Rüdiger J. Blaschke

Targeted Mutation Reveals Essential Functions of the Homeodomain Transcription Factor Shox2 in Sinoatrial and Pacemaking Development

Background— Identifying molecular pathways regulating the development of pacemaking and coordinated heartbeat is crucial for a comprehensive mechanistic understanding of arrhythmia-related diseases. Elucidation of these pathways has been complicated mainly by an insufficient definition of the developmental structures involved in these processes and the unavailability of animal models specifically targeting the relevant tissues. Here, we report on a highly restricted expression pattern of the homeodomain transcription factor Shox2 in the sinus venosus myocardium, including the sinoatrial nodal region and the venous valves. Methods and Results— To investigate its function in vivo, we have generated mouse lines carrying a targeted mutation of the Shox2 gene. Although heterozygous animals did not exhibit obvious defects, homozygosity of the targeted allele led to embryonic lethality at 11.5 to 13.5 dpc. Shox2−/− embryos exhibited severe hypoplasia of the sinus venosus myocardium in the posterior heart field, including the sinoatrial nodal region and venous valves. We furthermore demonstrate aberrant expression of connexin 40 and connexin 43 and the transcription factor Nkx2.5 in vivo specifically within the sinoatrial nodal region and show that Shox2 deficiency interferes with pacemaking function in zebrafish embryos. Conclusions— From these results, we postulate a critical function of Shox2 in the recruitment of sinus venosus myocardium comprising the sinoatrial nodal region.

SHOX: Growth, Léri–Weill and Turner Syndromes

Linear growth is a multifactorial trait involving environmental, hormonal and genetic factors. The multitude of growth-affecting genetic factors has recently been supplemented by the discovery of the homeobox gene SHOX. Although originally described as causing idiopathic short stature, SHOX mutations are also responsible for mesomelic growth retardation and Madelung deformity in Léri-Weill dyschondrosteosis and Langer mesomelic dysplasia. Furthermore, recent studies implicate SHOX haploinsufficiency in the etiology of additional somatic stigmata frequently observed in Turner syndrome. Therefore, SHOX has a broad functional scope and leads to a variety of different phenotypes upon mutation.

Shox2 mediates Tbx5 activity by regulating Bmp4 in the pacemaker region of the developing heart

Heart formation requires a highly balanced network of transcriptional activation of genes. The homeodomain transcription factor, Shox2, is essential for the formation of the sinoatrial valves and for the development of the pacemaking system. The elucidation of molecular mechanisms underlying the development of pacemaker tissue has gained clinical interest as defects in its patterning can be related to atrial arrhythmias. We have analyzed putative targets of Shox2 and identified the Bmp4 gene as a direct target. Shox2 interacts directly with the Bmp4 promoter in chromatin immunoprecipitation assays and activates transcription in luciferase-reporter assays. In addition, ectopic expression of Shox2 in Xenopus embryos stimulates transcription of the Bmp4 gene, and silencing of Shox2 in cardiomyocytes leads to a reduction in the expression of Bmp4. In Tbx5del/+ mice, a model for Holt-Oram syndrome, and Shox2−/− mice, we show that the T-box transcription factor Tbx5 is a regulator of Shox2 expression in the inflow tract and that Bmp4 is regulated by Shox2 in this compartment of the embryonic heart. In addition, we could show that Tbx5 acts cooperatively with Nkx2.5 to regulate the expression of Shox2 and Bmp4. This work establishes a link between Tbx5, Shox2 and Bmp4 in the pacemaker region of the developing heart and thus contributes to the unraveling of the intricate interplay between the heart-specific transcriptional machinery and developmental signaling pathways.

Transcriptional and translational regulation of the Leri-Weill and Turner syndrome homeobox gene SHOX

Regulation of gene expression is particularly important for gene dosage-dependent diseases and the phenomenon of clinical heterogeneity frequently associated with these phenotypes. We here report on the combined transcriptional and translational regulatory mechanisms controlling the expression of the Léri-Weill and Turner syndrome gene SHOX. We define an alternative promotor within exon 2 of the SHOX gene by transient transfections of mono- and bicistronic reporter constructs and demonstrate substantial differences in the translation efficiency of the mRNAs transcribed from these alternative promotors by in vitro translation assays and direct mRNA transfections into different cell lines. Although transcripts generated from the intragenic promotor (P2) are translated with high efficiencies, mRNA originating from the upstream promotor (P1) exhibit significant translation inhibitory effects due to seven AUG codons upstream of the main open reading frame (uAUGs). Site-directed mutagenesis of these uAUGs confers full translation efficiency to reporter mRNAs in different cell lines and after injection of Xenopus embryos. In conclusion, our data support a model where functional SHOX protein levels are regulated by a combination of transcriptional and translational control mechanisms.

SHOX in Short Stature Syndromes

Linear growth is a multifactorial trait that is influenced and regulated by a combination of environmental and internal factors. Among the intrinsic determinants of final body height, genetic factors have become more and more prominent, and the list of genes involved in growth-related processes has been extended accordingly. One of the most exciting additions to this list is represented by the discovery of the pseudoautosomal gene SHOX. Originally described as a gene responsible for idiopathic short stature, it has become clear that SHOX mutations can also cause mesomelic short stature and Madelung deformity in Léri-Weill syndrome. In addition, recent studies implicate SHOX haploinsufficiency in a variety of somatic Turner syndrome stigmata.

Impairment of SHOX nuclear localization as a cause for Leri-Weill syndrome

We report the characterization of the nuclear localization signal (NLS) of the short stature homeobox gene SHOX. Mutations within the SHOX gene cause Léri-Weill dyschondrosteosis (LWD) and Langer mesomelic dysplasia (LD) as well as idiopathic short stature (ISS). Furthermore, haploinsufficiency of SHOX has also been implicated in Turner syndrome. SHOX has been shown to be a cell-type-specific transcriptional activator that localizes to the nucleus. The SHOX protein contains a central homeodomain that together with its transactivation domain regulates the transcription of its target sequences within the nucleus. The sequences for its nuclear localization have not been identified yet. Experimental characterization of SHOX-NLS by deletion mapping identified a non-classic type basic signal, AKCRK, in the recognition helix of the homeodomain. Fusion of this stretch of five amino acids to a cytoplasmic reporter protein resulted in its nuclear translocation. Functional analysis of a missense mutation R173C (C517T) affecting the identified SHOX-NLS in two families with LWS and LD showed that the mutated SHOX protein is unable to enter the nucleus. Conversely, we can demonstrate that insertion of the identified signal adjacent to the mutant site can restore its nuclear translocation. These results establish impairment of nuclear localization as a mechanistic basis for SHOX-related diseases.

A novel point mutation A170P in the SHOX gene defines impaired nuclear translocation as a molecular cause for Léri–Weill dyschondrosteosis and Langer dysplasia

1-3 and encodes a paired related homeodomain transcription factor. Nominal levels of the SHOX protein have been implicated in bone development and longitudinal body growth, as heterozygous and homozygous loss of SHOX functions result in Leri-Weill dyschondrosteosis (LWD) and Langer dysplasia (LD), respectively. 45 Apart from mesomelic short stature and a characteristic deformity of the forearm leading to a limited mobility of the wrist (Madelung deformity), some individuals with LWD and LD present with a subset of clinical stigmata frequently observed in females with Turner syndrome, including high arched palate, curvature of radius/ulna/tibia, and short fourth metacarpals. 6-8 These clinical features are variable, leading to a significant phenotypic heterogeneity particularly among persons with LWD. 9 In addition, SHOX mutations are a major cause of isolated short stature conditions, with an estimated incidence of 2-3% in children presenting with idiopathic growth retardation. 10 11 This is higher than the incidence of achondroplasia and growth hormone deficiency together. 12 13

Control of MYEOV Protein Synthesis by Upstream Open Reading Frames

The myeov gene has been isolated by the tumorigenicity assay and is localized at chromosome 11q13, a frequent site for chromosomal rearrangements in various carcinomas and B-cell neoplasms. In addition, myeov is coamplified with cyclin D1 and overexpressed in carcinomas of various organs. The mechanisms of myeov regulation remain enigmatic. The 5′-untranslated region (5′-UTR) of the myeov gene is long, encompasses several upstream AUGs, and is predicted to fold in a strong secondary structure, suggesting that its translation might be regulated by an internal ribosomal entry site. Here we show that initial experiments using monocistronic and dicistronic reporter constructs supported this assumption. However, the application of in vitro transcription/translation assays, Northern blot analysis, and promoterless dicistronic constructs revealed promoter activity of the myeov 5′-UTR. DNA transfection of dicistronic DNA constructs, normal and mutated forms of myeov cDNA fragments cloned in a eukaryotic expression vector, and direct RNA transfection analysis revealed that upstream AUG triplets in the 5′-UTR of the myeov transcript abrogate translation. Alternative splicing mechanisms in specific cell types and/or developmental stage may evade this translation control. Control experiments suggest that the 5′-UTR from encephalomyocarditis virus, when inserted at the midpoint of a dicistronic vector, is also able to function as a cryptic promoter.