- Email: [email protected]
myc Family DNA amplification in small cell lung cancer cell lines and tumors
Lung Cance~ 4 (1988) 131-134
131
Elsevier mye FAMILY DNA AMPLIFICATION
IN SMALL CELL LUNG CANCER CELL LINES AND TUMORS
BRUCE E. JOHNSON AND ALFREDA SIMMONS NCI-Navy Medical Oncology Branch, Building 8, Room 5101,
Naval Hospital,
Bethesda Maryland 20814 USA INTRODUCTION myc family
DNA amplification
and mRNA expression has been shown to play an important
in the biology of small cell lung cancer, associated
and mRNA expression has been
with a variant subset of small cell lung cancer cell lines which have more aggressive
biologic characteristics proto-oncogene
than the more common classic phenotype
(1-4).
Transfectlon of the c-myc
leading to expression of c-myc mRNA in a small cell lung cancer cell llne which
did not express addition,
c-myc DNA amplification
role
c-myc mRNA reproduces
c-myc DNA amplification
some of these aggressive growth characteristics
(5).
In
has been associated with shortened survival in treated small
cell lung cancer patients who have had tumor cell lines established
(6).
other myc family members,
in small cell lung cancer
cell lines and tumors studied
N-myc and L-myc,
(7-i 2).
have also been described
The incidence of m vc family DNA amplification
in paraffin embedded small cell lung cancer tissue (13).
amplification described.
in unprocessed
However,
of
has also been
the incidence of DNA
cancer tissue from small cell lung cancer patients has not been
We therefore decided to systematically
tumors from small cell lung cancer patients amplification
DNA amplification
evaluate
the DNA prepared from cell lines and
treated at our branch.
pattern was correlated with the clinical presentation
The myc family DNA and outcome of the small cell
lung cancer patients and the results are reported here.
METHODS Cell lines were grown in RPMI 1640 plus 10% fetal calf serum and were harvested in log phase growth.
Tumors were obtained
examinations.
to nitrocellulose
l-Eco RI 3rd exon fragment
(14).
The DNA was digested with restriction endonucleases,
paper (15) and hybridized
to radiolabelled
c-myc probe, a Cla
(16), N-myc, an Ec___~oRI-Ba___mmHI second exon fragment
Sma l-Eco R1 third exon fragment (7). prepared.
and 30 post-mortem
The tumors were finely minced and the DNA was isolated from the cell ines and
tumors by the method of Heiter transferred
from 4 surgical biopsy specimens
The DNA was considered
(17), and L-myc,
to be amplified if the signal intensity was found to be four
fold greater than a single copy control.
The clinical course of the patient was reviewed
and survival duration from the initiation
of therapy was noted.
establishment
a
The blots were exposed to x-ray film and autoradiographs
of the cell line or procurement
In addition,
the date of the
of tumor tissue was noted.
RESULTS myc family DNA amplification
in small cell lun~ cancer cell lines
The DNA from cell lines established f or amplification
of
c-myc, N-myc and L-my c.
cell lines had c-myc amplification, (Table 1).
The DNA amplification
chemotherapy
untreated
The DNA from 7 small cell lung patients'
5 had N-m~c amplification,
small cell lung cancer patients.
from chemotherapy
tumor
and 6 had L-mycampllfication
was more common in tumor cell lines established
treated than untreated
cell lines established family genes
from 66 small cell lung cancer patients was examined
from
Fifteen of 35 (43%)
treated patients had-DNA amplification
of one of the myc
(7 c-myc, 4 N-myc, and 4 L-m~c) compared to 3 of 31 (10%) cell lines established
patients (I N-myc and 2 L-myc) .
Chemotherapy
whose tumor cell lines had c-mzc DNA amplification of chemotherapy
from
treated small cell lung cancer patients
lived a shorter period of time from initiation
than similar patients whose tumor cell lines did not have c-myc DNA amplification.
0169-5002/88/$03.50 © 1988 Elsevier Science Publishers B.V. (Biomedical Division)
132 TABLE I. mye FAMILY
DNA AMPLIFICATION
CHEMOTHERAPY
OF SMALL CELL LUNG CANCER CELL LINES AND ITS RELATIONSHIP
TO
TREATMENT
Chemotherapy
Treated
Untreated
c'-m.yc
7/35
N-myc
4/35
1/31
L-myc
4/35
2/31
TOTAL
15/35
3/31
The chemotherapy amplification
0/31
treated small cell lung cancer patients whose tumor cell lines had c-myc DNA
lived a median of 27 weeks
(range 13-58) compared
to 49 (range 19-112) weeks in
patients whose tumor cell lines did not show c-myc DNA amplification. myc family DNA amplification The DNA amplification was also studied
in small cell lun~ cancer tumors
pattern in tumors taken directly from small cell lung cancer patients
(Table 2).
The DNA from six patients who had received chemotherapy
having the tumor harvested was amplified None of the tumors obtained had DNA amplification
TABLE
prior to
for one of the myc family genes (4 N-myc and 2 L-myc).
from six patients who had not been treated with chemotherapy
of any of the m~,c family genes.
2.
myc FAMILY DNA AMPLIFICATION CHEMOTHERAPY
OF SMALL CELL LUNG CANCER TUMORS AND ITS RELATIONSHIP
TREATMENT
Chemotherapy
Treated
Untreated
c-m_,y_£.
0/28
0/6
N-myc
4/28
0/6
L~_~
2/28
0/6
TOTAL
6/28
0/6
The incidence of myc family DNA amplification established
TO
from patients
treated with chemotherapy
was more common in the tumor cell lines (15/35; 43%) studied here than in the tumors
obtained directly from similarly treated patients (6/28%; achieve statistical
significance
finding of myc family was unusual.
21%) although this difference did not
at the p~0.05 level using a chi-square
DNA amplification
analysis.
The
in tumors or tumor cell lines from untreated patients
Only 3 of 37 (8%) of untreated patients studied had DNA amplification
of one of the
myc family genes.
DISCUSSION myc family DNA amplification tumor tissue
of small cell lung cancer cell lines (I-4, 6-12), unprocessed
(7,9) and paraffin embedded
The percentage of myc family
tissue
DNA amplification
(13) has been reported by numerous investigators. in small cell lung cancer cell lines reported here
(20/66, 30%), is within the range of other recent reports of 2/4 (8), I/I (I0), 0/6 (II), and 5/6 (12) from studies of smaller numbers of cell lines. amplification
Although examples of myc family DNA
in tumors obtained directly from small cell lung cancer have been reported
this study reports the incidence of myc family patients whose tumors are not amplified.
DNA amplification
The incidence of myc family DNA amplification
cell lung cancer tumors reported here (6/34,
18%),
(7,9),
in tumors by also reporting the in small
is similar to that reported by Wong (13) in
133 their study of DNA extracted
from paraffin embedded small cell lung cancer tissue (5/45,
The results here extend our previous studies in small cell lung cancer. reported an association chemotherapy established
betweeen myc family
We have extended our analysis i0 established
from 44 tumor cell lines to 66.
chemotherapy
that myc family DNA amplification
and 12 from untreated patients,
family genes.
from the chemotherapy
In contrast,
treated patients was amplified for one of the myc
DNA from only 3/31 (10%) of the cell lines established
in cell lines established
to that reported previously exclusively
(5).
in tumor specimens
only 6 untreated patients'
This difference
between myc
from treated and untreated patients is similar
The study of tumors showed myc family DNA amplification
from chemotherapy
treated small cell lung cancer patients although
in tumor cell lines established
from chemotherapy
small cell lung cancer patients has been associated with shortened survival extended our previous observations after chemotherapy
on 25 patients
treatment.
lines had c-myc DNA amplification of 49 weeks
from untreated
tumors were studied.
c-myc DNA amplification
established
from
DNA prepared from 15 of 35, 43%, tumor
small cell lung cancer patients had myc family DNA amplification. DNA amplification
the previous
was more common in cell lines established
treated than untreated patients was still true. cell line established
With the addition
from tumors obtained from small cell lung cancer patients who
had been treated with combination
family
We have previously
in tumor cell lines and and previous
treatment of the small cell lung cancer patients from whom these cell lines were (6).
of 22 cell lines,
observation
DNA amplifcation
11%).
treated
(5).
We have
to 35 patients who have had cell lines
The 7 chemotherapy
treated patients whose tumor cell
lived a median of 27 weeks (range 13-58) compared to a median
(range 19-112) for patients whose tumor cell lines were not amplified for c-m~c.
In addition to this clinical association of c-myc DNA amplification cell lines with shortend patient survival, of c-myc DNA amplification
Gazdar and Carney have also reported an association
with a variant phenotype of small cell lung cancer cell line which
has more aggressive biologic characteristics have been reproduced by transfecting does not express proto-oncogene
in small cell lung cancer
c-myc mRNA (5).
plays an important
(1,2).
Some of these aggressive characteristics
a c-myc gene into a small cell lung cancer cell line which
This evidence suggests
that amplification
of the c-myc
role in the biology of small cell lung cancer.
study of myc family DNA amplification
will hopefully continue
The continued
to provide insights into the
biology of small cell lung cancer.
ACKNOWLEDGEMENTS The opionions
or assertions
contained herein are the private views of the authors and are not to
be construed as official or as reflecting
the views of the Department of the Navy or the
Department of Defense. REFERENCES I.
Gazdar AF, Carney DN, Nau MM, Minna J D (1985) Cancer Res 45:2924-2930
2.
Carney DN, Gazdar AF, Bepler G, Gucclon JG, Marangos P J, Moody I%/, Zweig MH, Minna J D (1985) Cancer Res 45:2913-2923
3.
Bepler G, Jaques G, Havemann K, Koehler A, Johnson BE, Gazdar AF (1987) Cancer Res 47: 1883-1891
4.
Little CD, Nau MM, Carney DN, C~zdar AF, Minna J D (1983) Nature 306:194-196
5.
Johnson BE, Battey J, Linnolla I, Becket KL, Makuch RW, Snider RH, Carney DN, Minna J D (1986) J Clin Invest 78:525-532
6.
Johnson BE, lhde DC, Makuch RW, C~zdar AF, Carney DN, Oie H, Russell E, Nau MM, Minna JD. (1987) J Clln Invest 79:1629-1634
134 7.
Nau MM, Brooks BJ, Battey J, Sausville E, Gezdar AF, McBride OW, Bertness V, Hollis GF, Minna JD (1985) Nature 318:69-73
8.
Saksela K, Bergh J, [ehto VP, Nllsson K, Alitalo K (1985) Cancer Res 45:1823-1827
9.
Nau /414, Brooks B J, Carney DN, Gazdar AF, Battey JF, Sausville EA, and Minna JD. (1986) Proc Natl Acad Scl USA 83:1092-1096
I0. Grazlano SL, Cowan BY, Carney DN, Bryke CR, Mitter NS, Johnson BE, Mark GE, Planas AT, Catlno J J, Corals RL, Polesz BJ (1987) Cancer Res 47:2148-2155 II. Morstyn G, Brown J, Navak U, Gardner J, Bishop J, Cerson M. (1987) Cancer Res 47:3332-3327 12. Klefer PE, Bepler G, Kubasch M, Havemann K (1987) Cancer Res 47:6236-6242 13. Wong AJ, Ruppert JM, Eggleston J, Hamilton SR, Baylln SB, and Vogelsteln B (1986) Science 233:461-464 14. Hieter PA, Hallls GF, Korsmeyer SJ, Waldman TA, fader P (1981) Nature 294:536-540 15. Southern EM (1975) J Mol Blol 98:503-517 16. Battey J, Moulding C, Taub R, Murphy W, Stewart T, Potter H, Lenoir G, heder P (1983) Cell 34:779-787 17. Schwab M, Alltalo K, Klempnauer KH, Varmus HE, Bishop JM, Gilbert F, Brodeur G, Goldsteln M, Trent J (1983) Nature 305:245-248
131
Elsevier mye FAMILY DNA AMPLIFICATION
IN SMALL CELL LUNG CANCER CELL LINES AND TUMORS
BRUCE E. JOHNSON AND ALFREDA SIMMONS NCI-Navy Medical Oncology Branch, Building 8, Room 5101,
Naval Hospital,
Bethesda Maryland 20814 USA INTRODUCTION myc family
DNA amplification
and mRNA expression has been shown to play an important
in the biology of small cell lung cancer, associated
and mRNA expression has been
with a variant subset of small cell lung cancer cell lines which have more aggressive
biologic characteristics proto-oncogene
than the more common classic phenotype
(1-4).
Transfectlon of the c-myc
leading to expression of c-myc mRNA in a small cell lung cancer cell llne which
did not express addition,
c-myc DNA amplification
role
c-myc mRNA reproduces
c-myc DNA amplification
some of these aggressive growth characteristics
(5).
In
has been associated with shortened survival in treated small
cell lung cancer patients who have had tumor cell lines established
(6).
other myc family members,
in small cell lung cancer
cell lines and tumors studied
N-myc and L-myc,
(7-i 2).
have also been described
The incidence of m vc family DNA amplification
in paraffin embedded small cell lung cancer tissue (13).
amplification described.
in unprocessed
However,
of
has also been
the incidence of DNA
cancer tissue from small cell lung cancer patients has not been
We therefore decided to systematically
tumors from small cell lung cancer patients amplification
DNA amplification
evaluate
the DNA prepared from cell lines and
treated at our branch.
pattern was correlated with the clinical presentation
The myc family DNA and outcome of the small cell
lung cancer patients and the results are reported here.
METHODS Cell lines were grown in RPMI 1640 plus 10% fetal calf serum and were harvested in log phase growth.
Tumors were obtained
examinations.
to nitrocellulose
l-Eco RI 3rd exon fragment
(14).
The DNA was digested with restriction endonucleases,
paper (15) and hybridized
to radiolabelled
c-myc probe, a Cla
(16), N-myc, an Ec___~oRI-Ba___mmHI second exon fragment
Sma l-Eco R1 third exon fragment (7). prepared.
and 30 post-mortem
The tumors were finely minced and the DNA was isolated from the cell ines and
tumors by the method of Heiter transferred
from 4 surgical biopsy specimens
The DNA was considered
(17), and L-myc,
to be amplified if the signal intensity was found to be four
fold greater than a single copy control.
The clinical course of the patient was reviewed
and survival duration from the initiation
of therapy was noted.
establishment
a
The blots were exposed to x-ray film and autoradiographs
of the cell line or procurement
In addition,
the date of the
of tumor tissue was noted.
RESULTS myc family DNA amplification
in small cell lun~ cancer cell lines
The DNA from cell lines established f or amplification
of
c-myc, N-myc and L-my c.
cell lines had c-myc amplification, (Table 1).
The DNA amplification
chemotherapy
untreated
The DNA from 7 small cell lung patients'
5 had N-m~c amplification,
small cell lung cancer patients.
from chemotherapy
tumor
and 6 had L-mycampllfication
was more common in tumor cell lines established
treated than untreated
cell lines established family genes
from 66 small cell lung cancer patients was examined
from
Fifteen of 35 (43%)
treated patients had-DNA amplification
of one of the myc
(7 c-myc, 4 N-myc, and 4 L-m~c) compared to 3 of 31 (10%) cell lines established
patients (I N-myc and 2 L-myc) .
Chemotherapy
whose tumor cell lines had c-mzc DNA amplification of chemotherapy
from
treated small cell lung cancer patients
lived a shorter period of time from initiation
than similar patients whose tumor cell lines did not have c-myc DNA amplification.
0169-5002/88/$03.50 © 1988 Elsevier Science Publishers B.V. (Biomedical Division)
132 TABLE I. mye FAMILY
DNA AMPLIFICATION
CHEMOTHERAPY
OF SMALL CELL LUNG CANCER CELL LINES AND ITS RELATIONSHIP
TO
TREATMENT
Chemotherapy
Treated
Untreated
c'-m.yc
7/35
N-myc
4/35
1/31
L-myc
4/35
2/31
TOTAL
15/35
3/31
The chemotherapy amplification
0/31
treated small cell lung cancer patients whose tumor cell lines had c-myc DNA
lived a median of 27 weeks
(range 13-58) compared
to 49 (range 19-112) weeks in
patients whose tumor cell lines did not show c-myc DNA amplification. myc family DNA amplification The DNA amplification was also studied
in small cell lun~ cancer tumors
pattern in tumors taken directly from small cell lung cancer patients
(Table 2).
The DNA from six patients who had received chemotherapy
having the tumor harvested was amplified None of the tumors obtained had DNA amplification
TABLE
prior to
for one of the myc family genes (4 N-myc and 2 L-myc).
from six patients who had not been treated with chemotherapy
of any of the m~,c family genes.
2.
myc FAMILY DNA AMPLIFICATION CHEMOTHERAPY
OF SMALL CELL LUNG CANCER TUMORS AND ITS RELATIONSHIP
TREATMENT
Chemotherapy
Treated
Untreated
c-m_,y_£.
0/28
0/6
N-myc
4/28
0/6
L~_~
2/28
0/6
TOTAL
6/28
0/6
The incidence of myc family DNA amplification established
TO
from patients
treated with chemotherapy
was more common in the tumor cell lines (15/35; 43%) studied here than in the tumors
obtained directly from similarly treated patients (6/28%; achieve statistical
significance
finding of myc family was unusual.
21%) although this difference did not
at the p~0.05 level using a chi-square
DNA amplification
analysis.
The
in tumors or tumor cell lines from untreated patients
Only 3 of 37 (8%) of untreated patients studied had DNA amplification
of one of the
myc family genes.
DISCUSSION myc family DNA amplification tumor tissue
of small cell lung cancer cell lines (I-4, 6-12), unprocessed
(7,9) and paraffin embedded
The percentage of myc family
tissue
DNA amplification
(13) has been reported by numerous investigators. in small cell lung cancer cell lines reported here
(20/66, 30%), is within the range of other recent reports of 2/4 (8), I/I (I0), 0/6 (II), and 5/6 (12) from studies of smaller numbers of cell lines. amplification
Although examples of myc family DNA
in tumors obtained directly from small cell lung cancer have been reported
this study reports the incidence of myc family patients whose tumors are not amplified.
DNA amplification
The incidence of myc family DNA amplification
cell lung cancer tumors reported here (6/34,
18%),
(7,9),
in tumors by also reporting the in small
is similar to that reported by Wong (13) in
133 their study of DNA extracted
from paraffin embedded small cell lung cancer tissue (5/45,
The results here extend our previous studies in small cell lung cancer. reported an association chemotherapy established
betweeen myc family
We have extended our analysis i0 established
from 44 tumor cell lines to 66.
chemotherapy
that myc family DNA amplification
and 12 from untreated patients,
family genes.
from the chemotherapy
In contrast,
treated patients was amplified for one of the myc
DNA from only 3/31 (10%) of the cell lines established
in cell lines established
to that reported previously exclusively
(5).
in tumor specimens
only 6 untreated patients'
This difference
between myc
from treated and untreated patients is similar
The study of tumors showed myc family DNA amplification
from chemotherapy
treated small cell lung cancer patients although
in tumor cell lines established
from chemotherapy
small cell lung cancer patients has been associated with shortened survival extended our previous observations after chemotherapy
on 25 patients
treatment.
lines had c-myc DNA amplification of 49 weeks
from untreated
tumors were studied.
c-myc DNA amplification
established
from
DNA prepared from 15 of 35, 43%, tumor
small cell lung cancer patients had myc family DNA amplification. DNA amplification
the previous
was more common in cell lines established
treated than untreated patients was still true. cell line established
With the addition
from tumors obtained from small cell lung cancer patients who
had been treated with combination
family
We have previously
in tumor cell lines and and previous
treatment of the small cell lung cancer patients from whom these cell lines were (6).
of 22 cell lines,
observation
DNA amplifcation
11%).
treated
(5).
We have
to 35 patients who have had cell lines
The 7 chemotherapy
treated patients whose tumor cell
lived a median of 27 weeks (range 13-58) compared to a median
(range 19-112) for patients whose tumor cell lines were not amplified for c-m~c.
In addition to this clinical association of c-myc DNA amplification cell lines with shortend patient survival, of c-myc DNA amplification
Gazdar and Carney have also reported an association
with a variant phenotype of small cell lung cancer cell line which
has more aggressive biologic characteristics have been reproduced by transfecting does not express proto-oncogene
in small cell lung cancer
c-myc mRNA (5).
plays an important
(1,2).
Some of these aggressive characteristics
a c-myc gene into a small cell lung cancer cell line which
This evidence suggests
that amplification
of the c-myc
role in the biology of small cell lung cancer.
study of myc family DNA amplification
will hopefully continue
The continued
to provide insights into the
biology of small cell lung cancer.
ACKNOWLEDGEMENTS The opionions
or assertions
contained herein are the private views of the authors and are not to
be construed as official or as reflecting
the views of the Department of the Navy or the
Department of Defense. REFERENCES I.
Gazdar AF, Carney DN, Nau MM, Minna J D (1985) Cancer Res 45:2924-2930
2.
Carney DN, Gazdar AF, Bepler G, Gucclon JG, Marangos P J, Moody I%/, Zweig MH, Minna J D (1985) Cancer Res 45:2913-2923
3.
Bepler G, Jaques G, Havemann K, Koehler A, Johnson BE, Gazdar AF (1987) Cancer Res 47: 1883-1891
4.
Little CD, Nau MM, Carney DN, C~zdar AF, Minna J D (1983) Nature 306:194-196
5.
Johnson BE, Battey J, Linnolla I, Becket KL, Makuch RW, Snider RH, Carney DN, Minna J D (1986) J Clin Invest 78:525-532
6.
Johnson BE, lhde DC, Makuch RW, C~zdar AF, Carney DN, Oie H, Russell E, Nau MM, Minna JD. (1987) J Clln Invest 79:1629-1634
134 7.
Nau MM, Brooks BJ, Battey J, Sausville E, Gezdar AF, McBride OW, Bertness V, Hollis GF, Minna JD (1985) Nature 318:69-73
8.
Saksela K, Bergh J, [ehto VP, Nllsson K, Alitalo K (1985) Cancer Res 45:1823-1827
9.
Nau /414, Brooks B J, Carney DN, Gazdar AF, Battey JF, Sausville EA, and Minna JD. (1986) Proc Natl Acad Scl USA 83:1092-1096
I0. Grazlano SL, Cowan BY, Carney DN, Bryke CR, Mitter NS, Johnson BE, Mark GE, Planas AT, Catlno J J, Corals RL, Polesz BJ (1987) Cancer Res 47:2148-2155 II. Morstyn G, Brown J, Navak U, Gardner J, Bishop J, Cerson M. (1987) Cancer Res 47:3332-3327 12. Klefer PE, Bepler G, Kubasch M, Havemann K (1987) Cancer Res 47:6236-6242 13. Wong AJ, Ruppert JM, Eggleston J, Hamilton SR, Baylln SB, and Vogelsteln B (1986) Science 233:461-464 14. Hieter PA, Hallls GF, Korsmeyer SJ, Waldman TA, fader P (1981) Nature 294:536-540 15. Southern EM (1975) J Mol Blol 98:503-517 16. Battey J, Moulding C, Taub R, Murphy W, Stewart T, Potter H, Lenoir G, heder P (1983) Cell 34:779-787 17. Schwab M, Alltalo K, Klempnauer KH, Varmus HE, Bishop JM, Gilbert F, Brodeur G, Goldsteln M, Trent J (1983) Nature 305:245-248