Agoff SN, Lamps LW, Philip AT, Amin MB, Schmidt RA, True LD & Folpe
AL (2000) Thyroid transcription factor-1 is expressed in extrapulmonary
small cell carcinomas but not in other extrapulmonary neuroendocrine tumors.
Mod Pathol, 13, 238-242.
Abstract: Thyroid transcription factor-1 (TTF-1) is a nuclear
homeodomain transcription factor that is expressed in the developing thyroid,
respiratory epithelium, and diencephalon. TTF-1 is thought to be expressed
specifically in pulmonary or thyroid neoplasms, and it is expressed in a
significant subset of pulmonary non-small cell carcinomas, small cell
carcinomas, and carcinoids but not in nonpulmonary, non-small cell
carcinomas. Neuroendocrine tumors from sites other than the lung have not
been evaluated for TFF-1 expression. We examined TFF-1 expression using
immunohistochemistry on formalin-fixed, paraffin-embedded sections of 49
gastrointestinal carcinoids; 15 pancreatic islet cell tumors; 21
paragangliomas; 8 medullary thyroid carcinomas; 7 small cell carcinomas of
the uterine cervix; 4 prostate, 4 bladder, and 6 Merkel cell (primary
cutaneous neuroendocrine) carcinomas; and 1 renal carcinoma No
gastrointestinal carcinoid tumor, pancreatic islet cell tumor,
paraganglioma, or Merkel cell carcinoma expressed TFF-1. All of the
medullary thyroid carcinomas strongly expressed TTF-1. However, 44% of
nonpulmonary small cell carcinomas were also TTF-1 positive, including four
of four prostate, two of four bladder, and one of seven cervical small cell
carcinomas. We conclude that TTF-1 expression is not specific for small cell
carcinomas of pulmonary origin and should not be used to distinguish primary
from metastatic small cell carcinomas in extrapulmonary sites. However,
TTF-1 expression may be useful in distinguishing Merkel cell carcinomas and
cutaneous metastasis of small cell carcinomas. Among well-differentiated
neuroendocrine tumors, TTF-1 expression seems to be present only in
carcinoid tumors of the lung and medullary carcinomas of the thyroid and may
be of differential diagnostic value when dealing with a metastatic
well-differentiated neuroendocrine tumor
Bejarano PA, Baughman RP, Biddinger PW, Miller MA, Fenoglio-Preiser C,
al-Kafaji B, Di Lauro R & Whitsett JA (1996) Surfactant proteins and
thyroid transcription factor-1 in pulmonary and breast carcinomas. Mod
Pathol, 9, 445-452.
Abstract: Antibodies to the pulmonary epithelial cell-specific
proteins surfactant proteins A and B (SP-A and SP-B) and to thyroid
transcription factor-1 (TTF-1), a homeodomain nuclear transcription protein,
were used as immunohistochemical markers to asses their ability to
distinguish primary pulmonary non-small cell carcinomas (n = 57) from
carcinomas of the breast (n = 51). SP-A, SP-B, and TTF-1 were detected in
49%, 53%, and 63% of non-small cell carcinomas, respectively. These three
antibodies stained pulmonary adenocarcinomas in 54%, 63% and 76% of
specimens, respectively. Squamous cell carcinomas rarely stained using these
markers. Antibodies to SP-B and TTF-1 never stained any of the 51 breast
carcinomas, whereas four of these tumors stained for SP-A. To better define
the potential diagnostic value of these antibodies, 13 breast carcinomas
metastatic to the lung were studied. Of the three antibodies tested, only
TTF-1 seemed useful, because none of the 13 metastatic tumors showed
immunoreactivity to this antibody, whereas six specimens (46%) showed
reactivity for both SP-A and SP-B. To emphasize further the potential
usefulness of antibodies to TTF-1, sections of adenocarcinomas of the colon
(n = 18) and prostate (n = 9), renal cell carcinomas (n = 8), and
epithelioid mesotheliomas (n = 4) were evaluated; none was positive. Only
one of 66 gastric and one of eight endometrial adenocarcinomas showed focal
positivity. These results demonstrate the usefulness of immunodetection of a
pulmonary cell selective transcription protein (TTF-1) in the diagnosis of
pulmonary adenocarcinoma, readily distinguishing breast carcinomas from
primary pulmonary adenocarcinomas. In contrast, staining for SP-A and SP-B
is of limited value, because there is an unacceptably high rate of
cross-reactivity between breast carcinomas metastatic to the lung and
primary pulmonary carcinomas. The latter finding illustrates and supports
the fact that tumor marker phenotypes might differ in primary and secondary
tissue sites
Bejarano PA, Nikiforov YE, Swenson ES & Biddinger PW (2000) Thyroid
transcription factor-1, thyroglobulin, cytokeratin 7, and cytokeratin 20 in
thyroid neoplasms. Appl Immunohistochem Molecul Morphol,8 (3 ):189 -94.
Abstract: Thyroid transcription factor-1 (TTF-1), a member of the
NKx2 family of homeodomain transcription factors, is a mediator of
thyroid-specific transcription of the thyroglobulin (TG) gene. The combined
immunohistochemical profile of TTF-1, TG, cytokeratin 7 (CK7), and
cytokeratin 20 (CK20) in neoplasms of the thyroid gland and their metastases
to other sites has not been defined previously. Formalin-fixed tissue of 43
thyroid tumors, including 31 carcinomas and 12 adenomas, and 16 metastasic
lesions were immunostained using monoclonal antibodies to TTF-1, TG, CK7,
and CK20. Immunoreactivity of the primary tumors (adenomas and carcinomas)
for TTF-1 was seen in 32 cases (74%), TG 32 (74%), and CK7 34 (79%), whereas
none (0%) showed positivity for CK20. The distribution of reactivity in the
31 carcinomas for TTF-1, TG, and CK7, respectively was papillary (8/8),
(8/8), and (8/8); poorly differentiated (6/7), (4/7), and (6/7); oncocytic
(Hurthle) cell (2/6), (6/6), and (4/6); follicular (4/4), (3/4), and (3/4);
medullary (1/2), (0/2), and (1/2). One of four anaplastic carcinomas was
focally immunoreactive showing positivity for TTF-1 only. Of the six
follicular adenomas, five were positive for TTF-1, six for TG, and six for
CK7. Among the six oncocytic cell adenomas, five were reactive for TTF-1,
five for TG, and all six for CK7. Twelve (75%) of the 16 metastatic tumors
were positive for TTF-1, 10 (63%) for TG, 15 (94%) for CK7, and none (0%)
for CK20. In summary, TTF-1 and TG are demonstrable by immunohistochemistry
in the majority of thyroid neoplasms. Compared with TG, an antibody to TTF-I
is a similarly sensitive marker for thyroid tumors. Moreover, TTF-1 is a
more sensitive marker for poorly differentiated carcinomas and metastasis.
In most cases, its nuclear pattern of immunoreactivity facilitates
interpretation. Thyroid tumors are CK7+/CK20-. The panel of antibodies for
TG, TTF-1, CK7, and CK20 is useful when the thyroid origin of a metastatic
tumor is a consideration
Cai Y, Banner B, Glickman J & Odze RD (2002) Cytokeratin 7 and 20 and
thyroid transcription factor 1 can help distinguish pulmonary from
gastrointestinal carcinoid and pancreatic endocrine tumors. Hum Pathol,
32, 1087-1093.
Chan AC & Chan JK (2000) Pulmonary sclerosing hemangioma consistently
expresses thyroid transcription factor-1 (TTF-1): a new clue to its
histogenesis. Am J Surg Pathol, 24, 1531-1536.
Abstract: The histogenesis of pulmonary sclerosing hemangioma has
remained controversial despite extensive studies by many investigators. The
availability of an antibody to thyroid transcription factor-1 (TTF-1), which
is expressed in type II pneumocytes and Clara cells, has prompted us to
readdress this issue. Sixteen cases were immunostained with a panel of
antibodies including TTF-1. The patients were predominantly women with an
age range of 30 to 73 years (mean, 52 yrs). All tumors were solitary. The
single male patient showed regional lymph node metastases, an unusual
occurrence reported only once in the literature. All cases exhibited the
classic histologic features, with variegated patterns. TTF-1 expression was
observed in both the surface lining cells and the pale polygonal cells. The
surface lining cells were epithelial membrane antigen (EMA)+ cytokeratin+
surfactant apoprotein A+, whereas the polygonal cells were EMA+ cytokeratin-
surfactant apoprotein A-. The neuroendocrine markers synaptophysin and
chromogranin were both negative. The metastatic deposits in the lymph nodes
comprised only polygonal cells and exhibited an EMA+ cytokeratin- surfactant
apoprotein A- TTF- 1+ immunophenotype. These results suggest that pulmonary
sclerosing hemangioma is an epithelial neoplasm derived from primitive
respiratory epithelium or incompletely differentiated type II pneumocyte or
Clara cell
Devouassoux-Shisheboran M, Hayashi T, Linnoila RI, Koss MN & Travis
WD (2000) A clinicopathologic study of 100 cases of pulmonary sclerosing
hemangioma with immunohistochemical studies: TTF-1 is expressed in both
round and surface cells, suggesting an origin from primitive respiratory
epithelium. Am J Surg Pathol, 24, 906-916.
Abstract: Pulmonary sclerosing hemangioma (SH) is a lung neoplasm of
uncertain histogenesis that is composed of two major cell types: surface and
round cells. The authors studied 100 cases of pulmonary SH that presented as
a peripheral (95%), solitary (96%) mass of less than 3 cm in diameter (74%)
in asymptomatic patients who were mostly women (83%) with a mean age of 46.2
years. Immunohistochemistry of multiple epithelial, mesothelial, pneumocyte,
neuroendocrine, and mesenchymal markers was performed on 47 cases to
investigate the histogenesis of this neoplasm. Both surface and round cells
stained with epithelial membrane antigen (EMA) and thyroid transcription
factor-1 (TTF-1) in more than 90% of cases; however, the round cells were
uniformly negative for pancytokeratin and positive for cytokeratin-7 and CAM
5.2 in only 31% and 17% of cases, respectively. Surfactant proteins A and B
as well as Clara cell antigen were positive in varying numbers of surface
cells but they were negative in the round cells. Neuroendocrine cells either
as isolated scattered cells or as a tumorlet within the center of SH were
detected (chromogranin, Leu-7, synaptophysin positive) in three cases. The
expression of TTF-1 in the absence of surfactant proteins A and B and Clara
cell antigens in the round cells of SH suggests that they are derived from
primitive respiratory epithelium. The alveolar pneumocytes and
neuroendocrine cells may either represent phenotypic differentiation of a
primitive respiratory epithelial component or they may correspond to
non-neoplastic entrapped or hyperplastic elements. The concomitant
positivity of both cell types in SH for TTF-1 and EMA, and the negativity of
round cells for pancytokeratin and neuroendocrine markers, provide useful
clues not only for histogenesis but also for the diagnosis of this lung
neoplasm
di Loreto C, Di L, V, Puglisi F, Damante G, Fabbro D & Beltrami CA
(1997) Immunocytochemical expression of tissue specific transcription
factor-1 in lung carcinoma. J Clin Pathol, 50, 30-32.
Abstract: AIMS: To investigate the immunocytochemical expression of
the tissue specific transcription factor-1 (TTF-1) on cytological specimens
of small cell lung carcinoma (SCLC) and to establish its value in the
cytological diagnosis of lung cancer. METHODS: For each case, the diagnosis
was made on cytological specimens and confirmed on subsequent bronchial
biopsy specimens. TTF-1 was detected immunocytochemically using the
avidinbiotin complex technique with a rabbit antiserum. Expression of TTF-1
was evaluated in 41 cases of SCLC and 17 cases of non-small cell carcinoma
(NSCC). The latter were subdivided into eight cases of adenocarcinomas and
nine cases of squamous cell carcinomas (SCC). RESULTS: Positive nuclear
immunoreactivity to TTF-1 was identified in 38 (92.7%) of the 41 cases of
SCLC, in five (62.5%) of eight cases of adenocarcinoma, and one (11%) of
nine cases of SCC. A significant difference was observed between the two
main groups, SCLC and NSCC. A comparison between SCLC and adenocarcinoma and
SCC showed that TTF-1 expression was significantly different. TTF-1
immunoreactivity was not detected in the inflammatory cells of the same
cases. CONCLUSIONS: TTF-1 is strictly associated with SCLC; it was weakly
expressed in the various subtypes of NSCC. Although TTF-1 is not specific
for SCLC, it can be used to highlight neoplastic cells to good effect when a
large inflammatory component is present, and to differentiate SCLC from
lymphoid infiltrates
di Loreto C, Puglisi F, Di L, V, Damante G & Beltrami CA (1998) TTF-1
protein expression in pleural malignant mesotheliomas and adenocarcinomas of
the lung. Cancer Lett, 124, 73-78.
Abstract: TTF-1 is a tissue-specific transcription factor expressed
in the epithelial cells of thyroid and lung. This study investigates the
immunohistochemical expression of TTF-1 in pleural malignant mesotheliomas
(MM) and adenocarcinomas (AC) of the lung, respectively. For this purpose,
33 biopsy specimens of pulmonary AC and 24 specimens of MM were studied.
TTF-1 immunoreactivity was identified in 19 of 33 cases of AC (57.5%) and in
none of the 24 cases of MM. Positivity for TTF-1 was 100% specific and 57.5%
sensitive for lung AC. Alternatively, negativity for TTF-1 was 57.5%
specific and 100% sensitive for MM. These results suggest that TTF-1 can be
favourably added to the immunohistochemical diagnostic panel for distinction
between AC of the lung involving the pleura and pleural MM
Folpe AL, Gown AM, Lamps LW, Garcia R, Dail DH, Zarbo RJ & Schmidt RA
(1999) Thyroid transcription factor-1: immunohistochemical evaluation in
pulmonary neuroendocrine tumors. Mod Pathol, 12, 5-8.
Abstract: Thyroid transcription factor-1 (TTF-1), a nuclear
transcription protein selectively expressed in the thyroid, the
diencephalon, and respiratory epithelium, is expressed in more than 90% of
pulmonary small cell carcinomas (SCLCs) and in almost 75% of pulmonary
non-small cell carcinomas (NSCLCs), but it is absent in typical pulmonary
carcinoids (TCs). Therefore, it was thought that SCLC and NSCLC might share
a common lineage, different from that of TC. TTF-1 expression in atypical
pulmonary carcinoids (ACs) and large-cell neuroendocrine carcinomas (LCNECs)
was not studied previously. We examined TTF-1 expression in 51 TCs, 9 ACs, 8
LCNECs, and 21 SCLCs with use of formalin-fixed material and heat-induced
epitope retrieval. TTF-1 expression was seen in 18 (35%) of 51 TCs, all of
the 9 ACs, 6 (75%) of the 8 LCNECs, and 20 (95%) of the 21 SCLCs. These
results reinforce earlier findings of the excellent sensitivity of TTF-1 for
SCLC, and they show similar sensitivity for AC and LCNEC, but they argue
against the hypothesis that SCLC and TC are of different cell lineages. The
ubiquity of TTF-1 expression in pulmonary NECs demonstrated in this study
also argues against its use in their subclassification
Goldstein NS & Thomas M (2001) Mucinous and nonmucinous
bronchioloalveolar adenocarcinomas have distinct staining patterns with
thyroid transcription factor and cytokeratin 20 antibodies. Am J Clin
Pathol, 116, 319-325.
Abstract: We studied 14 mucinous and 26 nonmucinous
bronchioloalveolar adenocarcinomas (BACs) with thyroid transcription factor
(TTF), cytokeratin (CK) 7, CK20, and villin to characterize their staining
patterns with these antibodies and identify staining differences between the
neoplasms. We also stained 11 mucinous colon adenocarcinomas with the same
antibodies to compare their reaction patterns with mucinous BACs. All
pulmonary neoplasms were confirmed pulmonary primary BACs. Three (21%) of 14
mucinous neoplasms had weak TTF reactivity in fewer than 25% of neoplastic
cell nuclei, and the other 11 (79%) were nonreactive. In contrast, 24 (92%)
of 26 nonmucinonus BACs were strongly TTF reactive. Eleven mucinous BACs
(79%) had CK20 reactivity in more than 25% of neoplastic cells, whereas only
1 nonmucinous BAC (4%) had reactivity in fewer than 50% of the cells. One
mucinous BAC (7%) had villin reactivity in approximately 10% of the
neoplastic cells. All mucinous colon adenocarcinomas were diffusely reactive
with CK20 and villin. Mucinous and nonmucinous BACs have disparate staining
patterns with TTF and CK20. Mucinous BACs are usually TTF nonreactive and
CK20 reactive, but nonreactive with villin, which distinguishes them from
mucinous colon adenocarcinomas
Hanly AJ, Elgart GW, Jorda M, Smith J & Nadji M (2000) Analysis of
thyroid transcription factor-1 and cytokeratin 20 separates merkel cell
carcinoma from small cell carcinoma of lung. J Cutan Pathol 2000 27,
118-120.
Abstract: Merkel cell carcinoma needs to be separated from small cell
carcinoma metastatic from visceral sites to skin. Pulmonary small cell
carcinoma is the most common primary site of small cell carcinoma. We
evaluated the immunophenotypic characteristics of 21 Merkel cell carcinomas
and 33 small cell carcinomas of lung using thyroid transcription factor-1
and cytokeratin 20. Thyroid transcription factor-1 was 100% specific for the
diagnosis of small cell carcinoma of lung associated with a diagnostic
sensitivity of 85%. Cytokeratin 20 was present in 95% of Merkel cell
carcinomas; however, 33% of small cell carcinoma of lung were also positive.
Both antibodies typically demonstrate diffuse and intense staining of their
respective tumor cells. We conclude that thyroid transcription factor-1 is a
sensitive and specific marker for small cell carcinomas of lung and that a
combination of thyroid transcription factor-1 and cytokeratin 20 is
indicated to assist in the differentiation of metastatic small cell
carcinoma of lung from merkel cell carcinoma
Harlamert HA, Mira J, Bejarano PA, Baughman RP, Miller MA, Whitsett JA
& Yassin R (1998) Thyroid transcription factor-1 and cytokeratins 7 and
20 in pulmonary and breast carcinoma. Acta Cytol, 42,
1382-1388.
Abstract: OBJECTIVE: To evaluate the immunohistochemical expression
of a lung epithelial gene transcription factor, thyroid transcription
factor-1 (TTF-1), in lung and breast carcinoma in pulmonary cytologic
preparations and to correlate the results with the expression of cytokeratin
7 (CK7) and 20 (CK20). STUDY DESIGN: Cell blocks of cytologic specimens were
immunostained with antibodies to TTF-1, CK7 and CK20. Specimens included 41
primary lung carcinomas (21 adenocarcinomas, 8 squamous cell carcinomas and
12 small cell undifferentiated carcinomas) and 6 metastatic breast
adenocarcinomas. RESULTS: The lung adenocarcinomas showed nuclear reactivity
for TTF-1 in 76% (16/21) of the cases and a staining combination of
CK7+/CK20- in 95% (20/21) of the cases. Only one case was CK7+/CK20+. All
the breast carcinomas were nonreactive to TTF-1, and all were CK7+/CK20-.
The squamous cell carcinomas and small cell undifferentiated carcinomas
showed TTF-1 positivity in 38% (3/8) and 83% (10/12), respectively
Kaufmann O & Dietel M (2000a) Expression of thyroid transcription
factor-1 in pulmonary and extrapulmonary small cell carcinomas and other
neuroendocrine carcinomas of various primary sites. Histopathology 36,
415-420.
Abstract: AIMS: The thyroid transcription factor-1 (TTF-1) is a
highly specific immunohistochemical marker for the identification of
pulmonary adenocarcinomas and non-neuroendocrine large cell carcinomas,
especially in patients presenting with metastatic carcinomas of unknown
primary site. In this study we tested if anti-TTF-1 can also be used to
verify a pulmonary origin of neuroendocrine carcinomas, placing emphasis on
the discrimination of pulmonary small cell carcinomas (SCCs) from
extrapulmonary SCCs and the distinction of SCCs from Merkel cell carcinomas
of the skin. METHODS AND RESULTS: We studied 37 pulmonary SCCs, 15 SCCs of
extrapulmonary origin, 4 pulmonary large cell neuroendocrine carcinomas
(LCNECs), four extrapulmonary LCNECs, six medullary thyroid carcinomas, 16
Merkel cell carcinomas, and a total of 32 carcinoids/low-grade
neuroendocrine carcinomas of pulmonary (12 cases) and extrapulmonary (20
cases) origin. Using the commercially available monoclonal antibody 8G7G3/1,
TTF-1 was immunohistochemically detectable in 81% of pulmonary SCCs but also
in 80% of extrapulmonary SCCs. Furthermore, anti-TTF-1 showed a positive
staining in 50% of all pulmonary carcinoids, in one gastric carcinoid, in
2/4 of pulmonary, and 1/4 of extrapulmonary LCNECs. All medullary thyroid
carcinomas were also TTF-1-positive. Merkel cell carcinomas were
consistently TTF-1-negative. CONCLUSIONS: Our results suggest that in
contrast to non-neuroendocrine carcinomas, anti-TTF-1 cannot be used to
prove or to exclude a pulmonary origin of SCCs or LCNECs of unknown or
uncertain primary site. Therefore, before using anti-TTF-1 as a marker for
pulmonary carcinomas one should be sure to have excluded SCC and LCNEC. On
the other hand, anti-TTF-1 might be used to specifically discriminate SCCs
of various origin from Merkel cell carcinomas
Kaufmann O & Dietel M (2000b) Thyroid transcription factor-1 is the
superior immunohistochemical marker for pulmonary adenocarcinomas and large
cell carcinomas compared to surfactant proteins A and B. Histopathology,
36, 8-16.
Abstract: AIMS: Antibodies against the thyroid transcription factor-1
(TTF-1) and the surfactant proteins A and B (SPA, SPB) were compared as
paraffin-reactive immunohistochemical markers for non-small cell carcinomas
of pulmonary origin. METHODS AND RESULTS: We studied 138 carcinomas of
pulmonary origin (98 adenocarcinomas, 20 non-neuroendocrine large cell
carcinomas, 20 squamous cell carcinomas) and a total of 276 extrapulmonary
carcinomas of various primary origins. Using the monoclonal antibody
8G7G3/1, TTF-1 was detectable in 75% of non-mucinous pulmonary
adenocarcinomas and in 40% of large cell carcinomas but in only 10% of
mucinous adenocarcinomas and not in squamous cell carcinomas. In contrast,
both SPA and SPB were positive in only 45% of pulmonary adenocarcinomas and
in 10% and in 5% of the large cell carcinomas, respectively. TTF-1 had a
specificity of 0.98 for pulmonary carcinomas as 5/7 thyroid carcinomas were
the only TTF-1-positive extrapulmonary tumours. Anti-SPB and anti-SPA had
specificities of 1. 00 and 0.97, respectively. CONCLUSIONS: The monoclonal
antibody 8G7G3/1 against TTF-1 should be the first choice as a component of
an antibody panel aiming to prove or to exclude the pulmonary origin of
non-mucinous adenocarcinomas and non-neuroendocrine poorly differentiated
carcinomas, especially in patients presenting with metastatic carcinomas of
unknown primary site
Khoor A, Whitsett JA, Stahlman MT, Olson SJ & Cagle PT (1999) Utility
of surfactant protein B precursor and thyroid transcription factor 1 in
differentiating adenocarcinoma of the lung from malignant mesothelioma. Hum
Pathol, 30, 695-700.
Abstract: Differentiation of malignant mesothelioma from
adenocarcinoma, particularly from a lung primary, remains a difficult
diagnostic problem. Surfactant protein B precursor (pro-SP-B) and thyroid
transcription factor 1 (ITF-1) are expressed selectively in the normal
respiratory epithelium and in adenocarcinomas of the lung. In this study, we
evaluated the utility of pro-SP-B and ITF-1 in distinguishing pulmonary
adenocarcinomas and malignant mesotheliomas. Immunoreactivity for pro-SP-B
and TTF-1 was examined in paraffin sections of 370 primary lung carcinomas
(208 adenocarcinomas, 101 squamous cell carcinomas, and 61 large cell
carcinomas) and 95 malignant mesotheliomas, using a pro-SP-B antiserum and a
monoclonal TTF-1 antibody with a biotin-streptavidin detection system.
Immunostaining for pro-SP-B was detected in 57% of adenocarcinomas, and 20%
of large cell carcinomas. Immunoreactivity for TTF-1 was shown in 76% of
adenocarcinomas and 26% of large cell carcinomas. Malignant mesotheliomas
and squamous cell carcinomas did not stain with either antibody. The
expression of pro-SP-B and TTF-1 in adenocarcinomas of the lung but not in
malignant mesotheliomas shows that pro-SP-B and TTF-1 staining is useful in
differentiating these neoplasms
Oliveira AM, Tazelaar HD, Myers JL, Erickson LA & Lloyd RV (2001)
Thyroid transcription factor-1 distinguishes metastatic pulmonary from
well-differentiated neuroendocrine tumors of other sites. AM J SURG
PATHOL, 25, 815-819.
Abstract: Metastatic neuroendocrine neoplasms can have similar
histologic appearances, and without an obvious primary, it may be difficult
to determine the site of origin of the metastasis. Thyroid transcription
factor-1 (TTF-1) is a nuclear protein expressed during the development of
thyroid, lung, and forebrain. The clinical utility of TTF-1 to
distinguishing between metastatic pulmonary and nonpulmonary
well-differentiated neuroendocrine tumors (WDNET) has not been previously
studied. One hundred fifty-eight primary and metastatic WDNET were evaluated
for TTF-1 expression. The tumors included 20 pulmonary WDNET, including 17
typical and 3 atypical carcinoid tumors, 10 metastatic pulmonary WDNET, 26
intestinal WDNET, 24 metastatic intestinal WDNET, 3 thymic mediastinal
WDNET, 30 thyroid tumors (10 medullary carcinomas, 5 follicular carcinomas,
5 follicular adenomas, 5 papillary carcinomas, and 5 anaplastic carcinomas),
10 parathyroid adenomas, 20 pituitary adenomas, 10 pancreatic WDNET, and 5
pheochromocytomas. TTF-1 expression was found in 19 of 20 (95%) pulmonary
WDNET, 8 of 10 (80%) metastatic pulmonary WDNET, and in 0 of 50 (0%)
intestinal WDNET. All thyroid tumors were diffusely positive for TTF-1,
except for three anaplastic carcinomas. All parathyroid and pituitary
adenomas, pancreatic and thymic WDNET, and pheochromocytomas were uniformly
negative for TTF-1. These results indicate that TTF-1 is clinically useful
in distinguishing metastatic pulmonary from metastatic WDNET of
extrapulmonary origin
Ordonez NG (2000a) Value of thyroid transcription factor-1 immunostaining
in distinguishing small cell lung carcinomas from other small cell
carcinomas. Am J Surg Pathol, 24, 1217-1223.
Abstract: The distinction between small cell lung carcinoma (SCLC)
and small cell carcinomas of other sites is difficult by routine histology.
Thyroid transcription factor-1 (TTF-1) is a homeodomain-containing
transcription factor that is selectively expressed in thyroid and pulmonary
epithelial cells. TTF-1 expression has also been demonstrated in
adenocarcinomas of the thyroid and lung, and SCLC. However, the value of
TTF-1 immunostaining in discriminating between SCLC and nonpulmonary small
cell carcinomas has not been investigated. In the present study using an
immunoperoxidase staining procedure on paraffin sections, we investigated
the expression of TTF-1 and cytokeratin 20 (CK20), a marker that has
previously been demonstrated in small cell carcinomas of the skin (Merkel
cell carcinomas), in 82 small cell carcinomas from a wide variety of sites
(28 lung, 18 skin, 12 gastrointestinal tract, 8 sinonasal, 5 bladder, 3
prostate, 3 uterine cervix, 2 thyroid, 2 salivary gland, and 1 pancreas).
Twenty-seven (96%) of the 28 SCLCs were positive for TTF-1. Among the
nonpulmonary small cell carcinomas, two tumors of the gastrointestinal
tract, one of the bladder, and one of the uterine cervix exhibited TTF-1
positivity. Sixteen (89%) of the 18 Merkel cell carcinomas and one SCLC were
CK20-positive. All other small cell carcinomas were negative for this
marker. These results indicate that although TTF-1 is not a specific marker
for SCLC, it may assist in distinguishing SCLC from some nonpulmonary small
cell carcinomas, particularly Merkel cell carcinoma, especially when it is
used in conjunction with CK20
Ordonez NG (2000b) Value of thyroid transcription factor-1, E-cadherin,
BG8, WT1, and CD44S immunostaining in distinguishing epithelial pleural
mesothelioma from pulmonary and nonpulmonary adenocarcinoma. Am J Surg
Pathol, 24, 598-606.
Abstract: The distinction between malignant pleural mesotheliomas and
adenocarcinomas, particularly those originating in the lung, is a difficult
diagnostic problem that can be facilitated by the use of immunohistochemical
markers. In this study, the immunoreactivity of thyroid transcription
factor-1 (TTF-1), E-cadherin, BG8, WT1, and CD44S was investigated in 50
epithelial mesotheliomas, and 40 pulmonary and 95 nonpulmonary
adenocarcinomas. After analyzing the results, it was concluded that
E-cadherin and BG8 are useful markers for distinguishing between epithelial
mesotheliomas and adenocarcinomas of various origins, including the lung.
Because TTF-1 expression is found almost exclusively in adenocarcinomas of
the lung but is absent in mesotheliomas, immunostaining for this marker is
particularly useful for distinguishing between these two malignancies.
Although WT1 immunostaining may also be useful, its value, as determined in
this study, is lower than that reported by other investigators. CD44S
immunostaining does not have any practical value in discriminating between
epithelial mesothelioma and lung adenocarcinoma
Reis-Filho JS, Carrilho C, Valenti C, Leitao D, Ribeiro CA, Ribeiro SG
& Schmitt FC (2000) Is TTF1 a good immunohistochemical marker to
distinguish primary from metastatic lung adenocarcinomas? Pathol Res
Pract, 196, 835-840.
Abstract: To evaluate the immunohistochemical expression of thyroid
transcription factor 1 (TTF1) in primary and metastatic pulmonary
adenocarcinomas, and test the diagnostic accuracy of this antibody, two
surgical pathologists independently evaluated 34 cases of adenocarcinomas in
the lung without clinical data and tried to distinguish between primary and
metastatic cases using histological criteria exclusively. Thirteen cases
were primary in the lung and 21 were metastases of extrapulmonary
adenocarcinomas: 6 from the endometrium, 4 from the ovary, 3 from the colon,
2 from the kidney, 2 from the breast, 2 from the liver and 1 from the
prostate. Afterward, the immunoreactivity of TTF1 in these neoplasms was
evaluated and correlated with morphological and clinical data. The two
pathologists were able to diagnose only 5 out of 13 cases of primary lung
adenocarcinomas (sensitivity of 38.46%) and also misdiagnosed two primary
malignancies as metastases. After correlation with TTF1 data, the
sensitivity increased to 61.53%. The specificity of TTF1 was 100%. In
conclusion, TTF1 is a highly specific marker for primary lung
adenocarcinomas, and should be included in a panel of antibodies for the
differential diagnosis between primary and metastatic adenocarcinomas of the
lung
Sturm N, Lantuejoul S, Laverriere MH, Papotti M, Brichon PY, Brambilla C
& Brambilla E (2001) Thyroid transcription factor 1 and cytokeratins 1,
5, 10, 14 (34betaE12) expression in basaloid and large-cell neuroendocrine
carcinomas of the lung. Hum Pathol, 32, 918-925.
Abstract: Basaloid carcinoma (BC) and large-cell neuroendocrine
carcinoma (LCNEC) are 2 recently recognized variants of large-cell lung
carcinomas that may overlap in their morphology, and are discriminated by
expression of neuroendocrine markers in LCNEC. Because thyroid transcription
factor 1 (TTF-1) is expressed in lung adenocarcinomas but not in squamous
cell carcinomas (SCC), and 34betaE12 recognizes a set of
high-molecular-weight cytokeratins characteristic of basal stem cells, we
hypothesized that these 2 markers could help in distinguishing BC from
LCNEC. Immunostaining for TTF-1 was detected in 40.9% of pure LCNEC but in
no BC or basaloid variant of SCC. In contrast, immunoreactivity for
34betaE12 was shown in all BC and basaloid variant of SCC but in only 1
LCNEC. Bouin fixation was less efficient than formalin in the
immunodetection of both markers for its well-known deleterious effect on
antigen preservation. Specificity of TTF-1 for LCNEC (100%) and that of
34betaE12 for BC (98.3%) exceeded that of NE markers for distinction of
these 2 entities. These data show that TTF-1 and 34betaE12, in association
with specific neuroendocrine markers, represent a useful panel of antibodies
in differentiating carcinomas presenting with a solid pattern, palisading,
or pseudorosettes, the expression of TTF-1 excluding the diagnosis of BC,
and staining with 34betaE12 excluding pure LCNEC.
