Matthias Porsch scite author profile

optomotor-blind (omb) and optomotor-blind related-1 (org-1) encode T-domain DNA binding proteins in Drosophila. Members of this family of transcription factors play widely varying roles during early development and organogenesis in both vertebrates and invertebrates. Functional specificity differs in spite of similar DNA binding preferences of all family members. Using a series of domain swap chimeras, in which different parts of OMB and ORG-1 were mutually exchanged, we investigated the relevance of individual domains in vitro and in vivo. In cell culture transfection assays, ORG-1 was a strong transcriptional activator, whereas OMB appeared neutral. The main transcriptional activation function was identified in the C-terminal part of ORG-1. Also in vivo, OMB and ORG-1 showed qualitative differences when the proteins were ectopically expressed during development. Gain-of-function expression of OMB is known to counteract eye formation and resulted in the loss of the arista, whereas ORG-1 had little effect on eye development but caused antenna-to-leg transformations and shortened legs in the corresponding gain-of-function situations. The functional properties of OMB/ORG-1 chimeras in several developmental contexts was dominated by the origin of the C-terminal region, suggesting that the transcriptional activation potential can be one major determinant of developmental specificity. In late eye development, we observed, however, a strong influence of the T-domain on ommatidial differentiation. The specificity of chimeric omb/org-1transgenes, thus, depended on the cellular context in which they were expressed. This suggests that both transcriptional activation/repression properties as well as intrinsic DNA binding specificity can contribute to the functional characteristics of T-domain factors.

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Isolation of a Drosophila T-box gene closely related to human TBX1

Porsch¹,

Hofmeyer²,

Bausenwein³

et al. 1998

Gene

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HOXB4 confers a constant rate of in vitro proliferation to transduced bone marrow cells

et al. 2004

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HOXB4 overexpression mediates increased self-renewal of haematopoietic stem cells (HSCs) ex vivo. Since HOXB4-expanded HSCs retain normal differentiation potential and there is no leukaemia development from transduced HSCs, HOXB4 represents a promising tool for human HSC therapy. However, the increased proliferation capacity of HOXB4 overexpressing fibroblasts resulting from upregulation of JunB, Fra-1 and cyclin D1 protein levels may indicate a potential risk associated with the HOXB4 overexpression approach. This prompted us to investigate the proliferation rate, differentiation and expression of cell cycle regulators directly in bone marrow cultures overexpressing HOXB4. Here we show that in comparison to neo-transduced control bone marrow cultures, HOXB4-overexpressing cultures had a more homogenous morphology and increased numbers of haematopoietic progenitor cells capable to generate primitive colonies in vitro. In contrast, neo-transduced bone marrow cells in long-term cultures showed hallmarks of myeloid differentiation and a reduced secondary colony forming activity. We further show that multilineage repopulating activity in vivo, which was present only in HOXB4 long-term cultures, declined over time. HOXB4 overexpression in vitro did not result in an increase but in a stabilization of the proliferation rate (1.4-1.8 cell divisions per day), while the proliferation rate of control neo-transduced bone marrow cultures gradually declined. Correspondingly, increased HOXB4 expression was paralleled by decreased expression levels of cyclins, CDKs and AP-1 family members. These results suggest that the growth rate of HOXB4-compared to neotransduced bone marrow cells remains constant in longterm cultures along with a suppression of myeloid differentiation. In contrast to HOXB4 overexpression in fibroblasts, bone marrow cells engineered to overexpress HOXB4 do not upregulate AP-1 complex members or cyclins indicating that HOXB4 acts in a cell typespecific way.

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Defective Pigment Granule Biogenesis and Aberrant Behavior Caused by Mutations in the Drosophila AP-3β Adaptin Gene ruby

Kretzschmar

Poeck

Roth³

et al. 2000

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Lysosomal protein trafficking is a fundamental process conserved from yeast to humans. This conservation extends to lysosome-like organelles such as mammalian melanosomes and insect eye pigment granules. Recently, eye and coat color mutations in mouse (mocha and pearl) and Drosophila (garnet and carmine) were shown to affect subunits of the heterotetrameric adaptor protein complex AP-3 involved in vesicle trafficking. Here we demonstrate that the Drosophila eye color mutant ruby is defective in the AP-3β subunit gene. ruby expression was found in retinal pigment and photoreceptor cells and in the developing central nervous system. ruby mutations lead to a decreased number and altered size of pigment granules in various cell types in and adjacent to the retina. Humans with lesions in the related AP-3βA gene suffer from Hermansky-Pudlak syndrome, which is caused by defects in a number of lysosome-related organelles. Hermansky-Pudlak patients have a reduced skin pigmentation and suffer from internal bleeding, pulmonary fibrosis, and visual system malfunction. The Drosophila AP-3β adaptin also appears to be involved in processes other than eye pigment granule biogenesis because all ruby allele combinations tested exhibited defective behavior in a visual fixation paradigm.

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Matthias Porsch

The relative role of the T-domain and flanking sequences for developmental control and transcriptional regulation in protein chimeras of Drosophila OMB and ORG-1

Isolation of a Drosophila T-box gene closely related to human TBX1

HOXB4 confers a constant rate of in vitro proliferation to transduced bone marrow cells

Defective Pigment Granule Biogenesis and Aberrant Behavior Caused by Mutations in the Drosophila AP-3β Adaptin Gene ruby

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