IVS10-6T>G, an ancient ATM germline mutation linked with breast cancer.

Patients with autosomal recessive multisystemic disorder ataxia-telangiectasia are homozygous or compound heterozygous for mutations in the ataxia-telangiectasia mutated (ATM) gene. Heterozygous carriers of an ATM germline mutation have an increased susceptibility for breast cancer. The subject of this study is one particular germline mutation, the ATM exon 11 splice-site mutation IVS10-6T>G, that has been identified as being associated with an increased risk for breast cancer both in the general population and in high-risk breast cancer families. We investigated the natural history of this mutation, i.e., whether it is frequently arising de novo in a population, or whether it can be traced back to a single ancient mutational event. Genotyping of a number of polymorphic markers (two extragenic and two intragenic microsatellite loci, a single nucleotide insertion/deletion polymorphism, and a dinucleotide insertion/deletion polymorphism) was performed in 18 samples from different populations carrying the IVS10-6T>G mutation (17 unrelated breast cancer patients who were heterozygous carriers of this mutation and a single A-T patient who was homozygous for the IVS10-6T>G mutation). The same markers were also genotyped among 39 unrelated healthy individuals without this mutation. Haplotype analyses revealed one common ancestor in all mutation carriers. By means of a maximum likelihood method, we estimated the age of this mutation to be approximately 2,000 generations. We provide evidence that the IVS10-6T>G mutation occurred only once during human evolution, at least 50,000 years ago. Our results predict that this mutation could be widely distributed across Europe and, probably, the Middle East and Western Asia.

TIL therapy broadens the tumor-reactive CD8(+) T cell compartment in melanoma patients.

There is strong evidence that both adoptive T cell transfer and T cell checkpoint blockade can lead to regression of human melanoma. However, little data are available on the effect of these cancer therapies on the tumor-reactive T cell compartment. To address this issue we have profiled therapy-induced T cell reactivity against a panel of 145 melanoma-associated CD8(+) T cell epitopes. Using this approach, we demonstrate that individual tumor-infiltrating lymphocyte cell products from melanoma patients contain unique patterns of reactivity against shared melanoma-associated antigens, and that the combined magnitude of these responses is surprisingly low. Importantly, TIL therapy increases the breadth of the tumor-reactive T cell compartment in vivo, and T cell reactivity observed post-therapy can almost in full be explained by the reactivity observed within the matched cell product. These results establish the value of high-throughput monitoring for the analysis of immuno-active therapeutics and suggest that the clinical efficacy of TIL therapy can be enhanced by the preparation of more defined tumor-reactive T cell products.