Comparison of Iroquois gene expression in limbs/fins of vertebrate embryos

In Drosophila, Iroquois (Irx) genes have various functions including the specification of the identity of wing veins. Vertebrate Iroquois (Irx) genes have been reported to be expressed in the developing digits of mouse limbs. Here we carry out a phylogenetic analysis of vertebrate Irx genes and compare expression in developing limbs of mouse, chick and human embryos and in zebrafish pectoral fin buds. We confirm that the six Irx gene families in vertebrates are well defined and that Clusters A and B are duplicates; in contrast, Irx1 and 3, Irx2 and 5, and Irx4 and 6 are paralogs. All Irx genes in mouse and chick are expressed in developing limbs. Detailed comparison of the expression patterns in mouse and chick shows that expression patterns of genes in the same cluster are generally similar but paralogous genes have different expression patterns. Mouse and chick Irx1 are expressed in digit condensations, whereas mouse and chick Irx6 are expressed interdigitally. The timing of Irx1 expression in individual digits in mouse and chick is different. Irx1 is also expressed in digit condensations in developing human limbs, thus showing conservation of expression of this gene in higher vertebrates. In zebrafish, Irx genes of all but six of the families are expressed in early stage pectoral fin buds but not at later stages, suggesting that these genes are not involved in patterning distal structures in zebrafish fins.     

Rhombomere boundaries are Wnt signaling centers that regulate metameric patterning in the zebrafish hindbrain.

The vertebrate hindbrain develops from a series of segments (rhombomeres) distributed along the anteroposterior axis. We are studying the roles of Wnt and Delta-Notch signaling in maintaining rhombomere boundaries as organizing centers in the zebrafish hindbrain. Several wnt genes (wnt1, wnt3a, wnt8b, and wnt10b) show elevated expression at rhombomere boundaries, whereas several delta genes (dlA, dlB, and dlD) are expressed in transverse stripes flanking rhombomere boundaries. Partial disruption of Wnt signaling by knockdown of multiple wnt genes, or the Wnt mediator tcf3b, ablates boundaries and associated cell types. Expression of dlA is chaotic, and cell types associated with rhombomere centers are disorganized. Similar patterning defects are observed in segmentation mutants spiel-ohne-grenzen (spg) and valentino (val), which fail to form rhombomere boundaries due to faulty interactions between adjacent rhombomeres. Stripes of wnt expression are variably disrupted, with corresponding disturbances in metameric patterning. Mutations in dlA or mind bomb (mib) disrupt Delta-Notch signaling and cause a wide range of patterning defects in the hindbrain. Stripes of wnt1 are initially normal but subsequently dissipate, and metameric patterning becomes increasingly disorganized. Driving wnt1 expression using a heat-shock construct partially rescues metameric patterning in mib mutants. Thus, rhombomere boundaries act as Wnt signaling centers required for precise metameric patterning, and Delta signals from flanking cells provide feedback to maintain wnt expression at boundaries. Similar feedback mechanisms operate in the Drosophila wing disc and vertebrate limb bud, suggesting coaptation of a conserved signaling module that spatially organizes cells in complex organ systems.     

The Prx1 limb enhancers: Targeted gene expression in developing zebrafish pectoral fins

Limbs represent an excellent model to study the induction, growth, and patterning of several organs. A breakthrough to study gene function in various tissues has been the characterization of regulatory elements that allow tissue‐specific interference of gene function. The mouse Prx1 promoter has been used to generate limb‐specific mutants and overexpress genes in tetrapod limbs. Although zebrafish possess advantages that favor their use to study limb morphogenesis, there is no driver described suitable for specifically interfering with gene function in developing fins. We report the generation of zebrafish lines that express enhanced green fluorescent protein (EGFP) driven by the mouse Prx1 enhancer in developing pectoral fins. We also describe the expression pattern of the zebrafish prrx1 genes and identify three c onserved n on‐coding e lements (CNEs) that we use to generate fin‐specific EGFP reporter lines. Finally, we show that the mouse and zebrafish regulatory elements may be used to modify gene function in pectoral fins. Developmental Dynamics 240:1977–1988, 2011. © 2011 Wiley‐Liss, Inc.     

Expression of sox11 gene duplicates in zebrafish suggests the reciprocal loss of ancestral gene expression patterns in development.

To investigate the role of sox genes in vertebrate development, we have isolated sox11 from zebrafish (Danio rerio). Two distinct classes of sox11-related cDNAs were identified, sox11a and sox11b. The predicted protein sequences shared 75% identity. In a gene phylogeny, both sox11a and sox11b cluster with human, mouse, chick, and Xenopus Sox11, indicating that zebrafish, like Xenopus, has two orthologues of tetrapod Sox11. The work reported here investigates the evolutionary origin of these two gene duplicates and the consequences of their duplication for development. The sox11a and sox11b genes map to linkage groups 17 and 20, respectively, together with other loci whose orthologues are syntenic with human SOX11, suggesting that during the fish lineage, a large chromosome region sharing conserved syntenies with mammals has become duplicated. Studies in mouse and chick have shown that Sox11 is expressed in the central nervous system during development. Expression patterns of zebrafish sox11a and sox11b confirm that they are expressed in the developing nervous system, including the forebrain, midbrain, hindbrain, eyes, and ears from an early stage. Other sites of expression include the fin buds and somites. The two sox genes, sox11a and sox11b, are expressed in both overlapping and distinct sites. Their expression patterns suggest that sox11a and sox11b may share the developmental domains of the single Sox11 gene present in mouse and chick. For example, zebrafish sox11a is expressed in the anterior somites, and zebrafish sox11b is expressed in the posterior somites, but the single Sox11 gene of mouse is expressed in all the somites. Thus, the zebrafish duplicate genes appear to have reciprocally lost expression domains present in the sox11 gene of the last common ancestor of tetrapods and zebrafish. This splitting of the roles of Sox11 between two paralogues suggests that regulatory elements governing the expression of the sox11 gene in the common ancestor of zebrafish and tetrapods may have been reciprocally mutated in the zebrafish gene duplicates. This is consistent with duplicate gene evolution via a duplication-degeneration-complementation process.     

Cadherin-1, -2, and -11 expression and cadherin-2 function in the pectoral limb bud and fin of the developing zebrafish.

Cadherins are cell adhesion molecules that play important roles in development of a variety of organs, including the vertebrate limb. In this study, we analyze cadherin expression patterns in the embryonic zebrafish pectoral limb buds and larval pectoral fins by using both in situ hybridization and immunocytochemical methods. cadherin-1 is detected in the epidermis of the embryonic limb buds and the larval pectoral fins. Cadherin-2 is expressed in the pectoral limb bud mesenchyme and chondrogenic condensation. As development proceeds, cadherin-2 expression is detected in newly differentiated pectoral fin endoskeleton, but its expression is greatly down-regulated in the fin endoskeleton of larval zebrafish. cadherin-11 is found in the basal region of the embryonic limb buds and in the proximal endoskeleton of the larval pectoral fins. Interfering with cadherin-2 function using two specific antisense morpholino oligonucleotides disrupts formation of the chondrogenic condensation/endoskeleton, suggesting that cadherin-2 is crucial for the normal development of the zebrafish pectoral fins.     

Gene expression analysis on sections of zebrafish regenerating fins reveals limitations in the whole-mount in situ hybridization method.

The caudal fin of adult zebrafish is used to study the molecular mechanisms that govern regeneration processes. Most reports of gene expression in regenerating caudal fins rely on in situ hybridization (ISH) on whole-mount samples followed by sectioning of the samples. In such reports, expression is mostly confined to cells other than those located between the dense collagenous structures that are the actinotrichia and lepidotrichia. Here, we re-examined the expression of genes by performing ISH directly on cryo-sections of regenerates. We detected expression of some of these genes in cell types that appeared to be non-expressing when ISH was performed on whole-mount samples. These results demonstrate that ISH reagents have a limited capacity to penetrate between the regenerating skeletal matrices and suggest that ISH performed directly on fin sections is a preferable method to study gene expression in fin regenerates.     

Cloning and expression of three zebrafish roundabout homologs suggest roles in axon guidance and cell migration.

We report the cloning and expression patterns of three novel zebrafish Roundabout homologs. The Roundabout (robo) gene encodes a transmembrane receptor that is essential for axon guidance in Drosophila and Robo family members have been implicated in cell migration. Analysis of extracellular domains and conserved cytoplasmic motifs shows that zebrafish Robo1 and Robo2 are orthologs of mammalian Robo1 and Robo2, respectively, while zebrafish Robo3 is likely to be an ortholog of mouse Rig-1. The three zebrafish robos are expressed in distinct but overlapping patterns during embryogenesis. They are highly expressed in the developing nervous system, including the olfactory system, visual system, hindbrain, cranial ganglia, spinal cord, and posterior lateral line primordium. They are also expressed in several nonneuronal tissues, including somites and fin buds. The timing and patterns of expression suggest roles for zebrafish robos in axon guidance and cell migration. Wiley-Liss, Inc.     

鱼藤素可影响斑马鱼胚胎Wnt信号通路相关基因的表达

背景：前期研究发现,在斑马鱼早期发育的不同时期,经过一定浓度鱼藤素处理的胚胎表现出不同程度的发育延缓和表型异常。 目的：观察斑马鱼早期胚胎发育过程中鱼藤素对wnt信号通路相关基因表达的影响。 方法：收集孵育至shield期的斑马鱼胚胎于6孔板中,加入0.6 μmol/L浓度的鱼藤素溶液,避光处理,28 ℃培养箱中孵养。用0.1%二甲基亚砜溶液作为对照组,相同条件培养。在受精后6,8,10,12,14,24 h时用正置荧光显微镜拍照观察鱼藤素处理后斑马鱼胚胎发育表型。实时荧光定量核酸扩增检测鱼藤素作用前后目的基因表达水平的变化。 结果与结论：shield期处理的斑马鱼胚胎在bud期停止生长;wnt信号通路上的wnt9a,wnt10b和axin2以及与wnt信号具有密切联系的snail1b,Jnk2表达发生显著变化,其中wnt9a,wnt10b,axin2,snail1b表达下调,Jnk2表达上调。结果提示鱼藤素对斑马鱼体内wnt信号具有负调节作用。     

Zebrafish wnt3 is expressed in developing neural tissue

Wnt signaling regulates embryonic patterning and controls stem cell homeostasis, while aberrant Wnt activity is associated with disease. One Wnt family member, Wnt3, is required in mouse for specification of mesoderm, and later regulates neural patterning, apical ectodermal ridge formation, and hair growth. We have identified and performed preliminary characterization of the zebrafish wnt3 gene. wnt3 is expressed in the developing tailbud and neural tissue including the zona limitans intrathalamica (ZLI), optic tectum, midbrain‐hindbrain boundary, and dorsal hindbrain and spinal cord. Expression in these regions suggests that Wnt3 participates in processes such as forebrain compartmentalization and regulation of tectal wiring topography by retinal ganglia axons. Surprisingly, wnt3 expression is not detectable during mesoderm specification, making it unlikely that Wnt3 regulates this process in zebrafish. This lack of early expression should make it possible to study later Wnt3‐regulated patterning events, such as neural patterning, by knockdown studies in zebrafish. Developmental Dynamics 238:1768–1795, 2009. © 2009 Wiley‐Liss, Inc.     

Asynchronous activation of 10 muscle-specific protein (MSP) genes during zebrafish somitogenesis.

In the present study, 10 zebrafish cDNA clones coding for muscle-specific proteins (MSPs) were characterized and most of them encode fast skeletal muscle isoforms. They are skeletal muscle alpha-actin (acta1), fast skeletal muscle a-tropomyosin (tpma), fast skeletal muscle troponin C (tnnc), fast skeletal muscle troponin T (tnnt), fast skeletal muscle myosin heavy chain (myhz1), fast skeletal muscle myosin light chain 2 (mylz2), fast skeletal muscle myosin light chain 3 (mylz3), muscle creatine kinase (ckm), parvalbumin (pvalb), and desmin (desm). Using these cDNA probes, their expression patterns in developing embryos and adults were compared by Northern blot hybridization and whole-mount in situ hybridization. All of the 10 genes are expressed in both embryos and adult fish, and the expression is highly abundant in skeletal muscle. Among them, acta1, tpma, tnnc, tnnt, myhz1, mylz2, mylz3 and pvalb, are expressed specifically in fast skeletal muscle while ckm and desm are expressed in both fast and slow skeletal muscles. In addition, tpma, ckm, and desm are also expressed in the heart. Ontogenetically, the onset of expression of these MSP genes in zebrafish skeletal muscle varies and the expression occurs rostral-caudally in developing somites. Shortly after the expression of myoD, desm is the first to be activated at approximately 9 hpf, followed by tpma (approximately 10 hpf), tnnc (approximately 12 hpf), acta1 (approximately 12 hpf), ckm (approximately 14 hpf), myhz1 (approximately 14 hpf), mylz2 (approximately 16 hpf), mylz3 (approximately 16.5 hpf), tnnt (approximately 16.5 hpf), and pvalb (approximately 16.5 hpf). At later stages (after 48 hpf), these MSP genes are also expressed in fin buds and head muscles including eye, jaw, and gill muscles. Thus, our experiment demonstrated the order of expression of the 10 MSP genes, which may reflect the sequence of muscle filament assembly. In spite of the asynchrony in activation of these MSP genes, the timing of expression for each individual MSP gene appears to be synchronous to somite development as each somite has an identical timetable to express the set of MSP genes.     

Two divergent slit1 genes in zebrafish.

Members of the Slit family regulate axon guidance and cell migration. To date, three vertebrate slit1 genes have been identified in mammals and orthologs of two, slit2 and slit3, have been identified in zebrafish. Here, we describe the cloning of full-length cDNAs for two zebrafish slit orthologs, slit1a and slit1b. Both predicted proteins contain the conserved motifs that characterize other vertebrate Slits. slit1a and slit1b are both expressed in the midline, hypochord, telencephalon, and hindbrain. Apart from these shared expression domains, however, their expression patterns largely differ. Whereas slit1a is expressed broadly in the central nervous system (CNS) and in the somites, pectoral fin buds, tail bud, and caudal fin folds, slit1b is expressed in the olfactory system throughout embryonic and larval development, and in the retina during larval stages. Their expression patterns, particularly that of slit1a, suggest that Slit proteins may have roles in tissue morphogenesis in addition to their established roles in axon guidance and cell migration.     

Expression of the fras1/frem gene family during zebrafish development and fin morphogenesis

Mouse studies have highlighted the requirement of the extracellular matrix Fras and Frem proteins for embryonic epidermal adhesion. Mutations of the genes encoding some of these proteins underlie the blebs mouse mutants, whereas mutations in human FRAS1 and FREM2 cause Fraser syndrome, a congenital disorder characterized by embryonic blistering and renal defects. We have cloned the zebrafish homologues of these genes and characterized their evolutionary diversification and expression during development. The fish gene complement includes fras1, frem1a, frem1b, frem2a, frem2b, and frem3, which display complex overlapping and complementary expression patterns in developing tissues including the pharyngeal arches, hypochord, musculature, and otic vesicle. Expression during fin development delineates distinct populations of epidermal cells which have previously only been described at a morphological level. We detect relatively little gene expression in epidermis or pronephros, suggesting that the essential role of these proteins in mediating their development in humans and mice is recently evolved.