Your search keyword '"Melissa H, Little"' showing total 10 results

1. An integrated cell, tissue and whole organ profile of kidney morphogenesis

Author

Kylie Georgas, Timothy O. Lamberton, Bree Rumballe, Andrew P. McMahon, Ian M. Smyth, Nicholas A. Hamilton, James G. Lefevre, Adler Ju, Melissa H. Little, Oliver Cairncross, Alexander N. Combes, and Kieran M. Short

Subjects

Embryology, medicine.anatomical_structure, Cell, medicine, Biology, Kidney morphogenesis, Developmental Biology, Cell biology

Published

2017

2. Involvement of Islet-2 in the Slit signaling for axonal branching and defasciculation of the sensory neurons in embryonic zebrafish

Author

Hitoshi Okamoto, Toshiya Yamada, Sang-Yeob Yeo, Cornelia Fricke, Toshio Miyashita, Melissa H. Little, Tae Lin Huh, John Y. Kuwada, and Chi Bin Chien

Subjects

Nervous system, Embryology, Recombinant Fusion Proteins, LIM-Homeodomain Proteins, Nerve Tissue Proteins, Animals, Genetically Modified, Mauthner cell, Genes, Reporter, SLIT2, medicine, Animals, Neurons, Afferent, RNA, Messenger, Receptors, Immunologic, Growth cone, Zebrafish, Glycoproteins, Homeodomain Proteins, biology, Anatomy, Zebrafish Proteins, biology.organism_classification, Slit, Axons, Cell biology, medicine.anatomical_structure, Trigeminal Ganglion, nervous system, Sensory Ganglion, Axon guidance, sense organs, Signal Transduction, Transcription Factors, Developmental Biology

Abstract

In Drosophila melanogaster, Slit acts as a repulsive cue for the growth cones of the commissural axons which express a receptor for Slit, Roundabout (Robo), thus preventing the commissural axons from crossing the midline multiple times. Experiments using explant culture have shown that vertebrate Slit homologues also act repulsively for growth cone navigation and neural migration, and promote branching and elongation of sensory axons. Here, we demonstrate that overexpression of Slit2 in vivo in transgenic zebrafish embryos severely affected the behavior of the commissural reticulospinal neurons (Mauthner neurons), promoted branching of the peripheral axons of the trigeminal sensory ganglion neurons, and induced defasciculation of the medial longitudinal fascicles. In addition, Slit2 overexpression caused defasciculation and deflection of the central axons of the trigeminal sensory ganglion neurons from the hindbrain entry point. The central projection was restored by either functional repression or mutation of Robo2, supporting its role as a receptor mediating the Slit signaling in vertebrate neurons. Furthermore, we demonstrated that Islet-2, a LIM/homeodomain-type transcription factor, is essential for Slit2 to induce axonal branching of the trigeminal sensory ganglion neurons, suggesting that factors functioning downstream of Islet-2 are essential for mediating the Slit signaling for promotion of axonal branching.

Published

2004

3. Directing stem cells to kidney: From development to regeneration

Author

Melissa H. Little

Subjects

Embryology, Kidney, medicine.anatomical_structure, Regeneration (biology), medicine, Biology, Stem cell, Developmental Biology, Cell biology

Published

2017

4. Motile nephron progenitors can exit and re-enter the niche over time

Author

Kynan T. Lawlor, Melissa H. Little, and Alexander N. Combes

Subjects

Embryology, medicine.anatomical_structure, Niche, medicine, Anatomy, Nephron, Progenitor cell, Biology, Developmental Biology, Cell biology

Published

2017

5. Distinct but overlapping expression patterns of two vertebrate slit homologs implies functional roles in CNS development and organogenesis

Author

Toshiya Yamada, Elizabeth M. Algar, Sunil Raman, Linda M. Burridge, Greg P. Holmes, Kylie Negus, and Melissa H. Little

Subjects

Central Nervous System, Male, Embryology, Embryo, Nonmammalian, Molecular Sequence Data, Urogenital System, Nerve Tissue Proteins, Biology, Cell Line, SLIT3, Mice, SLIT1, Notochord, SLIT2, medicine, Animals, Drosophila Proteins, Humans, Amino Acid Sequence, Cloning, Molecular, In Situ Hybridization, Floor plate, Regulation of gene expression, Genetics, Expressed Sequence Tags, Sequence Homology, Amino Acid, Infant, Newborn, Brain, Gene Expression Regulation, Developmental, Extremities, Embryo, Mammalian, Slit, medicine.anatomical_structure, Spinal Cord, Vertebrates, Intercellular Signaling Peptides and Proteins, Female, Neural development, Sequence Analysis, Developmental Biology

Abstract

The Drosophila slit gene (sli) encodes a secreted leucine-rich repeat-containing protein (slit) expressed by the midline glial cells and required for normal neural development. A putative human sli homolog, SLIT1, has previously been identified by EST database scanning. We have isolated a second human sli homolog, SLIT2, and its murine homolog Slit2. Both SLIT1 and SLIT2 proteins show approximately 40% amino acid identity to slit and 60% identity to each other. In mice, both genes are expressed during CNS development in the floor plate, roof plate and developing motor neurons. As floor plate represents the vertebrate equivalent to the midline glial cells, we predict a conservation of function for these vertebrate homologs. Each gene shows additional but distinct sites of expression outside the CNS suggesting a variety of functions for these proteins.

Published

1998

6. 07-P023 GUDMAP – An online genitourinary resource

Author

Xingjun Pi, Jane F. Armstrong, Derek Houghton, Simon D. Harding, Michelle Southard-Smith, Sue Lloyd-MacGlip, Cathy Mendelsohn, Jamie A. Davies, Sean M. Grimmond, Jane Brennan, Steve Potter, James L. Lessard, Peter Koopman, Melissa H. Little, Bruce J. Aronow, Ying Cheng, Andy McMahon, Mehran Sharghi, and Duncan Davidson

Subjects

Embryology, Knowledge management, Resource (biology), business.industry, Genitourinary system, Biology, business, Developmental Biology

Published

2009

7. Knockdown of zebrafish crim1 results in a bent tail phenotype with defects in somite and vascular development

Author

Andrew C. Perkins, Melissa H. Little, Brian Key, Adrian Carter, Graham J. Lieschke, Gabriel Kolle, and Genevieve Kinna

Subjects

Tail, Embryology, animal structures, Morpholino, Green Fluorescent Proteins, Molecular Sequence Data, Epiboly, Neovascularization, Physiologic, Sequence Homology, Animals, Genetically Modified, Notochord, medicine, Animals, Cloning, Molecular, Zebrafish, Body Patterning, biology, Base Sequence, fungi, Gene Expression Regulation, Developmental, Membrane Proteins, Morphant, Bone Morphogenetic Protein Receptors, Oligonucleotides, Antisense, Zebrafish Proteins, biology.organism_classification, Molecular biology, Somite, medicine.anatomical_structure, Phenotype, Somites, embryonic structures, Blood Vessels, Otic vesicle, Chordin, Developmental Biology

Abstract

The Crim1 gene encodes a transmembrane protein containing six cysteine-rich repeats similar to those found in the BMP antagonist, chordin (chd). To investigate its physiological role, zebrafish crim1 was cloned and shown to be both maternally and zygotically expressed during zebrafish development in sites including the vasculature, intermediate cell mass, notochord, and otic vesicle. Bent or hooked tails with U-shaped somites were observed in 85% of morphants from 12 hpf. This was accompanied by a loss of muscle pioneer cells. While morpholino knockdown of crim1 showed some evidence of ventralisation, including expansion of the intermediate cell mass (ICM), reduction in head size bent tails and disruption to the somites and notochord, this did not mimic the classically ventralised phenotype, as assessed by the pattern of expression of the dorsal markers chordin, otx2 and the ventral markers eve1, pax2.1, tal1 and gata1 between 75% epiboly and six-somites. From 24 hpf, morphants displayed an expansion of the ventral mesoderm-derived ICM, as evidenced by expansion of tal1, lmo2 and crim1 itself. Analysis of the crim1 morphant phenotype in Tg(fli:EGFP) fish showed a clear reduction in the endothelial cells forming the intersegmental vessels and a loss of the dorsal longitudinal anastomotic vessel (DLAV). Hence, the primary role of zebrafish crim1 is likely to be the regulation of somitic and vascular development.

Published

2005

8. Expression of Crim1 during murine ocular development

Author

Toshiya Yamada, Frank J. Lovicu, Gabriel Kolle, J.W. McAvoy, and Melissa H. Little

Subjects

Regulation of gene expression, Embryology, medicine.medical_specialty, Morphogenesis, Gene Expression Regulation, Developmental, Nuclear Proteins, Proteins, Biology, Fibroblast growth factor, Bone morphogenetic protein, Eye, Cell biology, Proto-Oncogene Proteins c-myc, Mice, medicine.anatomical_structure, Endocrinology, Lens (anatomy), Internal medicine, medicine, Animals, Lens placode, Chordin, Developmental Biology, Corneal epithelium

Abstract

Crim1 (cysteine-rich motor neuron 1), a novel gene encoding a putative transmembrane protein, has recently been isolated and characterized (Kolle, G., Georgas, K., Holmes, G.P., Little, M.H., Yamada, T., 2000. CRIM1, a novel gene encoding a cysteine-rich repeat protein, is developmentally regulated and implicated in vertebrate CNS development and organogenesis. Mech. Dev. 90, 181-193). Crim1 contains an IGF-binding protein motif and multiple cysteine-rich repeats, analogous to those of chordin and short gastrulation (sog) proteins that associate with TGFbeta superfamily members, namely Bone Morphogenic Protein (BMP). High levels of Crim1 have been detected in the brain, spinal chord and lens. As members of the IGF and TGFbeta growth factor families have been shown to influence the behaviour of lens cells (Chamberlain, C.G., McAvoy, J. W., 1997. Fibre differentiation and polarity in the mammalian lens: a key role for FGF. Prog. Ret. Eye Res. 16, 443-478; de Iongh R.U., Lovicu, F.J., Overbeek, P.A., Schneider, M.D., McAvoy J.W., 1999. TGF-beta signalling is essential for terminal differentiation of lens fibre cells. Invest. Ophthalmol. Vis. Sci. 40, S561), to further understand the role of Crim1 in the lens, its expression during ocular morphogenesis and growth is investigated. Using in situ hybridisation, the expression patterns of Crim1 are determined in murine eyes from embryonic day 9.5 through to postnatal day 21. Low levels of transcripts for Crim1 are first detected in the lens placode. By the lens pit stage, Crim1 is markedly upregulated with high levels persisting throughout embryonic and foetal development. Crim1 is expressed in both lens epithelial and fibre cells. As lens fibres mature in the nucleus, Crim1 is downregulated but strong expression is maintained in the lens epithelium and in the young fibre cells of the lens cortex. Crim1 is also detected in other developing ocular tissues including corneal and conjunctival epithelia, corneal endothelium, retinal pigmented epithelium, ciliary and iridial retinae and ganglion cells. During postnatal development Crim1 expression is restricted to the lens, with strongest expression in the epithelium and in the early differentiating secondary fibres. Thus, strong expression of Crim1 is a distinctive feature of the lens during morphogenesis and postnatal growth.

Published

2000

9. Expression of the vertebrate Slit gene family and their putative receptors, the Robo genes, in the developing murine kidney

Author

Toshiya Yamada, Kylie Georgas, Melissa H. Little, and Michael Piper

Subjects

Genetics, Embryology, Gene Expression Regulation, Developmental, Nerve Tissue Proteins, Biology, Kidney, Slit, Cell biology, SLIT3, Mesoderm, Mice, Chemorepulsion, ROBO1, SLIT1, SLIT2, Animals, Drosophila Proteins, Intercellular Signaling Peptides and Proteins, Axon guidance, Receptors, Immunologic, Neural development, Developmental Biology

Abstract

The slit (sli) gene, encoding a secreted glycoprotein, has been demonstrated to play a vital role in axonal guidance in Drosophila melanogaster by acting as a signalling ligand for the robe receptor (Rothberg, J.M., Jacobs, J.R., Goodman, C.S., Artavanis-Tsakonas, S., 1990. slit: an extracellular protein necessary for development of midline glia and commissural axon pathways contains both EGF and LRR domains. Genes Dev. 4, 2169-2187; Kidd, T., Bland, K.S., Goodman, C.S., 1999. Slit is the midline repellent for the robo receptor in Drosophila. Cell 96, 785-794). Multiple homologs of both sli and robe have been identified in vertebrates and are thought to play similar roles to their fly counterparts in neural development (Brose, K., Bland, K.S., Wang, K.H., Arnott, D., Henzel, W., Goodman, C.S., Tessier-Lavigne, M., Kidd, T., 1999. Slit proteins bind Robe receptors and have an evolutionarily conserved role in repulsive axon guidance. Cell 96, 795-806). Slit2 has been shown to bind Robo1, mediating both neuronal and axonal guidance in the developing central nervous system (CNS), (Brose et al., 1999; Hu, H., 1999. Chemorepulsion of neuronal migration by Slit2 in the developing mammalian forebrain. Neuron 23, 703-711). Importantly, both gene families display distinct expression patterns outside the CNS (Holmes, G.P., Negus, K., Burridge, L., Raman, S., Algar, E., Yamada, T., Little, M.H., 1998. Distinct but overlapping expression patterns of two vertebrate slit homologs implies functional roles in CNS development and organogenesis. Mech. Dev. 79, 57-72; Yuan, W., Zhou, L., Chen, J.H., Wu, J.Y., Rao, Y., Ornitz, D.M., 1999. The mouse SLIT family: secreted ligands for ROBO expressed in patterns that suggest a role in morphogenesis and axon guidance. Dev. Biol. 212, 290-306). Using in situ hybridization on metanephric explant cultures and urogenital tract sections, the expression patterns of Slit1, 2, 3 and Robo1 and 2 were investigated during murine metanephric development. Slit1 was expressed in the metanephric mesenchyme (MM) surrounding the invading ureteric tree (UT). Slit2 was expressed at the tips of the UT and both Slit2 and Slid were expressed at the far proximal end of the comma shaped and S-shaped bodies. Expression of Robo1 was initially diffuse throughout the MM, then upregulated in the pretubular aggregates, and maintained at the distal end of the comma and S-shaped bodies. Robo2 was detected in the induced MM surrounding the arborizing UT tips and later in the proximal end of the S-shaped bodies. Coincident expression of Robo1 with Slit1 in the metanephric mesenchyme and Robo2, Slit2 and Slid in the far proximal end of the S-shaped bodies was observed during metanephric development. (C) 2000 Elsevier Science Ireland Ltd. All rights reserved.

Published

2000

10. CRIM1, a novel gene encoding a cysteine-rich repeat protein, is developmentally regulated and implicated in vertebrate CNS development and organogenesis

Author

Toshiya Yamada, G. P. Holmes, Kylie Georgas, Gabriel Kolle, and Melissa H. Little

Subjects

Adult, Embryology, Molecular Sequence Data, Restriction Mapping, Organogenesis, Conserved sequence, Evolution, Molecular, Proto-Oncogene Proteins c-myc, Mice, Notochord, medicine, Animals, Humans, Tissue Distribution, Amino Acid Sequence, RNA, Messenger, Sonic hedgehog, Conserved Sequence, In Situ Hybridization, Floor plate, Genetics, Regulation of gene expression, biology, Sequence Homology, Amino Acid, Brain, Gene Expression Regulation, Developmental, Membrane Proteins, Nuclear Proteins, Proteins, Bone Morphogenetic Protein Receptors, Blotting, Northern, Invertebrates, Transmembrane protein, medicine.anatomical_structure, Spinal Cord, Chromosomes, Human, Pair 2, Vertebrates, biology.protein, Female, Chordin, Developmental Biology

Abstract

Development of the vertebrate central nervous system is thought to be controlled by intricate cell-cell interactions and spatio-temporally regulated gene expressions. The details of these processes are still not fully understood. We have isolated a novel vertebrate gene, CRIM1/Crim1, in human and mouse. Human CRIM1 maps to chromosome 2p21 close to the Spastic Paraplegia 4 locus. Crim1 is expressed in the notochord, somites, floor plate, early motor neurons and interneuron subpopulations within the developing spinal cord. CRIM1 appears to be evolutionarily conserved and encodes a putative transmembrane protein containing an IGF-binding protein motif and multiple cysteine-rich repeats similar to those in the BMP-associating chordin and sog proteins. Our results suggest a role for CRIM1/Crim1 in CNS development possibly via growth factor binding.

Published

2000