Diverging Clonal Evolution during Sequential Therapy with Chemoimmunotherapy Followed By BTK Inhibitors

Background: Treatment confers an evolutionary bottleneck for cancer. Little data exists on the genomic evolution of CLL under different treatment pressure and disease compartments. Methods: We identified 13 patients uniformly treated with chemoimmunotherapy (CIT) as first-line therapy and a BTK inhibitor (BTKi) as second-line. We collected peripheral blood (PB) samples before CIT, at relapse after CIT (which was also before starting a BTKi), and 6 months on a BTKi. Five patients on a long-term BTKi were additionally tested at two years on BTKi. Two patients had samples from bone marrow (BM) and/or lymph node (LN) compartments at 6 months on a BTKi. In total, 48 tumor samples paired with saliva serving as a germline control were tested with whole exome sequencing (WES). We used high confidence variants identified by at least two variant callers for somatic single nucleotide polymorphisms and insertion-deletion variants, and TitanCNA for copy number variations. Clonal composition was reconstructed using PhyloWGS. Results: The median age of the cohort was 60 years at the start of CIT. The median duration of follow-up was 7 years. Median time between the start of CIT and a BTKi was 43 months (range 10-135). To date, eleven patients are alive and remain in response to a BTKi. Two patients died, one due to hepatitis B virus reactivation, and one with Richter's transformation. The median tumor mutational burden (TMB), defined as the number of nonsynonymous coding mutations per Mb, was 1.9 before CIT, 2.1 after CIT, and 1.9 after 6 months on a BTKi, consistent with previous reports in CLL. TMB was loosely associated with time since CIT exposure (R2=0.12, P=0.014). All patients had at least one mutation in known driver genes, most commonly NOTCH1 and SF3B1 (31% each; Figure A). Most of these mutations were subclonal and remained subclonal throughout the treatment course. The number of known driver gene mutations per patient remained relatively stable during the treatment course (median: 2 before CIT, 3 after CIT, 3 at 6 months on a BTKi; all P>0.05). We recomposed clonal structures and estimated the cancer cell fraction (CCF) of each clone. Phylogenetic analysis showed branching evolution in most patients with a median of three child clones originating from a parent clone. In these patients, multiple clonal branches and its descendants were simultaneously being selected during therapy. In addition, we observed linear evolution in three (23%) patients, characterized by a repetitive selection of one parent clone and its leading progeny per generation. Treatment with CIT and a BTKi selected for distinct sets of clones. BTKi therapy effectively downsized clones which grew to dominance after CIT, except in one patient whose subclone with concurrent NRAS and TP53 mutations remained dominant throughout CIT and BTKi therapy. The median CCF decrease of CIT-selected clones was 18% during BTKi therapy (range 1-52). In all patients with SF3B1 mutation, clonal fractions of SF3B1 mutated clones were higher at relapse after CIT and lower during BTKi therapy. There was no consistent pattern of clonal selection for NOTCH1 mutation. We compared patterns of clonal evolution in different compartments in two patients who had PB, LN and/or BM samples available. Each compartment had a distinct clonal composition. Notably, one patient who progressed with Richter's transformation after 6 months on a BTKi showed three main clones shared among all compartments and a set of compartment-restricted clones (Figure B). The LN was preferentially enriched with clones carrying HIST1H1E mutation and complex copy number changes, reflecting transformed clones. The NOTCH1 mutated clone and its progeny, reflecting CLL clones, were dominant in PB and BM, but not in LN. Conclusion: The number and clonality of somatic mutations affecting known driver genes, remained relatively stable over the course of treatment with CIT followed by a BTKi at relapse. Distinct sets of clones evolved under each line of therapy. Clonal composition is shaped by the growth potential of individual clones, the selective pressure of the therapy used, and the tumor microenvironment. Figure Disclosures Wiestner: Pharmayclics: Research Funding; Acerta: Research Funding; Nurix: Research Funding; Merck: Research Funding.

Implications of chromosome pairing in a monohaploid and its colchidiploid of Solanum tuberosum (x = 12)

A monohaploid (x = 12) of Solanum tuberosum, its colchidiploid and their 2n parent clone have been cytologically examined. The meiotic analysis of the monoploid shows a certain degree of pairing at pachytene with a high frequency of bivalents at metaphase I. The bivalent frequency ranges from 2.07 to 3.0 per pollen mother cell (PMC). The most frequent classes are 3II + 6I and 2II + 8I. Several PMCs show secondary associations. At anaphase I (AI), the chromosomes distribute frequently in groups of 7 to 5 (32% of PMCs) and 6 to 6 (30% of PMCs). Occasionally, however, both disjunct chromosomes and univalents remain at the equatorial plane and divide with or without segregation, resulting in the formation of dyads or monads. The PMCs with a regular AI show a parallel orientation of spindles as well as a normal one, a situation that ends at telophase II with dyads, triads, and tetrads but 0% pollen fertility. The overall frequency of monads, dyads, triads, and tetrads is equal to 13, 69, 7 and 11%, respectively. Both in the parent clone and in the 2n colchidiploid clone, chromosome pairing is normal. The pairing behaviour in the monohaploid suggests the presence of duplicated sequences in the chromosome complement. An alteration of genes controlling the level of pairing is excluded.Key words: monohaploid, colchidiploid, chromosome pairing, meiosis.

Isolation of Theileria parasites from African buffalo (Syncerus caffer) and characterization with anti-schizont monoclonal antibodies

Antigenic differences between intra-lymphocytic theilerial parasites isolated from the blood of 18 African buffalo and grown in vitro were assessed with anti-schizont monoclonal antibodies (mAbs). There was marked antigenic diversity both between isolates from different buffalo and between isolates taken at different times from the same buffalo. Many of the isolates from both wild and captive buffalo appeared to consist of mixed parasite populations. Some isolates were found by limiting dilution cloning and mAb testing to contain at least 3 or 4 distinct populations of Theileria. Once cloned, Theileria-infected lymphoblastoid cell lines retained their mAb profiles during prolonged in vitro cultivation and, when recloned, the subclones had the same mAb profile as their parent clone. The implications of these results for further studies on buffalo-derived theilerial parasites are discussed.

Embryo sac and early embryo development in the salmonberry (Rubus spectabilis)

Embryo sac development was studied in two clones of salmonberry. U.B.C. clones I-37 and II-4 were used in the study. Clone II-4 is a ruby-fruited seedling of a gold-fruited parent. Clone I-37 is the gold-fruited seedling of a ruby-fruited parent. Reproduction was sexual and embryo development normal in this diploid species. Embryo sac development was of the normal or Polygonum type and abnormalities such as multiple embryo sacs and abbreviated integument were also found. Very generally, the development of embryo sacs in both clones was similar.