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1.
Am J Physiol Cell Physiol ; 325(2): C519-C537, 2023 08 01.
Article in English | MEDLINE | ID: mdl-37399500

ABSTRACT

V3 is an isoform of the extracellular matrix (ECM) proteoglycan (PG) versican generated through alternative splicing of the versican gene such that the two major exons coding for sequences in the protein core that support chondroitin sulfate (CS) glycosaminoglycan (GAG) chain attachment are excluded. Thus, versican V3 isoform carries no GAGs. A survey of PubMed reveals only 50 publications specifically on V3 versican, so it is a very understudied member of the versican family, partly because to date there are no antibodies that can distinguish V3 from the CS-carrying isoforms of versican, that is, to facilitate functional and mechanistic studies. However, a number of in vitro and in vivo studies have identified the expression of the V3 transcript during different phases of development and in disease, and selective overexpression of V3 has shown dramatic phenotypic effects in "gain and loss of function" studies in experimental models. Thus, we thought it would be useful and instructive to discuss the discovery, characterization, and the putative biological importance of the enigmatic V3 isoform of versican.


Subject(s)
Alternative Splicing , Versicans , Extracellular Matrix , Protein Isoforms/genetics , Versicans/genetics , Humans
2.
J Neurosci ; 35(10): 4366-85, 2015 Mar 11.
Article in English | MEDLINE | ID: mdl-25762681

ABSTRACT

Biophysical forces play important roles throughout embryogenesis, but the roles of spatial differences in cellular resting potentials during large-scale brain morphogenesis remain unknown. Here, we implicate endogenous bioelectricity as an instructive factor during brain patterning in Xenopus laevis. Early frog embryos exhibit a characteristic hyperpolarization of cells lining the neural tube; disruption of this spatial gradient of the transmembrane potential (Vmem) diminishes or eliminates the expression of early brain markers, and causes anatomical mispatterning of the brain, including absent or malformed regions. This effect is mediated by voltage-gated calcium signaling and gap-junctional communication. In addition to cell-autonomous effects, we show that hyperpolarization of transmembrane potential (Vmem) in ventral cells outside the brain induces upregulation of neural cell proliferation at long range. Misexpression of the constitutively active form of Notch, a suppressor of neural induction, impairs the normal hyperpolarization pattern and neural patterning; forced hyperpolarization by misexpression of specific ion channels rescues brain defects induced by activated Notch signaling. Strikingly, hyperpolarizing posterior or ventral cells induces the production of ectopic neural tissue considerably outside the neural field. The hyperpolarization signal also synergizes with canonical reprogramming factors (POU and HB4), directing undifferentiated cells toward neural fate in vivo. These data identify a new functional role for bioelectric signaling in brain patterning, reveal interactions between Vmem and key biochemical pathways (Notch and Ca(2+) signaling) as the molecular mechanism by which spatial differences of Vmem regulate organogenesis of the vertebrate brain, and suggest voltage modulation as a tractable strategy for intervention in certain classes of birth defects.


Subject(s)
Body Patterning/physiology , Cell Proliferation/physiology , Membrane Potentials/physiology , Neurons/physiology , Receptors, Notch/metabolism , Signal Transduction/physiology , Age Factors , Animals , Body Patterning/genetics , Calcium/metabolism , Embryo, Nonmammalian , Fluorescent Dyes/metabolism , Gap Junctions/drug effects , Gap Junctions/physiology , Gene Expression Regulation, Developmental/drug effects , Gene Expression Regulation, Developmental/physiology , Ion Channels/drug effects , Ion Channels/genetics , Ion Channels/metabolism , Membrane Potentials/genetics , Microinjections , Nerve Tissue Proteins/genetics , Nerve Tissue Proteins/metabolism , Neural Tube/cytology , Neural Tube/embryology , Receptors, Notch/genetics , Signal Transduction/genetics , Transcription Factors/genetics , Transcription Factors/metabolism , Transduction, Genetic , Xenopus laevis
3.
Development ; 140(2): 313-22, 2013 Jan 15.
Article in English | MEDLINE | ID: mdl-23250205

ABSTRACT

A main goal of regenerative medicine is to replace lost or damaged tissues and organs with functional parts of the correct size and shape. But the proliferation of new cells is not sufficient; we will also need to understand how the scale and ultimate form of newly produced tissues are determined. Using the planarian model system, we report that membrane voltage-dependent bioelectric signaling determines both head size and organ scaling during regeneration. RNA interference of the H(+),K(+)-ATPase ion pump results in membrane hyperpolarization, which has no effect on the amount of new tissue (blastema) that is regenerated yet produces regenerates with tiny 'shrunken' heads and proportionally oversized pharynges. Our data show that this disproportionality results from a lack of the apoptosis required to adjust head and organ size and placement, highlighting apoptotic remodeling as the link between bioelectric signaling and the establishment of organ size during regeneration.


Subject(s)
Planarians/physiology , Regeneration/physiology , Animals , Apoptosis , Cell Differentiation , Cell Proliferation , Cloning, Molecular , Electrophysiology/methods , H(+)-K(+)-Exchanging ATPase/metabolism , Head/physiology , Microscopy, Fluorescence/methods , Models, Biological , Morphogenesis , Organ Size/genetics , Planarians/metabolism , RNA Interference , Signal Transduction
4.
J Biol Chem ; 289(49): 34089-103, 2014 Dec 05.
Article in English | MEDLINE | ID: mdl-25320080

ABSTRACT

Leiomyosarcoma (LMS) is a mesenchymal cancer that occurs throughout the body. Although LMS is easily recognized histopathologically, the cause of the disease remains unknown. Versican, an extracellular matrix proteoglycan, increases in LMS. Microarray analyses of 80 LMSs and 24 leiomyomas showed a significant elevated expression of versican in human LMS versus benign leiomyomas. To explore the importance of versican in this smooth muscle cell tumor, we used versican-directed siRNA to knock down versican expression in a LMS human cell line, SK-LMS-1. Decreased versican expression was accompanied by slower rates of LMS cell proliferation and migration, increased adhesion, and decreased accumulation of the extracellular matrix macromolecule hyaluronan. Addition of purified versican to cells expressing versican siRNA restored cell proliferation to the level of LMS controls, increased the pericellular coat and the retention of hyaluronan, and decreased cell adhesion in a dose-dependent manner. The presence of versican was not only synergistic with hyaluronan in increasing cell proliferation, but the depletion of versican decreased hyaluronan synthase expression and decreased the retention of hyaluronan. When LMS cells stably expressing versican siRNA were injected into nude mice, the resulting tumors displayed significantly less versican and hyaluronan staining, had lower volumes, and had reduced levels of mitosis as compared with controls. Collectively, these results suggest a role for using versican as a point of control in the management and treatment of LMS.


Subject(s)
Gene Expression Regulation, Neoplastic , Hyaluronic Acid/metabolism , Leiomyosarcoma/genetics , Muscle Neoplasms/genetics , Versicans/genetics , Animals , Cell Adhesion/drug effects , Cell Line, Tumor , Cell Movement/drug effects , Cell Proliferation/drug effects , Gene Expression Profiling , Glucuronosyltransferase/genetics , Glucuronosyltransferase/metabolism , Humans , Hyaluronan Synthases , Leiomyosarcoma/metabolism , Leiomyosarcoma/pathology , Mice , Mice, Nude , Muscle Neoplasms/metabolism , Muscle Neoplasms/pathology , Muscle, Smooth/metabolism , Muscle, Smooth/pathology , RNA, Small Interfering/genetics , RNA, Small Interfering/metabolism , Signal Transduction , Tissue Array Analysis , Versicans/antagonists & inhibitors , Versicans/metabolism , Versicans/pharmacology
5.
Development ; 139(2): 313-23, 2012 Jan.
Article in English | MEDLINE | ID: mdl-22159581

ABSTRACT

Uncovering the molecular mechanisms of eye development is crucial for understanding the embryonic morphogenesis of complex structures, as well as for the establishment of novel biomedical approaches to address birth defects and injuries of the visual system. Here, we characterize change in transmembrane voltage potential (V(mem)) as a novel biophysical signal for eye induction in Xenopus laevis. During normal embryogenesis, a striking hyperpolarization demarcates a specific cluster of cells in the anterior neural field. Depolarizing the dorsal lineages in which these cells reside results in malformed eyes. Manipulating V(mem) of non-eye cells induces well-formed ectopic eyes that are morphologically and histologically similar to endogenous eyes. Remarkably, such ectopic eyes can be induced far outside the anterior neural field. A Ca(2+) channel-dependent pathway transduces the V(mem) signal and regulates patterning of eye field transcription factors. These data reveal a new, instructive role for membrane voltage during embryogenesis and demonstrate that V(mem) is a crucial upstream signal in eye development. Learning to control bioelectric initiators of organogenesis offers significant insight into birth defects that affect the eye and might have significant implications for regenerative approaches to ocular diseases.


Subject(s)
Embryonic Induction/physiology , Eye/embryology , Membrane Potentials/physiology , Xenopus laevis/embryology , Animals , Calcium Channels/metabolism , Coumarins , Ethanolamines , In Situ Hybridization , Microscopy, Fluorescence , Transcription Factors/metabolism
6.
Proc Natl Acad Sci U S A ; 109(31): 12586-91, 2012 Jul 31.
Article in English | MEDLINE | ID: mdl-22802643

ABSTRACT

Many types of embryos' bodyplans exhibit consistently oriented laterality of the heart, viscera, and brain. Errors of left-right patterning present an important class of human birth defects, and considerable controversy exists about the nature and evolutionary conservation of the molecular mechanisms that allow embryos to reliably orient the left-right axis. Here we show that the same mutations in the cytoskeletal protein tubulin that alter asymmetry in plants also affect very early steps of left-right patterning in nematode and frog embryos, as well as chirality of human cells in culture. In the frog embryo, tubulin α and tubulin ƎĀ³-associated proteins are required for the differential distribution of maternal proteins to the left or right blastomere at the first cell division. Our data reveal a remarkable molecular conservation of mechanisms initiating left-right asymmetry. The origin of laterality is cytoplasmic, ancient, and highly conserved across kingdoms, a fundamental feature of the cytoskeleton that underlies chirality in cells and multicellular organisms.


Subject(s)
Blastomeres/metabolism , Body Patterning/physiology , Cell Division/physiology , Microtubules/metabolism , Tubulin/metabolism , Xenopus Proteins/metabolism , Animals , Blastomeres/cytology , HL-60 Cells , Humans , Xenopus laevis
7.
J Neurosci ; 30(39): 13192-200, 2010 Sep 29.
Article in English | MEDLINE | ID: mdl-20881138

ABSTRACT

Amphibians such as frogs can restore lost organs during development, including the lens and tail. To design biomedical therapies for organ repair, it is necessary to develop a detailed understanding of natural regeneration. Recently, ion transport has been implicated as a functional regulator of regeneration. Whereas voltage-gated sodium channels play a well known and important role in propagating action potentials in excitable cells, we have identified a novel role in regeneration for the ion transport function mediated by the voltage-gated sodium channel, Na(V)1.2. A local, early increase in intracellular sodium is required for initiating regeneration following Xenopus laevis tail amputation, and molecular and pharmacological inhibition of sodium transport causes regenerative failure. Na(V)1.2 is absent under nonregenerative conditions, but misexpression of human Na(V)1.5 can rescue regeneration during these states. Remarkably, pharmacological induction of a transient sodium current is capable of restoring regeneration even after the formation of a nonregenerative wound epithelium, confirming that it is the regulation of sodium transport that is critical for regeneration. Our studies reveal a previously undetected competency window in which cells retain their intrinsic regenerative program, identify a novel endogenous role for Na(V) in regeneration, and show that modulation of sodium transport represents an exciting new approach to organ repair.


Subject(s)
Regeneration/physiology , Sodium Channels/physiology , Tail/physiology , Xenopus Proteins/physiology , Xenopus laevis/growth & development , Animals , Epithelium/growth & development , Epithelium/metabolism , Humans , Larva , Organ Culture Techniques , Sodium Channels/genetics , Tail/cytology , Xenopus Proteins/genetics , Xenopus Proteins/metabolism
8.
BMC Dev Biol ; 11: 29, 2011 May 20.
Article in English | MEDLINE | ID: mdl-21599922

ABSTRACT

BACKGROUND: Consistent asymmetry of the left-right (LR) axis is a crucial aspect of vertebrate embryogenesis. Asymmetric gene expression of the TGFƟ superfamily member Nodal related 1 (Nr1) in the left lateral mesoderm plate is a highly conserved step regulating the situs of the heart and viscera. In Xenopus, movement of maternal serotonin (5HT) through gap-junctional paths at cleavage stages dictates asymmetry upstream of Nr1. However, the mechanisms linking earlier biophysical asymmetries with this transcriptional control point are not known. RESULTS: To understand how an early physiological gradient is transduced into a late, stable pattern of Nr1 expression we investigated epigenetic regulation during LR patterning. Embryos injected with mRNA encoding a dominant-negative of Histone Deacetylase (HDAC) lacked Nr1 expression and exhibited randomized sidedness of the heart and viscera (heterotaxia) at stage 45. Timing analysis using pharmacological blockade of HDACs implicated cleavage stages as the active period. Inhibition during these early stages was correlated with an absence of Nr1 expression at stage 21, high levels of heterotaxia at stage 45, and the deposition of the epigenetic marker H3K4me2 on the Nr1 gene. To link the epigenetic machinery to the 5HT signaling pathway, we performed a high-throughput proteomic screen for novel cytoplasmic 5HT partners associated with the epigenetic machinery. The data identified the known HDAC partner protein Mad3 as a 5HT-binding regulator. While Mad3 overexpression led to an absence of Nr1 transcription and randomized the LR axis, a mutant form of Mad3 lacking 5HT binding sites was not able to induce heterotaxia, showing that Mad3's biological activity is dependent on 5HT binding. CONCLUSION: HDAC activity is a new LR determinant controlling the epigenetic state of Nr1 from early developmental stages. The HDAC binding partner Mad3 may be a new serotonin-dependent regulator of asymmetry linking early physiological asymmetries to stable changes in gene expression during organogenesis.


Subject(s)
Body Patterning/physiology , Embryonic Development/physiology , Gene Expression Regulation, Developmental , Histone Deacetylases/metabolism , Organogenesis/physiology , Xenopus Proteins/metabolism , Xenopus laevis/anatomy & histology , Xenopus laevis/embryology , Animals , Epigenesis, Genetic , Histone Deacetylase Inhibitors/metabolism , Histone Deacetylases/genetics , In Situ Hybridization , Proteome/analysis , Repressor Proteins/metabolism , Serotonin/metabolism , Signal Transduction/physiology , Xenopus Proteins/genetics , Xenopus laevis/physiology
9.
Nat Commun ; 8(1): 587, 2017 09 25.
Article in English | MEDLINE | ID: mdl-28943634

ABSTRACT

Possible roles of brain-derived signals in the regulation of embryogenesis are unknown. Here we use an amputation assay in Xenopus laevis to show that absence of brain alters subsequent muscle and peripheral nerve patterning during early development. The muscle phenotype can be rescued by an antagonist of muscarinic acetylcholine receptors. The observed defects occur at considerable distances from the head, suggesting that the brain provides long-range cues for other tissue systems during development. The presence of brain also protects embryos from otherwise-teratogenic agents. Overexpression of a hyperpolarization-activated cyclic nucleotide-gated ion channel rescues the muscle phenotype and the neural mispatterning that occur in brainless embryos, even when expressed far from the muscle or neural cells that mispattern. We identify a previously undescribed developmental role for the brain and reveal a non-local input into the control of early morphogenesis that is mediated by neurotransmitters and ion channel activity.Functions of the embryonic brain prior to regulating behavior are unclear. Here, the authors use an amputation assay in Xenopus laevis to demonstrate that removal of the brain early in development alters muscle and peripheral nerve patterning, which can be rescued by modulating bioelectric signals.


Subject(s)
Brain/metabolism , Gene Expression Regulation, Developmental , Muscles/metabolism , Nervous System/metabolism , Animals , Body Patterning/genetics , Brain/embryology , Embryo, Nonmammalian/embryology , Embryo, Nonmammalian/metabolism , Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels/genetics , In Situ Hybridization , Muscles/embryology , Nervous System/embryology , Signal Transduction/genetics , Xenopus Proteins/genetics , Xenopus laevis
10.
Biol Open ; 6(10): 1445-1457, 2017 Oct 15.
Article in English | MEDLINE | ID: mdl-28818840

ABSTRACT

Laterality is a basic characteristic of all life forms, from single cell organisms to complex plants and animals. For many metazoans, consistent left-right asymmetric patterning is essential for the correct anatomy of internal organs, such as the heart, gut, and brain; disruption of left-right asymmetry patterning leads to an important class of birth defects in human patients. Laterality functions across multiple scales, where early embryonic, subcellular and chiral cytoskeletal events are coupled with asymmetric amplification mechanisms and gene regulatory networks leading to asymmetric physical forces that ultimately result in distinct left and right anatomical organ patterning. Recent studies have suggested the existence of multiple parallel pathways regulating organ asymmetry. Here, we show that an isoform of the hyperpolarization-activated cyclic nucleotide-gated (HCN) family of ion channels (hyperpolarization-activated cyclic nucleotide-gated channel 4, HCN4) is important for correct left-right patterning. HCN4 channels are present very early in Xenopus embryos. Blocking HCN channels (Ih currents) with pharmacological inhibitors leads to errors in organ situs. This effect is only seen when HCN4 channels are blocked early (pre-stage 10) and not by a later block (post-stage 10). Injections of HCN4-DN (dominant-negative) mRNA induce left-right defects only when injected in both blastomeres no later than the 2-cell stage. Analysis of key asymmetric genes' expression showed that the sidedness of Nodal, Lefty, and Pitx2 expression is largely unchanged by HCN4 blockade, despite the randomization of subsequent organ situs, although the area of Pitx2 expression was significantly reduced. Together these data identify a novel, developmental role for HCN4 channels and reveal a new Nodal-Lefty-Pitx2 asymmetric gene expression-independent mechanism upstream of organ positioning during embryonic left-right patterning.

11.
Commun Integr Biol ; 10(3): e1309488, 2017.
Article in English | MEDLINE | ID: mdl-28702127

ABSTRACT

Hyperpolarization-activated cyclic-nucleotide gated channel (HCN) proteins are important regulators of both neuronal and cardiac excitability. Among the 4 HCN isoforms, HCN4 is known as a pacemaker channel, because it helps control the periodicity of contractions in vertebrate hearts. Although the physiological role of HCN4 channel has been studied in adult mammalian hearts, an earlier role during embryogenesis has not been clearly established. Here, we probe the embryonic roles of HCN4 channels, providing the first characterization of the expression profile of any of the HCN isoforms during Xenopus laevis development and investigate the consequences of altering HCN4 function on embryonic pattern formation. We demonstrate that both overexpression of HCN4 and injection of dominant-negative HCN4 mRNA during early embryogenesis results in improper expression of key patterning genes and severely malformed hearts. Our results suggest that HCN4 serves to coordinate morphogenetic control factors that provide positional information during heart morphogenesis in Xenopus.

12.
Mech Ageing Dev ; 127(8): 660-9, 2006 Aug.
Article in English | MEDLINE | ID: mdl-16650460

ABSTRACT

Hutchinson-Gilford Progeria syndrome (HGPS) is a rare genetic disorder that displays features of segmental aging. It is manifested predominantly in connective tissue, with most prominent histological changes occurring in the skin, cartilage, bone and cardiovascular tissues. Detailed quantitative real time reverse-transcription polymerase chain reaction studies confirmed the previous observation that platelet-derived growth factor A-chain transcripts are consistently elevated 11+/-2- to 13+/-2-fold in two HGPS dermal fibroblast lines compared with age-matched controls. Furthermore, we identified two additional genes with substantially altered transcript levels. Nucleotide pyrophosphatase transcription was virtually shut down with decreased expression of 13+/-3- to 59+/-3-fold in HGPS, whereas aggrecan mRNA was elevated to 24+/-5 times to 41+/-4 times that of chronologically age-matched controls. Aggrecan, normally a component of cartilage and not always detectable in normal fibroblasts cultures, was secreted by HGPS fibroblast lines and was produced as a proteoglycan. This demonstrates that elevated aggrecan expression and its secretion are aberrant features of HGPS. We conclude that HGPS cells can display massively altered transcript levels leading to the secretion of inappropriate protein species.


Subject(s)
Chondroitin Sulfate Proteoglycans/genetics , Extracellular Matrix Proteins/genetics , Fibroblasts/physiology , Lectins, C-Type/genetics , Progeria/physiopathology , Skin/cytology , Actins/genetics , Aggrecans , Cell Line , Child , Child, Preschool , Chondroitin Sulfate Proteoglycans/metabolism , Extracellular Matrix Proteins/metabolism , Humans , Matched-Pair Analysis , Platelet-Derived Growth Factor/genetics , Progeria/genetics , Pyrophosphatases/genetics , RNA, Messenger/chemistry , Reverse Transcriptase Polymerase Chain Reaction , Up-Regulation
13.
Circ Res ; 90(4): 481-7, 2002 Mar 08.
Article in English | MEDLINE | ID: mdl-11884379

ABSTRACT

Versican is an extracellular matrix (ECM) proteoglycan that is synthesized as multiple splice variants. In a recent study, we demonstrated that retroviral-mediated overexpression of the variant V3, which lacks chondroitin sulfate (CS) chains, altered arterial smooth muscle cell (ASMC) phenotype in short-term cell culture. We now report that V3-overexpressing ASMCs exhibit significantly increased expression of tropoelastin and increased formation of elastic fibers in long-term cell cultures. In addition, V3-overexpressing ASMCs seeded into ballooned rat carotid arteries continued to overexpress V3 and, at 4 weeks after seeding, produced a highly structured neointima significantly enriched in elastic fiber lamellae. In contrast to the hydrated, myxoid neointima produced by rounded or stellate vector-alone--transduced cells, V3-expressing cells produced a compact and highly ordered neointima, which contained elongated ASMCs that were arranged in parallel arrays and separated by densely packed collagen bundles and elastic fibers. These results indicate that a variant of versican is involved in elastic fiber assembly and may represent a novel therapeutic approach to facilitate the formation of elastic fibers.


Subject(s)
Chondroitin Sulfate Proteoglycans/biosynthesis , Elastic Tissue/metabolism , Muscle, Smooth, Vascular/metabolism , Tropoelastin/biosynthesis , Tunica Intima/metabolism , Animals , Carotid Arteries/cytology , Carotid Arteries/physiology , Catheterization , Cells, Cultured , Chondroitin Sulfate Proteoglycans/genetics , Elastic Tissue/ultrastructure , Elastin/metabolism , Elastin/ultrastructure , Gene Expression , Immunohistochemistry , Lectins, C-Type , Male , Muscle, Smooth, Vascular/cytology , Muscle, Smooth, Vascular/transplantation , Protein Isoforms/biosynthesis , Protein Isoforms/genetics , RNA, Messenger/analysis , RNA, Messenger/metabolism , Rats , Rats, Inbred F344 , Retroviridae/genetics , Time Factors , Transduction, Genetic , Tropoelastin/genetics , Tunica Intima/cytology , Tunica Intima/ultrastructure , Versicans
14.
Integr Biol (Camb) ; 8(3): 267-86, 2016 Mar 14.
Article in English | MEDLINE | ID: mdl-26928161

ABSTRACT

Consistently-biased left-right (LR) patterning is required for the proper placement of organs including the heart and viscera. The LR axis is especially fascinating as an example of multi-scale pattern formation, since here chiral events at the subcellular level are integrated and amplified into asymmetric transcriptional cascades and ultimately into the anatomical patterning of the entire body. In contrast to the other two body axes, there is considerable controversy about the earliest mechanisms of embryonic laterality. Many molecular components of asymmetry have not been widely tested among phyla with diverse bodyplans, and it is unknown whether parallel (redundant) pathways may exist that could reverse abnormal asymmetry states at specific checkpoints in development. To address conservation of the early steps of LR patterning, we used the Xenopus laevis (frog) embryo to functionally test a number of protein targets known to direct asymmetry in plants, fruit fly, and rodent. Using the same reagents that randomize asymmetry in Arabidopsis, Drosophila, and mouse embryos, we show that manipulation of the microtubule and actin cytoskeleton immediately post-fertilization, but not later, results in laterality defects in Xenopus embryos. Moreover, we observed organ-specific randomization effects and a striking dissociation of organ situs from effects on the expression of left side control genes, which parallel data from Drosophila and mouse. Remarkably, some early manipulations that disrupt laterality of transcriptional asymmetry determinants can be subsequently "rescued" by the embryo, resulting in normal organ situs. These data reveal the existence of novel corrective mechanisms, demonstrate that asymmetric expression of Nodal is not a definitive marker of laterality, and suggest the existence of amplification pathways that connect early cytoskeletal processes to control of organ situs bypassing Nodal. Counter to alternative models of symmetry breaking during neurulation (via ciliary structures absent in many phyla), our data suggest a widely-conserved role for the cytoskeleton in regulating left-right axis formation immediately after fertilization of the egg. The novel mechanisms that rescue organ situs, even after incorrect expression of genes previously considered to be left-side master regulators, suggest LR patterning as a new context in which to explore multi-scale redundancy and integration of patterning from the subcellular structure to the entire bodyplan.


Subject(s)
Body Patterning/physiology , Cytoskeleton/physiology , Animals , Arabidopsis , Body Patterning/genetics , Drosophila , Gene Expression Regulation, Developmental , Mice , Microtubules/physiology , Myosins/genetics , Myosins/metabolism , Protein Processing, Post-Translational , Tubulin/genetics , Tubulin/metabolism , Ubiquitin-Protein Ligases/genetics , Ubiquitin-Protein Ligases/metabolism , Xenopus laevis/embryology , Xenopus laevis/genetics
15.
Int J Dev Biol ; 59(7-9): 327-40, 2015.
Article in English | MEDLINE | ID: mdl-26198142

ABSTRACT

Bioelectric signals, particularly transmembrane voltage potentials (Vmem), play an important role in large-scale patterning during embryonic development. Endogenous bioelectric gradients across tissues function as instructive factors during eye, brain, and other morphogenetic processes. An important and still poorly-understood aspect is the control of cell behaviors by the voltage states of distant cell groups. Here, experimental alteration of endogenous Vmem was induced in Xenopus laevis embryos by misexpression of well-characterized ion channel mRNAs, a strategy often used to identify functional roles of Vmem gradients during embryonic development and regeneration. Immunofluorescence analysis (for activated caspase 3 and phosphor-histone H3P) on embryonic sections was used to characterize apoptosis and proliferation. Disrupting local bioelectric signals (within the developing neural tube region) increased caspase 3 and decreased H3P in the brain, resulting in brain mispatterning. Disrupting remote (ventral, non-neural region) bioelectric signals decreased caspase 3 and highly increased H3P within the brain, with normal brain patterning. Disrupting both the local and distant bioelectric signals produced antagonistic effects on caspase 3 and H3P. Thus, two components of bioelectric signals regulate apoptosis-proliferation balance within the developing brain and spinal cord: local (developing neural tube region) and distant (ventral non-neural region). Together, the local and long-range bioelectric signals create a binary control system capable of fine-tuning apoptosis and proliferation with the brain and spinal cord to achieve correct pattern and size control. Our data suggest a roadmap for utilizing bioelectric state as a diagnostic modality and convenient intervention parameter for birth defects and degenerative disease states of the CNS.


Subject(s)
Apoptosis/physiology , Body Patterning/physiology , Cell Proliferation/physiology , Membrane Potentials/physiology , Neural Tube/embryology , Animals , Caspase 3/metabolism , Histones/metabolism , Neural Tube/metabolism , Phosphorylation , Signal Transduction/physiology , Xenopus laevis/embryology , Xenopus laevis/metabolism
16.
Int J Dev Biol ; 58(10-12): 851-61, 2014.
Article in English | MEDLINE | ID: mdl-25896279

ABSTRACT

Developmental bioelectricity, electrical signaling among non-excitable cells, is now known to regulate proliferation, apoptosis, gene expression, and patterning during development. The extraordinary temporal and spatial resolution offered by optogenetics could revolutionize the study of bioelectricity the same way it has revolutionized neuroscience. There is, however, no guide to adapting optogenetics to patterning systems. To fill this gap, we used optogenetic reagents, both proteins and photochemical switches, to vary steady-state bioelectrical properties of non-spiking embryonic cells in Xenopus laevis. We injected mRNA for various proteins, including Channelrhodopsins and Archaerhodopsin, into 1-8 cell embryos, or soaked embryos in media containing photochemical switches, then examined the effect of light and dark on membrane voltage (Vmem) using both electrodes and fluorescent membrane voltage reporters. We also scored tadpoles for known effects of varying Vmem, including left-right asymmetry disruption, hyperpigmentation, and craniofacial phenotypes. The majority of reagents we tested caused a significant increase in the percentage of light-exposed tadpoles showing relevant phenotypes; however, the majority of reagents also induced phenotypes in controls kept in the dark. Experiments on this "dark phenotype" yielded evidence that the direction of ion flux via common optogenetic reagents may be reversed, or unpredictable in non-neural cells. When used in combination with rigorous controls, optogenetics can be a powerful tool for investigating ion-flux based signaling in non-excitable systems. Nonetheless, it is crucial that new reagents be designed with these non-neural cell types in mind.


Subject(s)
Body Patterning/physiology , Ion Transport/physiology , Light , Membrane Potentials/physiology , Optogenetics/methods , Animals , Archaeal Proteins/genetics , Cell Proliferation , Electricity , Embryo Culture Techniques , Embryo, Nonmammalian/cytology , Gene Expression Regulation , Gene Expression Regulation, Developmental , Larva/physiology , Patch-Clamp Techniques , Photochemical Processes , RNA, Messenger/genetics , Rhodopsin/genetics , Signal Transduction/physiology , Xenopus laevis
17.
Commun Integr Biol ; 6(6): e27155, 2013 Nov 01.
Article in English | MEDLINE | ID: mdl-24505508

ABSTRACT

For centuries, scientists and physicians have been captivated by the consistent left-right (LR) asymmetry of the heart, viscera, and brain. A recent study implicated tubulin proteins in establishing laterality in several experimental models, including asymmetric chemosensory receptor expression in C. elegans neurons, polarization of HL-60 human neutrophil-like cells in culture, and asymmetric organ placement in Xenopus. The same mutations that randomized asymmetry in these diverse systems also affect chirality in Arabidopsis, revealing a remarkable conservation of symmetry-breaking mechanisms among kingdoms. In Xenopus, tubulin mutants only affected LR patterning very early, suggesting that this axis is established shortly after fertilization. This addendum summarizes and extends the knowledge of the cytoskeleton's role in the patterning of the LR axis. Results from many species suggest a conserved role for the cytoskeleton as the initiator of asymmetry, and indicate that symmetry is first broken during early embryogenesis by an intracellular process.

18.
Dis Model Mech ; 6(1): 261-8, 2013 Jan.
Article in English | MEDLINE | ID: mdl-22899856

ABSTRACT

Consistent left-right (LR) patterning of the heart and viscera is a crucial part of normal embryogenesis. Because errors of laterality form a common class of birth defects, it is important to understand the molecular mechanisms and stage at which LR asymmetry is initiated. Frog embryos are a system uniquely suited to analysis of the mechanisms involved in orientation of the LR axis because of the many genetic and pharmacological tools available for use and the fate-map and accessibility of early blastomeres. Two major models exist for the origin of LR asymmetry and both implicate pre-nervous serotonergic signaling. In the first, the charged serotonin molecule is instructive for LR patterning; it is redistributed asymmetrically along the LR axis and signals intracellularly on the right side at cleavage stages. A second model suggests that serotonin is a permissive factor required to specify the dorsal region of the embryo containing chiral cilia that generate asymmetric fluid flow during neurulation, a much later process. We performed theory-neutral experiments designed to distinguish between these models. The results uniformly support a role for serotonin in the cleavage-stage embryo, long before the appearance of cilia, in ventral right blastomeres that do not contribute to the ciliated organ.


Subject(s)
Body Patterning/physiology , Serotonin/physiology , Xenopus laevis/embryology , Xenopus laevis/physiology , Animals , Blastomeres/cytology , Blastomeres/drug effects , Blastomeres/physiology , Body Patterning/drug effects , Cilia/physiology , Cleavage Stage, Ovum/cytology , Cleavage Stage, Ovum/drug effects , Cleavage Stage, Ovum/physiology , Gene Expression Regulation, Developmental , Models, Animal , Models, Biological , Serotonin/pharmacology , Serotonin Antagonists/pharmacology , Signal Transduction/drug effects , Xenopus Proteins/genetics , Xenopus Proteins/physiology , Xenopus laevis/genetics
19.
Mech Dev ; 130(4-5): 254-71, 2013.
Article in English | MEDLINE | ID: mdl-23354119

ABSTRACT

The earliest steps of left-right (LR) patterning in Xenopus embryos are driven by biased intracellular transport that ensures a consistently asymmetric localization of maternal ion channels and pumps in the first 2-4 blastomeres. The subsequent differential net efflux of ions by these transporters generates a bioelectrical asymmetry; this LR voltage gradient redistributes small signaling molecules along the LR axis that later regulate transcription of the normally left-sided Nodal. This system thus amplifies single cell chirality into a true left-right asymmetry across multi-cellular fields. Studies using molecular-genetic gain- and loss-of-function reagents have characterized many of the steps involved in this early pathway in Xenopus. Yet one key question remains: how is the chiral cytoskeletal architecture interpreted to localize ion transporters to the left or right side? Because Rab GTPases regulate nearly all aspects of membrane trafficking, we hypothesized that one or more Rab proteins were responsible for the directed, asymmetric shuttling of maternal ion channel or pump proteins. After performing a screen using dominant negative and wildtype (overexpressing) mRNAs for four different Rabs, we found that alterations in Rab11 expression randomize both asymmetric gene expression and organ situs. We also demonstrated that the asymmetric localization of two ion transporter subunits requires Rab11 function, and that Rab11 is closely associated with at least one of these subunits. Yet, importantly, we found that endogenous Rab11 mRNA and protein are expressed symmetrically in the early embryo. We conclude that Rab11-mediated transport is responsible for the movement of cargo within early blastomeres, and that Rab11 expression is required throughout the early embryo for proper LR patterning.


Subject(s)
Body Patterning , Xenopus laevis/embryology , Xenopus laevis/metabolism , rab GTP-Binding Proteins/metabolism , Animals , Cell Polarity , Cilia/metabolism , Embryo, Nonmammalian/cytology , Embryo, Nonmammalian/metabolism , Epistasis, Genetic , Gene Expression Regulation, Developmental , Genes, Dominant , Humans , Ion Transport/genetics , Models, Biological , Proteolipids/metabolism , RNA, Messenger/genetics , RNA, Messenger/metabolism , Signal Transduction/genetics , Vacuolar Proton-Translocating ATPases/metabolism , Xenopus laevis/genetics , rab GTP-Binding Proteins/genetics
20.
Stem Cells Dev ; 21(12): 2085-94, 2012 Aug 10.
Article in English | MEDLINE | ID: mdl-22339734

ABSTRACT

The ability to stop producing or replacing cells at the appropriate time is essential, as uncontrolled growth can lead to loss of function and even cancer. Tightly regulated mechanisms coordinate the growth of stem cell progeny with the patterning needs of the host organism. Despite the importance of proper termination during regeneration, cell turnover, and embryonic development, very little is known about how tissues determine when patterning is complete during these processes. Using planarian flatworms, we show that the planar cell polarity (PCP) pathway is required to stop the growth of neural tissue. Although traditionally studied as regulators of tissue polarity, we found that loss of the PCP genes Vangl2, DAAM1, and ROCK by RNA interference (individually or together) resulted in supernumerary eyes and excess optical neurons in intact planarians, while regenerating planarians had continued hyperplasia throughout the nervous system long after controls ceased new growth. This failure to terminate growth suggests that neural tissues use PCP as a readout of patterning, highlighting a potential role for intact PCP as a signal to stem and progenitor cells to halt neuronal growth when patterning is finished. Moreover, we found this mechanism to be conserved in vertebrates. Loss of Vangl2 during normal development, as well as during Xenopus tadpole tail regeneration, also leads to the production of excess neural tissue. This evolutionarily conserved function of PCP represents a tractable new approach for controlling the growth of nerves.


Subject(s)
Cell Polarity , Homeostasis , Nerve Regeneration , Planarians/cytology , Adult Stem Cells/physiology , Animals , Cell Proliferation , Cloning, Molecular , Eye/innervation , Gene Knockdown Techniques , Helminth Proteins/genetics , Helminth Proteins/metabolism , In Situ Hybridization , Intracellular Signaling Peptides and Proteins/genetics , Intracellular Signaling Peptides and Proteins/metabolism , Larva/genetics , Larva/physiology , Nervous System/cytology , Nervous System/growth & development , Nervous System/metabolism , Planarians/genetics , Planarians/growth & development , Planarians/physiology , RNA Interference , Xenopus/genetics , Xenopus/physiology , rho-Associated Kinases/genetics , rho-Associated Kinases/metabolism
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