HOXB4 overexpression mediates very rapid stem cell regeneration and competitive hematopoietic repopulation.

OBJECTIVE: Hox transcription factors have emerged as important regulators of hematopoiesis. In particular, we have shown that overexpression of HOXB4 in mouse bone marrow can greatly enhance the level of hematopoietic stem cell (HSC) regeneration achieved at late times (> 4 months) posttransplantation. The objective of this study was to resolve if HOXB4 increases the rate and/or duration of HSC regeneration, and also to see if this enhancement was associated with impaired production of end cells or would lead to competitive reconstitution of all compartments. METHODS: Retroviral vectors were generated with the GFP reporter gene +/- HOXB4 to enable the isolation and direct tracking of transduced cells in culture or following transplantation. Stem cell recovery was measured by limit dilution assay for long-term competitive repopulating cells (CRU). RESULTS: HOXB4-overexpressing cells have enhanced growth in vitro, as demonstrated by their rapid dominance in mixed cultures and their shortened population doubling time. Furthermore, HOXB4-transduced cells have a marked competitive repopulating advantage in vivo in both primitive and mature compartments. CRU recovery in HOXB4 recipients was extremely rapid, reaching 25% of normal by 14 days posttransplant or some 80-fold greater than control transplant recipients, and attaining normal numbers by 12 weeks. Mice transplanted with even higher numbers of HOXB4-transduced CRU regenerated up to but not beyond the normal CRU levels. CONCLUSIONS: HOXB4 is a potent enhancer of primitive hematopoietic cell growth, likely by increasing self-renewal probability but without impairing homeostatic control of HSC population size or the rate of production and maintenance of mature end cells.

Transfer of the human telomerase reverse transcriptase (TERT) gene into T lymphocytes results in extension of replicative potential.

In most human somatic cells telomeres progressively shorten with each cell division eventually leading to chromosomal instability and cell senescence. The loss of telomere repeats with cell divisions may also limit the replicative life span of antigen-specific T lymphocytes. Recent studies have shown that the replicative life span of various primary human cells can be prolonged by induced expression of the telomerase reverse transcriptase (hTERT) gene. To test whether introduction of hTERT can extend the life span of primary human T lymphocytes, naive CD8(+) T lymphocytes were transfected with retroviral vectors containing the hTERT gene. Transduced T-cell clones expressed high levels of telomerase and either maintained or elongated their telomere lengths upon culture for extended periods of time. Two of the transduced subclones retained a normal cloning efficiency for more than 170 population doublings (PDs). In contrast, T-cell clones transfected with control vectors exhibited progressive telomere length shortening and stopped proliferation at around 108 PDs. Telomerase-positive T clones had a normal 46,XY karyotype, maintained their cytotoxic properties, and showed very little staining for the apoptotic marker annexin-V. These results indicate that ectopic hTERT gene expression is capable of extending the replicative life span of primary human CD8(+) cytotoxic T lymphocytes. (Blood. 2001;98:597-603)

Overexpression of HOXA10 perturbs human lymphomyelopoiesis in vitro and in vivo.

Several studies point to multiple members of the Hox transcription factor family as playing key roles in normal hematopoietic development, and they link the imbalanced expression of these transcription factors, in particular of the Abd-like A cluster HOX genes HOXA9 and HOXA10, to leukemogenesis. To test directly the hypothesis that HOXA10 is involved in human hematopoietic development, the gene was retrovirally overexpressed in human highly purified CD34(+)/GFP(+) hematopoietic progenitor cells derived from cord blood or fetal liver sources, and the impact of aberrant gene expression was analyzed on differentiation and proliferation in vitro and in vivo. HOXA10 misexpression profoundly impaired myeloid differentiation with a higher yield of blast cells in liquid culture and a greater than 100-fold increased generation of blast colonies after in vitro expansion or after replating of primary colonies first plated in methylcellulose directly after transduction (P < .01). Furthermore, aberrant HOXA10 expression almost completely blocked erythroid differentiation in methylcellulose (P < .02). HOXA10 deregulation also severely perturbed the differentiation of human progenitors in vivo, reducing B-cell development by 70% in repopulated NOD/SCID mice and enhancing myelopoiesis in the transduced compartment. The data provide evidence that the balanced expression of HOXA10 is pivotal for normal human hematopoietic development and that aberrant expression of the gene contributes to impaired differentiation and increased proliferation of human hematopoietic progenitor cells. These results also provide a framework to initiate more detailed analyses of HOX regulatory domains and HOX cofactors in the human system in vitro and in vivo.

Enhancer of Polycomb is a suppressor of position-effect variegation in Drosophila melanogaster.

Polycomb group (PcG) genes of Drosophila are negative regulators of homeotic gene expression required for maintenance of determination. Sequence similarity between Polycomb and Su(var)205 led to the suggestion that PcG genes and modifiers of position-effect variegation (PEV) might function analogously in the establishment of chromatin structure. If PcG proteins participate directly in the same process that leads to PEV, PcG mutations should suppress PEV. We show that mutations in E(Pc), an unusual member of the PcG, suppress PEV of four variegating rearrangements: In(l)wm4, B(SV), T(2;3)Sb(V) and In(2R)bw(VDe2). Using reversion of a Pelement insertion, deficiency mapping, and recombination mapping as criteria, homeotic effects and suppression of PEV associated with E(Pc) co-map. Asx is an enhancer of PEV, whereas nine other PcG loci do not affect PEV. These results support the conclusion that there are fewer similarities between PcG genes and modifiers of PEV than previously supposed. However, E(Pc) appears to be an important link between the two groups. We discuss why Asx might act as an enhancer of PEV.