Analysis of abnormal branchial arch structures of a Hoxb3 transgenic mouse mutant using a lacZ Reporter mouse line

Hung, Siu-chun., 洪少俊.

January 2004

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

Homeobox genes.

Branchial arch.

Transgenic mice.

Analysis of abnormal branchial arch structures of a Hoxb3 transgenic mouse mutant using a lacZ Reporter mouse line

Hung, Siu-chun.

January 2004

Thesis (M.Med.Sc.)--University of Hong Kong, 2004. / Also available in print.

Investigation of hoxa2 gene function in palate development using a retroviral gene delivery system

Wang, Xia

19 April 2006

Cleft palate is a common human birth defect caused by any process which interferes with palatogenesis. Studies in Hoxa2 mutant (Hoxa2-/-) mice which exhibit a secondary cleft palate were reported to be due to an abnormal positioning of the tongue which prevents normal palatal shelf fusion to occur. To obtain direct evidence for the importance of Hoxa2 in murine palate development, an in vitro whole organ palatal culture model was developed, eliminating any influences from the tongue. A retroviral gene delivery system was employed, containing either Hoxa2 sense or Hoxa2 antisense cDNA, to respectively enhance or knockdown the expression of Hoxa2 mRNA in the developing palate. <p>Our results show that palatal cultures infected with the lowest titer of Hoxa2 sense virus induce a fusion rate of 72.7%, which is similar to palatal cultures treated with the control virus (81.8%), although fusion rates of 41.2% to 50.0% were observed in palates infected with higher titers. With the antisense virus treated group, a more profound inhibition of the fusion rate was observed (27.7% - 46.1%), which is comparable with the frequency of palatal fusion in Hoxa2-/- mice (44.4%). Additionally, the palatal shelves in both sense and antisense virus treated groups appear to be relatively shorter in length, than those measured in the control group. Interestingly, in the antisense virus treated group, the ratio of the length of the fused portion to the length of palatal shelves appears to be relatively large compared to the control group. Verification and quantification of Hoxa2 mRNA in the developing palate between E12.5 and E15.5 was performed by real-time RT-PCR. Hoxa2 gene expression was observed at all stages studied, with expression being the highest at E12.5 and declining from E13.5. The expression level remained constant from E13.5 through E15.5. These findings demonstrate for the first time that Hoxa2 may play a direct role in murine palate development. Results suggest that both factors (the absence of Hoxa2 gene in the palate causing delayed palatal development, as well as the position of the tongue) appear to act in unison to produce cleft palate in Hoxa2 knockout mice.

real-time RT-PCR

Hoxa2 sense retrovirus

Hoxa2 gene

Palate

Hoxa2 antisense retrovirus

First branchial arch

Investigation of hoxa2 gene function in palate development using a retroviral gene delivery system

Wang, Xia

19 April 2006

Cleft palate is a common human birth defect caused by any process which interferes with palatogenesis. Studies in Hoxa2 mutant (Hoxa2-/-) mice which exhibit a secondary cleft palate were reported to be due to an abnormal positioning of the tongue which prevents normal palatal shelf fusion to occur. To obtain direct evidence for the importance of Hoxa2 in murine palate development, an in vitro whole organ palatal culture model was developed, eliminating any influences from the tongue. A retroviral gene delivery system was employed, containing either Hoxa2 sense or Hoxa2 antisense cDNA, to respectively enhance or knockdown the expression of Hoxa2 mRNA in the developing palate. <p>Our results show that palatal cultures infected with the lowest titer of Hoxa2 sense virus induce a fusion rate of 72.7%, which is similar to palatal cultures treated with the control virus (81.8%), although fusion rates of 41.2% to 50.0% were observed in palates infected with higher titers. With the antisense virus treated group, a more profound inhibition of the fusion rate was observed (27.7% - 46.1%), which is comparable with the frequency of palatal fusion in Hoxa2-/- mice (44.4%). Additionally, the palatal shelves in both sense and antisense virus treated groups appear to be relatively shorter in length, than those measured in the control group. Interestingly, in the antisense virus treated group, the ratio of the length of the fused portion to the length of palatal shelves appears to be relatively large compared to the control group. Verification and quantification of Hoxa2 mRNA in the developing palate between E12.5 and E15.5 was performed by real-time RT-PCR. Hoxa2 gene expression was observed at all stages studied, with expression being the highest at E12.5 and declining from E13.5. The expression level remained constant from E13.5 through E15.5. These findings demonstrate for the first time that Hoxa2 may play a direct role in murine palate development. Results suggest that both factors (the absence of Hoxa2 gene in the palate causing delayed palatal development, as well as the position of the tongue) appear to act in unison to produce cleft palate in Hoxa2 knockout mice.

real-time RT-PCR

Hoxa2 sense retrovirus

Hoxa2 gene

Palate

Hoxa2 antisense retrovirus

First branchial arch

Gene regulation in embryonic development

Losa Llabata, Marta

January 2016

Branchial arches (BAs) are a series of transient structures that develop on the ventro-lateral surface of the head in vertebrate embryos. BAs initially appear as a series of similar segments; as development proceeds each BA will contribute to different structures. Here, it was investigated the transcriptional mechanisms that instruct the different fates of the BAs in development. Initially, each BA contains a blood vessel, known as aortic arch (AA) artery, that connects the dorsal aorta with the heart. Remodelling of the AAs is crucial to form the adult heart circulation. This process leads to regression of the anterior AAs, running though the first and second BAs (BA1 and BA2), and persistence of the AAs contained in more posterior BAs (PBA). To identify the mechanisms that control remodelling of the AAs, we compared the transcriptomes and epigenomic landscapes of different BAs. Using RNA-seq and H3K27Ac ChIP-seq, we uncovered the activation of a vascular smooth muscle cell (VSMC) differentiation transcriptional program exclusively in the PBAs (and not in BA1/BA2). In support of this finding, we show that VSMC differentiation occurs specifically in the PBAs, but not BA1-2 in mouse embryonic development. Despite the absence of VSMC differentiation in developing BA1-2, cells harvested from these tissues reveal a spontaneous tendency to differentiate towards VSMC fate when grown in vitro, and activate several VSMC-specific genes (Myocd, Acta2, Tagln, Jag1). Together, our results suggest that forming VSMCs is a key process for the persistence of AAs. We also showed that cells derived from all BAs have the potential to differentiate to VSMCs in vitro. However, only cells in the PBAs differentiate to VSMCs in vivo, resulting in the maintenance of posterior AAs. In this study, we also uncovered a novel transcriptional principle that specifies the fate of BA2. Using ChIP-seq, we found that binding of Meis transcription factors establish a ground pattern in the BAs. Hoxa2, which specifies BA2 identity, selects a subset of Meis-bound sites. Meis binding is strongly increased at these sites, which coincide with active enhancers, linked to genes highly expressed in the BA2 and regulated by Hoxa2. Thus, Hoxa2 modifies a ground state binding of Meis to instruct segment-specific transcriptional programs.

612.6

Adaptive Responses of Branchial Morphology to Hypoxia in the Neotropical Electric Fish Genus Brachyhypopomus

Pathak, Leilani B.

01 January 2011

Many tropical aquatic environments worldwide are characterized by intermittent or prolonged hypoxia (low dissolved oxygen). Nevertheless, many tropical freshwater fishes are able to inhabit these challenging environments via a range of morphological, physiological and behavioral adaptations. Brachyhypopomus is a diverse genus of weakly electric fishes represented by 28 known species distributed from Panama to Argentina. 17 species are restricted to permanently normoxic habitats (blackwater rivers and terra firme streams), eight species are restricted to seasonally or perennially hypoxic habitats (whitewater floodplains of large tropical rivers or permanent swampy habitats), and three species are eurytopic (occur in both seasonally hypoxic and normoxic habitats). These habitat distributions offer the opportunity to explore both species- and population-level variation in adaptive responses to hypoxia. Across 25 of the 28 known species in the genus (for which specimens were available), one- and two-way ANOVA was used to correlate total gill filament length (a metric of gill surface area) with lifestyle-divided into four categories: 1) stenotopic species (i.e. species occurring in a narrow range of habitats) restricted to hypoxic habitats; 2) stenotopic species restricted to normoxic habitats; 3) populations of eurytopic species from hypoxic habitats, and; 4) populations of eurytopic species from normoxic habitats. One-way ANOVA revealed that populations of eurytopic species from hypoxic habitats had significantly larger total gill filament lengths than stenotopic species from the same habitat (P = 0.0169). Likewise, populations of eurytopic from normoxic habitats had significantly larger total gill filament lengths than stenotopic species from normoxic habitats (P[less than] 0.005). Two-way ANOVA showed that eurytopic species had significantly larger total gill filament lengths than stenotopic species, independent of the disparity in total gill filament length associated with either hypoxic or normoxic habitats. Results indicate a strong correlation between gill surface area and oxygen-habitat among species and populations, which supports the hypothesis that an enlarged gill surface area increases oxygen uptake and serves as an adaptive response to seasonal hypoxia.

Branchial arch

Electric fishes

South America

Morphology

Gills

Hypoxia

anoxia

knifefishes

Biology