Clonally transmissible cancers are somatic cell lineages that are spread between individuals via the transfer of living cancer cells. There are only three known naturally occurring transmissible cancers, and these affect dogs, soft-shell clams, and Tasmanian devils, respectively. The Tasmanian devil transmissible facial cancer was first observed in 1996, and is threatening its host species with extinction. Until now, this disease has been consistently associated with a single aneuploid cancer cell lineage that we refer to as DFT1. Here we describe a second transmissible cancer, DFT2, in five devils located in southern Tasmania in 2014 and 2015. DFT2 causes facial tumors that are grossly indistinguishable but histologically distinct from those caused by DFT1. DFT2 bears no detectable cytogenetic similarity to DFT1 and carries a Y chromosome, which contrasts with the female origin of DFT1. DFT2 shows different alleles to both its hosts and DFT1 at microsatellite, structural variant, and major histocompatibility complex (MHC) loci, confirming that it is a second cancer that can be transmitted between devils as an allogeneic, MHC-discordant graft. These findings indicate that Tasmanian devils have spawned at least two distinct transmissible cancer lineages and suggest that transmissible cancers may arise more frequently in nature than previously considered. The discovery of DFT2 presents important challenges for the conservation of Tasmanian devils and raises the possibility that this species is particularly prone to the emergence of transmissible cancers. More generally, our findings highlight the potential for cancer cells to depart from their hosts and become dangerous transmissible pathogens.
The number of Tasmanian devils in the wild is rapidly declining owing to a transmissible cancer, devil facial tumor disease (DFTD). Although progress has been made to understand the spread of this disease, crucial research on the pathogenesis of DFTD has been limited because of the threatened status of the host species. Here, the authors describe the development of a NOD/SCID (nonobese diabetic / severe combined immunodeficiency) mouse model that reproduces DFTD and provides a much-needed model to undertake studies into this intriguing transmissible cancer. Histologically, the DFTD produced in NOD/SCID mice (xenografted DFTD) was indistinguishable from the DFTD identified in Tasmanian devils. At the protein level, all xenografted DFTD tumors expressed periaxin, a marker that confirmed the diagnosis of DFTD. The karyotype of DFTD in NOD/SCID mice reproduced similar chromosomal alterations as seen in diseased devils. Furthermore, each NOD/SCID mouse inoculated with cultured DFTD tumor cells developed tumors, whereas DFTD did not develop in any of the inoculated immunecompetent BALB/c mice. Keywords Tasmanian devil, devil facial tumor disease, NOD/SCID mouse, cytogeneticThe Tasmanian devil (Sarcophilus harrisii), a marsupial carnivore endemic to Tasmania, Australia, is facing extinction owing to an emergent transmissible cancer, devil facial tumor disease (DFTD). This disease is clearly an important problem, and devils have been recently upgraded to endangered under the Tasmanian and Commonwealth of Australia listings. Without a cure or a vaccine against DFTD, devils may become extinct in the wild within the next 25 to 35 years. 15It has been proposed that this tumor is transmitted as an allograft from devil to devil during intraspecies facial biting. The tumor-karyotypic arrangement is consistent among affected devils regardless of region, stage of disease, or sex. 20In addition, genotypic analyses have confirmed that all DFTD tumors are identical clones of transformed cells, in contrast to the genotypes of each affected devil.17,22 DFTD tumor cell transmission experiments in Tasmanian devils have not formally been reported in the literature. However, unpublished evidence suggests that DFTD can successfully be reproduced in previously unaffected devils after tumor cell inoculation. 21The mechanism of acceptance of these neoplastic cells by a new host is not yet well understood, primarily as a consequence of the many ethical and financial impediments for undertaking a study of DFTD in diseased devils. In the presence of a competent immune system, 12,13 restriction of major histocompatibility complex genes has been proposed as the main factor in the allograft acceptance of DFTD cells. Experiments with skin grafts among unrelated individuals, however, still need to be performed to prove this hypothesis. 22With only a limited knowledge of the pathobiology of DFTD, an alternative model is urgently required. NOD/SCID (nonobese diabetic / severe combined immunodeficiency) mice are immunocompromised and provide an...
Randomized trials in acute myeloid leukemia (AML) have demonstrated improved survival by the BCL-2 inhibitor venetoclax combined with azacitidine in older patients, and clinical trials are actively exploring the role of venetoclax in combination with intensive chemotherapy in fitter patients with AML. As most patients still develop recurrent disease, improved understanding of relapse mechanisms is needed. We find that 17% of patients relapsing after venetoclax-based therapy for AML have acquired inactivating missense or frameshift/nonsense mutations in the apoptosis effector gene BAX. In contrast, such variants were rare after genotoxic chemotherapy. BAX variants arose within either leukemic or pre-leukemic compartments, with multiple mutations observed in some patients. In vitro, AML cells with mutated BAX were competitively selected during prolonged exposure to BCL-2 antagonists. In model systems, AML cells rendered deficient for BAX, but not its close relative BAK, displayed resistance to BCL-2 targeting, whereas sensitivity to conventional chemotherapy was variable. Acquired mutations in BAX during venetoclax-based therapy represents a novel mechanism of resistance to BH3-mimetics and a potential barrier to longer-term efficacy of drugs targeting BCL-2 in AML.
Chromosome abnormalities detected during cytogenetic investigations for B-cell malignancy offer prognostic information that can have wide ranging clinical impacts on patients. These impacts may include monitoring frequency, treatment type, and disease staging level. The use of the synthetic oligonucleotide DSP30 combined with interleukin 2 (IL2) has been described as an effective mitotic stimulant in B-cell disorders, not only in chronic lymphocytic leukemia (CLL) but also in a range of other B-cell malignancies. Here, we describe the comparison of two B-cell mitogens, lipopolysaccharide (LPS), and DSP30 combined with IL2 as mitogens in a range of common B-cell disorders excluding CLL. The results showed that DSP30/IL2 was an effective mitogen in mature B-cell disorders, revealing abnormal cytogenetic results in a range of B-cell malignancies. The abnormality rate increased when compared to the use of LPS to 64% (DSP30/IL2) from 14% (LPS). In a number of cases the disease burden was proportionally very low, less than 10% of white cells. In 37% of these cases, the DSP30 culture revealed abnormal results. Importantly, we also obtained abnormal conventional cytogenetics results in 3 bone marrow cases in which immunophenotyping showed an absence of an abnormal B-cell clone. In these cases, the cytogenetics results correlated with the provisional diagnosis and altered their staging level. The use of DSP30 and IL2 is recommended for use in many B-cell malignancies as an effective mitogen and their use has been shown to enable successful culture of the malignant clone, even at very low levels of disease.
Key Points• BCR-ABL1 rearrangement as a subclonal change in ETV6-RUNX1-positive B-ALL is a rare occurrence not previously reported.• The prognosis of this rare subclonal change has not been determined, yet inclusion of tyrosine kinase inhibitors in treatment is ubiquitous.We report here on a case of ETV6-RUNX1-positive B-cell acute lymphoblastic leukemia (B-ALL) that has acquired a BCR-ABL1 gene rearrangement as a subclonal change. The 19-year-old female patient presented with B symptoms, pancytopenia, and circulating blasts.The bone marrow aspirate was hypercellular and was infiltrated by an immature blast population that was confirmed as B-ALL by flow cytometry. Sequential fluorescent in situ hybridization was performed on the patient's leukemic cells, which were shown to contain both ETV6-RUNX1 and BCR-ABL1 gene rearrangements. The majority of nuclei (85%) showed only the ETV6-RUNX1 gene rearrangement; however, an additional 10% also showed a variant BCR-ABL1 gene rearrangement, indicating the ETV6-RUNX1 gene rearrangement was the primary change. A review of the literature has shown that acquisition of a BCR-ABL1 gene rearrangement as a secondary change in B-ALL is a very rare occurrence, and the effect it may have on prognosis is uncertain in the modern therapy age.
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