary Table 1). For
β-catenin two different antibodies were used: All cases were first
stained automatically. Cases of unsecure nuclear reaction were stained
additionally by manual staining.Stainings for β-catenin, CD133, Ki67, p53 and PAX8 were
subjected to heat-induced epitope unmasking with pressure cooker heating
followed by staining using a Ventana Benchmark XT autostainer (Ventana Medical
Systems, Oro Valley, AZ) with the XT UltraView diaminobenzidine kit (Vector
Laboratories, Burlingame, CA) and hematoxylin counterstaning (Vector
Laboratories, Burlingame, CA).For CD44, LEF1, β-catenin, CD49f and PAX2 manual staining slides
were exposed to heat pretreatment, followed by incubation with primary
antibodies for 1 h at room temperature, secondary anti-species antibodies
(Vectastain, ABC kit universal, PK 6200, Vector Laboratories, Burlingame, CA,
USA for LEF1, β-catenin BD and CD44; ImmPRESS reagent kit, anti-rabbit
IgG, MP -7401, Vector Laboratories, Burlingame, CA, USA for CD49f and PAX2) and
detection with ABC Elite kit (Vector Laboratories, Burlingame, CA). The
DAB+ system (Dako, Hamburg, Germany) was used as chromogen and the
slides were then counterstained with hematoxylin (Vector Laboratories,
Burlingame, CA, USA). System controls were included.
Analysis of lesions
STIC is defined by a proliferation of dysplastic epithelial cells with
loss of cell polarity and absence of ciliated cells. PAX8 is expressed
continuously. STIC is marked by increased proliferation (Ki67 > 10%
of cells) and aberrant status of p53 immunostaining, which includes either
strong diffuse staining of p53 or complete absence of p53 staining, as compared
to weak nuclear staining in neighboring stromal cells (7–9,
22–25).p53 signatures are morphologically inconspicuous and consists of at
least 12 consecutive PAX8 positive secretory cells, that are p53 positive, but
lack any cellular atypia and show a low proliferative index
(Ki67<10%) (4, 7, 23, 24).SCOUTs consist of at least 30 almost exclusively secretory PAX8 positive
epithelial cells with a pseudostratified appearance. Immunohistochemistry for
p53 is negative and the proliferative-index is low (Ki67 <10%) (11–13). The cells of these lesions usually contain wild-type p53
manifested as weak nuclear staining. Such staining is also typically observed in
stromal cells.All lesions were independently analyzed by several pathologists (ES,
LHE, DM, and AYN). All histological sections were digitized at giga-pixel
resolution, 24-bit color and 40X magnification using Aperio ScanScope CS2 (Leica
Biosystems, Buffalo Grove, IL). Image analysis was performed using ImageJ
software (National Institute of Health, Bethesda, MD). Size of STICs, p53
signatures and SCOUTs was determined in parallel sections followed by 3D
reconstruction of lesions. The distance to the tubal-peritoneal junctions was
measured for all STICs, p53 signatures and SCOUTs located in the same tissue
section as the tubal-peritoneal junctions.For the immunohistochemical analysis of LEF1 expression in the
tubal-peritoneal junctions 15 mesothelial cells and 60 tubal epithelial cells
were evaluated. Together a total length of 400–550 μm (in most
cases 475 μm) was counted for each junction. The number of junctions
found per analyzed case ranged from 1–5 and the average expression was
calculated for each case. The referring distant regions were chosen and defined
based on them having overall representative staining composition of the distal
tubal epithelium in each case. The average of two distant regions, each
consisting of 60 cells was calculated.Expression of LEF1 in STICs, p53 signatures, SCOUTs and high-grade
serous carcinoma was quantified as the percentage of positive stained cells in
each lesion using ImageJ cell counter in digital images. Due to injured tubal
mucosa or missing tubal-peritoneal junctions on parallel slides used for the
immunohistochemical stainings, subsets of 19 high-grade serous carcinoma cases,
20 BRCA cases and 12 controls were used for detailed analysis of
immunohistochemical stainings. Among those, 21 STICs, 16 p53 signatures, and 15
SCOUTs were stained for LEF1, β-catenin, CD44, and CD133. High-grade
serous carcinoma were considered to be positive for LEF1 and nuclear
β-catenin in cases with over 30% stained neoplastic cells.
Statistical analysis
Statistical analysis was performed using SPSS version 19.0 (PASW
Statistics; SPSS Inc., IBM, Chicago, IL, USA), GraphPad Prism version 6
(GraphPad, La Jolla, USA) and MedCalc version 17 (Ostend, Belgium). An average
percent positivity and standard deviation was taken for each region for each
independent uterine tube case. Average percent positivity was used in all
statistical analysis. Unpaired t-tests with Welch’s correction (Gaussian
distribution) or Mann-Whitney tests (nonparametric test) were used to determine
if within a given region differences in means between markers were statistically
significant. Overall survival was analyzed using Kaplan-Meier method with log
rank test and Cox proportional-hazards regression. P values of
< 0.05 were considered statistically significant.
Results
Incidence and size of tubal intraepithelial lesions
Among 19 STIC cases in the high-grade serous carcinoma-group (Table 1), 7 cases presented with a small
solid tumor mass in the ovary (≤. 3.5 cm in diameter) and an ipsilateral
manifestation of STIC. The remaining 12 cases presented with a larger solid and
cystic tumor mass in the ovaries. In 9 out of 19 STIC cases in the high-grade
serous carcinoma-group a microscopic invasive tumor in the fimbria was bordering
the STIC. In the BRCA-group one case included an early high-grade serous
carcinoma of the fallopian tube (FIGO IC) and a contralateral STIC as well as
SCOUT on the side of the invasive cancer.
Table 1
Distribution of tubal intraepithelial lesions in study groups
Lesion/Group
HGSC n=42*
BRCA n=44*#
Control n=31*
STIC
19 (45%)
4 (9%)
0
p53 signature
10 (24%)
6 (14%)
5 (16%)
SCOUT
11 (26%)
4 (9%)
3 (10%)
No lesions
14 (33%)
34 (77%)
26 (84%)
Some cases include several types of lesions.
BRCA group includes BRCA1 (n=29) and BRCA2 (n=15) cases with
STIC/p53 signature/SCOUT distribution 3/5/3 and 1/1/1, respectively.
10 out of 19 (52.63%) STICs completely lacked p53
immunostaining, as typical for p53 null mutations, in the
high-grade serous carcinoma group. In all cases the p53 immunostaining status
(aberrant accumulation vs complete lack of staining) in STICs was identical in
the high-grade serous carcinoma of the same patient. In the BRCA-group 2 out of
4 (50%) STICs had complete lack of p53 staining. One case of the
BRCA-group contained a STIC with complete lack of p53 staining and a p53
signature in the same tube.The average size of STICs (2.73 mm) was significantly larger than p53
signatures (1.12 mm, P = 0.0004) and SCOUTs (1.04 mm, P =
0.0001; Table 2). Sizes of SCOUTs and p53
signatures were not significantly different (P = 0.6974).
Table 2
Size, location and distance to the TPJ among tubal intraepithelial lesions.
Lesion/Group
Size mm ± SD
Location
Distance to TPJ, mm ±
SD*
Fimbriae
Infundibulum
Ampulla
Isthmus
STIC, n=33**
2.73±1.55
28 (85%)
5 (15%)
0 (0%)
0 (0%)
1.34±1.15
p53 signature, n=16
1.12±0.90#
10 (62%)
3(19%)
3 (19%)
0 (0%)
1.96±1.55
SCOUT, n=15
1.04±0.33&
1 (4%)
15 (65%)
6 (26%)
1 (4%)
NA
for lesions located in the fimbria;
denotes P=0.0004 vs STIC;
denotes P=0.0001 vs STIC.
Includes 10 cases from Weill Cornell Medicine, New York.
Distance from tubal intraepithelial lesions to tubal-peritoneal
junctions
Consistent with previous reports (2, 4), the majority of STICs
(85%) and p53 signatures (62%) were located in the fimbriated
region (Table 2 and Figure 1a). Furthermore, no STICs were located more
proximally than the infundibulum (15%), while 19% of p53
signatures were found in the ampulla region. Importantly, the majority of SCOUTs
were observed in the infundibulum (65%), followed by the ampulla
(26%).
Figure 1
Lesions in the fallopian tube. a. Distribution of tubal lesions.
b. STIC (arrowhead) at the tubal-peritoneal junction (arrow),
flanked by the mesothelium and the tubal epithelium at the right and the left
sides, respectively. Line shows the length of STIC. Hematoxylin and eosin. Scale
bar, 300 μm.
Among lesions located in the fimbriated region, STICs tend to be closer
to the tubal-peritoneal junctions (mean distance 1.34 mm) than p53 signatures
(1.96 mm); however this difference is not statistically significant
(P=0.1217). In three cases, STICs were located directly at the
tubal-peritoneal junctions and were flanked by the mesothelial layer at the one
side and columnar tubal epithelium at the other (Figure 1b).
Increased frequency of LEF1 expressing cells in the tubal-peritoneal
junctions and all tubal intraepithelial lesions
Since epithelial transitional regions may contain stem cell niches, we
have evaluated a panel of markers characteristic for stem/progenitor cell, such
as LEF1, CD44, CD49f, CD133 and β-catenin in the morphologically normal
fallopian tube epithelium at the tubal-peritoneal junctions and in the proximal
tubal epithelium of the same section at distance of 4 mm. Among those markers
the frequency of LEF1 positive cells was significantly higher in the area of
tubal-peritoneal junctions. LEF1 positive cells were also more frequent in
morphologically normal epithelium of high-grade serous carcinoma and BRCA groups
(Figure 2). There were no preferential
distribution of CD44, CD49f and β-catenin stained cells, while CD133 was
mainly detected in the proximal region of the fallopian tube.
Figure 2
LEF1 expression in the morphologically normal tubal epithelium. a.
LEF1 expression in a large fraction of cells (arrow) in the tubal epithelium
near the tubal-peritoneal junctions region (arrowhead) of the control group.
b. LEF1 in few cells (arrow) of the tubal epithelium of the
proximal region of the control group. ABC Elite method, hematoxylin
counterstaining. Scale bar, 50 μm. c. Quantitative analysis
of LEF1 expression in control (n=12), high-grade serous carcinoma
(n=19) and BRCA (n=16) groups. Error bars denote SD.
The average number of LEF1 positive cells was significantly higher in
STIC, p53 signature and SCOUT compared to the bordering normal tubal epithelium
(Figure 3). Importantly, STICs
completely lacking p53 expression also expressed LEF1, thereby simplifying
detection of such lesions. (Figure 3c and
d).
Figure 3
Immunohistochemical characterization of tubal lesions. a–d.
Expression of p53, LEF1, Ki67, PAX8, and β-catenin in the altered
(arrow) and morphologically normal (arrowhead) epithelium in p53 signature (a),
SCOUT (b), and STIC cases with p53 aberrant accumulation (aa), (c) and p53
complete lack (cl) of staining. (d). Note mainly membrane staining of
β-catenin in p53 signatures and STICs. ABC Elite method, hematoxylin
counterstaining, HE, hematoxylin and eosin. Scale bars, 70 μm for all
images. e. Quantitative analysis of LEF1 expression in STIC
(n=21), p53 signature (n=16), SCOUT (n=15) and adjacent
morphologically normal tubal epithelium (TE). Error bars denote SD.
Divergent β-catenin cellular location differentiates STICs,
signatures and high-grade serous carcinoma from SCOUTs
In all SCOUTs the expression of LEF1 was associated with a marked
nuclear expression of β-catenin (Figure
3). STICs and p53 signatures showed only minimal nuclear expression
of β-catenin in single cells, whereas the majority of cells in these
lesions presented with a distinct membranous expression of
β-catenin.To establish if divergent expression of LEF1 and β-catenin is
also present in advanced malignancies, immunostaining was additionally performed
in 35 cases of sporadic high-grade serous carcinoma (Figure 4). Nuclear expression was similar to that of
intraepithelial lesions, but the frequency of LEF1-ranged from 0% to
75% (mean ± SD, 18 ± 16.7%). Similar to STICs
and p53 signatures, β-catenin showed a distinct membranous expression in
the cancers with only minimal nuclear expression in the majority of cases.
However, focal nuclear expression was detected in all high-grade serous
carcinoma cases studied, ranging from 2 to 55 %. As compared to LEF1,
expression of β-catenin was observed more uniformly in all high-grade
serous carcinoma cases. Patient’s survival correlated significantly with
frequency of LEF1 and nuclear β-catenin positive cells in the cancer
(Figure 4).
Figure 4
LEF1 and β-catenin in high-grade serous carcinoma. a.
Expression of p53, LEF1 and β-catenin. Arrows indicated nuclear
staining. Note mainly membrane staining of β-catenin in neoplastic
cells. Parallel sections of the same block. ABC Elite method, hematoxylin
counterstaining, HE, hematoxylin and eosin. Scale bar, 150 μm for all
images. b, c. Survival of patients with high-grade serous carcinoma
stratified according to LEF1 (b) and nuclear β-catenin (c) expression.
Kaplan-Meier survival analysis, n=35, P=0.0306 (a) and
P=0.0029 (b). Cox proportional-hazards regression analysis P=
0.0394 (a) and P= 0.0060 (b).
Discussion
Recent studies of risk-reducing salpingo-oophorectomies in women with
BRCA1/2 germ-line mutations showed that STICs are identified in 2 to 12% of
the patients (2, 14, 26). In
context of high-grade serous carcinoma the incidence of STIC ranges rather up to
19–60% (15, 27–29).
Our studies have found the frequency of STICs to be 9 % and 45% in
the above groups, respectively, thereby confirming the earlier observations. It
should be noted that all of these studies cannot exclude that some STICs may
represent metastatic implants from the associated high-grade serous carcinoma (30, 31).
Due to its proximity to the ovary, the location of the majority of STICs in the
fimbriae may be the preferential site of implantation from extra-tubal carcinomas.
In such a scenario, it would be more likely to observe random distribution of tumor
implants within the tubal fimbria. However, consistent with the recent study by
Seidman (15), we have observed preferential
location of STICs at or in the immediate vicinity to the tubal-peritoneal junctions.
Furthermore, we have observed similar distribution of STICs in the BRCA1/2 cases,
where no overt tumor was observed. This is consistent with the notion that a large
fraction of lesions described as STICs are of primary, not metastatic implantation,
origin.Consistent with previous observations (11, 13, 14), we have shown that STICs and p53 signatures are
preferentially located within the tubal fimbria, while SCOUTs are detected in the
more proximal regions of the tube. Both p53 signatures and SCOUTs have approximately
the same size (about 1.1 mm on average), while STICs are 2.5 times larger (2.73 mm).
All STICs and p53 signatures but not SCOUTs contain aberrant p53 immunostaining. In
high-grade serous carcinoma cases, the type of p53 immunostaining, either aberrant
accumulation or aberrant lack of staining, were identical to the carcinoma of the
same patient. Further supporting the common pathogenesis of STICs and p53
signatures, in contrast to that of SCOUTs, only SCOUTs have marked nuclear location
of β-catenin, a key component of the canonical WNT pathway. STICs, p53
signatures as well as high-grade serous carcinomas were characterized by
preferential membrane and cytoplasmic staining with only minimal nuclear location of
β-catenin. In sum, based on the distinct location and different patterns of
p53 and beta-catenin expression in STICs/p53 signatures, p53 signatures but not
SCOUTs are likely to represent the steps in the continuous progression towards STICs
and overt high-grade serous carcinoma. Consistent with this notion, the frequency of
p53 signatures is two times higher than that of STICs in fallopian tubes from women
in the BRCA group (14% vs 9%). However, in high-grade serous
carcinoma group, these frequencies are inverse (24% vs 45%)
suggesting that either all STIC’s arise from p53 signatures or that some
STICs may in fact represent implants of high-grade serous carcinoma. Consistent with
this possibility, according to recent next-generation sequencing, a STIC represented
a micro-metastasis in 25% of cases (31, 32). Since in our study
SCOUTs are defined by an accumulation of at least 30 secretory cells, we cannot rule
out that some smaller groups of secretory cells might exist in the distal tube and
progress to p53 signatures and/or STICs. More extensive results based on targeting
tubal epithelium stem cells and their lineages in combination with single cell
genome sequencing will better inform us in future.Previously, we have reported the existence of a cancer-prone stem cell niche
in the junction/transitional zone between ovarian surface epithelium, tubal
epithelium and mesothelium located within the mouse hilum of the ovary (19). In humans, the same hilum-based
transitional zone is not maintained. However, the tubal-peritoneal junctions of the
tubal fimbria may represent a counterpart to the mouse junction zone. Consistent
with the possibility of stem cell niche located in the tubal-peritoneal junctions we
have observed expression of LEF1 in that area. LEF1 is expressed in a number of
normal stem cells, such as hematopoietic (33)
and ovarian surface epithelium stem cells (19). Moreover, deregulated LEF1 expression has been implicated in leukemic
transformation (33). Further studies testing
functional properties of tubal-peritoneal junctions cells should specifically
evaluate the key parameters of stem cells, such as their ability to self-renew and
to give rise to more differentiated progeny. These studies will also test if
putative stem cells previously identified in the distal end of the fallopian tube
(34) are identical or similar to LEF1
positive cells found in the tubal-peritoneal junctions area. We have noted that
other tested stem/progenitor cell markers did not have preferential association with
cells located near the tubal-peritoneal junctions. Some of these markers, such as
CD44 and CD49f (aka integrin α 6) have been reported to be expressed in
putative stem cells of the human tubal epithelium (34). Thus it is possible that the tubal epithelium may have several
pools of stem cells. At the same time, such markers are not always entirely specific
and may label non-stem cells in some tissues.LEF1 is frequently found to be an important component of WNT pathway (20). However according to our studies, LEF1
expression in p53 signatures, SCOUTs and high-grade serous carcinomas does not
correlate with the nuclear location of β-catenin, a property of active WNT
signaling. Thus it is likely that the LEF1 function in these lesions are WNT pathway
independent. WNT independent functions of LEF1 were previously described in
granulocyte progenitor cells (35) and murineT-cell lymphomas (36). At the same time, we
observed a strong coincidence of nuclear accumulation of β-catenin and LEF1
expression in SCOUTs, supporting a distinct pathogenesis of SCOUTs, as compared with
other tubal lesions. We have also shown that both high LEF1 expression and nuclear
location of β-catenin correlate with decreased survival of high-grade serous
carcinomapatients. Further studies should elucidate specific mechanisms by which
LEF1 regulates the function of stem and neoplastic cells in tubal-peritoneal
junctions, tubal lesions and high-grade serous carcinoma. They also should address
the extent to which both WNT pathway dependent and independent functions contribute
to the high-grade serous carcinoma pathogenesis.Our study has shown that LEF1 expression together with strong nuclear
location of β-catenin is indicative of SCOUTs, while LEF1 expression
together with largely membranous and cytoplasmic β-catenin is typical for
p53 signatures and STICs. Thus LEF1 may be used as an auxiliary marker for detection
of tubal lesions, particularly in conjunction with beta-catenin detection. This
could be a particularly useful tool for the detection of TP53 with aberrant lack of
immunostaining in STICs and p53 signatures. It has been previously reported that
high LEF1 expression correlates with poor prognosis of acral melanoma (37) and colorectal cancer (38), B-precursor acute lymphoblastic leukemia (39) and in chronic lymphocytic leukemia (40, 41).
Our studies indicate that LEF1 expression may be also a useful prognostic marker in
ovarian cancer. Since both LEF1 and strong nuclear location of β-catenin
correlate with a worse prognosis, further studies on a larger cohort of patients are
needed to establish if correlation between these parameters has additional
prognostic value.In sum, our findings support the existence of cancer prone stem cell niche
within the tubal-peritoneal junctions. They also suggest that the pathogenesis of
STICs and p53 signatures is distinct from that of SCOUTs. Furthermore, detection of
LEF1 expression, especially in combination with β-catenin intracellular
distribution, may be used as a highly sensitive and reliable tool for the diagnosis
of tubal intraepithelial lesions, particularly well-suited for detection of STICs
with aberrant lack of p53 immunostaining.
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