David J. Pennisi

Mutations in Sox18 underlie cardiovascular and hair follicle defects in ragged mice.

Analysis of classical mouse mutations has been useful in the identification and study of many genes. We previously mapped Sox18, encoding an SRY-related transcription factor, to distal mouse chromosome 2 (ref. 2). This region contains a known mouse mutation, ragged (Ra), that affects the coat and vasculature. Here we have directly evaluated Sox18 as a candidate for Ra. We found that Sox18 is expressed in the developing vascular endothelium and hair follicles in mouse embryos. Furthermore, we found no recombination between Sox18 and Ra in an interspecific backcross segregating for the Ra phenotype. We found point mutations in Sox18 in two different Ra alleles that result in missense translation and premature truncation of the encoded protein. Fusion proteins containing these mutations lack the ability to activate transcription relative to wild-type controls in an in vitro assay. Our observations implicate mutations in Sox18 as the underlying cause of the Ra phenotype, and identify Sox18 as a critical gene for cardiovascular and hair follicle formation.

Mice null for sox18 are viable and display a mild coat defect.

ABSTRACT We have previously shown that Sox18 is expressed in developing vascular endothelium and hair follicles during mouse embryogenesis and that point mutations in Sox18 are the underlying cause of cardiovascular and hair follicle defects inragged (Ra) mice. Here we describe the analysis of Sox18 −/− mice produced by gene targeting. Despite the profound defects seen in Ra mice,Sox18 −/− mice have no obvious cardiovascular defects and only a mild coat defect with a reduced proportion of zigzag hairs. A reduction in the amount of pheomelanin pigmentation in hair shafts was also observed; later-forming hair follicles showed a reduced subapical pheomelanin band, giving Sox18 −/−mice a slightly darker appearance than Sox18 +/+and Sox18 +/− siblings.Sox18 −/− mice are viable and fertile and show no difference in the ability to thrive relative to littermates. Because of the mild effect of the mutation on the phenotype ofSox18 −/− mice, we conclude that the semidominant nature of the Ra mutations is due to atrans-dominant negative effect mediated by the mutant SOX18 proteins rather than haploinsufficiency as has been observed for otherSOX genes. Due to the similarity of SOX18 to other subgroup F SOX proteins, SOX7 and −17, and the overlap in expression of these genes, functional redundancy amongst these SOX proteins could also account for the mild phenotype of Sox18 −/−mice.

Hemodynamic-dependent patterning of endothelin converting enzyme 1 expression and differentiation of impulse-conducting Purkinje fibers in the embryonic heart

Impulse-conducting Purkinje fibers differentiate from myocytes during embryogenesis. The conversion of contractile myocytes into conduction cells is induced by the stretch/pressure-induced factor, endothelin (ET). Active ET is produced via proteolytic processing from its precursor by ET-converting enzyme 1 (ECE1) and triggers signaling by binding to its receptors. In the embryonic chick heart, ET receptors are expressed by all myocytes, but ECE1 is predominantly expressed in endothelial cells of coronary arteries and endocardium along which Purkinje fiber recruitment from myocytes takes place. Furthermore, co-expression of exogenous ECE1 and ET-precursor in the embryonic heart is sufficient to ectopically convert cardiomyocytes into Purkinje fibers. Thus, localized expression of ECE1 defines the site of Purkinje fiber recruitment in embryonic myocardium. However, it is not known how ECE1 expression is regulated in the embryonic heart. The unique expression pattern of ECE1 in the embryonic heart suggests that blood flow-induced stress/stretch may play a role in patterning ECE1 expression and subsequent induction of Purkinje fiber differentiation. We show that gadolinium, an antagonist for stretch-activated cation channels, downregulates the expression of ECE1 and a conduction cell marker, Cx40, in ventricular chambers, concurrently with delayed maturation of a ventricular conduction pathway. Conversely, pressure-overload in the ventricle by conotruncal banding results in a significant expansion of endocardial ECE1 expression and Cx40-positive putative Purkinje fibers. Coincident with this, an excitation pattern typical of the mature heart is precociously established. These in vivo data suggest that biomechanical forces acting on, and created by, the cardiovascular system during embyogenesis play a crucial role in Purkinje fiber induction and patterning.

Epicardium is required for the full rate of myocyte proliferation and levels of expression of myocyte mitogenic factors FGF2 and its receptor, FGFR‐1, but not for transmural myocardial patterning in the embryonic chick heart

Proper heart development requires patterning across the myocardial wall. Early myocardial patterning is characterized by a transmural subdivision of the myocardium into an outer, highly mitotic, compact zone and an inner, trabecular zone with lower mitotic activity. We have shown previously that fibroblast growth factor receptor (FGFR) ‐mediated signaling is central to myocyte proliferation in the developing heart. Consistent with this, FGFR‐1 and FGF2 are more highly expressed in myocytes of the compact zone. However, the mechanism that regulates the transmural pattern of myocyte proliferation and expression of these mitogenic factors is unknown. The present study examined whether this transmural patterning occurs in a myocardium‐autonomous manner or by signals from the epicardium. Microsurgical inhibition of epicardium formation in the embryonic chick gives rise to a decrease in myocyte proliferation, accounting for a thinner compact myocardium. We show that the transmural pattern of myocyte mitotic activity is maintained in these hearts. Consistent with this, the expression patterns of FGF1, FGF2, and FGFR‐1 across the myocardium persist in the absence of the epicardium. However, FGF2 and FGFR‐1 mRNA levels are reduced in proportion to the depletion of epicardium. The results suggest that epicardium‐derived signals are essential for maintenance of the correct amount of myocyte proliferation in the compact myocardium, by means of levels of mitogen expression in the myocardium. However, initiation and maintenance of transmural patterning of the myocardium occurs largely independently of the epicardium. Developmental Dynamics 228:161–172, 2003.

Kidney development: two tales of tubulogenesis.

The mammalian kidney may well be one of the most complex organs of postnatal life. Each adult human kidney contains on average more than one million functional filtration units, the nephrons, residing within a specialized cellular interstitium. Each kidney also contains over 25 distinct cell types, each of which must be specifically aligned with respect to each other to ensure both normal development and ultimately, normal renal function. Despite this complexity, the development of the kidney can be simplistically described as the coordinate formation of two distinct sets of tubules. These tubules develop cooperatively with each other in time and space, yet represent two distinct but classical types of tubulogenesis. The first of these tubules, the ureteric bud, forms as an outgrowth of another epithelial tube, the nephric duct, and undergoes extensive branching morphogenesis to create the collecting system of the kidney. The second tubules are the nephrons themselves which arise via a mesenchyme-to-epithelial transition induced by the first set of tubules. These tubules never branch, but must elongate to become intricately patterned and functionally segmented tubules. The molecular drivers for these two tales of tubulogenesis include many gene families regulating tubulogenesis and branching morphogenesis in other organs; however, the individual players and codependent interrelationships between a branched and non-branched tubular network make organogenesis in the kidney unique. Here we review both what is known and remains to be understood in kidney tubulogenesis.

Crim1KST264/KST264 Mice Implicate Crim1 in the Regulation of Vascular Endothelial Growth Factor-A Activity during Glomerular Vascular Development

Crim1, a transmembrane cysteine-rich repeat-containing protein that is related to chordin, plays a role in the tethering of growth factors at the cell surface. Crim1 is expressed in the developing kidney; in parietal cells, podocytes, and mesangial cells of the glomerulus; and in pericytes that surround the arterial vasculature. A gene-trap mouse line with an insertion in the Crim1 gene (Crim1(KST264/KST264)) displayed perinatal lethality with defects in multiple organ systems. This study further analyzed the defects that are present within the kidneys of these mice. Crim1(KST264/KST264) mice displayed abnormal glomerular development, illustrated by enlarged capillary loops, podocyte effacement, and mesangiolysis. When outbred, homozygotes that reached birth displayed podocyte and glomerular endothelial cell defects and marked albuminuria. The podocytic co-expression of Crim1 with vascular endothelial growth factor-A (VEGF-A) suggested a role for Crim1 in the regulation of VEGF-A action. Crim1 and VEGF-A were shown to interact directly, providing evidence that cysteine-rich repeat-containing proteins can bind to non-TGF-beta superfamily ligands. Crim1(KST264/KST264) mice display a mislocalization of VEGF-A within the developing glomerulus, as assessed by immunogold electron microscopy and increased activation of VEGF receptor 2 (Flk1) in the glomerular endothelial cells, suggesting that Crim1 regulates the delivery of VEGF-A by the podocytes to the endothelial cells. This is the first in vivo demonstration of regulation of VEGF-A delivery and supports the hypothesis that Crim1 functions to regulate the release of growth factors from the cell of synthesis.

FGFR-1 is required by epicardium-derived cells for myocardial invasion and correct coronary vascular lineage differentiation.

Critical steps in coronary vascular formation include the epithelial-mesenchyme transition (EMT) that epicardial cells undergo to become sub-epicardial; the invasion of the myocardium; and the differentiation of coronary lineages. However, the factors controlling these processes are not completely understood. Epicardial and coronary vascular precursors migrate to the avascular heart tube during embryogenesis via the proepicardium (PE). Here, we show that in the quail embryo fibroblast growth factor receptor (FGFR)-1 is expressed in a spatially and temporally restricted manner in the PE and epicardium-derived cells, including vascular endothelial precursors, and is up-regulated in epicardial cells after EMT. We used replication-defective retroviral vectors to over-express or knock-down FGFR-1 in the PE. FGFR-1 over-expression resulted in increased epicardial EMT. Knock-down of FGFR-1, however, did not inhibit epicardial EMT but greatly compromised the ability of PE progeny to invade the myocardium. The latter could, however, contribute to endothelia and smooth muscle of sub-epicardial vessels. Correct FGFR-1 levels were also important for correct coronary lineage differentiation with, at E12, an increase in the proportion of endothelial cells amongst FGFR-1 over-expressing PE progeny and a decrease in the proportion of smooth muscle cells in antisense FGFR-1 virus-infected PE progeny. Finally, in a heart explant system, constitutive activation of FGFR-1 signaling in epicardial cells resulted in increased delamination from the epicardium, invasion of the sub-epicardium, and invasion of the myocardium. These data reveal novel roles for FGFR-1 signaling in epicardial biology and coronary vascular lineage differentiation, and point to potential new therapeutic avenues.

Crim1KST264/KST264 mice display a disruption of the Crim1 gene resulting in perinatal lethality with defects in multiple organ systems.

Crim1 is a transmembrane protein, containing six vWF‐C type cysteine‐rich repeats, that tethers growth factors to the cell surface. A mouse line, KST264, generated in a LacZ insertion mutagenesis gene‐trap screen, was examined to elucidate Crim1 function in development. We showed that Crim1KST264/KST264 mice were not null for Crim1 due to the production of a shortened protein isoform. These mice are likely to represent an effective hypomorph or a dominant‐negative for Crim1. Transgene expression recapitulated known Crim1 expression in lens, brain, and limb, but also revealed expression in the smooth muscle cells of the developing heart and renal vasculature, developing cartilage, mature ovary and detrusor of the bladder. Transgene expression was also observed in glomerular epithelial cells, podocytes, mesangial cells, and urothelium in the kidney. Crim1KST264/KST264 mice displayed perinatal lethality, syndactyly, eye, and kidney abnormalities. The severe and complex phenotype observed in Crim1KST264/KST264 mice highlights the importance of Crim1 in numerous aspects of organogenesis. Developmental Dynamics 236:502–511, 2007.

Distinct sites of renal fibrosis in Crim1 mutant mice arise from multiple cellular origins

Crim1 is a transmembrane protein that regulates the bioavailability of growth factors such as VEGFA. Crim1KST264/KST264 hypomorphic mice develop renal disease characterized by glomerular cysts and loss of endothelial integrity, progressing to peritubular and pericystic fibrosis. Peritubular capillary endothelial cells display morphological changes as well as detachment from the basement membrane. In this study, gene expression profiling of CD31+ endothelial cells isolated from Crim1KST264/KST264 kidneys showed up‐regulation of transcripts associated with fibrosis (Col3a1, Loxl1), endothelial dysfunction (Abp1, Dcn, Lcn2), biomarkers of renal damage (Lcn2, Havcr1/Kim1) as well as evidence for a TGFβ1/TNF‐associated inflammatory process. To determine whether the aberrant endothelium may in part contribute to the fibrogenic process, Tie2Cre‐DsRed lineage tracing was undertaken in Crim1KST264/KST264 mice. Approximately 31% of de novo αSMA+ myofibroblasts detected within the tubulointerstitium were Tie2+DsRed+. However, 5.3% were F4/80+DsRed+, indicating a small population of myofibroblasts of monocytic rather than endothelial origin. In contrast, only 12% of myofibroblasts located around glomerular cysts were Tie2+DsRed+, with 7.7% being monocyte‐derived (F4/80+DsRed+). Collectively, this model supports the involvement of endothelial cells/monocytes in fibrosis within the tubulointerstitium, but also the heterogeneity of the fibrotic process even within distinct regions of the same kidney. Copyright

Structure, mapping, and expression of human SOX18

SOX genes are found throughout the animal kingdom and encode a highly conserved family of transcription factors involved in a wide range of developmental processes (for review, see Wegner, 1999). SOX proteins bind DNA in a sequence-dependent manner via the HMG box domain, and many have been shown to have separable domains associated with transcriptional regulation. Several SOX genes have been implicated in inherited human disorders: SRY in male-to-female sex reversal and gonadal dysgenesis (Berta et al. 1990; Ja ger et al. 1990), SOX9 in the skeletal dys-morphogenesis syndrome campomelic dysplasia (Foster and Graves 1994; Wagner et al. 1994), and SOX10 in the neurochristopathy Waardenburg Shah syndrome-4 (Pingault et al. 1998). Furthermore, targeted disruption in mice has demonstrated vital roles for Sox4 in cardiac development (Schilham et al. 1996), Sox9 in chondrogenesis (Bi et al. 1999), and Sox1 in lens development (Nishiguchi et al. 1998).