Vesna Jurecic

Tbx1 haploinsufficiency in the DiGeorge syndrome region causes aortic arch defects in mice

DiGeorge syndrome is characterized by cardiovascular, thymus and parathyroid defects and craniofacial anomalies, and is usually caused by a heterozygous deletion of chromosomal region 22q11.2 (del22q11) (ref. 1). A targeted, heterozygous deletion, named Df(16)1, encompassing around 1 megabase of the homologous region in mouse causes cardiovascular abnormalities characteristic of the human disease. Here we have used a combination of chromosome engineering and P1 artificial chromosome transgenesis to localize the haploinsufficient gene in the region, Tbx1. We show that Tbx1, a member of the T-box transcription factor family, is required for normal development of the pharyngeal arch arteries in a gene dosage-dependent manner. Deletion of one copy of Tbx1 affects the development of the fourth pharyngeal arch arteries, whereas homozygous mutation severely disrupts the pharyngeal arch artery system. Our data show that haploinsufficiency of Tbx1 is sufficient to generate at least one important component of the DiGeorge syndrome phenotype in mice, and demonstrate the suitability of the mouse for the genetic dissection of microdeletion syndromes.

Engineering Mouse Chromosomes with Cre-loxP: Range, Efficiency, and Somatic Applications

ABSTRACT Chromosomal rearrangements are important resources for genetic studies. Recently, a Cre-loxP-based method to introduce defined chromosomal rearrangements (deletions, duplications, and inversions) into the mouse genome (chromosome engineering) has been established. To explore the limits of this technology systematically, we have evaluated this strategy on mouse chromosome 11. Although the efficiency of Cre-loxP-mediated recombination decreases with increasing genetic distance when the two endpoints are on the same chromosome, the efficiency is not limiting even when the genetic distance is maximized. Rearrangements encompassing up to three quarters of chromosome 11 have been constructed in mouse embryonic stem (ES) cells. While larger deletions may lead to ES cell lethality, smaller deletions can be produced very efficiently both in ES cells and in vivo in a tissue- or cell-type-specific manner. We conclude that any chromosomal rearrangement can be made in ES cells with the Cre-loxP strategy provided that it does not affect cell viability. In vivo chromosome engineering can be potentially used to achieve somatic losses of heterozygosity in creating mouse models of human cancers.

A Genetic Etiology for Interruption of the Aortic Arch Type B

Interrupted aortic arch (IAA) type B is a congenital heart defect believed to be caused by an anomaly of bronchial arch mesenchymal development. IAA type B has been associated with DiGeorge syndrome (DGS), which includes conotruncal heart defects, T-cell immunodeficiency, hypocalcemia, and facial abnormalities. The great majority of DGS cases are associated with hemizygous deletions at the chromosome 22q11 locus. The present study was designed to establish the involvement of the 22q11 locus in the etiology of IAA type B, independently from the typical DGS phenotype. An evaluation was performed on 73 patients with conotruncal heart defects using fluorescence in situ hybridization (FISH) analysis with probes from the 22q11 DGS locus. From this group, 7 patients were deleted (including 4 of the 11 patients with IAA type B). FISH analysis was extended to a total of 22 patients with IAA type B and 11 of these (50%) were deleted. FISH and Southern blot analyses using additional markers within the DiGeorge chromosomal region were performed on patients found not to be deleted in the initial FISH screening. No small deletions or rearrangements were detected. In our patient population, a single, specific genetic defect is the basis for one half of the IAA type B cases. These data suggest that IAA type B is one of the most etiologically homogeneous congenital heart defects. A 22q11 deletion in IAA type B may or may not be associated with the typical DGS phenotype. Therefore, IAA type B, per se, should be an indication for 22q11 deletion testing.

Comparative mapping of the DiGeorge syndrome region in mouse shows inconsistent gene order and differential degree of gene conservation

We have constructed a comparative map in mouse of the critical region of human 22q11 deleted in DiGeorge (DGS) and Velocardiofacial (VCFS) syndromes. The map includes 11 genes potentially haploinsufficient in these deletion syndromes. We have localized all the conserved genes to mouse Chromosome (Chr) 16, bands B1-B3. The determination of gene order shows the presence of two regions (distal and proximal), containing two groups of conserved genes. The gene order in the two regions is not completely conserved; only in the proximal group is the gene order identical to human. In the distal group the gene order is inverted. These two regions are separated by a DNA segment containing at least one gene which, in the human DGS region, is the most proximal of the known deleted genes. In addition, the gene order within the distal group of genes is inverted relative to the human gene order. Furthermore, a clathrin heavy chain-like gene was not found in the mouse genome by DNA hybridization, indicating that there is an inconsistent level of gene conservation in the region. These and other independent data obtained in our laboratory clearly show a complex evolutionary history of the DGS-VCFS region. Our data provide a framework for the development of a mouse model for the 22q11 deletion with chromosome engineering technologies.

DiGeorge anomaly and chromosome 10p deletions: One or two loci?

We report on a patient with DiGeorge syndrome (DGS) phenotype or anomaly and an unbalanced translocation [45,XY,-10,-22,+der(10),t(10;22)(p13;q11)] resulting in monosomy of 10p13-pter and 22q11-pter. Because both regions involved in this rearrangement have been implicated in DGS, we performed a molecular cytogenetic analysis of both loci in this patient. Results indicate that the chromosome 22 DGS locus is intact but that the terminal deletion of the short arm of chromosome 10 is adjacent to or partially overlapping with the recently defined consensus deleted region observed in DGS patients with 10p deletions. We conclude that the DGS anomaly in our patient is likely to be due to haploinsufficiency of genes located on chromosome 10p. Most, if not all, of the region included in the previously described 10p smallest region of deletion overlap is not deleted in our patient. Therefore, this deletion breakpoint either narrows the previously proposed 10p region or defines a second region within 10p critical for the DGS anomaly.

Structure and chromosomal locations of mouse steroid receptor coactivator gene family

SummaryThe newly recognized steroid receptor coactivators (SRC-1, SRC-2, and SRC-3) belong to a homologous gene family and are important transcriptional mediators for nuclear receptors. Through fluorescence in situ hybridization, we have mapped the mouse SRC-1, SRC-2, and SRC-3 genes to chromosomal locations 12A2-A3, 1A3-A5, and 2H2-H4, respectively. By screening a mouse genomic DNA library, performing long-range polymerase chain reaction and sequencing, we have cloned and characterized the mouse SRC-3 gene. The SRC-3 gene contains 19 exons and spans more than 38 kilobases (kb). Intron sizes are variable. Intron 1 (13.5 kb) and intron 15 (4.6 kb) contribute to almost half the total length of the gene. Among 20 exons identified, exon 10 is the largest (869 bp) and encodes the receptor interaction domain. The start and stop codons for translation are in exon 2 and 20, respectively. The relationship between SRC-3 gene structure and its functional protein domains suggests that many functional domains or subdomains are encoded by individual exons. The correlation between gene structure and alternative splice variants is also discussed. In summary, we have defined the structure of mouse SRC-3 gene and found that the genes in the SRC family are located in different mouse chromosomes. This information is important for developing valuable animal models harboring multiple disruptions of the SRC gene family to study their biological functions.

Goosecoid-Like Sequences and the Smallest Region of Deletion Overlap in DiGeorge and Velocardiofacial Syndromes

We wish to thank Annalisa Botta for the isolation of the murine Gscl sequence. Research in the laboratory of Antonio Baldini is funded by National Institutes of Health grant HL51524 and by American Heart Association grant 94010250. The support of the cores of the Baylor Mental Retardation Research Center and Child Health Research Center is acknowledged.

Rapamycin targets several pathophysiological features of immune-mediated bone marrow failure in murine models

In this issue of Haematologica , Feng et al. [1][1] compare the efficacy of treatment with cyclosporine A (CsA) and rapamycin to ameliorate pancytopenia, improve bone marrow (BM) cellularity, and extend survival in murine models of immune-mediated aplastic anemia (AA). Interestingly, while the