Imbalanced globin chain synthesis determines erythroid cell pathology in thalassemic mice

Background

β-thalassemia occurs from the imbalanced globin chain synthesis due to the absence or inadequate β-globin chain production. The excessive unbound α-globin chains precipitate in erythroid precursors and mature red blood cells leading to ineffective erythropoiesis and hemolysis.

Design and Methods

In vitro globin chain synthesis in reticulocytes from different types of thalassemic mice was performed. The effect of imbalanced globin chain synthesis was assessed from changes of red blood cell properties including increased numbers of red blood cells vesicles and apoptotic red blood cells, increased reactive oxygen species and decreased red blood cell survival.

Results

The α/β-globin chain ratio in β^IVSII-654-thalassemic mice, 1.26±0.03, was significantly higher than that of wild type mice, 0.96±0.05. The thalassemic mice show abnormal hematologic data and defective red blood cell properties. These values were improved significantly in doubly heterozygous thalassemic mice harboring 4 copies of human β^E-globin transgene, with a more balanced globin chain synthesis, 0.92±0.05. Moreover, transgenic mice harboring 8 extra copies of the human β^E-globin transgene showed inversely imbalanced α/β-globin synthesis ratio, 0.83±0.01, that resulted in a mild β-thalassemia phenotype due to the excessive β-globin chains. The degree of ineffective erythropoiesis also correlated with the degree of imbalanced globin chain synthesis. Bone marrow and splenic erythroid precursor cells of β^IVSII-654-thalassemic mice showed increased phosphatidylserine exposure in basophilic and polychromatophilic stages, which was restored to the normal level in doubly heterozygous mice.

Conclusions

Imbalanced α/β-globin chain as a consequence of either reduction or enhancement of β-globin chain synthesis can cause abnormal red blood cell properties in mouse models.     

Globin gene expression in Hb Lepore-BAC transgenic mice

We generated five lines of transgenic mice carrying 1-3 copies of the Hb Lepore deltabeta fusion gene, in the context of a Bacterial Artificial Chromosome containing the whole human beta globin gene cluster. Normal developmental regulation of human genes occurred at levels approximating to those of endogenous genes. Deltabeta transgene expression became detectable during fetal life and rose to a mean level of 13.0% in adults, similar to that of humans. Low levels of human gamma chains were detectable as F cells in adult mice, but numbers did not increase after treatment with drugs that raise F cells in human subjects, even on a thalassaemic background.     

Haemopoietic progenitor cell lines generated by the myeloproliferative leukaemia virus: a model system to analyse murine and human lineage-affiliated genes

Multipotential progenitor and stem cells occur with a low frequency in haemopoietic tissue. As a result, it is often difficult to obtain sufficient numbers of cells to undertake many of the assays that would be informative about the molecular events involved in the regulation of lineage-affiliated genes within these multipotent cells. To circumvent this problem, we have used the myeloproliferative leukaemia virus (MPLV) to generate a phenotypically diverse array of haemopoietic progenitors from adult mouse bone marrow and embryonic blood. These cells could be expanded to perform a variety of analyses that would not previously have been possible using analogous primary cells. The validity of these assays was supported by the observation that the phenotype of several MPLV-infected lines was very similar to previously described primary haemopoietic progenitor cells. By using mice transgenic for the human alpha and beta globin gene clusters, we have shown that human genes may also be investigated. In addition, this strategy has a wide potential applicability including the rescue of haemopoietic progenitors from mouse embryos lacking genes critical for their survival as well as the study of any haemopoietic gene for which an appropriate transgenic mouse is available.     

MicroRNA-15a and -16-1 act via MYB to elevate fetal hemoglobin expression in human trisomy 13

Many human aneuploidy syndromes have unique phenotypic consequences, but in most instances it is unclear whether these phenotypes are attributable to alterations in the dosage of specific genes. In human trisomy 13, there is delayed switching and persistence of fetal hemoglobin (HbF) and elevation of embryonic hemoglobin in newborns. Using partial trisomy cases, we mapped this trait to chromosomal band 13q14; by examining the genes in this region, two microRNAs, miR-15a and -16-1, appear as top candidates for the elevated HbF levels. Indeed, increased expression of these microRNAs in primary human erythroid progenitor cells results in elevated fetal and embryonic hemoglobin gene expression. Moreover, we show that a direct target of these microRNAs, MYB, plays an important role in silencing the fetal and embryonic hemoglobin genes. Thus we demonstrate how the developmental regulation of a clinically important human trait can be better understood through the genetic and functional study of aneuploidy syndromes and suggest that miR-15a, -16-1, and MYB may be important therapeutic targets to increase HbF levels in patients with sickle cell disease and β-thalassemia.     

Hemoglobin synthesis in somatic cell hybrids: coexpression of mouse with human or chinese hamster globin genes in interspecific somatic cell hybrids of mouse erythroleukemia cells.

Somatic cell hybrids were derived by fusion of mouse erythroleukemia cells with fractionated human marrow enriched in erythroblasts, or with chinese hamster fetal liver erythroid cells. Such interspecific hybrid cells, when isolated in suspension culture, had retained nearly all the mouse chromosomes and had lost most of the human or chinese hamster chromosomes. However, two such hybrids (one human, the other hamster) studied 4-6 weeks after fusion, were found to contain several non-mouse chromosomes. RNA extracted from the human marrow x erythroleukemia hybrid annealed equally to both human and mouse globin complementary DNA, indicating that coexpression of the globin genes of each species had occurred in the hybrid cells. Mouse and human mRNA were found to accumulate only after incubation of the cells in 2% dimethylsulfoxide. The chinese hamster x erythroleukemia hybrid appeared to contain a double complement of mouse chromosomes in addition to several chinese hamster chromosomes. After 7 days of incubation in 2% dimethylsulfoxide, [3H]leucine was incorporated into chinese hamster beta-globin and the mouse globin chains. Thus, globin genes from differentiated cells, when introduced into spontaneously proliferating erythroleukemia cells, may be expressed after exposure of the resulting hybrid cells to an agent capable of inducing hemoglobin synthesis in the erythroleukemia cell.     

Hemoglobin synthesis in somatic cell hybrids: globin gene expression in hybrids between mouse erythroleukemia and human marrow cells or fibroblasts.

Somatic cell hybrids were generated by fusion of mouse erythroleukemia cells either to mouse L cells (B82), human fibroblasts (W1-18 VA2), or human marrow fractions enriched in erythroblasts. The hybrid cells were examined for globin gene expression by benzidine staining to detect cytoplasmic hemoglobin, and by molecular hybridization of cellular RNA to globin complementary DNA (cDNA) to detect globin messenger RNA (MRNA). The fibroblast (human or mouse) times erythroleukemia cell hybrids grown in monolayer retained most of the chromosomes of each parent. Neither cytoplasmic hemoglobin nor globin mRNA was detected in dimethylsulfoxide-treated fibroblast times erythroleukemia hybrid cells, indicating extinction of hemoglobin synthesis prior to the formation of cytoplasmic mRNA. The human marrow times mouse erythroleukemia hybrid cells grown in suspension culture contained only a few human chromosomes and exhibited low levels of hemoglobin synthesis which were amplified by 2% dimethylsulfoxide. Mouse (but not human) globin mRNA was demonstrated in these hybrid cells. The results suggest that somatic cell hybrids may be useful in searching for genetic factors which regulate activity of the globin genes.     

Exogenous wild-type p53 gene improved survival of nude mice injected with murine erythroleukemia cell line through amelioration of hemorheological changes

OBJECTIVES: Previous investigations have shown that human wild-type p53 gene (WTp53) inhibits the growth of leukemia and tumor cells in vitro. In the present study, the authors used nude mice and examined the therapeutic role of p53 gene for erythroleukemia in vivo in the absence of MHC effects. METHODS: The nude mice were injected with murine erythroleukemia cells (MEL), MEL cells transfected with wild-type p53 gene (MEL-W), and MEL cells transfected with mutated p53 gene (MEL-M). Abnormalities were found in the hemorheological and biophysical properties of red blood cells in all 3 groups of animals, but the abnormalities were lesser in degree and later in appearance in MEL-W group than in MEL and MEL-M groups. Furthermore, the nude mice in MEL-W group lived longer than those in MEL and MEL-M groups. RESULTS: The results showed that WTp53 restrained the growth of erythroleukemia cells in vivo and reduced the erythroleukemia tumorigenesis in the microcirculation by improving the hemorheological and biophysical properties of MEL cells, which helped to prolong the life span of nude mice suffering from erythroleukemia. CONCLUSION: These results contribute to our knowledge on the use of wild-type p53 gene for the treatment of erythroleukemia disease.     

Effects of hTNFalpha expression in T cells on haematopoiesis in transgenic mice.

A transgenic line of mice carrying one copy of the hTNFalpha gene under the control of its own promoter and the CD2 locus control region has been analysed for the effects of TNFalpha on haematopoiesis. A low level constitutive expression of hTNFalpha in lymphoid tissue was observed. Human TNFalpha binds to and activates the murine p55 receptor, but not the p75 receptor. This implies that the observed effects of hTNFalpha in mice were mediated only through the p55 receptor. Various lymphoid tissues were depleted of lymphocytes, especially thymus, spleen and peripheral blood. Effects on thymus development were detected already at 3 wk of age, more general effects on haematopoiesis were evident by 5 wk: a drop in total blood leukocytes, mainly due to a 67% decline in lymphocytes. At 16 wk the mice had developed anaemia, whereas platelets, neutrophils and monocytes had increased. The fall in lymphocytes was due to lowered levels of T cells as well as B cells. The cause of the shortened lifespan of the transgenic mice was probably not the haematological effects of hTNFalpha directly. Absence of trophic factors supplied by the normal T cell population remains possible.     

Two arrangements of the human fetal globin genes may be responsible for high G gamma values in Chinese newborns: -G gamma-G gamma-delta-beta and -G gamma-A gamma G gamma-A gamma-delta-beta

High G gamma values (78% and higher) have been observed in about 3% of Chinese newborns from the Shanghai area. We describe here two arrangements different from the normal -G gamma-A gamma-delta-beta arrangement which have been characterized in the DNA from three of these babies. One baby was heterozygous for a chromosome with two linked G gamma globin genes (-G gamma-G gamma-delta-beta), which has also been observed in Black newborns [Powers et al, Nucleic Acids Res 12:7023, 1984], while the two other babies were heterozygous for a chromosome with triplicated gamma globin genes, presumably of the -G gamma-A gamma G gamma-A gamma-delta-beta arrangement. A similar triplication has been observed in natives of the New Hebrides [Trent et al, Nucleic Acids Res 9:6723, 1981].     

Abnormal gene expression in cloned mice derived from embryonic stem cell and cumulus cell nuclei

To assess the extent of abnormal gene expression in clones, we assessed global gene expression by microarray analysis on RNA from the placentas and livers of neonatal cloned mice derived by nuclear transfer (NT) from both cultured embryonic stem cells and freshly isolated cumulus cells. Direct comparison of gene expression profiles of more than 10,000 genes showed that for both donor cell types approximately 4% of the expressed genes in the NT placentas differed dramatically in expression levels from those in controls and that the majority of abnormally expressed genes were common to both types of clones. Importantly, however, the expression of a smaller set of genes differed between the embryonic stem cell- and cumulus cell-derived clones. The livers of the cloned mice also showed abnormal gene expression, although to a lesser extent, and with a different set of affected genes, than seen in the placentas. Our results demonstrate frequent abnormal gene expression in clones, in which most expression abnormalities appear common to the NT procedure whereas others appear to reflect the particular donor nucleus.     

Spontaneous myocarditis mimicking human disease occurs in the presence of an appropriate MHC and non-MHC background in transgenic mice

Most individuals have viral infections at some point in their life, however, only few develop autoreactivity to cardiac myosin following infection resulting in myocarditis suggesting a genetic predisposition. Most mouse models of myocarditis are induced by viral infection or by immunization with cardiac myosin. We generated HLA-DR3.Abetao and HLA-DQ8.Abetao transgenic mice in NOD and HLA-DQ8.Abetao in B10 background to study spontaneous autoimmunity. A high mortality was observed in NOD.DQ8 female mice 16 weeks or older. Echocardiography showed marked systolic dysfunction. Histopathology of various organs revealed an enlarged heart with mononuclear infiltrate consisting of CD4 and Mac-1+ cells and myocyte necrosis. The autoimmunity was associated with the presence of spontaneous autoreactive T cells and antibodies to cardiac myosin. Serologically, mice were negative for all known mouse viruses. NOD.DR3.Abetao, the transgene negative littermates, NOD, and B10.DQ8 Abetao mice had no gross or microscopic cardiac pathology. Spontaneous cellular and humoral response to cardiac myosin suggests that NOD.DQ8 may harbor autoreactive cells that can lead to spontaneous myocarditis and dilated cardiomyopathy. HLA-DQ8 is required for the predisposition to the spontaneous autoreactivity while NOD background influences onset and progression of disease. This model of myocarditis occurs predominantly in female mice and may provide insight into the pathogenesis of heart disease in women.     

The expression of human α-like globin genes in transgenic mice mediated by bacterial artificial chromosome

After screening a bacterial artificial chromosome of human genomic DNA library with human HS-40, zeta-, alpha-, and theta-globin probes, a 110-kb clone bearing the whole human alpha-globin gene cluster was obtained and rare restriction endonuclease mapping was performed. The bacterial artificial chromosome DNA was isolated, and transgenic mice were generated. Three founders were detected from 35 newborn mice. The copy numbers were 1, 2, and 2, and the expression of human alpha-globin genes in various tissues at different developmental stages in the transgenic mice was assayed. The human alpha-globin mRNA can be detected in bone marrow, kidney, liver, brain, but not in muscle, testis, or thymus. The human zeta-globin genes were switched off, and the alpha-globin genes were switched at day 11.5 in mouse embryo, indicating that developmental stage-specific expression of the alpha-like globin genes was properly regulated. The human alpha-globin mRNA ranged between 17-68% of the endogenous mouse alpha-globin, suggesting that the expression of human alpha-globin genes is integration site-dependent in transgenic mice. The ratio of human alpha(2)- and alpha(1)-globin gene expression in adult transgenic mouse is about 2.5:1 similar to the expression in human.     

Insulin-producing cells derived from human pancreatic non-endocrine cell cultures reverse streptozotocin-induced hyperglycaemia in mice

Aims/hypothesis The aim of the study was to investigate the potential of human pancreatic non-endocrine cells to transdifferentiate into endocrine cells that would be capable of secreting insulin in response to glucose and ameliorating insulin-deficient diabetes after transplantation.Materials and methods Cell fractions enriched with exocrine cells after human islet isolation were treated with streptozotocin to remove residual beta cells, grown in monolayer culture to allow de-differentiation, transferred to cluster culture for redifferentiation in the presence of activin A, betacellulin, nicotinamide and glucose, supplemented with 10% FCS, and administered to streptozotocin-induced diabetic SCID mice. A subset of cells was transfected with the IPF1 gene (also known as PDX1) before transdifferentiation.Results No insulin was detectable in cell preparations after 5 days of treatment with streptozotocin. In monolayer culture, 90% of the streptozotocin-treated pancreatic cells co-expressed cytokeratin-19 and vimentin at 2 weeks and 60% expressed nestin at 4 weeks. Cell cultures with a high proportion of nestin-expressing cells had greater plasticity for transdifferentiation into cells with phenotypic and functional markers of beta cells, this property being significantly enhanced by transfection with IPF1 gene and leading to 15±6.7% insulin-positive cells after transplantation vs. 0.01% of cells transplanted after streptozotocin treatment alone. These cells improved glucose control in all of 42 diabetic mice after transplantation, restoring normoglycaemia in 40%.Conclusions/interpretation Human pancreatic cells are a potential source of new glucose-responsive insulin-producing cells that may be developed further for clinical use.     

Genetic factors involved in human Gγ and Aγ globin gene expression

Gγ to Aγ globin ratios, haplotypes at the β globin gene cluster and the C →T substitution at -158 5′ to the Gγ globin gene were studied in three Algerian families that include SS or S-β°thal patients. Gγ to Aγ ratios were found similar, within a family, in subjects displaying the same combination of chromosomes 11, the ratio observed for a given combination depending on the chromosome haplotypes. Our data can be explained by the existence of several alleles of a genetic factor closely linked to the β globin gene cluster and involved in the determination of Gγ to Aγ globin ratio.     

Expression of MALT1 oncogene in hematopoietic stem/progenitor cells recapitulates the pathogenesis of human lymphoma in mice

Chromosomal translocations involving the MALT1 gene are hallmarks of mucosa-associated lymphoid tissue (MALT) lymphoma. To date, targeting these translocations to mouse B cells has failed to reproduce human disease. Here, we induced MALT1 expression in mouse Sca1(+)Lin(-) hematopoietic stem/progenitor cells, which showed NF-κB activation and early lymphoid priming, being selectively skewed toward B-cell differentiation. These cells accumulated in extranodal tissues and gave rise to clonal tumors recapitulating the principal clinical, biological, and molecular genetic features of MALT lymphoma. Deletion of p53 gene accelerated tumor onset and induced transformation of MALT lymphoma to activated B-cell diffuse large-cell lymphoma (ABC-DLBCL). Treatment of MALT1-induced lymphomas with a specific inhibitor of MALT1 proteolytic activity decreased cell viability, indicating that endogenous Malt1 signaling was required for tumor cell survival. Our study shows that human-like lymphomas can be modeled in mice by targeting MALT1 expression to hematopoietic stem/progenitor cells, demonstrating the oncogenic role of MALT1 in lymphomagenesis. Furthermore, this work establishes a molecular link between MALT lymphoma and ABC-DLBCL, and provides mouse models to test MALT1 inhibitors. Finally, our results suggest that hematopoietic stem/progenitor cells may be involved in the pathogenesis of human mature B-cell lymphomas.