Primary Central Nervous System and Testicular Lymphoma: From Genes to Action in One Year

Advances in genomic technology have allowed for the more rapid identification of recurrent genetic alterations in tumors, many of which are targetable with existing therapies. As such, the time from discovery of pathologic events to delivering clinical benefit to patients is shortening. Recent advances in the understanding and treatment of primary central nervous system (CNS) lymphoma (PCNSL) and primary testicular lymphoma (PTL) exemplify this remarkable advancement in moving from the laboratory to the bedside at break-neck speed.

PCNSL and relapsed PTL in the brain are associated with relatively high rates of chemotherapy resistance, with up to 33 percent of PCNSL not responding to chemotherapy and up to 50 percent relapsing within two years of their initial therapy. Additional therapies are needed to treat these relapsed and refractory patients. In February 2016, Dr. Bjoern Chapuy and colleagues reported the results of their comprehensive characterization of the genetic features of PCNSL and PTL. They analyzed copy number alterations by single nucleotide polymorphism arrays, transcript abundance by Affymetrix arrays, single nucleotide variants by whole-exome sequencing, and chromosomal rearrangements by DNAseq using a custom bait set in PCNSL, PTL, and primary mediastinal B cell lymphoma, and compared these findings to those observed in a previously analyzed diffuse large B cell lymphoma (DLBCL) cohort. Their analysis revealed genetic similarities between PCNSL and PTL that were distinct from DLBCL. These tumors demonstrated increased genomic instability with recurrent copy number gains in 3q12.3, 18q21.33, and 19q13.42, and copy number loss in 6p21.33, 6q21, and 9p21.3.

Among the candidate driver genes identified to be associated with these chromosomal gains and losses are NFKBIZ on chromosome 3q12.3 and CDKN2A on chromosome 9p21.3. Amplification of 9p24.1, containing the genes for PDL1 and PDL2, was also identified as a recurrent alteration in PTL as well as in the extension cohort of Epstein Barr Virus (EBV) –negative PCNSL. EBV-positive PCNSL was associated with increased expression of PDL1 and/or PDL2 in the absence of any copy number alterations. Inhibition of PD1, then, may be a promising therapy in these patients. Additionally, unique chromosomal rearrangements involving PDL2 were identified in several of these tumors, as well as recurrent rearrangements involving activation of BCL6 and inactivation of ETV6. In both the discovery cohorts and extension cohorts of PCNSL and PTL, mutations in Toll-like receptor (TLR) signaling component genes MYD88 and CD79B occurred at high frequency (>80%), with all CD79B mutations occurring in the context of a coincident MYD88 mutation. Similarly, a vast majority of EBV negative PCNSL and PTL tumors had an activating mutation in MYD88, and/or copy number gain of chromosome 3q12.3 with amplification of NFKBIZ, whose product IĸB-ζ is downstream of TLR activation. This near-uniform activation of TLR signaling suggests that therapies that inhibit IRAK1/4, IRF4, and/or BTK may be active in these diseases. Finally, very few of these tumors harbor mutations in TP53, but instead exhibit copy number loss of CDKN2A on chromosome 9p21.3, which lies upstream in the p53 pathway, thus making these tumors potential candidates for therapy with drugs that inhibit MDM2/4. Thus, out of this comprehensive genetic investigation of these two diseases emerged three potential therapeutic strategies, all of which can be targeted with existing drugs.