Chromosome abnormalities in a pancreatic adenocarcinoma

Short-term cultures initiated from a pancreatic adenocarcinoma were cytogenetically investigated. The composite karyotype was 74-76,XX,+X,+2,+3,+del(3)(p21),+5,+5,+der(7) t(1;7)(q21;p22),+der(7),del(8)(p21),+del(8)(p21),+der(8)t(8;?)(q24; +),+9,+9,+10,+10,+11,+11,+12,+13,+14,+der(14)t(14; +)(p11;?),+der(16)t(15;16)(q11;p13),+der(16),+der(17)t(17;?) (p11;?),+der(17),+18,+20,+20,-21,-21,+22,+22,+1-3mar. A comparison with the few previously cytogenetically characterized cases of this tumor type reveals no consistent abnormalities.     

Ossifying fibromyxoid tumor of soft parts. Cytogenetic findings

Ossifying fibromyxoid tumor (OFMT) of soft parts is a recently described, rare but morphologically distinctive soft tissue tumor. The histogenesis of this lesion remains uncertain, although several immunohistochemical and ultrastructural features suggest that it is an unusual neural tumor, possibly of Schwann cell origin. We report here a case of a malignant variant of OFMT that occurred in the foot of a 52-year-old man. The karyotype of a pulmonary metastasis exhibited the following complex numeric and structural aberrations:72 approximately 74,XXY,-5,+6,+del(8)(p21),del(9)(p22),+10,der(11)t(3;11)(p21;p15),del(12) (q13),der(13)t(5;13)(q13;q34),+18,+19,+20,-22 [cp10]. A kidney metastasis exhibited the following karyotypic abnormalities: 46,XY,add(3)(p11),+der(3)t(3;?;11)(3qter-->3p11::?::11q13-->11qter), -5,del(8)(p21),add(9)(q22),del(9)(p22),der(11)t(3;11)(p21;p15),del(12)(q13),+der(13)t(5;13) (q13;q34),-22. To our knowledge, this is the first reported case of OFMT in which clonal chromosomal aberrations have been shown.     

Complex karyotypic anomalies in a bizarre leiomyoma of the uterus

Cytogenetic investigation of short-term cultures from a bizarre leiomyoma of the uterus, a tumor type not hitherto karyotypically characterized, revealed two abnormal clones with multiple complex rearrangements. Three-fourths of the aberrant cells were hypodiploid with the composite karyotype 38–44, XX,?6,?7,?10,?11,+20,?22, r(1), der(2) (:2p23→cen→2q13::1q21→1qter), der(2)t(2;9)(p21;q13), t(5;?)(q35;?), t(5;?),(q35;?), + der(5)t(5;15)(q11;q15), der(8)t(8;11)(q24;q13), t(15;?)(p12;?), der(16)t(12;16)(q13;p13),+r,+mar. The remaining abnormal mitoses were hypotetraploid, with chromosome numbers ranging from 74 to 86. These massively rearranged cells showed the same markers that were found in the hypodiploid clone, but in duplicate, indicating that this clone had arisen through polyploidization of hypodiploid cells. Flow cytometry revealed a DNA index of 1.03.     

Multiple clonal chromosome aberrations in two thymomas

Cytogenetic investigations of two thymomas of different histopathology revealed unrelated clonal karyotypic changes: 44,XY,+X,inv(2)(p25q13),del(6)(q15),-8,-16,-17 in a cortical thymoma, and 48-49,XX,+del(X)(q24),+i(5p),+?del(7)(q22),der(11)t(1;11)(q23;q25),t(11; ?)(p15;?),-18,+r in a mixed-type thymoma. These are the first thymic tumors of epithelial origin that have been investigated with banding technique.     

Molecular cytogenetic characterization of human papillomavirus16-transformed foreskin keratinocyte cell line 16-MT

Anogenital cancers are closely associated with human papillomavirus (HPV), and HPV-infected individuals, particularly those with high-grade dysplasias, are at increased risk for cervical and anal cancers. Although genomic instability has been documented in HPV-infected keratinocytes, the full spectrum of genetic changes in HPV-associated lesions has not been fully defined. To address this, we examined an HPV16-transformed foreskin keratinocyte cell line, 16-MT, by GTG-banding, spectral karyotyping (SKY), and array comparative genomic hybridization (array CGH); these analyses revealed multiple numerical, complex, and cryptic chromosome rearrangements. Based on GTG-banding, the 16-MT karyotype was interpreted as 78-83,XXY,+add(1)(p36.3),+3,+4,+5,+5,+7,+8,+i(8)(q10)x2,+10,?der(12),der(13;14)(q10;q10),+15,+16,add(19)(q13.3),+21,+21,-22[cp20]. Multicolor analysis by SKY confirmed and further characterized the anomalies identified by GTG banding. The add(1) was identified as a der(1)(1qter-->1q25::1p36.1-->1qter), the add(19) as a dup(19), and the der(12) interpreted as a der(11) involving a duplication of chromosome 11 material and rearrangement with chromosome 19. In addition, previously unidentified der(9)t(9;22), der(3)t(3;19), and der(4)t(4;9) were noted. The 16-MT cell line showed losses and gains of DNA due to unbalanced translocations and complex rearrangements of regions containing known tumor suppressor genes. Chromosomal changes in these regions might explain the increased risk of cancer associated with HPV. Also, array CGH detected copy-number gains or amplifications of chromosomes 2, 8, 10, and 11 and deletions of chromosomes 3, 4, 11, and 15. These results provide the basis for the identification of candidate oncogenes responsible for cervical and anal cancer in amplified regions, and for putative tumor suppressor genes in commonly deleted regions like 11q22-23. Furthermore, these data represent the first full characterization of the HPV-positive cell line 16-MT.     

Common chromosome aberrations in the proximal type of epithelioid sarcoma

A new case of the proximal type of epithelioid sarcoma with a complex karyotype 70-98 <4N>,XX,-X,-X,+5,i(5)(q10),+7,del(7)(q31),i(8)(q10)x3 approximately 4,del(12)(p13),der(18)ins(18:?) (q11;?)del(18)(p11). ish der(18)ins(18;X)del(18)(p11)(wcp18+,wcpX+),+20,+20,dmin [cp9] is described. Both, dual-color FISH using probes specific for OATLI1/OATL2 genes and RT-PCR analysis excluded the presence of t(X;18), typical for synovial sarcoma. Our case together with the previously published ones suggest that the presence of i(8)(q10), losses of 12p and 18p together with the gain of chromosome 20 may represent a common cytogenetic aberrations in the proximal type of epithelioid sarcoma.     

Nonrandom chromosome changes in Kaposi sarcoma: cytogenetic and FISH results in a new cell line (KS-IMM) and literature review

The karyotype of a new tumorigenic Kaposi sarcoma (KS)-derived cell line, as defined by cytogenetic and fluorescence in situ hybridization (FISH) analysis is 49,XY,i(1)(q10),i(7)(p10),+i(7) (q10),+der(8)t(8;13)(p11;q11),-13,+del(14)(q22),+der(17)t(1;17)(p13;p13). Our aim was to point out some characteristics and recurrent chromosome changes probably playing a relevant role in the malignant progression of KS, by a comparison of the cytogenetic results obtained in the present study with data from the literature. The interpretation of the cytogenetic results is that KS development occurs by multiple steps: an initial reactive polyclonal cell proliferation is associated with chromosome instability; the cells in a later stage acquire clonal chromosome changes. If many chromosome changes are present, particularly 8q and 1q trisomy, 3p14-->pter deletion, 1p13, 13p14.3, 7q22, 8p11, 13q11, and 19q13 band rearrangements, KS acquires a neoplastic aggressive state.     

Evolution of a near-triploid karyotype in a secondary erythroleukemia

We report a case of erythroleukemia (EL;FAB M6), preceded by a myelodysplastic phase, in a 50-year-old male 8 years after treatment for Hodgkin's lymphoma. Cytogenetic analysis of bone marrow at time of diagnosis of EL revealed three cell lines: 1) 28 of 53 cells (53%) were hypodiploid, 43,XY,-5,-7,-12; 2) 23 of 53 cells (43%) were near-triploid, stemline 67-69,XY,+2,del(5)(q11.2),+del(5)(q11.2),+6,-7,+8,-9,-11,-12,+15,-16,der (17)t (17;?) (p11.2;?),-18,-20,-20,+22,+r, + mar (relative to a complete triploid cell); 3) 2 of 53 cells (4%) were normal 46,XY. The relative monosomies of 5, 7, and 12 in both abnormal lines suggest that the near-triploid line evolved from the hypodiploid line. A single hypodiploid cell with both del(5) and der(17) chromosomes that appeared identical to those in the near-triploid line suggests that polyploidization occurred after these structural rearrangements. While EL is not characterized by any well-defined structural abnormality, reported cases are frequently hypodiploid, with occasional cases of polyploidization, as in our patient, EL in adults without previous neoplasia or recognized mutagenic exposure has been shown to have loss or deletion of chromosomes 5 and 7, also characteristic of myelodysplastic syndromes and secondary leukemia. Our patient had a relative lack of chromosomes 5 and 7 in both abnormal clones, as well as a del(5)(q11) in the near-triploid line. This case of EL clearly demonstrates the evolution of a complex near-triploid line from a hypodiploid line, with chromosome abnormalities typical of both EL and secondary leukemia.     

Atypical congenital mesoblastic nephroma. Report of a case with karyotypic and flow cytometric analysis

Atypical congenital mesoblastic nephroma is a rare infantile renal tumor that may behave aggressively in older infants. A case of atypical congenital mesoblastic nephroma occurring in an 8-month-old hispanic male was analyzed by routine histopathologic, cytogenetic, and retrospective flow cytometric analysis for DNA ploidy. Light microscopy revealed marked hypercellularity. The karyotype was abnormal, with the following configuration: 45,XY,-1,-3,-9,-9,-15,-17,-21,+del(1)(q21q25),+der(3), t(3;9;15)(q23;p22;q11),+der(9),t(3;9;15) (q23;p22;q11),+der(9),t(9;?) (p?22;?),+r21, + mar. Retrospective DNA ploidy analysis revealed a DNA index of 1.0. The significance of karyotypic changes occurring in mesenchymal renal tumors of this type is currently unknown. Cytogenetic analysis might be of prognostic value in these potentially aggressive tumors.     

Multiple apparently unrelated clonal chromosome abnormalities in a squamous cell carcinoma of the tongue

We have cytogenetically examined short-term cultures from a squamous cell carcinoma of the tongue, a tumor type in which chromosome aberrations hitherto have not been reported. No less than 12 pseudodiploid clones were detected, giving the tumor karyotype 46,X,der(X)t(X;1)(q26;p32),der(1)(Xqter→Xq26::1p32→cen→1q42:),del(13)(q11q21),t(15;?) (q26;?)/46,XX,t(1;?)(p34;?),inv(2)(p21q11)/46,XX,t(1;10)(p32;q24)/46,XX,+der(1)(12pter→ 12p11::1p11→cen→1q32::11q13→11q32→1q42:),del(11)(q13q22), - 12, der(17)t(1:17) (q42;p13)/46,XX,inv(1)(p22q44)/47,XX,del(1)(q32),der(17)t(1:17)(p22;q25),der(1)inv(1) (q25q44)t(1;17)(p22;q25),ins(14;7)(q11;q22q36), + 14/46,XX,t(1;4)(q23;q35)/46,XX,t(1;21) (q25;q22),t(2;10)(q31;q26),t(22;?)(q12;?)/46,XX,del(1)(q32)/46,XX,t(1;8)(q44;q21)/46,XX, t(2;21)(q11;p11)/46,XX,t(9;11)(q34;q13). The large number of apparently unrelated abnormalities leads us to suggest that the carcinoma may have been of multiclonal origin.     

Cytogenetics of sacral chordoma.

Only four cases of chordoma have been described cytogenetically. We report the cytogenetic findings of a fifth case. Chromosome analysis of a primary sacral chordoma from a 69-year-old man showed the following chromosome complement: 43,XY,-2,-3,del(4)(q32),-6,+7,-11,der(12)t(9;12)(q12;p11),add(16)(q23),- 20,add(22)(q13),+mar.     

Direct chromosome analysis of seven primary colorectal carcinomas.

Chromosome studies were performed on direct preparations of seven cases of primary colorectal carcinomas. Two cases had relatively simple chromosome changes: 48,XY,+8,+21/51, XY,+8,+9,+10,+i(17q),+21, and 47,der(X)t(X;14)(q11;q11)-Y,t(6;18)(p22;q24)+7,+8,der(19)t (19;?)(q13;?). The five others had complicated deletions and translocations; 1p- was noted in five cases, and i(17q) was noted in three cases.     

Complex karyotypic changes, including rearrangements of 12q13 and 14q24, in two leiomyosarcomas

Cytogenetic investigation of short-term cultures from two leiomyosarcomas revealed complex karyotypic changes in both cases. The first tumor, a subcutaneous leiomyosarcoma of the knee, had the karyotype 70-80,XY, +X, +Y, +1, +1, +2, +2, +3, +3, +4, +4, +7, +7, +8, +8, +9, +10, +15, +15, +16, +16, +18, +19, +20, +21, +21, +22, +22,t(?;5)(5;21)(?;q35p11;q11), t(?;5)(5;21)(?;q35p11;q11), +del(11)(q22),der(13)t(12;13)(q13;q22),der(14)t(9;14)(p11;p11), +14p+, +t(20;?)(q13;?), +t(20;?)(q13;?), +2 mar. A polyploidized clone with 120-150 chromosomes was also observed. DNA flow cytometry revealed only one abnormal peak, corresponding to a DNA index of 1.76. The other tumor, a uterine leiomyosarcoma, had the karyotype 61-67, X, -X, +1, +3, +5, +6, +7, +8, +9, +12, +13, +15, +t(1;1)(p32;q32), +der(1)t(1;8)(p13;q11), +del(2)(p11), +del(2)(q22), +del(2)(q22), +del(3)(p13), +i(5p),t(8;14)(q24;q24), +der(8)t(8;14) (q24;q24), +del(10)(p12),der(11)t(11;15)(p15;q11),t(16;?)(p13;?),t(16;?)(q24;?), der dic(17) (17pter----cen----17q25::hsr::17q25----cen----17pte r), +t(19;?)(p13;?), +der dic(20)(20pter----cen----20q12::hsr::20q12----cen----+ ++20pter), +mar. The DNA index was 1.59. The finding in these leiomyosarcomas of rearrangements of the same regions of chromosomes 12 and 14 that are involved in the tumor-specific t(12;14)(q14-15;q23-24) of uterine leiomyoma indicates that the same genes in 12q and 14q might be important in the pathogenesis of benign and malignant smooth muscle tumors.     

11q23 abnormalities in children with acute nonlymphocytic leukemia (M4-M5). Association with previous chemotherapy

Cytogenetic studies of 12 patients aged less than 14 years with acute nonlymphoblastic leukemia (ANLL) (M4-M5) showed structural abnormalities on chromosome 11 at band q23-q24 in five cases (41.8%). Four of these 12 patients had ANLL (M4-M5) after treatment with cytostatics for non-Hodgkin lymphoma in one case and for an acute lymphoblastic leukemia (ALL) in the other three. Three of these four cases had 11q23 abnormalities [one [one 46,XY,t(11;17)(q23;25); another 47,XY,+8,-15,del(11)(q23),+der(15)t(15;?)(p11;?); the third 47,XX,+8,t(3;17) (p11;q25),t(4;11)(q21;q23)] and one had a normal karyotype on being diagnosed ANLL (M4-M5). The notable increase of ANLL (M4-M5) in our patients who had received cytostatics as treatment for a previous neoplasia makes evaluation of our results timely in comparison with those of other groups who use these therapeutic protocols.     

Multiple cytogenetic abnormalities in a case of osteosarcoma

Cytogenetic analysis of a highly malignant osteosarcoma in a 17-year-old girl revealed extremely complex karyotypic changes with several different clonal numerical and structural chromosome aberrations. The composite karyotype was interpreted as 39–41,X,t(X;9)(q11;p24), −1,der(1),−4,−4,−5,i(7q),−8,del(8)(q21),t(10;19)(p13;q13),del(11)(p11p13),t(12;18)(q24;q12), −13,13q+,−14,14p+,−15,15q+,17p+,19q+,−21,+22,+3–6 mar.     

Comparative cytogenetic analysis between cyclophosphamide-sensitive and -resistant lines of acute myeloid leukemia in the Lewis Brown Norway hybrid rat

An animal model of acute myeloid leukemia (AML) has been developed in the Brown Norway (BN) rat and has successfully been introduced into the Lewis x BN F₁ hybrid (LBN) and designated LBN AML. The original LBN AML is sensitive to the chemotherapeutic agent cyclophosphamide (CY). Recently, a CY-resistant cell line of LBN AML has been established. To characterize this animal model of human leukemia better, we analyzed and compared the chromosomal makeup of both the CY-sensitive and CY-resistant LBN AML lines. The CY-sensitive LBN AML cultures contained two cell lines—line 1 (88%):41, XX, –1, –2, –9,del(12)(q16),+der(1)t(1;?8)(p13;q31),+der(2)t(2;9)(p11;q11); and line 11 (12%): 41,XX,–1,–2,–9,del(12),del(20)(q13)+der(1)t(1;?8)(p13;q31),+der(2)t(2;9)(p11;q11). The recently developed CY-resistant AML cells contained two cell lines—line 1 (88%): 41,XX,–1,–2,–9,del(3)(q36q42.1),del(4)(q42.2),?t(5;?)(q35;?),?t(8;?)(q24;?),del(12)(q16),+der (1)t(1;?8)(p13;q31),+der(2)t(2;9)(p11;q11); and line II (12%): 42,XX (probably represents host contamination). The new chromosomal aberrations in the CY-resistant line 1 [del(3)(q36q42.1),del(4)(q42.2),?t(5;?)(q35;?), and ?t(8;?)(q24;?)] suggest a possible interrelationship between these secondary karyotypic abnormalities and acquisition of resistance to the chemotherapeutic agent.     

Complex karyotype in a low grade phyllodes tumor of the breast

Cytogenetic analysis of a phyllodes tumor of low grade malignancy disclosed the karyotype 52-55,XX, -1,+5,+7,+9,+10,+11,-15,+18,-19,+20,der(21)t(1;21)(p13;q22),+mar1x 2-4,+mar2[cp18]/46,XX. This study shows that a complex chromosome karyotype can be found in low-grade phyllodes tumors and is not necessarily a sign of extreme malignancy of these neoplasms.     

Cytogenetic study of a spindle-cell rhabdomyosarcoma of the parotid gland

The cytogenetic analysis of a spindle-cell rhabdomyosarcoma of the parotid gland in a 6-year-old boy is reported. The tumor cells showed an abnormal karyotype with a hypotriploid modal chromosome number and clonal structural rearrangements affecting chromosomes 1, 8, 12, 21, and 22. The tumor karyotype was: 59, XY, -1, -3, -4, -5, -6, +8, +8, +del(8)(q22q24), -9, -10, del(12)(q13), -15, -16, -17, -18, der(21)t(12;21)(p11;p11), -22, der(22)t(1;22)(q12;p11).     

Molecular analysis of a partial deletion of 22q in a central nervous system rhabdoid tumor.

We previously reported the non-random occurrence of monosomy 22 in rhabdoid or atypical teratoid tumors of the brain in three young children. We now present cytogenetic and molecular studies of an additional rhabdoid tumor with the karyotype 46,XX,-9,-22,+i(1q),+der(22)t(9;22)(p13;q11)/45,XX,-9,-10,- 22,+i(1q),+der(22)t(9;22)(p13;q11). These studies further demonstrate the involvement of chromosome 22, and they begin to define the critical region containing a gene or genes involved in the development or progression of rhabdoid tumors of the brain.     

Endometrial stromal sarcoma with clonal complex chromosome abnormalities. Report of a case and review of the literature.

Only eleven endometrial stromal sarcomas (ESS) with clonal chromosomal abnormalities have been reported in the literature. Of these, four have been reported to harbor the t(7;17) translocation. We report here an additional ESS that exhibited clonal complex chromosome abnormalities not described earlier: 38,XX,-1,del(1)(q11),-2,add(2)(p13),-3,der(4)add(4)(p12)psu dic(4;14)(q35;q11.2), add(6)(p21.3),add(7)(q22),del(7)(p11.2p13),-8,-9,add(9)(q34),- 10,add(10)(q24),-11,-11,ins(12;?) (q13;?),-14,-14,-15,ins(15;?)(q22;?),add(16)(q22),add(17)(q11.2),- 18,der(18)t(7;18)(q11.2;p11.2),-19, add(20)(p13),add(21)(p11.2),-22,add(22)(p11.2),+6mar in metaphase cells from primary short-term culture.