Acute leukemia has a high concordance rate in young identical twins and in infants this is known, from molecular analysis, to reflect an in utero origin in one twin followed by prenatal metastasis to the other twin via intraplacental anastomoses. The situation in older twins with leukemia has been less clear. We describe a pair of identical twins who were diagnosed with a T-cell malignancy at 9 and 11 years of age, one with T-cell non-Hodgkin's lymphoma and the other with T-cell acute lymphoblastic leukemia. Leukemic cells from the twins shared the same TCRβ gene rearrangement with an identical 11 bp N region. The most plausible interpretation of this result is that these malignancies were initiated in one twin fetus in utero, in a single T-lineage cell that had stable bi-allelic TCRβ rearrangements. Progeny of this cell then spread to the other twin before birth via shared placental vasculature. This was then followed by a 9- and 11-year preleukemic latent period before clinical disease manifestation as leukemia or lymphoma. This result has considerable implications for the etiology and natural history of pediatric leukemia.

THE ETIOLOGY of acute leukemia in young children is likely to involve critical events that occur in infancy, perinatally, or prenatally.1 Backtracking individual leukemias to these periods is difficult experimentally and definitive evidence for such early events has been, until recently, lacking. In rare cases of pediatric leukemias, inherited genetic abnormalities are involved2,3 but in the majority of cases it is assumed that constitutive mutations are absent and that initiating mutations occur postfertilization.1 For those relatively infrequent acute leukemias that present at birth or neonatally,4-9 an origin during fetal hematopoiesis is obvious. Many of these newborn or congenital cases have chromosome alterations involving 11q237 and rearrangement of the MLL gene.8,9 Other evidence has also been very suggestive of prenatal origins of some pediatric leukemias. In particular, prenatal or pregnancy associated risk factors, eg, diagnostic X-irradiation, alcohol or other exposures of the pregnant mother10-13 have been linked in epidemiological studies to increased risk of leukemia in offspring. The lack of N region nucleotides in rearranged IGH genes has been taken as an indication of a prenatal origin in B-cell precursor acute lymphoblastic leukemia (ALL) in young (<3 year) patients on the grounds that TdT activity is low in B-cell lymphopoiesis before birth.14,15 Definitive evidence of an in utero origin of some pediatric leukemias has been provided by studies of clonal markers in concordant leukemias of identical twins. Infant identical twins have a high (∼25%) concordance rate of acute leukemia16 and long-standing evidence has suggested that this probably reflects a prenatal clonal origin in one twin followed by metastatic spread to the other twin via intraplacental anastomoses.1,17 Convincing evidence for this interpretation of concordance was provided by the observation that each of four pairs of infant twins with leukemia shared the same unique MLL gene rearrangement.18-20 In two of these cases,18,20 plus another infant (Siamese) twin pair21 that we reported, there was also a common IGH gene rearrangement as judged by restriction fragment size in Southern blots. An in utero origin of infant acute leukemia is therefore likely in most if not all cases, but no such unambiguous data has existed for leukemia in older children. We report here a unique pair of identical twins with T-cell malignancy that provides such evidence.

Preparation of DNA

DNA was prepared essentially as described in Ford et al22 either from fresh leukemic cells isolated from bone marrow (BM) and peripheral blood or from scraped BM smears or cytospin preparations.

Southern Blot Analysis of Gene Rearrangement and Zygosity Status

DNA was digested with the restriction enzymes stated in the text, electrophoresed through 0.7% agarose gels, transferred to Magnacharge Nylon (Sartorius, Goettingen, Germany) and hybridized to either a probe containing the constant region of the TCRβ gene,23 the TCRγ joining region,24 or the joining region of the IGH gene.25 Confirmation of monozygosity was achieved using the multilocus fingerprinting probe 33.15 (Cellmark Diagnostics, Abingdon, UK).

Polymerase Chain Reaction (PCR) Analysis of Gene Rearrangement

Antigen receptor gene rearrangements were also examined by PCR using primers complementary to the consensus sequences within the framework 3 region of the variable regions and the joining regions of the IGH gene; consensus sequences within the variable, diversity, and joining regions of the TCRβ chain genes and consensus sequences within the variable and joining regions of the TCRγ chain genes.26 Controls included omission of DNA, a B-lymphoma sample rearranged for IGH but not TCRβ and primers for BCL-2.27  Reaction conditions were as previously described.26 PCR products were separated by electrophoresis on 10% polyacrylamide gels, stained with ethidium bromide, and visualized under UV light.

Cloning and Sequencing of PCR Products

Fragments amplified using primers from the diversity and joining regions of the TCRβ gene were also separated through 2.5% Low Gel agarose (Severn Biotech, Kidderminster, UK). After electrophoresis, gels were photographed and the fragment migrating with identical mobility for each twin was cut out. The separate fragments from each twin were then cloned into the Sma I site of Puc18 using a Sureclone Ligation kit (Pharmacia, Uppsala, Sweden). After transformation, 10 colonies from each twin were picked and screened for the presence of inserts. Five positive colonies from each individual screen were then amplified, sequenced on an Applied Biosystems 373A automated DNA sequencer, and further analyzed by Geneworks 2.1 (Intelligenetics, California).

The Twin Pregnancy

The parents were unrelated Brazilians of Portuguese origin. There was no family history of leukemia or lymphoma and there are no other siblings. The twin pregnancy and delivery were normal. During the pregnancy, the mother did not smoke or take alcohol, any drugs or antibiotics. There were no known infections during pregnancy and no exposure to diagnostic x-rays. The twin placenta was single, ie, monochorionic. The twin boys were of identical appearance and their monozygosity has been confirmed using Southern blotting with variable numbers of random-repeat (units) probes (data not shown).

Clinical Presentation

Twin 1.A 9-year-old boy presented in August 1992 with unexpected dyspnea and was admitted to a hospital for clinical examination. He was in satisfactory general condition and physical examination was normal. Chest x-ray and computerized tomography (CT) scan revealed a large mediastinal mass. A biopsy of the mediastinal mass disclosed a lymphoblastic lymphoma. Blood counts and biochemistry were normal and there were no malignant cells in the BM and/or cerebrospinal fluid. Chemotherapy was given following the German protocol BFM-83 (for high-risk ALL) with prophylaxis of the central nervous system (CNS, 18 Gy divided in 10 fractions). In November 1993 (16 months from diagnosis), while still under maintenance, he presented with drowsiness and left facial palsies. A brain CT scan showed a mass in the skull base. Stereotactic biopsy was performed and histology was consistent with lymphoblastic lymphoma. He received further cranial radiotherapy (18 Gy) and chemotherapy using the BFM protocol for relapsed ALL. This treatment resulted in minor improvement but progression of neurological symptoms with partial left hemiplegia, swallowing difficulties and dysphasia. In April 1995, a white blood cell (WBC) count showed: WBC 9.3 × 109/L with 30% lymphocytes and 10% blasts; there was no organomegaly. The immunophenotype (%) of the circulating cells was consistent with T-ALL/lymphoblastic lymphoma: CD2: 100, CD7: 92, cytoplasmic CD3: 100, CD1a: 30, CD4: 78, CD8: 72, CD38: 86 TdT:10; cells were negative with CD34, CD25, HLADR, CD19, CD10, αβTCR (cell surface) and γδTCR (cell surface). Because of persistent CNS involvement, the patient received symptomatic and palliative treatment, and in April 1996 was alive in a stable clinical condition.

Twin 2.An 11-year-old boy was admitted to the Hospital do Cancer, Rio de Janeiro, in April 1995 for bone pain and atony. Physical examination showed hepatosplenomegaly (spleen and liver were palpable 8 cm and 4 cm below the costal margins, respectively). There was no lymphadenopathy and neurological examination was normal. Blood counts showed hemoglobin 14.0 g/dL, WBC 193.0 × 109/L with 84% of blasts and platelets 77.0 × 109/L. Biochemistry was normal except for a high level of lactic dehydrogenase (1.114 UI) and cerebrospinal fluid was normal. BM aspirate showed replacement of normal hematopoiesis by medium to large blasts with rather irregular chromatin, 1 to 2 nucleoli compatible with ALL-L2 (French-American-British criteria). Immunophenotyping of the blood and marrow cells performed by flow cytometry and immunocytochemistry showed the following (%) results: CD2: 100, CD7: 94, CD38: 99, cytoplasmic CD3: 100, cell surface CD3: 94, CD4: 92, CD8: 92, CD1a: 74 and CD10: 10; cells were negative with CD34, CD25, TdT, HLADR, CD19, αβTCR (cell surface), and γδTCR. Cytogenetic analysis of BM cells identified 20 (50%) normal cells and 50% that were 46XY del (4) (q12) i (14)(q10).28 The patient was treated according to the German protocol BFM-83 (for high-risk) achieving complete remission. He was given maintenance therapy with 6-mercaptopurine and methotrexate but relapsed in the BM and CNS. At present (August 1996) he is hospitalized with severe aplasia following reinduction chemotherapy.

These presentation features are compatible with the diagnoses of T-NHL and T-ALL with a similar immunophenotype corresponding to the subset of CD1a+, CD4+/CD8+ cortical thymocytes of intermediate differentiation status.29,30 Such cases can be TdT negative at initial diagnosis as described here although the majority are TdT positive. Mature T-cell lymphoproliferative disease or leukemia (eg, T-cell prolymphocytic leukemia31; or human T-cell lymphotropic virus 1 [HTLV-1] associated adult T-cell leukemia/lymphoma32 ) is excluded by age, clinical features, morphology, and immunophenotype. Both cases were seronegative for HTLV-1. In his recent relapse, twin 2 leukemic cells were 40% TdT positive.

T-cell receptor β,γ gene and IGH gene rearrangements.Southern blot analysis of DNA from diagnostic samples (relapse blood in twin 1, pretreatment diagnostic blood in twin 2) revealed that the twins both had bi-allelic rearrangements of TCRβ with apparently identical sized restriction fragments suggesting similar or identical clonal rearrangements. The size of these fragments is indicative of one VDJβ and one DJβ rearrangement (Fig 1A). The identity of these rearrangements was analyzed by PCR. Using D and J region primers, a single identically sized fragment was amplified from the paired leukemic DNA. PCR was performed in laboratory conditions that did not provide any opportunity for cross-contamination and the same clonal rearrangements were amplified on a separate occasion from additional independent leukemic DNA samples retrieved from cytospin preparations (data not shown). The twin 1 DNA had a single V-JH rearrangement detectable by PCR which was absent in twin 2 DNA (Fig 1). The twin samples also appeared to have identical bi-allelic TCRγ rearrangements by both PCR (Fig 1B) and Southern blotting (data not shown). The PCR amplified TCRβ DJ rearrangement (Fig 1B) was then cloned independently from each twin sample as described in Materials and Methods. Sequencing of five independent clones from each twin revealed a single sequence (Fig 1C) which involved the joining of Dβ1 to Jβ2.4 with the deletion of the intervening sequences and addition of an identical N region of 11 nucleotides. Because one twin (2) was found to have isochromosome 14q, we attempted to verify this by FISH methodology and to similarly assess cells from twin 1. Unfortunately, the cell smears available were of inadequate quality for this purpose and no interpretable result was obtained.

Fig. 1.

Identical rearrangements of T-cell receptor genes in concordant twin T-cell malignancy. (A) Southern blot analysis of TCRβ rearrangements showing shared bi-allelic rearrangements (same sized restriction fragments). gl, germ line position. (B) PCR analysis of TCR and IGH gene rearrangements in the twin pair showing identical sized amplified bands for both TCRβ (TCRB) and TCRγ (TCRG) in the twin pair. Note twin 1 also has a weak clonal VDJ-IGH rearrangement that is absent in twin 2. It is not possible to say whether or not this clonal rearrangement was in the T-cell leukemic clone. bcl-2 primers were used as negative controls. M, markers. (C) Sequence comparison of cloned DJ-TCRβ amplicons showing identical N region (boxed).

Fig. 1.

Identical rearrangements of T-cell receptor genes in concordant twin T-cell malignancy. (A) Southern blot analysis of TCRβ rearrangements showing shared bi-allelic rearrangements (same sized restriction fragments). gl, germ line position. (B) PCR analysis of TCR and IGH gene rearrangements in the twin pair showing identical sized amplified bands for both TCRβ (TCRB) and TCRγ (TCRG) in the twin pair. Note twin 1 also has a weak clonal VDJ-IGH rearrangement that is absent in twin 2. It is not possible to say whether or not this clonal rearrangement was in the T-cell leukemic clone. bcl-2 primers were used as negative controls. M, markers. (C) Sequence comparison of cloned DJ-TCRβ amplicons showing identical N region (boxed).

Close modal

These data provide compelling evidence that the T-lymphoblastic lymphoma and T-lymphoblastic leukemia clones from identical twins had originated from the same single cell. The probability of two independent clones of T cells sharing an identical 11 bp N region in a rearranged TCRβ gene by chance alone is 1× 4−11. That the same T-cell clone can be associated with a diagnosis of pediatric T-ALL or T-NHL accords with the notion that these divergent clinical diagnoses are somewhat artificial and may disguise a common biological origin in T-cell precursors.33 

There are several theoretical possibilities to explain how this shared clonality might have arisen. One is that the twins became chimeric for normal T lymphocytes and other blood cells, before birth via their shared placental circulation and that cells belonging to the same T-cell clone were independently transformed postnatally — for example by mutation following extensive clonal expansion or proliferative stress via antigen recognition. This seems highly unlikely as it would require extraordinarily stringent immunological selection of cells from within a subclone of both twins, expressing not only the same VDJβ segments but the same N region. A second theoretical interpretation is that the leukemia developed postnatally in one twin and was somehow transferred to the other twin, who, being genetically identical, would not reject the accidental transplant. This would be operationally equivalent to the successful transplantation of animal leukemic cells between immunocompetent but inbred strains and similar to accidental transfer of cancer cells to immunosuppressed organ transplant recipients.34 The only documented “spontaneous” example of such a transfer of cancer cells, other than anecdotal reports on patients,35,36 is that of so-called infectious canine venereal sarcoma, the first cancer to be successfully transplanted 100 years ago, and which spreads via sexual contact.37 Successful, parasite-like, dissemination of malignant T cells between identical twins would require, we assume, body fluid and probably blood exchange. No blood transfusion between the twins has occurred and since we can think of no physical mechanism to facilitate such a transfer we consider it highly improbable, though not refuted.

The third and most plausible explanation is the same as that provided earlier for concordant leukemia in identical twin infants.17,18 This is that a single T cell in one twin in utero was subject to a transforming hit or mutation. This cell had already undergone stable allelic TCR β and γ rearrangements and these were preserved and present in the eventual leukemic and lymphoma subclones. Subsequently, but still prenatally, clonal descendants of this transformed cell metastasized to the other twin via the intraplacental anastomoses that commonly exist in monochorionic placentas.38 We cannot prove that this interpretation is correct in the absence of a unique, clonal mutation, equivalent to the MLL rearrangement in twin infant acute lymphoblastic leukemias; the T lymphoma/ALL cells were negative for all candidate genetic abnormalities assessed including TAL deletion, TCL-1 rearrangement and p53 mutations (exons 5-8) (data not shown).

What is extraordinary about this twin pair, compared with the infant twins, is that if the above interpretation is correct, then after birth the transformed or premalignant cells laid dormant or under some form of control many years before their eventual emergence as a dominant T lymphoma or T-cell acute lymphoblastic leukemia clone after 9 and 11 years, respectively, in the two twins. However, given the extended intervals between known genotoxic exposures and clinical leukemia,39,40 a latency of 9 or 11 years is not biologically implausible. Furthermore, a preclinical phase of clonal expansion of more than 10 years has been documented in serial studies on a patient with ataxia telangiectasia (AT) and T-cell leukemia.41 Because there is an increased concordance of T-cell leukemia in siblings with AT,41 we also considered the possibility that our twin pair might have had AT. Although both twins had hearing and balance problems from birth, in all other respects they lacked the clinical features of AT with no telangiectasias and no other neurological problems. Their development has been normal and they have had no signs of immunodeficiency (eg, recurrent infections).

More than 50 pairs of twins with concordant leukemia during childhood have been reported in the literature over the past 60 years but as far as we are aware, this is the first pair with T-cell leukemia. One adult pair of identical twins with concordant cutaneous T-cell lymphoma have been recorded.42 These had different TCRβ rearrangements. The concordance rate of T lymphoma/leukemia is unknown though probably significantly less than that of infants with ALL. We are aware of two examples of discordant T-ALL in identical twins (ie, where only one twin has T-ALL) and assume other such cases exist and are unreported. But lack of concordance in such pairs does not necessarily argue against a prenatal origin. First, only around 60% of monozygotic twins share a monochorionic placenta38 where the opportunities for interfetal migration of blood cells are optimized. Second, the twins could be discordant for some exposure or other postnatal event that is required for the preleukemia to leukemia conversion.

In the cases we report, a prenatal origin would never have been suspected were it not for the fact that two patients were identical twins. There is no reason to suppose that the etiological initiation of leukemia in a progenitor cell of a twin is any different in terms of mechanism and timing from that in non-twinned individuals. Therefore, we suggest that it is very likely that at least some other pediatric T malignancies are initiated in utero.

We thank Ramsa C. Harab and Marcelo H. Gomes for technical assistance, Dr G. Saglio for p53 mutation screening, Karin Gale for TAL-1 deletion screening, Dr Martin Yuille for TCl-1 rearrangement screening, Dr Elisabeth Vandenberghe for chromosome 14 FISH analysis, Dr Estela Matutes for review of the cases and Drs John Brown and Leanne Wiedemann for helpful suggestions, and Barbara Deverson with help in preparation of the manuscript.

Supported by the Leukaemia Research Fund (UK) and the Kay Kendall Leukaemia Fund.

Address reprint requests to Mel Greaves, PhD, Leukaemia Research Fund Centre, Institute of Cancer Research, Chester Beatty Laboratories, 237 Fulham Rd, London SW3 6JB UK.

1
Greaves
M
A natural history for pediatric acute leukemia.
Blood
82
1993
1043
2
Taylor GM, Birch JM: The hereditary basis of human leukemia, in Henderson ES, Lister TA, Greaves MF (eds): Leukemia, (ed 6). Philadelphia, PA, Saunders, 1996, p 210
3
Narod
SA
Stiller
C
Lenoir
GM
An estimate of the heritable fraction of childhood cancer.
Br J Cancer
63
1991
993
4
Gray
ES
Balch
NJ
Kohler
H
Thompson
WD
Simpson
JG
Congenital leukaemia: An unusual cause of stillbirth.
Arch Dis Child
61
1986
1001
5
Las
Heras J
Leal
G
Haust
MD
Congenital leukemia with placental involvement.
Cancer
58
1986
2278
6
Mattelaer
PM
Riley
HD
Leukemia in the perinatal period.
Ann Paediat
203
1964
124
7
Abe
R
Ryan
D
Cecalupo
A
Cohen
H
Sandberg
AA
Cytogenetic findings in congenital leukemia: Case report and review of the literature.
Cancer Genet Cytogenet
9
1983
139
8
Matamoros
N
Matutes
E
Hernandez
M
Galmes
A
Perez-Payarols
J
Buccheri
V
Morilla
R
Catovsky
D
Healy
LE
Ridge
SA
Greaves
MF
Neonatal mixed lineage acute leukaemia.
Leukemia
8
1994
1236
9
Ridge
SA
Cabrera
ME
Ford
AM
Tapia
S
Risueño
C
Labra
S
Barriga
F
Greaves
MF
Rapid intraclonal switch of lineage dominance in congenital leukaemia with a MLL gene rearrangement.
Leukemia
9
1995
2023
10
Stewart A, Webb J, Giles D, Hewitt D: Malignant disease in childhood and diagnostic irradiation in utero. Lancet ii:447, 1956
11
Shu
X-O
Ross
JA
Pendergrass
TW
Reaman
GH
Lampkin
B
Robison
LL
Parental alcohol consumption, cigarette smoking, and risk of infant leukemia: A Childrens Cancer Group Study.
J Natl Cancer Inst
88
1996
24
12
Robison
LL
Buckley
JD
Daigle
AE
Wells
R
Benjamin
D
Arthur
DC
Hammond
GD
Maternal drug use and risk of childhood nonlymphoblastic leukemia among offspring.
Cancer
63
1989
1904
13
Ross
JA
Davies
SM
Potter
JD
Robison
LL
Epidemiology of childhood leukemia, with a focus on infants.
Epidemiol Rev
16
1994
243
14
Wasserman
R
Galili
N
Ito
Y
Reichard
BA
Shane
S
Rovera
G
Predominance of fetal type DJH joining in young children with B precursor lymphoblastic leukemia as evidence for an in utero transforming event.
J Exp Med
176
1992
1577
15
Steenbergen
EJ
Verhagen
OJHM
van Leeuwen
EF
Behrendt
H
Merle
PA
Wester
MR
von dem Borne
AEGKr
van der Schoot
CE
B precursor acute lymphoblastic leukemia third complementarity-determining regions predominantly represent an unbiased recombination repertoire: Leukemia transformation frequently occurs in fetal life.
Eur J Immunol
24
1994
900
16
Zuelzer
WW
Cox
DE
Genetics aspects of leukemia.
Semin Hematol
228
1969
228
17
Clarkson
B
Boyse
EA
Possible explanation of the high concordance for acute leukaemia in monozygous twins.
Lancet
1
1971
699
18
Ford
AM
Ridge
SA
Cabrera
ME
Mahmoud
H
Steel
CM
Chan
LC
Greaves
M
In utero rearrangements in the trithorax-related oncogene in infant leukaemias.
Nature
363
1993
358
19
Gill
Super HJ
Rothberg
PG
Kobayashi
H
Freeman
AI
Diaz
MO
Rowley
JD
Clonal, nonconstitutional rearrangements of the MLL gene in infant twins with acute lymphoblastic leukemia: In utero chromosome rearrangement of 11q23.
Blood
83
1994
641
20
Mahmoud
HH
Ridge
SA
Behm
FG
Pui
C-H
Ford
AM
Raimondi
SC
Greaves
MF
Intrauterine monoclonal origin of neonatal concordant acute lymphoblastic leukemia in monozygotic twins.
Med Pediatr Oncol
24
1995
77
21
Pombo de Oliveira MS, Awad el Seed FER, Foroni L, Matutes E, Morilla R, Luzzatto L, Catovsky D: Lymphoblastic leukaemia in Siamese twins: Evidence for identity. Lancet ii:969, 1986
22
Ford
AM
Molgaard
HV
Greaves
MF
Gould
HJ
Immunoglobulin gene organisation and expression in haemopoietic stem cell leukaemia.
EMBO J
2
1983
997
23
Toyonaga
B
Mak
T
Genes of the T-cell antigen receptor in normal and malignant T cells.
Ann Rev Immunol
5
1987
585
24
Lefranc
MP
Rabbitts
T
Two tandemly organised human genes encoding the T-cell g constant-region sequences show multiple rearrangement in different T-cell types.
Nature
316
1985
464
25
Ravetch
JV
Siebenlist
U
Korsmeyer
S
Waldmann
T
Leder
P
Structure of human immunoglobulin Mu locus-Characterization of embryonic & rearranged J-genes & D-genes.
Cell
27
1981
583
26
Slack
DN
McCarthy
KP
Wiedemann
LM
Sloane
JP
Evaluation of the sensitivity, specificity and reproducibility of an optimized method for detecting clonal rearrangements of immunoglobulin and T-cell receptor genes in formalin-fixed, paraffin-embedded sections.
Diagn Mol Pathol
2
1993
223
27
Cleary
ML
Sklar
J
Nucleotide sequence of a t(14; 18) chromosomal breakpoint in follicular lymphoma and demonstration of a breakpoint cluster region near a transcriptional active locus on chromosome 18.
Proc Natl Acad Sci USA
82
1985
7439
28
Silva
MLM
Zalcberg
IQ
De Souza
MHO
Simões
FV
Cariço
KC
Tabak
DG
Ribeiro
RC
Abdelhay
E
Isochromosome 14q in T cell childhood acute lymphoblastic leukemia.
Cancer Genet Cytogenet
81
1996
1
29
Greaves
MF
Rao
J
Hariri
G
Verbi
W
Catovsky
D
Kung
P
Goldstein
G
Phenotypic heterogeneity and cellular origins of T cell malignancies.
Leuk Res
5
1981
81
30
Matutes
E
Brito-Babapulle
V
Swansbury
J
Ellis
J
Morilla
R
Dearden
C
Sempere
A
Catovsky
D
Clinical and laboratory features of 78 cases of T-prolymphocytic leukemia.
Blood
78
1991
3269
31
van Dongen JJM, Adriaansen HJ: Immunobiology of leukemia, in (eds): Henderson ES, Lister TA, Greaves MF: Leukemia, (ed 6). Philadelphia, PA, Saunders, 1996, pp 83-130
32
Takatsuki K, Matsuoka M, Yamaguchi K. Adult T-cell leukemia, in (eds): Henderson ES, Lister TA, Greaves MF: Leukemia, (ed 6). Philadelphia, PA, Saunders, 1996, pp 596-602
33
Magrath IT: The Non-Hodgkin's Lymphomas. Edward Arnold, London, UK, 1990
34
Penn
I
Tumors arising in organ transplant recipients.
Adv Cancer Res
28
1978
32
35
Parkes
Weber F
Schwarz
E
Hellenschmied
R
Spontaneous inoculation of melanotic sarcoma from mother to foetus.
Br Med J
1
1930
537
36
Balacesco
I
Tzovaru
DS
Une observation authentique de transmission spontanée du cancer d'homme à homme.
Bull du Cancer
25
1936
655
37
Cohen
D
The transmissible venereal tumor of the dog-a naturally occurring allograft.
Isrl J Med Sci
14
1978
14
38
Strong SJ, Corney G: The placenta in twin pregnancy. Oxford, UK, Pergamon, 1967
39
Boice JD, Inskip PD: Radiation-induced leukemia, in Henderson ES, Lister TA, Greaves MF (eds): Leukemia, (ed 6). Philadelphia, PA, Saunders, 1996, p 195
40
Grünwald H, Rosner F: Chemicals and leukemia, in Henderson ES, Lister TA, Greaves MF (eds): Leukemia, (ed 6). Philadelphia, PA, Saunders, 1996, p 179
41
Taylor
AMR
Metcalfe
JA
Thick
J
Mak
Y-F
Leukemia and lymphoma in ataxia telangiectasia.
Blood
87
1996
423
42
Schneider
BF
Christian
M
Hess
CE
Williams
ME
Familial occurrence of cutaneous T cell lymphoma: A case report of monozygotic twin sisters.
Leukemia
9
1995
1979
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