Tissue mast cell counts may be associated with decreased severity of gastrointestinal acute GVHD and nonrelapse mortality.

The functions of mast cells in human graft-versus-host disease (GVHD) are unknown. We studied 56 patients who had an allogeneic hematopoietic cell transplantation (alloHCT) with a biopsy for diagnosis of gastrointestinal tract (GIT) GVHD before any treatment (including steroids): 35 with GIT GVHD, 21 HCT recipients whose biopsies did not confirm GVHD, and 9 with a new diagnosis of inflammatory bowel disease (IBD) as a comparison. The median number of mast cells (mean of CD117+ cells, counted in 3 selected spots under 40× magnification) was similar between patients with GVHD (59 cells) and those without GVHD (60 cells). However, the median number of mast cells was significantly associated with maximum clinical stage of GIT GVHD; the lowest counts of mast cells were observed in the highest clinical stage of GIT GVHD (stage 1, 80; stage 2, 69; stage 3, 54; stage 4, 26; P = .01). Moreover, every decrease by 10 mast cells was associated with increased nonrelapse mortality through 1 year (hazard ratio, 0.77; 95% confidence interval, 0.59-1.00; P = .05). AlloHCT recipients all had significantly fewer mast cells, even those without GVHD compared with those with IBD (median, 59 vs 119; P < .01). The median number of GIT mast cells was also significantly lower in patients who received myeloablative conditioning (61.5 cells) than in those who received reduced intensity conditioning (78 cells) in the entire study population (P = .02). We conclude that GIT mast cells are depleted in all alloHCT patients, more prominently in those receiving myeloablative conditioning and those with severe GIT GVHD. Our novel findings warrant further investigation into the biological effects of mast cells in GIT GVHD.

Single-Cell Gene Expression Analyses Reveal Distinct Self-Renewing and Proliferating Subsets in the Leukemia Stem Cell Compartment in Acute Myeloid Leukemia.

Standard chemotherapy for acute myeloid leukemia (AML) targets proliferative cells and efficiently induces complete remission; however, many patients relapse and die of their disease. Relapse is caused by leukemia stem cells (LSC), the cells with self-renewal capacity. Self-renewal and proliferation are separate functions in normal hematopoietic stem cells (HSC) in steady-state conditions. If these functions are also separate functions in LSCs, then antiproliferative therapies may fail to target self-renewal, allowing for relapse. We investigated whether proliferation and self-renewal are separate functions in LSCs as they often are in HSCs. Distinct transcriptional profiles within LSCs of Mll-AF9/NRASG12V murine AML were identified using single-cell RNA sequencing. Single-cell qPCR revealed that these genes were also differentially expressed in primary human LSCs and normal human HSPCs. A smaller subset of these genes was upregulated in LSCs relative to HSPCs; this subset of genes constitutes "LSC-specific" genes in human AML. To assess the differences between these profiles, we identified cell surface markers, CD69 and CD36, whose genes were differentially expressed between these profiles. In vivo mouse reconstitution assays resealed that only CD69High LSCs were capable of self-renewal and were poorly proliferative. In contrast, CD36High LSCs were unable to transplant leukemia but were highly proliferative. These data demonstrate that the transcriptional foundations of self-renewal and proliferation are distinct in LSCs as they often are in normal stem cells and suggest that therapeutic strategies that target self-renewal, in addition to proliferation, are critical to prevent relapse and improve survival in AML. SIGNIFICANCE: These findings define and functionally validate a self-renewal gene profile of leukemia stem cells at the single-cell level and demonstrate that self-renewal and proliferation are distinct in AML. GRAPHICAL ABSTRACT: http://cancerres.aacrjournals.org/content/canres/80/3/458/F1.large.jpg.