Richard Pannell

Nuocytes represent a new innate effector leukocyte that mediates type-2 immunity

Innate immunity provides the first line of defence against invading pathogens and provides important cues for the development of adaptive immunity. Type-2 immunity—responsible for protective immune responses to helminth parasites and the underlying cause of the pathogenesis of allergic asthma—consists of responses dominated by the cardinal type-2 cytokines interleukin (IL)4, IL5 and IL13 (ref. 5). T cells are an important source of these cytokines in adaptive immune responses, but the innate cell sources remain to be comprehensively determined. Here, through the use of novel Il13-eGFP reporter mice, we present the identification and functional characterization of a new innate type-2 immune effector leukocyte that we have named the nuocyte. Nuocytes expand in vivo in response to the type-2-inducing cytokines IL25 and IL33, and represent the predominant early source of IL13 during helminth infection with Nippostrongylus brasiliensis. In the combined absence of IL25 and IL33 signalling, nuocytes fail to expand, resulting in a severe defect in worm expulsion that is rescued by the adoptive transfer of in vitro cultured wild-type, but not IL13-deficient, nuocytes. Thus, nuocytes represent a critically important innate effector cell in type-2 immunity.

A p53-dependent mechanism underlies macrocytic anemia in a mouse model of human 5q- syndrome

The identification of the genes associated with chromosomal translocation breakpoints has fundamentally changed understanding of the molecular basis of hematological malignancies. By contrast, the study of chromosomal deletions has been hampered by the large number of genes deleted and the complexity of their analysis. We report the generation of a mouse model for human 5q– syndrome using large-scale chromosomal engineering. Haploinsufficiency of the Cd74–Nid67 interval (containing Rps14, encoding the ribosomal protein S14) caused macrocytic anemia, prominent erythroid dysplasia and monolobulated megakaryocytes in the bone marrow. These effects were associated with defective bone marrow progenitor development, the appearance of bone marrow cells expressing high amounts of the tumor suppressor p53 and increased bone marrow cell apoptosis. Notably, intercrossing with p53-deficient mice completely rescued the progenitor cell defect, restoring common myeloid progenitor and megakaryocytic-erythroid progenitor, granulocyte-monocyte progenitor and hematopoietic stem cell bone marrow populations. This mouse model suggests that a p53-dependent mechanism underlies the pathophysiology of the 5q– syndrome.

The mll-AF9 gene fusion in mice controls myeloproliferation and specifies acute myeloid leukaemogenesis.

The MLL gene from human chromosome 11q23 is involved in >30 different chromosomal translocations resulting in a plethora of different MLL fusion proteins. Each of these tends to associate with a specific leukaemia type, for example, MLL–AF9 is found mainly in acute myeloid leukaemia. We have studied the role of the Mll–AF9 gene fusion made in mouse embryonic stem cells by an homologous recombination knock‐in. Acute leukaemias developed in heterozygous mice carrying this fusion as well as in chimeric mice. As with human chromosomal translocation t(9;11), the majority of cases were acute myeloid leukaemias (AMLs) involving immature myeloblasts, but a minority were acute lymphoblastic leukaemia. The AMLs were preceded by effects on haematopoietic differentiation involving a myeloproliferation resulting in accumulation of Mac‐1/Gr‐1 double‐positive mature myeloid cells in bone marrow as early as 6 days after birth. Therefore, non‐malignant expansion of myeloid precursors is the first stage of Mll–AF9‐mediated leukaemia followed by accumulation of malignant cells in bone marrow and other tissues. Thus, the late onset of overt tumours suggests that secondary tumorigenic mutations are necessary for malignancy associated with MLL–AF9 gene fusion and that myeloproliferation provides the pool of cells in which such events can occur.

Inadequate lung development and bronchial hyperplasia in mice with a targeted deletion in the Dutt1/Robo1 gene

Chromosome 3 allele loss in preinvasive bronchial abnormalities and carcinogen-exposed, histologically normal bronchial epithelium indicates that it is an early, possibly the first, somatic genetic change in lung tumor development. Candidate tumor suppressor genes have been isolated from within distinct 3p regions implicated by heterozygous and homozygous allele loss. We have proposed that DUTT1, nested within homozygously deleted regions at 3p12–13, is the tumor suppressor gene that deletion-mapping and tumor suppression assays indicate is located in proximal 3p. The same gene, ROBO1 (accession number AF040990), was independently isolated as the human homologue of the Drosophila gene, Roundabout. The gene, coding for a receptor with a domain structure of the neural-cell adhesion molecule family, is widely expressed and has been implicated in the guidance and migration of axons, myoblasts, and leukocytes in vertebrates. A deleted form of the gene, which mimics a naturally occurring, tumor-associated human homozygous deletion of exon 2 of DUTT1/ROBO1, was introduced into the mouse germ line. Mice homozygous for this targeted mutation, which eliminates the first Ig domain of Dutt1/Robo1, frequently die at birth of respiratory failure because of delayed lung maturation. Lungs from these mice have reduced air spaces and increased mesenchyme, features that are present some days before birth. Survivors acquire extensive bronchial epithelial abnormalities including hyperplasia, providing evidence of a functional relationship between a 3p gene and the development of bronchial abnormalities associated with early lung cancer.

Tumorigenesis in mice with a fusion of the leukaemia oncogene Mll and the bacterial lacZ gene

Many different chromosomal translocations occur in man at chromosome 11q23 in acute leukaemias. Molecular analyses revealed that the MLL gene (also called ALL‐1, HRX or HTRX) is broken by the translocations, causing fusion with genes from other chromosomes. The diversity of MLL fusion partners poses a dilemma about the function of the fusion proteins in tumour development. The consequence of MLL truncation and fusion has been analysed by joining exon 8 of Mll with the bacterial lacZ gene using homologous recombination in mouse embryonic stem cells. We show that this fusion is sufficient to cause embryonic stem cell‐derived acute leukaemias in chimeric mice, and these tumours occur with long latency compared with those found in MLL–Af9 chimeric mice. These findings indicate that an MLL fusion protein can contribute to tumorigenesis, even if the fusion partner has no known pathogenic role. Thus, truncation and fusion of MLL can be sufficient for tumorigenesis, regardless of the fusion partner.

Engineering de novo reciprocal chromosomal translocations associated with Mll to replicate primary events of human cancer

The etiology of human tumors often involves chromosomal translocations. Models that emulate translocations are essential to understanding the determinants of frank malignancy, those dictating the restriction of translocations to specific lineages, and as a basis for development of rational therapeutic methods. We demonstrate that developmentally regulated Cre-loxP-mediated interchromosomal recombination between the Mll gene, whose human counterpart is involved in a spectrum of leukemias, and the Enl gene creates reciprocal chromosomal translocations that cause myeloid tumors. There is a rapid onset and high penetrance of leukemogenesis in these translocator mice, and high proportions of cells carrying chromosomal translocations can be found in bone marrow as early as 12 days after birth. This de novo strategy is a direct recapitulation of naturally occurring human cancer-associated translocations.

The LMO2 T-cell oncogene is activated via chromosomal translocations or retroviral insertion during gene therapy but has no mandatory role in normal T-cell development.

ABSTRACT The LMO2 gene encodes a LIM-only protein and is a target of chromosomal translocations in human T-cell leukemia. Recently, two X-SCID patients treated by gene therapy to rescue T-cell lymphopoiesis developed T-cell leukemias with retroviral insertion into the LMO2 gene causing clonal T-cell proliferation. In view of the specificity of LMO2 in T-cell tumorigenesis, we investigated a possible role for Lmo2 in T-lymphopoiesis, using conditional knockout of mouse Lmo2 with loxP-flanked Lmo2 and Cre recombinase alleles driven by the promoters of the lymphoid-specific genes Rag1, CD19, and Lck. While efficient deletion of Lmo2 was observed, even in the earliest detectable lymphoid cell progenitors of the bone marrow, there was no disturbance of lymphopoiesis in either T- or B-cell lineages, and in contrast to Lmo2 transgenic mice, there were normal distributions of CD4− CD8− thymocytes. We conclude that there is no mandatory role for LMO2 in lymphoid development, implying that its specific role in T-cell tumorigenesis results from a reprogramming of gene expression after enforced expression in T-cell precursors.

Inter‐chromosomal recombination of Mll and Af9 genes mediated by cre‐loxP in mouse development

Chromosomal translocations are crucial events in the aetiology of many leukaemias, lymphomas and sarcomas, resulting in enforced oncogene expression or the creation of novel fusion genes. The study of the biological outcome of such events ideally requires recapitulation of the tissue specificity and timing of the chromosomal translocation itself. We have used the Cre‐loxP system of phage P1 to induce de novo Mll–Af9 chromosomal recombination during mouse development. loxP sites were introduced into the Mll and Af9 genes on chromosomes 9 and 4, respectively, and mice carrying these alleles were crossed with mice expressing Cre recombinase. A resulting Mll–Af9 fusion gene was detected whose transcription and splicing were verified. Thus, programmed inter‐chromosomal recombination can be achieved in mice. This approach should allow the design of mouse models of tumorigenesis with greater biological relevance than those available at present.

Deletion of the RNA-binding proteins ZFP36L1 and ZFP36L2 leads to perturbed thymic development and T lymphoblastic leukemia.

ZFP36L1 and ZFP36L2 are RNA-binding proteins (RBPs) that interact with AU-rich elements in the 3′ untranslated region of mRNA, which leads to mRNA degradation and translational repression. Here we show that mice that lacked ZFP36L1 and ZFP36L2 during thymopoiesis developed a T cell acute lymphoblastic leukemia (T-ALL) dependent on the oncogenic transcription factor Notch1. Before the onset of T-ALL, thymic development was perturbed, with accumulation of cells that had passed through the β-selection checkpoint without first expressing the T cell antigen receptor β-chain (TCRβ). Notch1 expression was higher in untransformed thymocytes in the absence of ZFP36L1 and ZFP36L2. Both RBPs interacted with evolutionarily conserved AU-rich elements in the 3′ untranslated region of Notch1 and suppressed its expression. Our data establish a role for ZFP36L1 and ZFP36L2 during thymocyte development and in the prevention of malignant transformation.

LOW CYTOPLASMIC MRNA LEVELS OF IMMUNOGLOBULIN KAPPA LIGHT CHAIN GENES CONTAINING NONSENSE CODONS CORRELATE WITH INEFFICIENT SPLICING

We have previously reported down‐regulation of mRNA expression of some of the kappa light chain transgenes in a hybridoma derived from a secondary immune response. Of the five heavily mutated transgene copies present in that hybridoma, three included premature stop codons and were poorly represented at the mRNA level. Here we show that the nonsense mutations are the cause of the low mRNA levels. While we found no evidence that the reduction in mRNA abundance was attributable to an increased rate of cytoplasmic mRNA decay, the amount of cytoplasmic mRNA correlated with the accumulation of unspliced transcripts in the nucleus. Similar results were obtained with a chimeric immunoglobulin gene containing a premature chain termination codon in the variable gene segment. We suggest that inhibition of splicing induced by in‐frame premature stop codons is an important mechanism for down‐regulation of undesirable immunoglobulin transcripts.