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Braf  V600E expression in resident macrophage progenitors leads to clonal expansion of ERK-activated microglia, which causes synaptic and neuronal loss in the brain and results in lethal neurodegenerative disease in adult mice. BRAF mutation begets brain disease Microglia—immune cells in the brain—derive from yolk-sac erythro-myeloid progenitors (EMPs), which are distinct from haematopoietic stem cells (HSCs). Frederic Geissmann and colleagues show that mosaic expression of a mutant BRAF, which activates the RAS–MEK–ERK pathway and causes tumours when expressed in HSCs, results in expansion of tissue-resident macrophages and late-onset neurodegeneration when expressed in EMPs. They show in a mouse model that neurobehavioural abnormalities, astrogliosis, deposition of amyloid precursor protein, synaptic loss and neuronal death are driven by ERK-activated microglia and can be prevented by BRAF inhibition. These results show that, in mice, activation of the MAP kinase pathway in microglia can cause neurodegeneration. These findings may explain the neurodegeneration observed in patients with histiocytosis—disorders of myeloid cell expansion associated with somatic mutations in the RAS–MEK–ERK pathway, such as the BRAF mutation studied here. The pathophysiology of neurodegenerative diseases is poorly understood and there are few therapeutic options. Neurodegenerative diseases are characterized by progressive neuronal dysfunction and loss, and chronic glial activation 1 . Whether microglial activation, which is generally viewed as a secondary process, is harmful or protective in neurodegeneration remains unclear 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 . Late-onset neurodegenerative disease observed in patients with histiocytoses 9 , 10 , 11 , 12 , which are clonal myeloid diseases associated with somatic mutations in the RAS–MEK–ERK pathway such as BRAF(V600E) 13 , 14 , 15 , 16 , 17 , suggests a possible role of somatic mutations in myeloid cells in neurodegeneration. Yet the expression of BRAF(V600E) in the haematopoietic stem cell lineage causes leukaemic and tumoural diseases but not neurodegenerative disease 18 , 19 . Microglia belong to a lineage of adult tissue-resident myeloid cells that develop during organogenesis from yolk-sac erythro-myeloid progenitors (EMPs) distinct from haematopoietic stem cells 20 , 21 , 22 , 23 . We therefore hypothesized that a somatic BRAF(V600E) mutation in the EMP lineage may cause neurodegeneration. Here we show that mosaic expression of BRAF(V600E) in mouse EMPs results in clonal expansion of tissue-resident macrophages and a severe late-onset neurodegenerative disorder. This is associated with accumulation of ERK-activated amoeboid microglia in mice, and is also observed in human patients with histiocytoses. In the mouse model, neurobehavioural signs, astrogliosis, deposition of amyloid precursor protein, synaptic loss and neuronal death were driven by ERK-activated microglia and were preventable by BRAF inhibition. These results identify the fetal precursors of tissue-resident macrophages as a potential cell-of-origin for histiocytoses and demonstrate that a somatic mutation in the EMP lineage in mice can drive late-onset neurodegeneration. Moreover, these data identify activation of the MAP kinase pathway in microglia as a cause of neurodegeneration and this offers opportunities for therapeutic intervention aimed at the prevention of neuronal death in neurodegenerative diseases.

Many pediatric cancer survivors experience chemotherapy-induced cognitive impairment (CICI), which negatively impacts their quality of life. However, while some patients develop CICI, others do not, suggesting that genetic variants may contribute to the development of CICI. The Apolipoprotein E (ApoE) E4 allele has been identified as a risk variant for CICI among pediatric cancer survivors. However, the mechanisms by which ApoE4 contributes to the development of CICI remain unknown. Using a commonly used chemotherapeutic agent known to induce CICI, doxorubicin, we treated five-week-old rats homozygous for either the human ApoE3 or ApoE4 allele with doxorubicin (2 mg/kg/week for 4 weeks) or saline. Behavioral assessments revealed that ApoE4 rats were more susceptible to doxorubicin-induced impairments in visual and spatial memory compared to ApoE3 rats. Pathophysiological analyses showed a significant reduction in hippocampal neurogenesis of ApoE4 doxorubicin-treated rats relative to the other groups. Serum levels of GFAP were significantly increased in ApoE4 doxorubicin-treated rats. These findings suggest that the ApoE genotype influences vulnerability to CICI and highlight a potential mechanistic link through impaired neurogenesis, laying the groundwork for genotype-specific therapeutic strategies.

Erdheim–Chester disease is a rare, non-Langerhans cell histiocytosis histologically characterized by multi-systemic proliferation of mature histiocytes in a background of inflammatory stroma. The disease can involve virtually any organ system; most commonly the bones, skin, retroperitoneum, heart, orbit, lung, and brain are affected. Although a histiocytic proliferation is the histological hallmark of the disease, a wide range of morphological appearances have been described as part of case studies or small series. A comprehensive review of histopathological features in clinically and molecularly defined Erdheim–Chester disease has yet to be characterized. To address this issue and help guide clinical practice, we comprehensively analyzed the pathological spectrum of Erdheim–Chester disease in a clinically and molecularly defined cohort. We reviewed 73 biopsies from 42 patients showing involvement by histiocytosis from a variety of organ systems, including bone (16), retroperitoneum (11), skin (19), orbit (6), brain (5), lung (6), cardiac structures (2), epidural soft tissue (3), oral cavity (2), subcutaneous soft tissue (2), and testis (2). In eight patients, one or more bone marrow biopsies were performed due to clinical indication and an accompanying myeloid neoplasm was detected in six of them. Thirty-eight cases were investigated for genetic abnormalities. Somatic mutations involving BRAF (25/38), MAP2K1 (6/38), ARAF (2/38), MAP2K2 (1/38), KRAS (1/38), and NRAS (1/38) genes were detected. One of the cases with a MAP2K1 mutation also harbored a PIK3CA mutation. We have observed marked heterogeneity in histology and immunophenotype, identified site-specific features, overlap with other histiocytic and myeloid disorders and potential diagnostic pitfalls. We hope that broadening the spectrum of recognized pathologic manifestations of Erdheim–Chester disease will help practicing clinicians and pathologists to diagnose Erdheim–Chester disease early in the disease course and manage these patients effectively.

Most eukaryotes harbor two distinct pre-mRNA splicing machineries: the major spliceosome, which removes >99% of introns, and the minor spliceosome, which removes rare, evolutionarily conserved introns. Although hypothesized to serve important regulatory functions, physiologic roles of the minor spliceosome are not well understood. For example, the minor spliceosome component ZRSR2 is subject to recurrent, leukemia-associated mutations, yet functional connections among minor introns, hematopoiesis and cancers are unclear. Here, we identify that impaired minor intron excision via ZRSR2 loss enhances hematopoietic stem cell self-renewal. CRISPR screens mimicking nonsense-mediated decay of minor intron-containing mRNA species converged on LZTR1, a regulator of RAS-related GTPases. LZTR1 minor intron retention was also discovered in the RASopathy Noonan syndrome, due to intronic mutations disrupting splicing and diverse solid tumors. These data uncover minor intron recognition as a regulator of hematopoiesis, noncoding mutations within minor introns as potential cancer drivers and links among ZRSR2 mutations, LZTR1 regulation and leukemias. Loss of function of the minor spliceosome component ZRSR2 enhances hematopoietic stem cell self-renewal through minor intron retention of its target LZTR1, which is a regulator of RAS-related GTPases. Minor intron retention of LZTR1 was also identified in Noonan syndrome and diverse solid tumor types.

Additional sex combs-like (ASXL) proteins are mammalian homologues of additional sex combs (Asx), a regulator of trithorax and polycomb function in Drosophila. While there has been great interest in ASXL1 due to its frequent mutation in leukemia, little is known about its paralog ASXL2, which is frequently mutated in acute myeloid leukemia patients bearing the RUNX1-RUNX1T1 (AML1-ETO) fusion. Here we report that ASXL2 is required for normal haematopoiesis with distinct, non-overlapping effects from ASXL1 and acts as a haploinsufficient tumour suppressor. While Asxl2 was required for normal haematopoietic stem cell self-renewal, Asxl2 loss promoted AML1-ETO leukemogenesis. Moreover, ASXL2 target genes strongly overlapped with those of RUNX1 and AML1-ETO and ASXL2 loss was associated with increased chromatin accessibility at putative enhancers of key leukemogenic loci. These data reveal that Asxl2 is a critical regulator of haematopoiesis and mediates transcriptional effects that promote leukemogenesis driven by AML1-ETO. While the role of ASLX1 in haematopoiesis and leukaemia has been heavily studied, the role of ASLX2 is unclear. Here the authors show that ASLX2 is required for normal haematopoietic stem cell self-renewal whereas Asxl2 loss promotes leukemogenesis, thus explaining the frequently observed mutations in AML patients

NSD2, a histone methyltransferase specific for methylation of histone 3 lysine 36 (H3K36), exhibits a glutamic acid to lysine mutation at residue 1099 (E1099K) in childhood acute lymphocytic leukemia (ALL), and cells harboring this mutation can become the predominant clone in relapsing disease. We studied the effects of this mutant enzyme in silico, in vitro, and in vivo using gene edited cell lines. The E1099K mutation altered enzyme/substrate binding and enhanced the rate of H3K36 methylation. As a result, cell lines harboring E1099K exhibit increased H3K36 dimethylation and reduced H3K27 trimethylation, particularly on nucleosomes containing histone H3.1. Mutant NSD2 cells exhibit reduced apoptosis and enhanced proliferation, clonogenicity, adhesion, and migration. In mouse xenografts, mutant NSD2 cells are more lethal and brain invasive than wildtype cells. Transcriptional profiling demonstrates that mutant NSD2 aberrantly activates factors commonly associated with neural and stromal lineages in addition to signaling and adhesion genes. Identification of these pathways provides new avenues for therapeutic interventions in NSD2 dysregulated malignancies.

Histiocytic neoplasms are a heterogeneous group of clonal haematopoietic disorders that are marked by diverse mutations in the mitogen-activated protein kinase (MAPK) pathway 1 , 2 . For the 50% of patients with histiocytosis who have BRAF V600 mutations 3 – 5 , RAF inhibition is highly efficacious and has markedly altered the natural history of the disease 6 , 7 . However, no standard therapy exists for the remaining 50% of patients who lack BRAF V600 mutations. Although ERK dependence has been hypothesized to be a consistent feature across histiocytic neoplasms, this remains clinically unproven and many of the kinase mutations that are found in patients who lack BRAF V600 mutations have not previously been biologically characterized. Here we show ERK dependency in histiocytoses through a proof-of-concept clinical trial of cobimetinib, an oral inhibitor of MEK1 and MEK2, in patients with histiocytoses. Patients were enrolled regardless of their tumour genotype. In parallel, MAPK alterations that were identified in treated patients were characterized for their ability to activate ERK. In the 18 patients that we treated, the overall response rate was 89% (90% confidence interval of 73–100). Responses were durable, with no acquired resistance to date. At one year, 100% of responses were ongoing and 94% of patients remained progression-free. Cobimetinib treatment was efficacious regardless of genotype, and responses were observed in patients with ARAF , BRAF , RAF1 , NRAS , KRAS , MEK1 (also known as MAP2K1 ) and MEK2 (also known as MAP2K2 ) mutations. Consistent with the observed responses, the characterization of the mutations that we identified in these patients confirmed that the MAPK-pathway mutations were activating. Collectively, these data demonstrate that histiocytic neoplasms are characterized by a notable dependence on MAPK signalling—and that they are consequently responsive to MEK inhibition. These results extend the benefits of molecularly targeted therapy to the entire spectrum of patients with histiocytosis. A proof-of-concept clinical trial of patients with histiocytoses with MAPK-pathway mutations showed durable responses to treatment with the MEK1 and MEK2 inhibitor cobimetinib, which indicates that histiocytic neoplasms are dependent on MAPK signalling.

Myelodysplastic syndromes (MDS) are driven by complex genetic and epigenetic alterations. The MSI2 RNA-binding protein has been demonstrated to have a role in acute myeloid leukaemia and stem cell function, but its role in MDS is unknown. Here, we demonstrate that elevated MSI2 expression correlates with poor survival in MDS. Conditional deletion of Msi2 in a mouse model of MDS results in a rapid loss of MDS haematopoietic stem and progenitor cells (HSPCs) and reverses the clinical features of MDS. Inversely, inducible overexpression of MSI2 drives myeloid disease progression. The MDS HSPCs remain dependent on MSI2 expression after disease initiation. Furthermore, MSI2 expression expands and maintains a more activated (G1) MDS HSPC. Gene expression profiling of HSPCs from the MSI2 MDS mice identifies a signature that correlates with poor survival in MDS patients. Overall, we identify a role for MSI2 in MDS representing a therapeutic target in this disease. Several studies have recently demonstrated the role of the MSI2 RNA binding protein in normal and malignant haematopoietc stem cells. In this study, the authors show that MSI2 is required for maintaining myelodysplastic syndrome stem cells in mice and that MSI2 expression predicts poor prognosis in patients affected by this disease.

In nine patients with chronic lymphocytic leukemia that responded to the noncovalent BTK inhibitor pirtobrutinib and then developed resistance, analysis revealed a number of new mutations in the BTK kinase domain and occasional mutations in downstream PLCγ2. Despite the inactivity of BTK, alternative pathways of B-cell–receptor signaling were evident.

Leukemias bearing heterozygous mutations in the SRSF2 splicing-factor-encoding gene can be therapeutically targeted by pharmacologic inhibition of residual spliceosome function. Mutations in genes encoding splicing factors (which we refer to as spliceosomal genes) are commonly found in patients with myelodysplastic syndromes (MDS) and acute myeloid leukemia (AML) 1 , 2 , 3 . These mutations recurrently affect specific amino acid residues, leading to perturbed normal splice site and exon recognition 4 , 5 , 6 . Spliceosomal gene mutations are always heterozygous and rarely occur together with one another, suggesting that cells may tolerate only a partial deviation from normal splicing activity. To test this hypothesis, we engineered mice to express a mutated allele of serine/arginine-rich splicing factor 2 ( Srsf2 P95H )—which commonly occurs in individuals with MDS and AML—in an inducible, hemizygous manner in hematopoietic cells. These mice rapidly succumbed to fatal bone marrow failure, demonstrating that Srsf2 -mutated cells depend on the wild-type Srsf2 allele for survival. In the context of leukemia, treatment with the spliceosome inhibitor E7107 (refs. 7 , 8 ) resulted in substantial reductions in leukemic burden, specifically in isogenic mouse leukemias and patient-derived xenograft AMLs carrying spliceosomal mutations. Whereas E7107 treatment of mice resulted in widespread intron retention and cassette exon skipping in leukemic cells regardless of Srsf2 genotype, the magnitude of splicing inhibition following E7107 treatment was greater in Srsf2 -mutated than in Srsf2 -wild-type leukemia, consistent with the differential effect of E7107 on survival. Collectively, these data provide genetic and pharmacologic evidence that leukemias with spliceosomal gene mutations are preferentially susceptible to additional splicing perturbations in vivo as compared to leukemias without such mutations. Modulation of spliceosome function may thus provide a new therapeutic avenue in genetically defined subsets of individuals with MDS or AML.