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2. Genetic Control of Convergent Extension Movements during Zebrafish Gastrulation

Author

Solnica-Krezel, L., Topczewski, J., Sepich, D., Myers, D., Marlow, F., and Jessen, J.

Subjects
Developmental genetics -- Research, Zebra fish -- Physiological aspects, Gastrulation -- Physiological aspects, Embryology -- Fishes, Biological sciences
Abstract

In the vertebrate gastrulation movements of convergent extension (CE) the entire embryo and most organ rudiments narrow along the mediolateral axis while extending their anterior-posterior dimension. Concurrently, a Bone morphogenetic proteins (Bmps) activity gradient establishes cell fates. To determine how cell fates and CE movements are coordinated we analyzed zebrafish mutants in which CE movements are defective. Mutations in Knypek (kny) gene impair CE movements early in gastrulation, without significantly influencing cell fates. CE defects are associated with abnormal cell polarity, as mutant cells fail to elongate and align mediolaterally. Positional cloning reveals that kny encodes a member of the glypican family of heparan sulfate proteoglycans. Double mutant and overexpression analyses show that Knypek potentiates Wnt11 signaling mediating CE via a noncanonical signal transduction cascade. By analyzing movements of cell populations in wild-type, ventralized chordino (chordin), and dorsalized somitabun (smad5) mutant gastrulae, we demonstrate that Bmp activity gradient specifies three morphogenic domains. High levels of Bmp inhibit convergence and extension ventrally, decreasing levels correlate with increasing convergence and extension, while dorsally, at low levels of Bmp activity, cells elongate and align mediolaterally, driving extension with little convergence. Bmp may limit CE in ventrolateral regions of the gastrula through negative regulation of genes required for this process, including wnt11.

Published
2001

3. Somites in knypek;trilobite Zebrafish Form Without Mesenchymal Internal Cells or Compaction of the Presomitic Mesoderm

Author

Henry, C.A., Hall, L.A., Solnica-Krezel, L., and Cooper, M.S.

Subjects
Developmental biology -- Research, Cell research -- Analysis, Zebra fish -- Physiological aspects, Morphogenesis -- Analysis, Epithelial cells -- Research, Biological sciences
Abstract

Vertebrate segmentation involves the partitioning of the paraxial mesoderm into numerous metameric units, known as somites. To determine how prospective somites physically segregate from each other, we have analyzed the cellular mechanics underlying early somitogenesis in wild-type zebrafish and trilobite, knypek, and knypek;trilobite mutants. We show through time lapse microscopy that the formation of segment boundaries in all of these embryos involves a local alignment of presumptive epithelial cells along nascent intersomitic borders, knypek;trilobite mutant embryos are extreme morphological variants whose somites lack internal mesenchymal cells, and form without the compaction of the paraxial mesoderm. Although knypek;trilobite somites are composed of only two epithelial cells in their anterior-posterior dimension, they still exhibit intrasegmental polarity. Furthermore, morphogenesis of segment boundaries in these embryos proceeds in a manner very similar to wild-type embryos. These results indicate that segment boundary formation in zebrafish involves short-range movements of presumptive epithelial border cells that do not require mechanical forces generated by internal mesenchymal cells.

Published
2000

5. Dispatched Homolog 2 is targeted by miR-214 through a combination of three weak microRNA recognition sites

Author

Li, N., Flynt, A.S., Kim, H.R., Solnica-Krezel, L., and Patton, J.G.

Abstract

MicroRNAs (miRNAs) regulate gene expression by inhibiting translation of target mRNAs through pairing with miRNA recognition elements (MREs), usually in 3′ UTRs. Because pairing is imperfect, identification of bona fide mRNA targets presents a challenge. Most target recognition algorithms strongly emphasize pairing between nucleotides 2–8 of the miRNA (the ‘seed’ sequence) and the mRNA but adjacent sequences and the local context of the 3′ UTR also affect targeting. Here, we show that dispatched 2 is a target of miR-214 . In zebrafish, dispatched 2 is expressed in the telencephalon and ventral hindbrain and is essential for normal zebrafish development. Regulation of dispatched 2 by miR-214 is via pairing with three, noncanonical, weak MREs. By comparing the repression capacity of GFP reporters containing different dispatched 2 sequences, we found that a combination of weak sites, which lack canonical seed pairing, can effectively target an mRNA for silencing. This finding underscores the challenge that prediction algorithms face and emphasizes the need to experimentally validate predicted MREs.

Published
2008

7. Mutations affecting craniofacial development in zebrafish

Author

Neuhauss, S. C. F., Solnica-Krezel, L., Alexander Franz Schier, Zwartkruis, F., Stemple, D. L., Malicki, J., Abdelilah, S., Stainier, D. Y. R., Driever, W., University of Zurich, and Driever, W

Subjects
Skull, Cell Differentiation, Facial Bones, 10124 Institute of Molecular Life Sciences, 1309 Developmental Biology, Branchial Region, Cartilage, Mutagenesis, Larva, 1312 Molecular Biology, Animals, 570 Life sciences, biology, Molecular Biology, Zebrafish, Developmental Biology
Abstract

In a large-scale screen for mutations affecting embryogenesis in zebrafish, we identified 48 mutations in 34 genetic loci specifically affecting craniofacial development. Mutants were analyzed for abnormalities in the cartilaginous head skeleton. Further, the expression of marker genes was studied to investigate potential abnormalities in mutant rhombencephalon, neural crest, and pharyngeal endoderm. The results suggest that the identified mutations affect three distinct aspects of craniofacial development. In one group, mutations affect the overall pattern of the craniofacial skeleton, suggesting that the genes are involved in the specification of these elements. Another large group of mutations affects differentiation and morphogenesis of cartilage, and may provide insight into the genetic control of chondrogenesis. The last group of mutations leads to the abnormal arrangement of skeletal elements and may uncover important tissue-tissue interactions underlying jaw development.

Published
1996

9. Early development of the zebrafish pronephros and analysis of mutations affecting pronephric function.

Author

Drummond, I A, Majumdar, A, Hentschel, H, Elger, M, Solnica-Krezel, L, Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Stemple, D L, Zwartkruis, F, Rangini, Z, Driever, W, Fishman, M C, Drummond, I A, Majumdar, A, Hentschel, H, Elger, M, Solnica-Krezel, L, Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Stemple, D L, Zwartkruis, F, Rangini, Z, Driever, W, and Fishman, M C

Abstract

The zebrafish pronephric kidney provides a simplified model of nephron development and epithelial cell differentiation which is amenable to genetic analysis. The pronephros consists of two nephrons with fused glomeruli and paired pronephric tubules and ducts. Nephron formation occurs after the differentiation of the pronephric duct with both the glomeruli and tubules being derived from a nephron primordium. Fluorescent dextran injection experiments demonstrate that vascularization of the zebrafish pronephros and the onset of glomerular filtration occurs between 40 and 48 hpf. We isolated fifteen recessive mutations that affect development of the pronephros. All have visible cysts in place of the pronephric tubule at 2-2.5 days of development. Mutants were grouped in three classes: (1) a group of twelve mutants with defects in body axis curvature and manifesting the most rapid and severe cyst formation involving the glomerulus, tubule and duct, (2) the fleer mutation with distended glomerular capillary loops and cystic tubules, and (3) the mutation pao pao tang with a normal glomerulus and cysts limited to the pronephric tubules. double bubble was analyzed as a representative of mutations that perturb the entire length of the pronephros and body axis curvature. Cyst formation begins in the glomerulus at 40 hpf at the time when glomerular filtration is established suggesting a defect associated with the onset of pronephric function. Basolateral membrane protein targeting in the pronephric duct epithelial cells is also severely affected, suggesting a failure in terminal epithelial cell differentiation and alterations in electrolyte transport. These studies reveal the similarity of normal pronephric development to kidney organogenesis in all vertebrates and allow for a genetic dissection of genes needed to establish the earliest renal function.

Published
1998

11. Mutations affecting craniofacial development in zebrafish.

Author

Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Solnica-Krezel, L, Schier, A F, Zwartkruis, F J T, Stemple, D L, Malicki, J, Abdelilah, S, Stainier, D Y, Driever, W, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Solnica-Krezel, L, Schier, A F, Zwartkruis, F J T, Stemple, D L, Malicki, J, Abdelilah, S, Stainier, D Y, and Driever, W

Abstract

In a large-scale screen for mutations affecting embryogenesis in zebrafish, we identified 48 mutations in 34 genetic loci specifically affecting craniofacial development. Mutants were analyzed for abnormalities in the cartilaginous head skeleton. Further, the expression of marker genes was studied to investigate potential abnormalities in mutant rhombencephalon, neural crest, and pharyngeal endoderm. The results suggest that the identified mutations affect three distinct aspects of craniofacial development. In one group, mutations affect the overall pattern of the craniofacial skeleton, suggesting that the genes are involved in the specification of these elements. Another large group of mutations affects differentiation and morphogenesis of cartilage, and may provide insight into the genetic control of chondrogenesis. The last group of mutations leads to the abnormal arrangement of skeletal elements and may uncover important tissue-tissue interactions underlying jaw development.

Published
1996

12. Mutations affecting the development of the embryonic zebrafish brain.

Author

Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Harvey, M, Malicki, J, Solnica-Krezel, L, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, Stemple, D L, Rangini, Z, Yang, H, Driever, W, Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Harvey, M, Malicki, J, Solnica-Krezel, L, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, Stemple, D L, Rangini, Z, Yang, H, and Driever, W

Abstract

In a large scale mutagenesis screen for embryonic mutants in zebrafish, we have identified 63 mutations in 24 loci affecting the morphogenesis of the zebrafish brain. The expression of marker genes and the integrity of the axonal scaffold have been studied to investigate abnormalities in regionalization, neurogenesis and axonogenesis in the brain. Mutants can be broadly classified into two groups, one affecting regionalization along the anterior-posterior or dorsal-ventral axis, and the other affecting general features of brain morphology. The first group includes one locus that is required to generate the anlage of the midbrain-hindbrain boundary region at the beginning of somitogenesis. Four loci were identified that affect dorsal-ventral patterning of the brain, including the previously described cyclops locus. Mutant embryos of this class show a reduction of ventral neuroectodermal structures and variable fusion of the eyes. The second group includes a large class of mutations affecting the formation of brain ventricles. Analysis of this class reveals the requirement of a functional cardiovascular system for ventricle enlargement during embryogenesis. Mutations in one locus lead to the formation of supernumerary primary neurons, a phenotype reminiscent of neurogenic mutants in Drosophila. Other mutant phenotypes described here range from abnormalities in the fasciculation and outgrowth of axons to defects in the diameter of the neural tube. The identified loci establish the genetic foundation for a further analysis of the development of the zebrafish embryonic brain.

Published
1996

13. Mutations affecting development of the zebrafish ear.

Author

Malicki, J, Schier, A F, Solnica-Krezel, L, Stemple, D L, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Stainier, D Y, Abdelilah, S, Rangini, Z, Zwartkruis, F, Driever, W, Malicki, J, Schier, A F, Solnica-Krezel, L, Stemple, D L, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Stainier, D Y, Abdelilah, S, Rangini, Z, Zwartkruis, F, and Driever, W

Abstract

In a large scale screen for genetic defects in zebrafish embryogenesis we identified mutations affecting several aspects of ear development, including: specification of the otic placode, growth of the otic vesicle (otocyst), otolith formation, morphogenesis of the semicircular canals and differentiation of the otic capsule. Here we report initial phenotypic and genetic characterization of 20 of these mutations defining 13 independent loci. Embryos mutant at the quadro locus display abnormal specification of the otic placode. As revealed by dlx-3 expression, the otic field in the mutant embryos is smaller or split into two fields. At later stages of development the ear of quadro mutants is frequently divided into two smaller, incomplete units. Four loci affect ear shape shortly after formation of the otic vesicle. All of them also display abnormal brain morphology. Mutations in five loci result in the absence of otolith formation; two of these also produce changes of ear morphology. Two loci, little richard and golas, affect morphology of the otic vesicle shortly before formation of the semicircular canals. In both cases the morphogenesis of the semicircular canals is disrupted. Finally, the antytalent locus is involved in late expansion of the ear structure. Analysis of mutations presented here will strengthen our understanding of vertebrate ear morphogenesis and provide novel entry points to its genetic analysis.

Published
1996

14. Mutations affecting development of the zebrafish retina.

Author

Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Solnica-Krezel, L, Stemple, D L, Stainier, D Y, Abdelilah, S, Zwartkruis, F J T, Rangini, Z, Driever, W, Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Solnica-Krezel, L, Stemple, D L, Stainier, D Y, Abdelilah, S, Zwartkruis, F J T, Rangini, Z, and Driever, W

Abstract

In a large scale screen for genetic defects in zebrafish embryogenesis we identified 49 mutations affecting development of the retina. Based on analysis of living embryos as well as histological sections, we grouped the isolated mutations into six phenotypic categories. (1) Mutations in three loci result in a loss of wild-type laminar pattern of the neural retina. (2) Defects in four loci lead to an abnormal specification of the eye anlagen. Only one eye frequently forms in this class of mutants. (3) Seven loci predominantly affect development of the outer retinal layers. Mutants in this category display cell loss mainly in the photoreceptor cell layer. (4) Nine mutations cause retardation of eye growth without any other obvious abnormalities in the retina. (5) A group of twelve mutations is characterized by nonspecific retinal degeneration. (6) Four mutations display retinal degeneration associated with a pigmentation defect. Finally, two mutations, one with absence of the ventral retina and one with an eye-specific pigmentation defect, are not classified in any of the above groups. The identified mutations affect numerous aspects of eye development, including: specification of the eye anlage, growth rate of the optic cup, establishment of retinal stratification, specification or differentiation of retinal neurons and formation of the dorsoventral axis in the developing eye.

Published
1996

15. Mutations affecting development of zebrafish digestive organs.

Author

Pack, M, Solnica-Krezel, L, Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Stemple, D L, Driever, W, Fishman, M C, Pack, M, Solnica-Krezel, L, Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Stemple, D L, Driever, W, and Fishman, M C

Abstract

The zebrafish gastrointestinal system matures in a manner akin to higher vertebrates. We describe nine mutations that perturb development of these organs. Normally, by the fourth day postfertilization the digestive organs are formed, the epithelial cells of the intestine are polarized and express digestive enzymes, the hepatocytes secrete bile, and the pancreatic islets and acini generate immunoreactive insulin and carboxypeptidase A, respectively. Seven mutations cause arrest of intestinal epithelial development after formation of the tube but before cell polarization is completed. These perturb different regions of the intestine. Six preferentially affect foregut, and one the hindgut. In one of the foregut mutations the esophagus does not form. Two mutations cause hepatic degeneration. The pancreas is affected in four mutants, all of which also perturb anterior intestine. The pancreatic exocrine cells are selectively affected in these four mutations. Exocrine precursor cells appear, as identified by GATA-5 expression, but do not differentiate and acini do not form. The pancreatic islets are spared, and endocrine cells mature and synthesize insulin. These gastrointestinal mutations may be informative with regard to patterning and crucial lineage decisions during organogenesis, and may be relevant to diabetes, congenital dysmorphogenesis and disorders of cell proliferation.

Published
1996

16. Mutations affecting development of the notochord in zebrafish.

Author

Stemple, D L, Solnica-Krezel, L, Zwartkruis, F J T, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Malicki, J, Stainier, D Y, Abdelilah, S, Rangini, Z, Mountcastle-Shah, E, Driever, W, Stemple, D L, Solnica-Krezel, L, Zwartkruis, F J T, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Schier, A F, Malicki, J, Stainier, D Y, Abdelilah, S, Rangini, Z, Mountcastle-Shah, E, and Driever, W

Abstract

The notochord is critical for the normal development of vertebrate embryos. It serves both as the major skeletal element of the embryo and as a signaling source for the establishment of pattern within the neurectoderm, the paraxial mesoderm and other tissues. In a large-scale systematic screen of mutations affecting embryogenesis in zebrafish we identified 65 mutations that fall into 29 complementation groups, each leading to a defect in the formation and/or maintenance of the notochord. These mutations produce phenotypic abnormalities at numerous stages of notochord development, thereby establishing a phenotypic pathway, which in turn suggests a genetic pathway for the development of the notochord. Perturbations within adjacent tissues in mutant embryos further indicate the importance of notochord-derived signals for patterning within the embryo and suggest that these mutations will yield additional insight into the cues that regulate these patterning processes.

Published
1996

17. Mutations affecting cell fates and cellular rearrangements during gastrulation in zebrafish.

Author

Solnica-Krezel, L, Stemple, D L, Mountcastle-Shah, E, Rangini, Z, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Malicki, J, Schier, A F, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, Driever, W, Solnica-Krezel, L, Stemple, D L, Mountcastle-Shah, E, Rangini, Z, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Malicki, J, Schier, A F, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, and Driever, W

Abstract

One of the major challenges of developmental biology is understanding the inductive and morphogenetic processes that shape the vertebrate embryo. In a large-scale genetic screen for zygotic effect, embryonic lethal mutations in zebrafish we have identified 25 mutations that affect specification of cell fates and/or cellular rearrangements during gastrulation. These mutations define at least 14 complementation groups, four of which correspond to previously identified genes. Phenotypic analysis of the ten novel loci revealed three groups of mutations causing distinct effects on cell fates in the gastrula. One group comprises mutations that lead to deficiencies in dorsal mesodermal fates and affect central nervous system patterning. Mutations from the second group affect formation of ventroposterior embryonic structures. We suggest that mutations in these two groups identify genes necessary for the formation, maintenance or function of the dorsal organizer and the ventral signaling pathway, respectively. Mutations in the third group affect primarily cellular rearrangements during gastrulation and have complex effects on cell fates in the embryo. This group, and to some extent mutations from the first two groups, affect the major morphogenetic processes, epiboly, convergence and extension, and tail morphogenesis. These mutations provide an approach to understanding the genetic control of gastrulation in vertebrates.

Published
1996

18. Mutations affecting the formation and function of the cardiovascular system in the zebrafish embryo.

Author

Stainier, D Y, Fouquet, B, Chen, J N, Warren, K S, Weinstein, B M, Meiler, S E, Mohideen, M A, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Solnica-Krezel, L, Schier, A F, Zwartkruis, F J T, Stemple, D L, Malicki, J, Driever, W, Fishman, M C, Stainier, D Y, Fouquet, B, Chen, J N, Warren, K S, Weinstein, B M, Meiler, S E, Mohideen, M A, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Solnica-Krezel, L, Schier, A F, Zwartkruis, F J T, Stemple, D L, Malicki, J, Driever, W, and Fishman, M C

Abstract

As part of a large-scale mutagenesis screen of the zebrafish genome, we have identified 58 mutations that affect the formation and function of the cardiovascular system. The cardiovascular system is particularly amenable for screening in the transparent zebrafish embryo because the heart and blood vessels are prominent and their function easily examined. We have classified the mutations affecting the heart into those that affect primarily either morphogenesis or function. Nine mutations clearly disrupt the formation of the heart. cloche deletes the endocardium. In cloche mutants, the myocardial layer forms in the absence of the endocardium but is dysmorphic and exhibits a weak contractility. Two loci, miles apart and bonnie and clyde, play a critical role in the fusion of the bilateral tubular primordia. Three mutations lead to an abnormally large heart and one to the formation of a diminutive, dysmorphic heart. We have found no mutation that deletes the myocardial cells altogether, but one, pandora, appears to eliminate the ventricle selectively. Seven mutations interfere with vascular integrity, as indicated by hemorrhage at particular sites. In terms of cardiac function, one large group exhibits a weak beat. In this group, five loci affect both chambers and seven a specific chamber (the atrium or ventricle). For example, the weak atrium mutation exhibits an atrium that becomes silent but has a normally beating ventricle. Seven mutations affect the rhythm of the heart causing, for example, a slow rate, a fibrillating pattern or an apparent block to conduction. In several other mutants, regurgitation of blood flow from ventricle to atrium is the most prominent abnormality, due either to the absence of valves or to poor coordination between the chambers with regard to the timing of contraction. The mutations identified in this screen point to discrete and critical steps in the formation and function of the heart and vasculature.

Published
1996

19. Mutations affecting neural survival in the zebrafish Danio rerio.

Author

Abdelilah, S, Mountcastle-Shah, E, Harvey, M, Solnica-Krezel, L, Schier, A F, Stemple, D L, Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Zwartkruis, F J T, Stainier, D Y, Rangini, Z, Driever, W, Abdelilah, S, Mountcastle-Shah, E, Harvey, M, Solnica-Krezel, L, Schier, A F, Stemple, D L, Malicki, J, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Zwartkruis, F J T, Stainier, D Y, Rangini, Z, and Driever, W

Abstract

Programmed cell death is a prominent feature of normal animal development. During neurogenesis, naturally occurring cell death is a mechanism to eliminate neurons that fail to make appropriate connections. To prevent accidental cell death, mechanisms that trigger programmed cell death, as well as the genetic components of the cell death program, are tightly controlled. In a large-scale mutagenesis screen for embryonic lethal mutations in zebrafish Danio rerio we have found 481 mutations with a neural degeneration phenotype. Here, we present 50 mutations that fall into two classes (termed spacehead and fala-like) that are characterized by two main features: first, they appear to affect cell survival primarily within the neuroectodermal lineages during somitogenesis, and second, they show an altered brain morphology at or before 28 hours of development. Evidence for the specificity of cell death within the central nervous system comes from visual inspection of dying cells and analysis of DNA fragmentation, a process associated with apoptotic cell death. In mutants, the level of dying cells is significantly increased in brain and spinal cord. Furthermore, at the end of somitogenesis, the cell count of radial glia and trigeminal neurons is reduced in some mutants of the spacehead class. A variety of neurodegenerative disorders in mouse and humans have been associated with abnormal levels of programmed cell death within the central nervous system. The mutations presented here might provide a genetic framework to aid in the understanding of the etiology of degenerative and physiological disorders within the CNS and the activation of inappropriate programmed cell death.

Published
1996

20. A genetic screen for mutations affecting embryogenesis in zebrafish.

Author

Driever, W, Solnica-Krezel, L, Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Malicki, J, Stemple, D L, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, Rangini, Z, Belak, J, Boggs, C, Driever, W, Solnica-Krezel, L, Schier, A F, Neuhauss, S C F; https://orcid.org/0000-0002-9615-480X, Malicki, J, Stemple, D L, Stainier, D Y, Zwartkruis, F J T, Abdelilah, S, Rangini, Z, Belak, J, and Boggs, C

Abstract

Systematic genome-wide mutagenesis screens for embryonic phenotypes have been instrumental in the understanding of invertebrate and plant development. Here, we report the results from the first application of such a large-scale genetic screening to vertebrate development. Male zebrafish were mutagenized with N-ethyl N-nitrosourea to induce mutations in spermatogonial cells at an average specific locus rate of one in 651 mutagenized genomes. Mutations were transmitted to the F1 generation, and 2205 F2 families were raised. F3 embryos from sibling crosses within the F2 families were screened for developmental abnormalities. A total of 2337 mutagenized genomes were analyzed, and 2383 mutations resulting in abnormal embryonic and early larval phenotypes were identified. The phenotypes of 695 mutants indicated involvement of the identified loci in specific aspects of embryogenesis. These mutations were maintained for further characterization and were classified into categories according to their phenotypes. The analyses and genetic complementation of mutations from several categories are reported in separate manuscripts. Mutations affecting pigmentation, motility, muscle and body shape have not been extensively analyzed and are listed here. A total of 331 mutations were tested for allelism within their respective categories. This defined 220 genetic loci with on average 1.5 alleles per locus. For about two-thirds of all loci only one allele was isolated. Therefore it is not possible to give a reliable estimate on the degree of saturation reached in our screen; however, the number of genes that can mutate to visible embryonic and early larval phenotypes in zebrafish is expected to be several-fold larger than the one for which we have observed mutant alleles during the screen. This screen demonstrates that mutations affecting a variety of developmental processes can be efficiently recovered from zebrafish.

Published
1996

22. The zebrafish bozozok locus encodes Dharma, a homeodomain protein essential for induction of gastrula organizer and dorsoanterior embryonic structures

Author

Fekany, K., primary, Yamanaka, Y., additional, Leung, T., additional, Sirotkin, H.I., additional, Topczewski, J., additional, Gates, M.A., additional, Hibi, M., additional, Renucci, A., additional, Stemple, D., additional, Radbill, A., additional, Schier, A.F., additional, Driever, W., additional, Hirano, T., additional, Talbot, W.S., additional, and Solnica-Krezel, L., additional

Published
1999
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24. Mutations affecting the formation and function of the cardiovascular system in the zebrafish embryo

Author

Stainier, D.Y., primary, Fouquet, B., additional, Chen, J.N., additional, Warren, K.S., additional, Weinstein, B.M., additional, Meiler, S.E., additional, Mohideen, M.A., additional, Neuhauss, S.C., additional, Solnica-Krezel, L., additional, Schier, A.F., additional, Zwartkruis, F., additional, Stemple, D.L., additional, Malicki, J., additional, Driever, W., additional, and Fishman, M.C., additional

Published
1996
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26. Mutations affecting neural survival in the zebrafish Danio rerio

Author

Abdelilah, S., primary, Mountcastle-Shah, E., additional, Harvey, M., additional, Solnica-Krezel, L., additional, Schier, A.F., additional, Stemple, D.L., additional, Malicki, J., additional, Neuhauss, S.C., additional, Zwartkruis, F., additional, Stainier, D.Y., additional, Rangini, Z., additional, and Driever, W., additional

Published
1996
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28. Hematopoietic mutations in the zebrafish

Author

Weinstein, B.M., primary, Schier, A.F., additional, Abdelilah, S., additional, Malicki, J., additional, Solnica-Krezel, L., additional, Stemple, D.L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Driever, W., additional, and Fishman, M.C., additional

Published
1996
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30. A genetic screen for mutations affecting embryogenesis in zebrafish

Author

Driever, W., primary, Solnica-Krezel, L., additional, Schier, A.F., additional, Neuhauss, S.C., additional, Malicki, J., additional, Stemple, D.L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Abdelilah, S., additional, Rangini, Z., additional, Belak, J., additional, and Boggs, C., additional

Published
1996
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31. Mutations affecting development of the notochord in zebrafish

Author

Stemple, D.L., primary, Solnica-Krezel, L., additional, Zwartkruis, F., additional, Neuhauss, S.C., additional, Schier, A.F., additional, Malicki, J., additional, Stainier, D.Y., additional, Abdelilah, S., additional, Rangini, Z., additional, Mountcastle-Shah, E., additional, and Driever, W., additional

Published
1996
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32. Mutations affecting the development of the embryonic zebrafish brain

Author

Schier, A.F., primary, Neuhauss, S.C., additional, Harvey, M., additional, Malicki, J., additional, Solnica-Krezel, L., additional, Stainier, D.Y., additional, Zwartkruis, F., additional, Abdelilah, S., additional, Stemple, D.L., additional, Rangini, Z., additional, Yang, H., additional, and Driever, W., additional

Published
1996
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38. The winged helix transcription factor Foxc1a is essential for somitogenesis in zebrafish.

Author

Topczewska, J M, Topczewski, J, Shostak, A, Kume, T, Solnica-Krezel, L, and Hogan, B L

Abstract

Previous studies identified zebrafish foxc1a and foxc1b as homologs of the mouse forkhead gene, Foxc1. Both genes are transcribed in the unsegmented presomitic mesoderm (PSM), newly formed somites, adaxial cells, and head mesoderm. Here, we show that inhibiting synthesis of Foxc1a (but not Foxc1b) protein with two different morpholino antisense oligonucleotides blocks formation of morphological somites, segment boundaries, and segmented expression of genes normally transcribed in anterior and posterior somites and expression of paraxis implicated in somite epithelialization. Patterning of the anterior PSM is also affected, as judged by the absence of mesp-b, ephrinB2, and ephA4 expression, and the down-regulation of notch5 and notch6. In contrast, the expression of other genes, including mesp-a and papc, in the anterior of somite primordia, and the oscillating expression of deltaC and deltaD in the PSM appear normal. Nevertheless, this expression is apparently insufficient for the maturation of the presumptive somites to proceed to the stage when boundary formation occurs or for the maintenance of anterior/posterior patterning. Mouse embryos that are compound null mutants for Foxc1 and the closely related Foxc2 have no morphological somites and show abnormal expression of Notch signaling pathway genes in the anterior PSM. Therefore, zebrafish foxc1a plays an essential and conserved role in somite formation, regulating both the expression of paraxis and the A/P patterning of somite primordia.

Published
2001
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39. Wnt8 is required in lateral mesendodermal precursors for neural posteriorization in vivo.

Author

Erter, C E, Wilm, T P, Basler, N, Wright, C V, and Solnica-Krezel, L

Abstract

The dorsal ectoderm of the vertebrate gastrula was proposed by Nieuwkoop to be specified towards an anterior neural fate by an activation signal, with its subsequent regionalization along the anteroposterior (AP) axis regulated by a graded transforming activity, leading to a properly patterned forebrain, midbrain, hindbrain and spinal cord. The activation phase involves inhibition of BMP signals by dorsal antagonists, but the later caudalization process is much more poorly characterized. Explant and overexpression studies in chick, Xenopus, mouse and zebrafish implicate lateral/paraxial mesoderm in supplying the transforming influence, which is largely speculated to be a Wnt family member. We have analyzed the requirement for the specific ventrolaterally expressed Wnt8 ligand in the posteriorization of neural tissue in zebrafish wild-type and Nodal-deficient embryos (Antivin overexpressing or cyclops;squint double mutants), which show extensive AP brain patterning in the absence of dorsal mesoderm. In different genetic situations that vary the extent of mesodermal precursor formation, the presence of lateral wnt8-expressing cells correlates with the establishment of AP brain pattern. Cell tracing experiments show that the neuroectoderm of Nodal-deficient embryos undergoes a rapid anterior-to-posterior transformation in vivo during a short period at the end of the gastrula stage. Moreover, in both wild-type and Nodal-deficient embryos, inactivation of Wnt8 function by morpholino (MO(wnt8)) translational interference dose-dependently abrogates formation of spinal cord and posterior brain fates, without blocking ventrolateral mesoderm formation. MO(wnt8) also suppresses the forebrain deficiency in bozozok mutants, in which inactivation of a homeobox gene causes ectopic wnt8 expression. In addition, the bozozok forebrain reduction is suppressed in bozozok;squint;cyclops triple mutants, and is associated with reduced wnt8 expression, as seen in cyclops;squint mutants. Hence, whereas boz and Nodal signaling largely cooperate in gastrula organizer formation, they have opposing roles in regulating wnt8 expression and forebrain specification. Our findings provide strong support for a model of neural transformation in which a planar gastrula-stage Wnt8 signal, promoted by Nodal signaling and dorsally limited by Bozozok, acts on anterior neuroectoderm from the lateral mesoderm to produce the AP regional patterning of the CNS.

Published
2001

40. Head and trunk in zebrafish arise via coinhibition of BMP signaling by bozozok and chordino.

Author

Gonzalez, E M, Fekany-Lee, K, Carmany-Rampey, A, Erter, C, Topczewski, J, Wright, C V, and Solnica-Krezel, L

Abstract

Spatial variations in the levels of bone morphogenetic protein (BMP) signaling are a critical determinant of dorsoanterior-ventroposterior pattern in vertebrate embryos. Whereas BMP overexpression abolishes both head and trunk development, known single and double loss-of-function mutations in BMP inhibitors have less dramatic effects. We report that combining mutations in the zebrafish genes bozozok and chordino causes a synergistic loss of head and trunk, whereas most cells express ventro-posterior markers and develop into a tail. Genetic inactivation of BMP signaling fully suppresses these defects. Thus, a remarkably simple genetic mechanism, involving a coinhibition of BMP function by the partially overlapping bozozok and chordino pathways is used to specify vertebrate head and trunk.

Published
2000

41. The localization of the divergent beta 2-tubulin isotype in the microtubular arrays of Physarum polycephalum

Author

Diggins-Gilicinski, M., Solnica-Krezel, L., Burland, T.G., Paul, E.C., and Dove, W.F.

Abstract

The beta 2-tubulin isotype of Physarum polycephalum is only 83% identical in amino acid sequence with the constitutively expressed beta 1B-tubulin and the myxamoeba-specific beta 1A-tubulin isotypes. A polyclonal antibody specific for beta 2-tubulin was used to monitor the subcellular distribution of the beta 2-tubulin antigen in the mitotic spindle of the mature plasmodium - the sole microtubular array in that stage of Physarum. By immunofluorescence, the beta 2-tubulin antigen was detected throughout this anastral mitotic spindle, at all stages of mitosis. Physarum myxamoebae contain astral mitotic spindles and cytoskeletal microtubules. No beta 2-tubulin antigen was detected in the myxamoebal stage. However, as cultures of myxamoebae developed into plasmodia, the beta 2-tubulin antigen was found in the astral mitotic spindles and cytoskeletons in developing cells. Thus, the presence of the plasmodial beta 2-tubulin isotype in a mitotic spindle does not determine a closed, anastral mitosis.

Published
1989
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42. A genetic screen for mutations affecting embryogenesis in zebrafish

Author

Driever W, Solnica-Krezel L, Alexander Franz Schier, Sc, Neuhauss, Malicki J, Dl, Stemple, Dy, Stainier, Zwartkruis F, Abdelilah S, Rangini Z, Belak J, Boggs C, University of Zurich, and Driever, W

Subjects
Genetic Complementation Test, fungi, Chromosome Mapping, Embryonic Development, 10124 Institute of Molecular Life Sciences, 1309 Developmental Biology, Phenotype, Mutagenesis, Organ Specificity, Mutation, 1312 Molecular Biology, Animals, 570 Life sciences, biology, Cloning, Molecular, Molecular Biology, Alleles, Zebrafish, Developmental Biology
Abstract

Systematic genome-wide mutagenesis screens for embryonic phenotypes have been instrumental in the understanding of invertebrate and plant development. Here, we report the results from the first application of such a large-scale genetic screening to vertebrate development. Male zebrafish were mutagenized with N-ethyl N-nitrosourea to induce mutations in spermatogonial cells at an average specific locus rate of one in 651 mutagenized genomes. Mutations were transmitted to the F1 generation, and 2205 F2 families were raised. F3 embryos from sibling crosses within the F2 families were screened for develop-mental abnormalities. A total of 2337 mutagenized genomes were analyzed, and 2383 mutations resulting in abnormal embryonic and early larval phenotypes were identified. The phenotypes of 695 mutants indicated involvement of the identified loci in specific aspects of embryogenesis. These mutations were maintained for further characterization and were classified into categories according to their phenotypes. The analyses and genetic complementation of mutations from several categories are reported in separate manuscripts. Mutations affecting pig-mentation, motility, muscle and body shape have not been extensively analyzed and are listed here. A total of 331 mutations were tested for allelism within their respective categories. This defined 220 genetic loci with on average 1.5 alleles per locus. For about two-thirds of all loci only one allele was isolated. Therefore it is not possible to give a reliable estimate on the degree of saturation reached in our screen; however, the number of genes that can mutate to visible embryonic and early larval phenotypes in zebrafish is expected to be several-fold larger than the one for which we have observed mutant alleles during the screen. This screen demonstrates that mutations affecting a variety of developmental processes can be efficiently recovered from zebrafish.

43. Mutations affecting development of zebrafish digestive organs

Author

Pack M, Solnica-Krezel L, Malicki J, Stephan Neuhauss, Af, Schier, Dl, Stemple, Driever W, Mc, Fishman, University of Zurich, and Fishman, M C

Subjects
Genetic Markers, Cell Differentiation, Epithelium, 10124 Institute of Molecular Life Sciences, 1309 Developmental Biology, Liver, Mutagenesis, Intestine, Small, 1312 Molecular Biology, Animals, 570 Life sciences, biology, Digestive System, Pancreas, Molecular Biology, Zebrafish, Body Patterning, Developmental Biology
Abstract

The zebrafish gastrointestinal system matures in a manner akin to higher vertebrates. We describe nine mutations that perturb development of these organs. Normally, by the fourth day postfertilization the digestive organs are formed, the epithelial cells of the intestine are polarized and express digestive enzymes, the hepatocytes secrete bile, and the pancreatic islets and acini generate immunoreactive insulin and carboxypeptidase A, respectively. Seven mutations cause arrest of intestinal epithelial development after formation of the tube but before cell polarization is completed. These perturb different regions of the intestine. Six preferentially affect foregut, and one the hindgut. In one of the foregut mutations the esophagus does not form. Two mutations cause hepatic degeneration. The pancreas is affected in four mutants, all of which also perturb anterior intestine. The pancreatic exocrine cells are selectively affected in these four mutations. Exocrine precursor cells appear, as identified by GATA-5 expression, but do not differentiate and acini do not form. The pancreatic islets are spared, and endocrine cells mature and synthesize insulin. These gastrointestinal mutations may be informative with regard to patterning and crucial lineage decisions during organogenesis, and may be relevant to diabetes, congenital dysmorphogenesis and disorders of cell proliferation.

46. CXCR3-CXCL11 Signaling Restricts Angiogenesis and Promotes Pericyte Recruitment.

Author

Lee J, Goeckel ME, Levitas A, Colijn S, Shin J, Hindes A, Mun G, Burton Z, Chintalapati B, Yin Y, Abello J, Solnica-Krezel L, and Stratman A

Abstract

Background: Endothelial cell (EC)-pericyte interactions are known to remodel in response to hemodynamic forces; yet there is a lack of mechanistic understanding of the signaling pathways that underlie these events. Here, we have identified a novel signaling network regulated by blood flow in ECs-the chemokine receptor CXCR3 (CXC motif chemokine receptor 3) and one of its ligands, CXCL11 (CXC motif chemokine ligand 11)-that delimits EC angiogenic potential and promotes pericyte recruitment to ECs during development., Methods: We investigated the role of CXCR3 on vascular development using both 2- and 3-dimensional in vitro assays, to study EC-pericyte interactions and EC behavioral responses to blood flow. Additionally, genetic mutants and pharmacological modulators were used in zebra fish in vivo to study the impacts of CXCR3 loss and gain of function on vascular development., Results: In vitro modeling of EC-pericyte interactions demonstrates that suppression of EC-specific CXCR3 signaling leads to loss of pericyte association with EC tubes. In vivo, phenotypic defects are particularly noted in the cranial vasculature, where we see a loss of pericyte association with ECs and expansion of the vasculature in zebra fish treated with the Cxcr3 inhibitor AMG487 or in homozygous cxcr3.1/3.2/3.3 triple mutants. We also demonstrate that CXCR3-deficient ECs are more elongated, move more slowly, and have impaired EC-EC junctions compared with their control counterparts., Conclusions: Our results suggest that CXCR3 signaling in ECs helps promote vascular stabilization events during development by preventing EC overgrowth and promoting pericyte recruitment.

Published
2024
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48. Loss of function of FAM177A1, a Golgi complex localized protein, causes a novel neurodevelopmental disorder.

Author

Kohler JN, Legro NR, Baldridge D, Shin J, Bowman A, Ugur B, Jackstadt MM, Shriver LP, Patti GJ, Zhang B, Feng W, McAdow AR, Goddard P, Ungar RA, Jensen T, Smith KS, Fresard L, Alvarez R, Bonner D, Reuter CM, McCormack C, Kravets E, Marwaha S, Holt JM, Worthey EA, Ashley EA, Montgomery SB, Fisher PG, Postlethwait J, De Camilli P, Solnica-Krezel L, Bernstein JA, and Wheeler MT

Subjects
Humans, Animals, Male, Female, Child, Phenotype, Child, Preschool, Intellectual Disability genetics, Intellectual Disability pathology, Intellectual Disability metabolism, Pedigree, Membrane Proteins genetics, Membrane Proteins metabolism, Zebrafish genetics, Neurodevelopmental Disorders genetics, Neurodevelopmental Disorders pathology, Neurodevelopmental Disorders metabolism, Golgi Apparatus metabolism, Golgi Apparatus genetics, Loss of Function Mutation
Abstract

Purpose: The function of FAM177A1 and its relationship to human disease is largely unknown. Recent studies have demonstrated FAM177A1 to be a critical immune-associated gene. One previous case study has linked FAM177A1 to a neurodevelopmental disorder in 4 siblings., Methods: We identified 5 individuals from 3 unrelated families with biallelic variants in FAM177A1. The physiological function of FAM177A1 was studied in a zebrafish model organism and human cell lines with loss-of-function variants similar to the affected cohort., Results: These individuals share a characteristic phenotype defined by macrocephaly, global developmental delay, intellectual disability, seizures, behavioral abnormalities, hypotonia, and gait disturbance. We show that FAM177A1 localizes to the Golgi complex in mammalian and zebrafish cells. Intersection of the RNA sequencing and metabolomic data sets from FAM177A1-deficient human fibroblasts and whole zebrafish larvae demonstrated dysregulation of pathways associated with apoptosis, inflammation, and negative regulation of cell proliferation., Conclusion: Our data shed light on the emerging function of FAM177A1 and defines FAM177A1-related neurodevelopmental disorder as a new clinical entity., Competing Interests: Conflict of Interest The authors declare no conflicts of interest., (Copyright © 2024 American College of Medical Genetics and Genomics. Published by Elsevier Inc. All rights reserved.)

Published
2024
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49. VPS13B is localized at the interface between Golgi cisternae and is a functional partner of FAM177A1.

Author

Ugur B, Schueder F, Shin J, Hanna MG, Wu Y, Leonzino M, Su M, McAdow AR, Wilson C, Postlethwait J, Solnica-Krezel L, Bewersdorf J, and De Camilli P

Subjects
Animals, Humans, HeLa Cells, Zebrafish Proteins metabolism, Zebrafish Proteins genetics, Brefeldin A pharmacology, Protein Binding, Protein Transport, Golgi Apparatus metabolism, Zebrafish genetics, Vesicular Transport Proteins metabolism, Vesicular Transport Proteins genetics
Abstract

Mutations in VPS13B, a member of a protein family implicated in bulk lipid transport between adjacent membranes, cause Cohen syndrome. VPS13B is known to be concentrated in the Golgi complex, but its precise location within this organelle and thus the site(s) where it achieves lipid transport remains unclear. Here, we show that VPS13B is localized at the interface between proximal and distal Golgi subcompartments and that Golgi complex reformation after Brefeldin A (BFA)-induced disruption is delayed in VPS13B KO cells. This delay is phenocopied by the loss of FAM177A1, a Golgi complex protein of unknown function reported to be a VPS13B interactor and whose mutations also result in a developmental disorder. In zebrafish, the vps13b ortholog, not previously annotated in this organism, genetically interacts with fam177a1. Collectively, these findings raise the possibility that bulk lipid transport by VPS13B may play a role in the dynamics of Golgi membranes and that VPS13B may be assisted in this function by FAM177A1., (© 2024 Ugur et al.)

Published
2024
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50. A conserved regulation of cell expansion underlies notochord mechanics, spine morphogenesis, and endochondral bone lengthening.

Author

Voigt B, Frazier K, Yazdi D, Gontarz P, Zhang B, Sepich DS, Solnica-Krezel L, and Gray RS

Abstract

Cell size is a key contributor to tissue morphogenesis 1 . As a notable example, growth plate hypertrophic chondrocytes use cellular biogenesis and disproportionate fluid uptake to expand 10-20 times in size to drive lengthening of endochondral bone 2,3 . Similarly, notochordal cells expand to one of the largest cell types in the developing embryo to drive axial extension 4-6 . In zebrafish, the notochord vacuolated cells undergo vacuole fusion to form a single large, fluid-filled vacuole that fills the cytoplasmic space and contributes to vacuolated cell expansion 7 . When this process goes awry, the notochord lacks sufficient hydrostatic pressure to support vertebral bone deposition resulting in adult spines with misshapen vertebral bones and scoliosis 8 . However, it remains unclear whether endochondral bone and the notochord share common genetic and cellular mechanisms for regulating cell and tissue expansion. Here, we demonstrate that the 5'-inositol phosphatase gene, inppl1a , regulates notochord expansion, spine morphogenesis, and endochondral bone lengthening in zebrafish. Furthermore, we show that inppl1a regulates notochord expansion independent of vacuole fusion, thereby genetically decoupling these processes. We demonstrate that inppl1a -dependent notochord expansion is essential to establish normal mechanical properties of the notochord to facilitate the development of a straight spine. Finally, we find that inppl1a is also important for endochondral bone lengthening in fish, as has been shown in the human INPPL1 -related endochondral bone disorder, Opsismodysplasia 9 . Overall, this work reveals a conserved mechanism of cell size regulation that influences disparate tissues critical for skeletal development and short-stature disorders.

Published
2024
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