Your search keyword '"Leah J Campbell"' showing total 15 results

1. Retinal regeneration requires dynamic Notch signaling

Author

Leah J Campbell, Jaclyn L Levendusky, Shannon A Steines, and David R Hyde

Subjects

differentiation, gliosis, müller glia, neuronal progenitor cell, notch signaling, proliferation, quiescence, retinal development, retinal regeneration, zebrafish, Neurology. Diseases of the nervous system, RC346-429

Abstract

Retinal damage in the adult zebrafish induces Müller glia reprogramming to produce neuronal progenitor cells that proliferate and differentiate into retinal neurons. Notch signaling, which is a fundamental mechanism known to drive cell-cell communication, is required to maintain Müller glia in a quiescent state in the undamaged retina, and repression of Notch signaling is necessary for Müller glia to reenter the cell cycle. The dynamic regulation of Notch signaling following retinal damage also directs proliferation and neurogenesis of the Müller glia-derived progenitor cells in a robust regeneration response. In contrast, mammalian Müller glia respond to retinal damage by entering a prolonged gliotic state that leads to additional neuronal death and permanent vision loss. Understanding the dynamic regulation of Notch signaling in the zebrafish retina may aid efforts to stimulate Müller glia reprogramming for regeneration of the diseased human retina. Recent findings identified DeltaB and Notch3 as the ligand-receptor pair that serves as the principal regulators of zebrafish Müller glia quiescence. In addition, multi-omics datasets and functional studies indicate that additional Notch receptors, ligands, and target genes regulate cell proliferation and neurogenesis during the regeneration time course. Still, our understanding of Notch signaling during retinal regeneration is limited. To fully appreciate the complex regulation of Notch signaling that is required for successful retinal regeneration, investigation of additional aspects of the pathway, such as post-translational modification of the receptors, ligand endocytosis, and interactions with other fundamental pathways is needed. Here we review various modes of Notch signaling regulation in the context of the vertebrate retina to put recent research in perspective and to identify open areas of inquiry.

Published

2022

2. Two types of Tet-On transgenic lines for doxycycline-inducible gene expression in zebrafish rod photoreceptors and a gateway-based tet-on toolkit.

Author

Leah J Campbell, John J Willoughby, and Abbie M Jensen

Subjects

Medicine, Science

Abstract

The ability to control transgene expression within specific tissues is an important tool for studying the molecular and cellular mechanisms of development, physiology, and disease. We developed a Tet-On system for spatial and temporal control of transgene expression in zebrafish rod photoreceptors. We generated two transgenic lines using the Xenopus rhodopsin promoter to drive the reverse tetracycline-controlled transcriptional transactivator (rtTA), one with self-reporting GFP activity and one with an epitope tagged rtTA. The self-reporting line includes a tetracycline response element (TRE)-driven GFP and, in the presence of doxycycline, expresses GFP in larval and adult rods. A time-course of doxycycline treatment demonstrates that maximal induction of GFP expression, as determined by the number of GFP-positive rods, is reached within approximately 24 hours of drug treatment. The epitope-tagged transgenic line eliminates the need for the self-reporting GFP activity by expressing a FLAG-tagged rtTA protein. Both lines demonstrate strong induction of TRE-driven transgenes from plasmids microinjected into one-cell embryos. These results show that spatial and temporal control of transgene expression can be achieved in rod photoreceptors. Additionally, system components are constructed in Gateway compatible vectors for the rapid cloning of doxycycline-inducible transgenes and use in other areas of zebrafish research.

Published

2012

3. Microarray analysis of microRNA expression during axolotl limb regeneration.

Author

Edna C Holman, Leah J Campbell, John Hines, and Craig M Crews

Subjects

Medicine, Science

Abstract

Among vertebrates, salamanders stand out for their remarkable capacity to quickly regrow a myriad of tissues and organs after injury or amputation. The limb regeneration process in axolotls (Ambystoma mexicanum) has been well studied for decades at the cell-tissue level. While several developmental genes are known to be reactivated during this epimorphic process, less is known about the role of microRNAs in urodele amphibian limb regeneration. Given the compelling evidence that many microRNAs tightly regulate cell fate and morphogenetic processes through development and adulthood by modulating the expression (or re-expression) of developmental genes, we investigated the possibility that microRNA levels change during limb regeneration. Using two different microarray platforms to compare the axolotl microRNA expression between mid-bud limb regenerating blastemas and non-regenerating stump tissues, we found that miR-21 was overexpressed in mid-bud blastemas compared to stump tissue. Mature A. mexicanum ("Amex") miR-21 was detected in axolotl RNA by Northern blot and differential expression of Amex-miR-21 in blastema versus stump was confirmed by quantitative RT-PCR. We identified the Amex Jagged1 as a putative target gene for miR-21 during salamander limb regeneration. We cloned the full length 3'UTR of Amex-Jag1, and our in vitro assays demonstrated that its single miR-21 target recognition site is functional and essential for the response of the Jagged1 gene to miR-21 levels. Our findings pave the road for advanced in vivo functional assays aimed to clarify how microRNAs such as miR-21, often linked to pathogenic cell growth, might be modulating the redeployment of developmental genes such as Jagged1 during regenerative processes.

Published

2012

4. Common and divergent gene regulatory networks control injury-induced and developmental neurogenesis in zebrafish retina

Author

Pin Lyu, Maria Iribarne, Dmitri Serjanov, Yijie Zhai, Thanh Hoang, Leah J. Campbell, Patrick Boyd, Isabella Palazzo, Mikiko Nagashima, Nicholas J. Silva, Peter F. Hitchcock, Jiang Qian, David R. Hyde, and Seth Blackshaw

Subjects

Science

Abstract

Abstract Following acute retinal damage, zebrafish possess the ability to regenerate all neuronal subtypes through Müller glia (MG) reprogramming and asymmetric cell division that produces a multipotent Müller glia-derived neuronal progenitor cell (MGPC). This raises three key questions. First, do MG reprogram to a developmental retinal progenitor cell (RPC) state? Second, to what extent does regeneration recapitulate retinal development? And finally, does loss of different retinal cell subtypes induce unique MG regeneration responses? We examined these questions by performing single-nuclear and single-cell RNA-Seq and ATAC-Seq in both developing and regenerating retinas. Here we show that injury induces MG to reprogram to a state similar to late-stage RPCs. However, there are major transcriptional differences between MGPCs and RPCs, as well as major transcriptional differences between activated MG and MGPCs when different retinal cell subtypes are damaged. Validation of candidate genes confirmed that loss of different subtypes induces differences in transcription factor gene expression and regeneration outcomes.

Published

2023

5. Clcf1/Crlf1a-mediated signaling is neuroprotective and required for Müller glia proliferation in the light-damaged zebrafish retina

Author

Patrick Boyd, Leah J. Campbell, and David R. Hyde

Subjects

zebrafish, retina, regeneration, Müller glia, CLCF1, CNTFR, Biology (General), QH301-705.5

Abstract

Zebrafish possess the innate ability to fully regenerate any neurons lost following a retinal injury. This response is mediated by Müller glia that reprogram and divide asymmetrically to produce neuronal precursor cells that differentiate into the lost neurons. However, little is understood about the early signals that induce this response. Ciliary neurotrophic factor (CNTF) was previously shown to be both neuroprotective and pro-proliferative within the zebrafish retina, however CNTF is not expressed following injury. Here we demonstrate that alternative ligands of the Ciliary neurotrophic factor receptor (CNTFR), such as Cardiotrophin-like cytokine factor 1 (Clcf1) and Cytokine receptor-like factor 1a (Crlf1a), are expressed within Müller glia of the light-damaged retina. We found that CNTFR, Clcf1, and Crlf1a are required for Müller glia proliferation in the light-damaged retina. Furthermore, intravitreal injection of CLCF1/CRLF1 protected against rod photoreceptor cell death in the light-damaged retina and induced proliferation of rod precursor cells in the undamaged retina, but not Müller glia. While rod precursor cell proliferation was previously shown to be Insulin-like growth factor 1 receptor (IGF-1R)-dependent, co-injection of IGF-1 with CLCF1/CRLF1 failed to induce further proliferation of either Müller glia or rod precursor cells. Together, these findings demonstrate that CNTFR ligands have a neuroprotective effect and are required for induction of Müller glia proliferation in the light-damaged zebrafish retina.

Published

2023

6. Retinal regeneration requires dynamic Notch signaling

Author

Jaclyn L Levendusky, Leah J. Campbell, David R. Hyde, and Shannon A Steines

Subjects

Müller glia, proliferation, Notch signaling pathway, Context (language use), Review, Biology, Developmental Neuroscience, medicine, quiescence, RC346-429, Zebrafish, neuronal progenitor cell, Notch signaling, retinal regeneration, Retinal regeneration, Retina, retinal development, Regeneration (biology), Neurogenesis, differentiation, biology.organism_classification, zebrafish, medicine.anatomical_structure, gliosis, müller glia, notch signaling, Neurology. Diseases of the nervous system, sense organs, Neuroscience, Muller glia

Abstract

Retinal damage in the adult zebrafish induces Müller glia reprogramming to produce neuronal progenitor cells that proliferate and differentiate into retinal neurons. Notch signaling, which is a fundamental mechanism known to drive cell-cell communication, is required to maintain Müller glia in a quiescent state in the undamaged retina, and repression of Notch signaling is necessary for Müller glia to reenter the cell cycle. The dynamic regulation of Notch signaling following retinal damage also directs proliferation and neurogenesis of the Müller glia-derived progenitor cells in a robust regeneration response. In contrast, mammalian Müller glia respond to retinal damage by entering a prolonged gliotic state that leads to additional neuronal death and permanent vision loss. Understanding the dynamic regulation of Notch signaling in the zebrafish retina may aid efforts to stimulate Müller glia reprogramming for regeneration of the diseased human retina. Recent findings identified DeltaB and Notch3 as the ligand-receptor pair that serves as the principal regulators of zebrafish Müller glia quiescence. In addition, multi-omics datasets and functional studies indicate that additional Notch receptors, ligands, and target genes regulate cell proliferation and neurogenesis during the regeneration time course. Still, our understanding of Notch signaling during retinal regeneration is limited. To fully appreciate the complex regulation of Notch signaling that is required for successful retinal regeneration, investigation of additional aspects of the pathway, such as post-translational modification of the receptors, ligand endocytosis, and interactions with other fundamental pathways is needed. Here we review various modes of Notch signaling regulation in the context of the vertebrate retina to put recent research in perspective and to identify open areas of inquiry.

Published

2021

7. Prophylactic Activation of Shh Signaling Attenuates TBI-Induced Seizures in Zebrafish by Modulating Glutamate Excitotoxicity through Eaat2a

Author

James Hentig, Leah J. Campbell, Kaylee Cloghessy, Mijoon Lee, William Boggess, and David R. Hyde

Subjects

post-traumatic seizures, QH301-705.5, traumatic brain injury, Medicine (miscellaneous), zebrafish, Article, General Biochemistry, Genetics and Molecular Biology, nervous system diseases, nervous system, sonic hedgehog signaling, blunt-force TBI, purmorphamine, Biology (General)

Abstract

Approximately 2 million individuals experience a traumatic brain injury (TBI) every year in the United States. Secondary injury begins within minutes after TBI, with alterations in cellular function and chemical signaling that contribute to excitotoxicity. Post-traumatic seizures (PTS) are experienced in an increasing number of TBI individuals that also display resistance to traditional anti-seizure medications (ASMs). Sonic hedgehog (Shh) is a signaling pathway that is upregulated following central nervous system damage in zebrafish and aids injury-induced regeneration. Using a modified Marmarou weight drop on adult zebrafish, we examined PTS following TBI and Shh modulation. We found that inhibiting Shh signaling by cyclopamine significantly increased PTS in TBI fish, prolonged the timeframe PTS was observed, and decreased survival across all TBI severities. Shh-inhibited TBI fish failed to respond to traditional ASMs, but were attenuated when treated with CNQX, which blocks ionotropic glutamate receptors. We found that the Smoothened agonist, purmorphamine, increased Eaat2a expression in undamaged brains compared to untreated controls, and purmorphamine treatment reduced glutamate excitotoxicity following TBI. Similarly, purmorphamine reduced PTS, edema, and cognitive deficits in TBI fish, while these pathologies were increased and/or prolonged in cyclopamine-treated TBI fish. However, the increased severity of TBI phenotypes with cyclopamine was reduced by cotreating fish with ceftriaxone, which induces Eaat2a expression. Collectively, these data suggest that Shh signaling induces Eaat2a expression and plays a role in regulating TBI-induced glutamate excitotoxicity and TBI sequelae.

Published

2021

8. Phosphodiesterase Inhibitors Sildenafil and Vardenafil Reduce Zebrafish Rod Photoreceptor Outer Segment Shedding

Author

Abbie M. Jensen and Leah J. Campbell

Subjects

0301 basic medicine, photoreceptor renewal, genetic structures, Sildenafil, Dark Adaptation, Sildenafil Citrate, Cell Line, Animals, Genetically Modified, 03 medical and health sciences, chemistry.chemical_compound, rods, Vardenafil Dihydrochloride, medicine, Animals, Zebrafish, Cyclic GMP, biology, Cilium, outer segments, Phosphodiesterase, Anatomy, Rod Cell Outer Segment, Phosphodiesterase 5 Inhibitors, biology.organism_classification, Cell biology, cGMP, 030104 developmental biology, chemistry, Retinal Cell Biology, Cell culture, Vardenafil, Models, Animal, sense organs, Visual phototransduction, medicine.drug

Abstract

Purpose The vertebrate rod photoreceptor undergoes daily growth and shedding to renew the rod outer segment (ROS), a modified cilium that contains the phototransduction machinery. It has been demonstrated that ROS shedding is regulated by the light-dark cycle; however, we do not yet have a satisfactory understanding of the molecular mechanisms that underlie this regulation. Given that phototransduction relies on the hydrolysis of cGMP via phosphodiesterase 6 (PDE6), we examined ROS growth and shedding in zebrafish treated with cGMP-specific PDE inhibitors. Methods We used transgenic zebrafish that express an inducible, transmembrane-bound mCherry protein, which forms a stripe in the ROS following a heat shock pulse and serves as a marker of ROS renewal. Zebrafish were reared in constant darkness or treated with PDE inhibitors following heat shock. Measurements of growth and shedding were analyzed in confocal z-stacks collected from treated retinas. Results As in dark-reared zebrafish, shedding was reduced in larvae and adults treated with the PDE5/6 inhibitors sildenafil and vardenafil but not with the PDE5 inhibitor tadalafil. In addition, vardenafil noticeably affected rod inner segment morphology. The inhibitory effect of sildenafil on shedding was reversible with drug removal. Finally, cones were more sensitive than rods to the toxic effects of sildenafil and vardenafil. Conclusions We show that pharmacologic inhibition of PDE6 mimics the inhibition of shedding by prolonged constant darkness. The data show that the influence of the light-dark cycle on ROS renewal is regulated, in part, by initiating the shedding process through activation of the phototransduction machinery.

Published

2017

9. Notch3 and DeltaB maintain Müller glia quiescence and act as negative regulators of regeneration in the light-damaged zebrafish retina

Author

Rebecca I Hipp, David R. Hyde, Patrick Boyd, Joshua S. Hobgood, Meng Jia, and Leah J. Campbell

Subjects

0301 basic medicine, Ependymoglial Cells, Notch signaling pathway, Biology, Retina, Animals, Genetically Modified, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, medicine, Animals, Zebrafish, Receptor, Notch3, Retinal regeneration, Cell Proliferation, Gene knockdown, Receptors, Notch, Regeneration (biology), Morphant, biology.organism_classification, Cell biology, 030104 developmental biology, medicine.anatomical_structure, nervous system, Neurology, sense organs, Muller glia, Neuroglia, 030217 neurology & neurosurgery

Abstract

Damage to the zebrafish retina stimulates resident Muller glia to reprogram, reenter the cell cycle, divide asymmetrically, and produce neuronal progenitor cells that amplify and differentiate into the lost neurons. The transition from quiescent to proliferative Muller glia involves both positive and negative regulators. We previously demonstrated that the Notch signaling pathway represses retinal regeneration by maintaining Muller glia quiescence in zebrafish. Here we examine which Notch receptor is necessary to maintain quiescence. Quantitative RT-PCR and RNA-Seq analyses reveal that notch3 is expressed in the undamaged retina and is downregulated in response to light damage. Additionally, Notch3 protein is expressed in quiescent Muller glia of the undamaged retina, is downregulated as Muller glia proliferate, and is reestablished in the Muller glia. Knockdown of Notch3 is sufficient to induce Muller glia proliferation in undamaged retinas and enhances proliferation during light damage. Alternatively, knockdown of Notch1a, Notch1b, or Notch2 decreases the number of proliferating cells during light damage, suggesting that Notch signaling is also required for proliferation during retinal regeneration. We also knockdown the zebrafish Delta and Delta-like proteins, ligands for the Notch receptors, and find that the deltaB morphant possesses an increased number of proliferating cells in the light-damaged retina. As with Notch3, knockdown of DeltaB is sufficient to induce Muller glia proliferation in the absence of light damage. Taken together, the negative regulation of Muller glia proliferation in zebrafish retinal regeneration is mediated by Notch3 and DeltaB.

Published

2019

10. A high content, small molecule screen identifies candidate molecular pathways that regulate rod photoreceptor outer segment renewal

Author

Abbie M. Jensen, Leah J. Campbell, and Megan C. West

Subjects

0301 basic medicine, Rhodopsin, Hot Temperature, Drug Evaluation, Preclinical, lcsh:Medicine, Animals, Genetically Modified, 03 medical and health sciences, Genes, Reporter, medicine, Animals, Cyclooxygenase Inhibitors, Stem Cell Niche, Eye Proteins, lcsh:Science, Zebrafish, PI3K/AKT/mTOR pathway, Multidisciplinary, Retinal pigment epithelium, biology, Chemistry, Cilium, lcsh:R, Zebrafish Proteins, Rod Cell Outer Segment, biology.organism_classification, Photoreceptor outer segment, Cell biology, 030104 developmental biology, medicine.anatomical_structure, biology.protein, lcsh:Q, Signal transduction, Metabolic Networks and Pathways, Signal Transduction, Visual phototransduction

Abstract

The outer segment of the vertebrate rod photoreceptor is a highly modified cilium composed of many discrete membranous discs that are filled with the protein machinery necessary for phototransduction. The unique outer segment structure is renewed daily with growth at the base of the outer segment where new discs are formed and shedding at the distal end where old discs are phagocytized by the retinal pigment epithelium. In order to understand how outer segment renewal is regulated to maintain outer segment length and function, we used a small molecule screening approach with the transgenic (hsp70:HA-mCherryTM) zebrafish, which expresses a genetically-encoded marker of outer segment renewal. We identified compounds with known bioactivity that affect five content areas: outer segment growth, outer segment shedding, clearance of shed outer segment tips, Rhodopsin mislocalization, and differentiation at the ciliary marginal zone. Signaling pathways that are targeted by the identified compounds include cyclooxygenase in outer segment growth, γ-Secretase in outer segment shedding, and mTor in RPE phagocytosis. The data generated by this screen provides a foundation for further investigation of the signaling pathways that regulate photoreceptor outer segment renewal.

Published

2018

11. Opportunities for CRISPR/Cas9 Gene Editing in Retinal Regeneration Research

Author

Leah J. Campbell and David R. Hyde

Subjects

0301 basic medicine, Retinal degeneration, retina, Müller glia, Computational biology, Review, Biology, 03 medical and health sciences, Cell and Developmental Biology, Genome editing, medicine, CRISPR, Zebrafish, CRISPR/Cas9, lcsh:QH301-705.5, neuronal progenitor cell, Retinal regeneration, Genetics, Cas9, Regeneration (biology), Cell Biology, medicine.disease, biology.organism_classification, zebrafish, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), regeneration, Muller glia, Developmental Biology

Abstract

While retinal degeneration and disease results in permanent damage and vision loss in humans, the severely damaged zebrafish retina has a high capacity to regenerate lost neurons and restore visual behaviors. Advancements in understanding the molecular and cellular basis of this regeneration response give hope that strategies and therapeutics may be developed to restore sight to blind and visually-impaired individuals. Our current understanding has been facilitated by the amenability of zebrafish to molecular tools, imaging techniques, and forward and reverse genetic approaches. Accordingly, the zebrafish research community has developed a diverse array of research tools for use in developing and adult animals, including toolkits for facilitating the generation of transgenic animals, systems for inducible, cell-specific transgene expression, and the creation of knockout alleles for nearly every protein coding gene. As CRISPR/Cas9 genome editing has begun to revolutionize molecular biology research, the zebrafish community has responded in stride by developing CRISPR/Cas9 techniques for the zebrafish as well as incorporating CRISPR/Cas9 into available toolsets. The application of CRISPR/Cas9 to retinal regeneration research will undoubtedly bring us closer to understanding the mechanisms underlying retinal repair and vision restoration in the zebrafish, as well as developing therapeutic approaches that will restore vision to blind and visually-impaired individuals. This review focuses on how CRISPR/Cas9 has been integrated into zebrafish research toolsets and how this new tool will revolutionize the field of retinal regeneration research.

Published

2017

12. Two types of transgenic lines for doxycycline-inducible, cell-specific gene expression in zebrafish ultraviolet cone photoreceptors

Author

Abbie M. Jensen, Leah J. Campbell, Megan C. West, and John J. Willoughby

Subjects

animal structures, Transgene, Genetic Vectors, Fluorescent Antibody Technique, Biology, Response Elements, Article, Cell Line, Green fluorescent protein, Animals, Genetically Modified, Transactivation, Gene Order, Gene expression, Genetics, Animals, Molecular Biology, Gene, Zebrafish, Regulation of gene expression, biology.organism_classification, Molecular biology, Gene Expression Regulation, Organ Specificity, Cell culture, Doxycycline, Retinal Cone Photoreceptor Cells, Trans-Activators, sense organs, Developmental Biology

Abstract

Temporal and spatial control of gene expression is important for studying the molecular and cellular mechanisms of development, physiology, and disease. We used the doxycycline (Dox)-inducible, Tet-On system to develop transgenic zebrafish for inducible, cell specific control of gene expression in the ultraviolet (UV) cone photoreceptors. Two constructs containing the reverse tetracycline-controlled transcriptional transactivator (rtTA) gene driven by the UV opsin-specific promoter (opn1sw1) were used to generate stable transgenic zebrafish lines using the Tol2-based transgenesis method. One construct included a self-reporting GFP (opn1sw1:rtTA, TRE:GFP) and the other incorporated an epitope tag on the rtTA protein (opn1sw1:rtTA(flag)). UV cone-specific expression of TRE-controlled transgenes was induced by Dox treatment in larvae and adults. Induction of gene expression was observed in 96% of all larval UV cones within 16 h of Dox treatment. UV cone-specific expression of two genes from a bidirectional TRE construct injected into one-cell Tg(opn1sw1:rtTA(flag)) embryos were also induced by Dox treatment. In addition, UV cone-specific expression of Crb2a(IntraWT) was induced by Dox treatment in progeny from crosses of the TRE-response transgenic line, Tg(TRE:HA-Crb2a(IntraWT)), to the Tg(opn1sw1:rtTA, TRE:GFP) line and the Tg(opn1sw1:rtTA(flag)) line. These lines can be used in addition to the inducible, rod-specific gene expression system from the Tet-On Toolkit to elucidate the photoreceptor-specific effects of genes of interest in photoreceptor cell biology and retinal disease.

Published

2014

13. Molecular and Cellular Basis of Regeneration and Tissue Repair

Author

Leah J. Campbell and Craig M. Crews

Subjects

Pharmacology, integumentary system, Cell division, Epidermis (botany), medicine.medical_treatment, Regeneration (biology), Cell migration, Cell Biology, Anatomy, Biology, Cell biology, body regions, Cellular and Molecular Neuroscience, Amputation, medicine, Molecular Medicine, Wound healing, Molecular Biology, Blastema, Process (anatomy)

Abstract

Upon amputation of the urodele limb, the epidermal cells surrounding the amputation plane migrate to heal the wound. The resulting wound epidermis (WE) induces the regeneration process, resulting in blastema formation, cell division, and ultimately repatterning into a new limb. Despite its central role in the initiation of limb regeneration, little is known about how the WE forms. Here we discuss various models of WE formation and the experimental data in support of each. (Part of a Multi-author Review)

Published

2007

14. Gene expression profile of the regeneration epithelium during axolotl limb regeneration

Author

Dunja Knapp, Craig M. Crews, Elly M. Tanaka, Edna C. Suárez-Castillo, Leah J. Campbell, and Humberto Ortiz-Zuazaga

Subjects

Expressed sequence tag, biology, Microarray analysis techniques, Regeneration (biology), Gene Expression Profiling, biology.organism_classification, Molecular biology, Amphibian Proteins, Epithelium, Article, Gene expression profiling, Ambystoma mexicanum, Epidermis (zoology), Axolotl, Gene expression, Animals, Regeneration, Gene, In Situ Hybridization, Developmental Biology, Oligonucleotide Array Sequence Analysis

Abstract

Urodele amphibians are unique amongst adult vertebrates in their ability to regenerate missing limbs. The process of limb regeneration requires several key tissues including a regeneration-competent wound epidermis called the regeneration epithelium (RE). We used microarray analysis to profile gene expression of the RE in the axolotl, a Mexican salamander. A list of 125 genes and expressed sequence tags (ESTs) showed a ≥1.5 fold expression in the RE than in a wound epidermis covering a lateral cuff wound. A subset of the RE ESTs and genes were further characterized for expression level changes over the time-course of regeneration. This study provides the first large scale identification of specific gene expression in the RE.

Published

2011

15. Microarray Analysis of microRNA Expression during Axolotl Limb Regeneration

Author

Craig M. Crews, John Hines, Edna C. Holman, and Leah J. Campbell

Subjects

Cellular differentiation, Limb Development, Gene Expression, lcsh:Medicine, Biochemistry, 0302 clinical medicine, Morphogenesis, Cluster Analysis, Serrate-Jagged Proteins, lcsh:Science, 0303 health sciences, Multidisciplinary, Gene Expression Regulation, Developmental, Cell biology, 030220 oncology & carcinogenesis, Intercellular Signaling Peptides and Proteins, Blastema, Research Article, Molecular Sequence Data, Biology, Cell fate determination, Cell Line, Molecular Genetics, 03 medical and health sciences, Axolotl, Regeneration, Animals, Gene Regulation, Ambystoma mexicanum, 030304 developmental biology, Base Sequence, Herpetology, Microarray analysis techniques, Gene Expression Profiling, Regeneration (biology), Calcium-Binding Proteins, lcsh:R, Computational Biology, Membrane Proteins, Extremities, Molecular Development, biology.organism_classification, Molecular biology, body regions, Gene expression profiling, MicroRNAs, Small Molecules, lcsh:Q, Organism Development, Zoology, Developmental Biology

Abstract

Among vertebrates, salamanders stand out for their remarkable capacity to quickly regrow a myriad of tissues and organs after injury or amputation. The limb regeneration process in axolotls (Ambystoma mexicanum) has been well studied for decades at the cell-tissue level. While several developmental genes are known to be reactivated during this epimorphic process, less is known about the role of microRNAs in urodele amphibian limb regeneration. Given the compelling evidence that many microRNAs tightly regulate cell fate and morphogenetic processes through development and adulthood by modulating the expression (or re-expression) of developmental genes, we investigated the possibility that microRNA levels change during limb regeneration. Using two different microarray platforms to compare the axolotl microRNA expression between mid-bud limb regenerating blastemas and non-regenerating stump tissues, we found that miR-21 was overexpressed in mid-bud blastemas compared to stump tissue. Mature A. mexicanum ("Amex") miR-21 was detected in axolotl RNA by Northern blot and differential expression of Amex-miR-21 in blastema versus stump was confirmed by quantitative RT-PCR. We identified the Amex Jagged1 as a putative target gene for miR-21 during salamander limb regeneration. We cloned the full length 3'UTR of Amex-Jag1, and our in vitro assays demonstrated that its single miR-21 target recognition site is functional and essential for the response of the Jagged1 gene to miR-21 levels. Our findings pave the road for advanced in vivo functional assays aimed to clarify how microRNAs such as miR-21, often linked to pathogenic cell growth, might be modulating the redeployment of developmental genes such as Jagged1 during regenerative processes.

Published

2012